US20140031254A1

US20140031254A1 - Detection of chromosomal abnormalities associated with endometrial cancer

Info

Publication number: US20140031254A1
Application number: US13/951,209
Authority: US
Inventors: Ekaterina Pestova; Larry Morrison; Jesse S. Voss; Lisa M. Peterson; Kevin C. Halling
Original assignee: Mayo Foundation for Medical Education and Research; Abbott Molecular Inc
Current assignee: Mayo Foundation for Medical Education and Research; Abbott Molecular Inc
Priority date: 2010-05-10
Filing date: 2013-07-25
Publication date: 2014-01-30
Also published as: EP2569624A1; EP2569624A4; WO2011142818A1; US20120065085A1; US20160304963A1; US10584388B2; EP2569624B1; CA2798190A1; ES2621812T3

Abstract

The methods and compositions described herein address the need for diagnostic method that could be offered to women during yearly checkups to allow for early detection, diagnosis and classification, and treatment of endometrial cancer. In addition, these methods and compositions address the current need for improving diagnostic accuracy of biopsy procedures in symptomatic patients.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 13/068,451, filed May 10, 2011, which claims the benefit of U.S. provisional application No. 61/395,303, filed May 10, 2010, which are hereby incorporated by reference in their entireties.

FIELD OF THE INVENTION

The present invention relates generally to the area of detecting, diagnosing, and monitoring of endometrial hyperplasia and carcinoma.

BACKGROUND OF THE INVENTION

Uterine cancer is the fourth most common malignancy diagnosed in women in the United States (estimated 42,793 cases in 2009) and is the seventh most common cause of cancer death among U.S. women. Over 95% of all uterine cancers are cancers of the endometrium (lining of the body of the uterus). Lifetime probability of developing cancer of the uterus is 1 in 40 (U.S.). 35-50% of women ages 35-70 present with one or more risk factors for endometrial cancer.
Two different clinicopathologic subtypes are recognized based on light microscopic appearance, clinical behavior, and epidemiology: the estrogen-related (type I, endometrioid) and the non-estrogen-related types (type II, nonendometrioid such as papillary serous and clear cell). Despite it aggressiveness, endometrial cancer is difficult to diagnose, thus many patients present with symptoms of the late-stage cancer.

SUMMARY OF THE INVENTION

In particular embodiments, the present invention provides a method of detecting the presence of endometrial carcinoma in a biological sample from a subject. The method entails contacting the sample with one or more probes for one or more chromosome regions selected from the group consisting of: 1q, 2p, 2q, 3p, 3q, 7p, 8p, 8q, 9p, 9q, the centromeric region of chromosome 10, 10q, 15q, 16q, 17p, the centromeric region of chromosome 18, 18q, 19p, 20q, and 22q. The one or more probes are incubated with the sample under conditions in which each probe binds selectively with a polynucleotide sequence on its target chromosome or chromosomal region to form a stable hybridization complex. Hybridization of the one or more probes is detected, wherein a hybridization pattern showing at least one gain or loss or imbalance at a chromosomal region targeted by the probes is indicative of endometrial carcinoma.
In certain embodiments, a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 1q, 2p, 3q, 8q, 10q, and 20q is indicative of endometrial carcinoma. In specific embodiments, a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 1q, 10p, and 10q is indicative of endometrioid carcinoma. In other specific embodiments, a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 3q, 8q, 18q, and 20q is indicative of non-endometrioid carcinoma. In an illustrative embodiment, a hybridization pattern showing a gain in 1q31-qtel is indicative of endometrial carcinoma.
In certain embodiments, a hybridization pattern showing a loss in one or more chromosome regions selected from the group consisting of: 9p, 9q, 15q, 16q, 17p, 18q, 19p, and 22q is indicative of endometrial carcinoma. In illustrative embodiments, a hybridization pattern showing a loss in one or more chromosome regions selected from the group consisting of: 15q11-q13, 18q21, and 19ptel is indicative of endometrial carcinoma.
In certain embodiments, the one or more probes are for one or more chromosome subregions selected from the group consisting of: 1q25, 2p24, 2q26, 3p21, 3q27-q29, 7p21, 8p11, 8q24, 9q34, the centromeric region of chromosome 10, 10q23, 10q26, 15q11-q13, 16q24, the centromeric region of chromosome 18, 18q21, 20q12 and 20q13.
In particular embodiments, the sample is contacted with a combination of at least 3 probes for a set of chromosome subregions selected from the group consisting of:

- 1q25, 8q24, 15q11-q13;
- 1q25, 10q26, 15q11-q13;
- 1q25, 2p24, 8q24
- 1q25, 8q24, 10q26;
- 1q25, 8p11, 15q11-q13;
- 1q25, 2p24, 8p11;
- 1q25, 8p11, 10q26;
- 1q25, 8p11, 8q24;
- 1q25, 2p24, 10q26;
- 1q25, 2p24, 15q11-q13;
- 8q24, 10q26, 15q11-q13;
- 1q25, 8p11, 20q13;
- 1q25, 8q24, 20q13;
- 1q25, 15q11-q13, 20q13;
- 1q25, 10q26, 20q13;
- 8p11, 10q26, 15q11-q13;
- 1q25, 2p24, 20q13;
- 2p24, 8p11, 10q26;
- 2p24, 8q24, 10q26;
- 2p24, 10q26, 15q11-q13;
- 2p24, 8q24, 15q11-q13;
- 10q26, 15q11-q13, 20q13;
- 1q25, 8p11, 18q21;
- 1q25, 8q24, 18q21;
- 1q25, 10q26, 18q21;
- 1q25, 15q11-q13, 18q21;
- 8p11, 8q24, 10q26;
- 8q24, 10q26, 20q13;
- 1q25, 2p24, 18q21;
- 2p24, 8p11, 8q24;
- 2p24, 8p11, 15q11-q13;
- 8p11, 8q24, 15q11-q13;
- 2p24, 10q26, 20q13;
- 8p11, 10q26, 20q13;
- 2p24, 8p11, 20q13;
- 2p24, 8q24, 20q13;
- 8q24, 15q11-q13, 20q13; and
- 8p11, 15q11-q13, 20q13.

In certain embodiments, the sample is contacted with a combination of at least 3 probes for a set of chromosome subregions selected from the group consisting of:

- 1q25, 18q21, CEP18, 8q24;
- 2p24, 2q26, 10q26, 2q13; and
- 10q23, CEP10, and 8p11.

In particular embodiments, the sample is contacted with a combination of at least 2 probes for a set of chromosome subregions selected from the group consisting of:

- 18q21, 1q24, 8q24, CEP18;
- 1q24, 8q24, 10q26, CEP18;
- 18q21, 1q24, 10q26, CEP18;
- 1q24, 8q24, CEP18, 3q27-q29;
- 18q21, 1q24, 8q24, 10q26;
- 1q24, 2p24, 10q26, CEP18;
- 1q24, 10q26, CEP18, 3q27-q29;
- 1q24, 10q26, CEP18, 20q13;
- 1q24, CEP18, 3q27-q29, 20q13;
- 1q24, 2p24, CEP18, 3q27-q29;
- 18q21, 1q24, 10q26, 20q13;
- 1q24, 8q24, CEP18;
- 18q21, 1q24, CEP18; and
- 1q24, CEP18.

In illustrative embodiments, the sample is contacted with a combination of at least 4 probes for a set of chromosome subregions selected from the group consisting of:

- 1q24, 8q24, CEP18, 20q13;
- 1q24, CEP18, 3q27-q29, 20q13;
- 1q24, CEP18, 20q13, 10q26;
- CEP10, 8q24, CEP18, 1q24;
- 10q26, CEP10, 1q24, 8q24;
- 8q24, 1q24, 20q13, CEP18; 10q26;
- 20q13, CEP10, 1q24, 10q26,
  wherein a hybridization pattern showing a gain in one or more of these chromosome subregions is indicative of endometrial carcinoma.

In specific embodiments, one or more of a gain at one of more of 1q24, 8q24, CEP18, and 20q13 are indicative of endometrial carcinoma. In alternative specific embodiments, one or more of a 20q13 gain, a 1q24 gain, a CEP10 imbalance, and a 10q26 gain are indicative of endometrial carcinoma.
In particular embodiments, the sample is contacted with a combination of at least 2 probes for a set of chromosome subregions selected from the group consisting of:

- 18q21, 1q25, 8q24, CEP18;
- 1q25, 8q24, 10q26, CEP18;
- 18q21, 1q25, 10q26, CEP18;
- 1q25, 8q24, CEP18, 3q27-q29;
- 18q21, 1q25, 8q24, 10q26;
- 1q25, 2p24, 10q26, CEP18;
- 1q25, 10q26, CEP18, 3q27-q29;
- 1q25, 10q26, CEP18, 20q13;
- 1q25, CEP18, 3q27-q29, 20q13;
- 1q25, 2p24, CEP18, 3q27-q29;
- 18q21, 1q25, 10q26, 20q13;
- 1q25, 8q24, CEP18;
- 18q21, 1q25, CEP18; and
- 1q25, CEP18.

- 1q25, 8q24, CEP18, 20q13;
- 1q25, CEP18, 3q27-q29, 20q13;
- 1q25, CEP18, 20q13, 10q26;
- CEP10, 8q24, CEP18, 1q25;
- 10q26, CEP10, 1q25, 8q24;
- 8q24, 1q25, 20q13, CEP18; 10q26;
- 20q13, CEP10, 1q25, 10q26,
  wherein a hybridization pattern showing a gain in one or more of these chromosome subregions is indicative of endometrial carcinoma.

In specific embodiments, one or more of a gain at one of more of 1q25, 8q24, CEP18, and 20q13 are indicative of endometrial carcinoma. In alternative specific embodiments, one or more of a 20q13 gain, a 1q25 gain, a CEP10 imbalance, and a 10q26 gain are indicative of endometrial carcinoma.
In variations of any of the preceding embodiments, the probe combination can distinguish samples including endometrial carcinoma from samples that do not include endometrial carcinoma with a sensitivity of at least 93% and a specificity of at least 90%. For example, the sensitivity can be at least 95% and the specificity can be at least 90.4%. In specific embodiments, the sensitivity is least 96% and the specificity is at least 91%.
In variations of any of the preceding embodiments, the probe combination can include between 2 and 10 probes. In particular embodiments, the probe combination includes between 3 and 8 probes. In an illustrative embodiment, the probe combination includes 4 probes.
In any of preceding embodiments, the method can be carried out by array comparative genomic hybridization (aCGH) to probes immobilized on a substrate. Alternatively, the method can be carried out by fluorescence in situ hybridization, and each probe in the probe combination can be labeled with a different fluorophore.
In any of the preceding embodiments, the sample can be an endometrial brushing specimen or an endometrial biopsy specimen.
In any of the preceding claims, when the results of the method indicate endometrial carcinoma, the method can additionally include treating the subject for endometrial carcinoma.
The invention also provides, in certain embodiments, a combination of probes including between 2 and 10 probes selected from any of the groups set forth above, wherein the combination of probes has a sensitivity of at least 93% and a specificity of at least 90% for distinguishing samples including endometrial carcinoma from samples that do not include endometrial carcinoma. In particular embodiments, the combination of probes has a sensitivity of at least 95% and a specificity of at least 90.4%. In illustrative embodiments, the combination of probes has a sensitivity of at least 96% and a specificity of at least 91%. In various embodiments, the probe combination includes between 3 and 8 probes, e.g., 4 probes.
Another aspect of the invention includes a kit for diagnosing endometrial carcinoma, wherein the kit includes a combination of probes including between 2 and 10 probes selected from any of the groups set forth above, wherein the combination of probes has a sensitivity of at least 93% and a specificity of at least 90% for distinguishing samples including endometrial carcinoma from samples that do not include endometrial carcinoma. In particular embodiments, the combination of probes has a sensitivity of at least 95% and a specificity of at least 90.4%. In illustrative embodiments, the combination of probes has a sensitivity of at least 96% and a specificity of at least 91%. In various embodiments, the probe combination includes between 3 and 8 probes, e.g., 4 probes.
In various embodiments, a chromosomal gain, loss, or imbalance detected by at least 2, 3, 4, 5, 6, 7, 8, 9, or 10 probes is indicative of endometrial carcinoma.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A-C: The frequency of genomic changes in all cancers from CGH data. A, 1ptel-7p12.3-p12.1; B, 7q11.23-15qtel; C, 16ptel-22qtel.

FIG. 2A(1-3)-B(1-3): The frequency of genomic changes in A, endometrioid cancers; B, non-endometrioid cancers from CGH data. A-1, 1ptel-6qtel; A-2, 7ptel-15q11.2-q12; A-3, 15q26.1-22qtel; B-1, 1ptel-6qtel; B-2, 7ptel-15qtel; B-3, 16ptel-22qtel.

FIG. 3: Complementation of selected genomic array clones. A, Abnormal (gain or loss); NC, no change in copy number.

FIG. 4A-I: Probe sets 1 and 2 shown on the aCGH data output; frequency of genomic changes in all cancers: A, 1ptel-7p12.3-p12.1; B, 7q11.23-15qtel; C, 16ptel-22qtel. Frequency of genomic changes in endometrioid cancers: D, 1ptel-6qtel; E, 7ptel-15q11.2-q12; F, 15q26.1-22qtel. Frequency of genomic changes in non-endometrioid cancers: G, 1ptel-6qtel; H, 7ptel-15qtel; I, 16ptel-22qtel. Frequency of genomic changes in endometrioid cancers:

FIG. 5: Representative example of cells with FISH signals (amplification).

FIG. 6A-C: Probe sets 1 and 2. Average % abnormal cells in all specimens evaluated. A, % Cells with Gain; B, % Cells with Loss; C, % Cells with Gains and Losses.

FIG. 7: ROC Curve for CEP18+1q24+MYC+DCC, % Abnormal (% cells with either copy number gain or copy number loss for at least 1 of 4 loci).

FIG. 8: Individual Probes and Combinations (ROC Curves, % Abnormal).

FIG. 9: ROC Curves, 4-Probe Combination, Gains of 1q24, MYC, CEP18 and 20q13.2.

FIG. 10: Evaluation of additional probes to improve sensitivity of endometrial cancer detection.

DETAILED DESCRIPTION

The present invention provides a method of detection of chromosomal abnormalities associated with endometrial carcinoma of both endometrioid and non-endometrioid types, as well as probe combinations and diagnostic kits. The methods can utilize techniques known as Comparative Genomic Hybridization on a microarray (aCGH) and in situ hybridization (e.g., Fluorescence In Situ Hybridization (FISH)) using a combination of Locus Specific Identifier (LSI) and Chromosome Enumerator (CEP) probes to detect cells that have chromosomal abnormalities consistent with a diagnosis of endometrial cancer. The methods described herein can be used to detect endometrial cancer in various types of specimens (e.g., endometrial brushing specimen or endometrial biopsy specimen) obtained in the doctors office or operating room.
There is currently no cytological diagnostic test for the early detection of endometrial cancer available today, and there is no test or procedure to routinely screen women at risk for endometrial cancer. Endometrial biopsy is recommended as the initial evaluation of women with abnormal uterine bleeding. The disadvantages of biopsy are that it an invasive and uncomfortable procedure for the patient. Moreover, tumors comprising <50% of the endometrium may be inadequately sampled by endometrial biopsy. Inadequate sampling by biopsy may result in false negative results and necessitate additional endometrial biopsies to determine the cause of persistent abnormal uterine bleeding. As endometrial cancers are relatively fast growing, patients often present after the cancers have already developed and spread locally.
Conventional cytology collected with an endometrial sampling device such as the Tao brush offers the advantage of being relatively non-invasive and therefore more comfortable for the patient. In addition, endometrial sampling for cytology is less likely than biopsy to result in false negative results due to inadequate sampling. The problem with conventional cytology is that most pathologists do not have experience with interpreting endometrial cytology and many consider it difficult to interpret. Furthermore, even experienced cytopathologists find that there are significant fraction of cases that cannot be definitely diagnosed as either positive or negative for cancer and which must be categorized as indeterminate for the presence of cancer.
The methods and compositions described herein will provide means for screening and improved diagnosis of endometrial cancer. Specifically, the methodology described herein can provide one or more of the following benefits: distinguish cancer from difficult benign conditions; distinguish benign tissue from pre-cancerous lesions and pre-cancerous lesions from cancer; distinguish endometrioid and non-endometrioid tumors; provide an early screening tool for outpatient tests on cytology specimens; aid in diagnosis of endometrial cancer in biopsy or surgical specimens (aid histological tissue evaluation); and provide an aid in monitoring of cancer and pre-cancerous conditions during therapy.
Advantages of the methods described herein can include one or more of the following: use of stable DNA for detection of chromosomal abnormalities (deletion, amplification, aneusomy, translocation); rapid detection: results could be obtained in 18-36 hours; implementation possibilities include multiplexed methods (e.g., microarray) and multicolor FISH; use as stand-alone test or as adjuncts to other tests (histology, PSA, nomogram, methylation, mutation); use on cytology specimens or biopsy (fresh-frozen or FFPE); combination of several probes increases sensitivity and specificity as compared to a single-analyte assay; increased sensitivity compared to conventional cytology.

DEFINITIONS

Terms used in the claims and specification are defined as set forth below unless otherwise specified.
The term “endometrial carcinoma” refers to a malignant neoplasm of the endometrium, which is the mucous membrane lining the uterus. Two different clinicopathologic subtypes are recognized based on light microscopic appearance, clinical behavior, and epidemiology: the estrogen-related (type I, “endometrioid”) and the non-estrogen-related types (type II, “nonendometrioid”, such as papillary serous and clear cell).
The terms “tumor” or “cancer” in an animal refer to the presence of cells possessing characteristics such as atypical growth or morphology, including uncontrolled proliferation, immortality, metastatic potential, rapid growth and proliferation rate, and certain characteristic morphological features. Often, cancer cells will be in the form of a tumor, but such cells may exist alone within an animal. The term tumor includes both benign and malignant neoplasms. The term “neoplastic” refers to both benign and malignant atypical growth.
The term “biological sample” or “specimen” is intended to mean a sample obtained from a subject suspected of having, or having endometrial carcinoma. In some embodiments, the sample includes a formalin-fixed paraffin-embedded biopsy. In addition to subjects suspected of having endometrial carcinoma, the biological sample may further be derived from a subject that has been diagnosed with endometrial carcinoma for confirmation of diagnosis or establishing that all of the tumor was removed (“clear margin”). The sample may be derived from a endometrial brushing specimen or endometrial biopsy specimen.
The terms “nucleic acid” or “polynucleotide,” as used herein, refer to a deoxyribonucleotide or ribonucleotide in either single- or double-stranded form. The term encompasses nucleic acids, i.e., oligonucleotides, containing known analogues of natural nucleotides which have similar or improved binding properties, for the purposes desired. The term also encompasses nucleic-acid-like structures with synthetic backbones. DNA backbone analogues provided by the invention include phosphodiester, phosphorothioate, phosphorodithioate, methylphosphonate, phosphoramidate, alkyl phosphotriester, sulfamate, 3′-thioacetal, methylene(methylimino), 3′-N-carbamate, morpholino carbamate, and peptide nucleic acids (PNAs); see Oligonucleotides and Analogues, a Practical Approach, edited by F. Eckstein, IRL Press at Oxford University Press (1991); Antisense Strategies, Annals of the New York Academy of Sciences, Volume 600, Eds. Baserga and Denhardt (NYAS 1992); Milligan (1993) J. Med. Chem. 36:1923-1937; Antisense Research and Applications (1993, CRC Press). PNAs contain non-ionic backbones, such as N-(2-aminoethyl)glycine units. Phosphorothioate linkages are described in WO 97/03211; WO 96/39154; Mata (1997) Toxicol. Appl. Pharmacol. 144:189-197. Other synthetic backbones encompassed by the term include methyl-phosphonate linkages or alternating methylphosphonate and phosphodiester linkages (Strauss-Soukup (1997) Biochemistry 36: 8692-8698), and benzylphosphonate linkages (Samstag (1996) Antisense Nucleic Acid Drug Dev 6: 153-156).
The terms “hybridizing specifically to,” “specific hybridization,” and “selectively hybridize to,” as used herein, refer to the binding, duplexing, or hybridizing of a nucleic acid molecule preferentially to a particular nucleotide sequence under stringent conditions. The term “stringent conditions” refers to conditions under which a probe will hybridize preferentially to its target sequence, and to a lesser extent to, or not at all to, other sequences. A “stringent hybridization” and “stringent hybridization wash conditions” in the context of nucleic acid hybridization (e.g., as in array, Southern or Northern hybridization, or FISH) are sequence-dependent, and are different under different environmental parameters. An extensive guide to the hybridization of nucleic acids is found in, e.g., Tijssen (1993) Laboratory Techniques in Biochemistry and Molecular Biology—Hybridization with Nucleic Acid Probes part I, Ch. 2, “Overview of principles of hybridization and the strategy of nucleic acid probe assays,” Elsevier, NY (“Tijssen”). Generally, highly stringent hybridization and wash conditions are selected to be about 5° C. lower than the thermal melting point (T_m) for the specific sequence at a defined ionic strength and pH. The T_mis the temperature (under defined ionic strength and pH) at which 50% of the target sequence hybridizes to a perfectly matched probe. Very stringent conditions are selected to be equal to the T_mfor a particular probe. An example of stringent hybridization conditions for hybridization of complementary nucleic acids which have more than 100 complementary residues on an array or on a filter in a Southern or northern blot is 42° C. using standard hybridization solutions (see, e.g., Sambrook and Russell (2001) Molecular Cloning: A Laboratory Manual (3rd ed.) Vol. 1-3, Cold Spring Harbor Laboratory, Cold Spring Harbor Press, NY, and detailed discussion, below).
A “chromosomal probe” or “chromosomal probe composition” refers to one or more polynucleotides that specifically hybridize to a region of a chromosome. The target sequences to which the probe can bind vary in length, e.g., from about 25,000 nucleotides to about 800,000 nucleotides. Smaller probes, e.g., that hybridize to a region of less than 100,000 nucleotides, or to a region of less than 10,000 nucleotides, can also be employed. Thus, in various embodiments, the probe can hybridize target sequences that are 25,000 nucleotides, 30,000 nucleotides, 50,000 nucleotides, 100,000 nucleotides, 150,000 nucleotides, 200,000 nucleotides, 250,000 nucleotides, 300,000 nucleotides, 350,000 nucleotides, 400,000 nucleotides, 450,000 nucleotides, 500,000 nucleotides, 550,000 nucleotides, 600,000 nucleotides, 650,000 nucleotides, 700,000 nucleotides, 750,000 nucleotides, or 800,00 nucleotides in length or that have a length falling in any range having any of these values as endpoints. A probe to a particular chromosomal region can include multiple polynucleotide fragments, e.g., ranging in size from about 50 to about 1,000 nucleotides in length.
A chromosome enumeration probe (CEP) is any probe able to enumerate the number of specific chromosomes in a cell.
The term “label containing moiety” or “detection moiety” generally refers to a molecular group or groups associated with a chromosomal probe, either directly or indirectly, that allows for detection of that probe upon hybridization to its target.
The term “target region” or “nucleic acid target” refers to a nucleotide sequence that resides at a specific chromosomal location whose loss and/or gain is indicative of the presence of endometrial carcinoma.

Introduction

The methods described herein are based, in part, on the identification of highly sensitive and specific chromosomal probe combinations that can be used to selectively detect endometrial carcinoma. The probe combinations provide higher sensitivity and specificity than individual probes. The probes encompass locus-specific probes as well as chromosome enumeration probes (CEPs), which typically hybridize to centromeric regions. The methods are carried by hybridizing one or more probes to nucleic acids from, e.g., cytology specimens (uterine brushings, washings, swabs) or cells from frozen specimens or fixed specimens, such as formalin-fixed, paraffin-embedded tissue.

Chromosomal Probes

Probes for use in the invention are used for hybridization to nucleic acids that are present in biological samples from subjects where there is some degree of suspicion of endometrial carcinoma. In certain embodiments, the probes are labeled with detectable labels, e.g., fluorescent labels.
Chromosome Enumeration Probe
A chromosome enumeration probe typically recognizes and binds to a region near to (referred to as “peri-centromeric”) or at the centromere of a specific chromosome, typically a repetitive DNA sequence. The centromere of a chromosome is typically considered to represent that chromosome entity since the centromere is required for faithful segregation during cell division. Deletion or amplification of a particular chromosomal region can be differentiated from loss or gain of the whole chromosome (aneusomy), within which it normally resides, by comparing the number of signals corresponding to the particular locus (copy number) to the number of signals for the corresponding centromere. One method for making this comparison is to divide the number of signals representing the locus by the number of signals representing the centromere. Ratios of less than one indicate relative loss or deletion of the locus, and ratios greater than one indicate relative gain or amplification of the locus. Similarly, comparison can be made between two different loci on the same chromosome, for example on two different arms of the chromosome, to indicate imbalanced gains or losses within the chromosome.
In lieu of a centromeric probe for a chromosome, one of skill in the art will recognize that a chromosomal arm probe may alternately be used to approximate whole chromosomal loss or gain. However, such probes are not as accurate at enumerating chromosomes since the loss of signals for such probes may not always indicate a loss of the entire chromosomes. Examples of chromosome enumeration probes include CEP® probes (e.g., CEP® 12 and X/Y probes) commercially available from Abbott Molecular, DesPlaines, Ill. (formerly Vysis, Inc., Downers Grove, Ill.).
Chromosome enumerator probes and locus-specific probes that target a chromosome region or subregion can readily be prepared by those in the art or can be obtained commercially, e.g., from Abbott Molecular, Molecular Probes, Inc. (Eugene, Oreg.), or Cytocell (Oxfordshire, UK). Such probes are prepared using standard techniques. Chromosomal probes may be prepared, for example, from protein nucleic acids, cloned human DNA such as plasmids, bacterial artificial chromosomes (BACs), and P1 artificial chromosomes (PACs) that contain inserts of human DNA sequences. A region of interest may be obtained via PCR amplification or cloning. Alternatively, chromosomal probes may be prepared synthetically.
Locus-Specific Probes
Probes that can be used in the method described herein include probes that selectively hybridize to chromosome regions (e.g., 1q, 2p, 2q, 3p, 3q, 7p, 8p, 8q, 9p, 9q, 10q, 15q, 16q, 17p, 18q, 19p, 20q, and 22q) or subregions of the chromosome regions (e.g., 1q25, 2p24, 2q26, 3p21, 3q27-q29, 7p21, 8p11, 8q24, 9q34, 10q23, 10q26, 15q11-q13, 16q24, 18q21, 20q12 and 20q13). (The subregion designations as used herein include the designated band and typically about 10 megabases of genomic sequence to either side.) Such probes are also referred to as “locus-specific probes.” A locus-specific probe selectively binds to a specific locus at a chromosomal region that is known to undergo gain or loss in endometrial carcinoma. A probe can target coding or non-coding regions, or both, including exons, introns, and/or regulatory sequences, such as promoter sequences and the like.
When targeting of a particular gene locus is desired, probes that hybridize along the entire length of the targeted gene are preferred in some embodiments, although not required. In specific embodiments, a locus-specific probe can be designed to hybridize to an oncogene or tumor suppressor gene, the genetic aberration of which is correlated with endometrial carcinoma.
Probes useful in the methods described herein generally include a collection of one or more nucleic acid fragments whose hybridization to a target can be detected. Probes can be produced from a source of nucleic acids from one or more particular (preselected) portions of the genome, for example one or more clones, an isolated whole chromosome or chromosome fragment, or a collection of polymerase chain reaction (PCR) amplification products. Probes useful in the method described herein can be produced from nucleic acids found in the regions described herein. The probe may be processed in some manner, for example, by blocking or removal of repetitive nucleic acids or enrichment with unique nucleic acids.
In certain embodiments, e.g., in in situ hybridization (e.g., FISH)-based embodiments, locus-specific probe targets preferably include at least 100,000 nucleotides. For cells of a given sample, relative to those of a control, increases or decreases in the number of signals for a probe indicate a gain or loss, respectively, for the corresponding region.
Probes may also be employed as isolated nucleic acids immobilized on a solid surface (e.g., nitrocellulose), as in aCGH. In some embodiments, the probes may be members of an array of nucleic acids as described, for instance, in WO 96/17958, which is hereby incorporated by reference it its entirety and specifically for its description of array CGH. Techniques capable of producing high density arrays are well-known (see, e.g., Fodor et al. Science 767-773 (1991) and U.S. Pat. No. 5,143,854), both of which are hereby incorporated by reference for this description.
As described in detail below, loci that were putatively associated with endometrial cancer were identified and the sensitivity and specificity of this association was examined in detail using array Comparative Genomic Hybridization (aCGH) and Fluoresence In Situ Hybridization (FISH). The clones selected from aCGH analysis included: LAMC2 (1q25-q31), MYCN (2p24.1), RASSF (3p21.3), TP63 (3q27-q29), IL6 (7p21), FGFR1 (8p11.2-p11.1), MYC (8q24), TSC1 (9q34), PTEN (10q23.3), FGFR2 (10q26), UBE3A/D15S10 (15q11-q13), FANCA (16q24.3), DCC (18q21.3), NCOA3 (20q12), and ZNF217 (20q13.2). The probes in FISH analysis included: 1q25, PTEN (10q23.3), DCC (18q21.2), CEP10, CEP18, FGFR1 (8p11.2), MYC (8q24), MYCN (2p24.3), PIK3CA (2q26.32), FGFR2 (10q26.13), and ZNF217 (20q13.2). New FISH probes were developed for NMYC, FGFR1, and FGFR2.
Probe Selection Methods
Probe combinations can be selected for their ability to simply detect endometrial carcinoma, but are typically selected for the ability to discriminate between endometrial carcinoma and other conditions. Thus, analyses of probe combinations are typically performed to determine the DFI values of different probe combinations for discriminating between endometrial carcinoma and other conditions or normal tissue. In particular embodiments, probe combinations can be analyzed to discriminate between endometrioid and non-endometrioid types of endometrial carcinoma.
Probe combinations for use in the methods of the present invention can be selected using the principles described in the examples. Combinations of chromosomal probes within a probe combination are chosen for sensitivity, specificity, and detectability regarding endometrial carcinoma. Sensitivity refers to the ability of a test (e.g. FISH) to detect disease (e.g. endometrial carcinoma) when it is present. More precisely, sensitivity is defined as True Positives/(True Positives+False Negatives). A test with high sensitivity has few false negative results, while a test with low sensitivity has many false negative results. In particular embodiments, the combination of probes has a sensitivity of least about: 93, 94, 95, 96, 97, 98, 99, or 100%, or a sensitivity falling in a range with any of these values as endpoints.
Specificity, on the other hand, refers to the ability of test (e.g. FISH) to give a negative result when disease is not present. More precisely, specificity is defined as True Negatives/(True Negatives+False Positives). A test with high specificity has few false positive results, while a test with a low specificity has many false positive results. In certain embodiments, the combination of probes has a specificity of at about: 88, 89, 90, 91, 92, 93, 94, or 95%, or a specificity falling in a range with any of these values as endpoints.
In general, chromosomal probe combinations with the highest combined sensitivity and specificity for the detection of endometrial carcinoma are preferred. In exemplary embodiments the combination of probes has a sensitivity and specificity of at least about: 93% and 88%, 95% and 90%, 96% and 91%, 97% and 92%, respectively, or any combination of sensitivity and specificity based on the values given above for each of these parameters.
The combined sensitivity and specificity of a probe combination can be represented by the parameter distance from ideal (DFI), defined as [(1−sensitivity)+(1'specificity)²]^1/2DFI values range from 0 to 1.414, with 0 representing a probe combination having 100% sensitivity and 100% specificity and 1.414 representing a probe combination with 0% sensitivity and 0% specificity.
There is no limit to the number of probes that can be employed in a combination, although, in certain embodiments, no more than ten probes are combined. Additionally, in some embodiments, the number of probes within a set that is to be viewed by a human observer (and not with computer assisted imaging techniques) may be restricted for practical reasons, e.g., by the number of unique fluorophores that provide visually distinguishable signals upon hybridization. For example, typically four or five unique fluorophores (e.g., which appear as red, green, aqua, and gold signals to the human eye) can be conveniently employed in a single probe combination. Generally, the sensitivity of an assay increases as the number of probes within a set increases. However, the increases in sensitivity become smaller and smaller with the addition of more probes and at some point the inclusion of additional probes to a probe combination is not associated with significant increases in the sensitivity of the assay (“diminishing returns”). Increasing the number of probes in a probe combination may decrease the specificity of the assay. Accordingly, a probe combination of the present invention typically includes two, three, or four chromosomal probes, as necessary to provide optimal balance between sensitivity and specificity.
Individual probes can be chosen for inclusion in a probe combination based on their ability to complement other probes within the combination. Specifically, they are targeted to chromosomes or chromosomal subregions that are not frequently altered simultaneously within a given endometrial carcinoma. Thus, each probe in a probe combination complements the other(s), i.e., identifies endometrial carcinoma where the other probes in the combination sometime fail to identify. One method for determining which probes complement one another is to identify single probes with the lowest DFI values for a group of tumor specimens. Then additional probes can be tested on the tumor samples that the initial probe failed to identify, and the probe with the lowest DFI value measured in combination with the initial probe(s) is added to the set. This may then be repeated until a full set of chromosomal probes with the desired DFI value is achieved.
Discrimination analysis is one method that can be used to determine which probes are best able to detect endometrial carcinoma. This method assesses if individual probes are able to detect a statistically different percentage of abnormal cells in test specimens (e.g., endometrial carcinoma) when compared to normal specimens. The detection of cells with chromosomal (or locus) gains or chromosomal (or locus) losses can both be used to identify neoplastic cells in endometrial carcinoma patients. However, chromosomal losses sometimes occur as an artifact in normal cells because of random signal overlap and/or poor hybridization. In sections of formalin-fixed paraffin-embedded material, commonly used to assess biopsies, truncation of nuclei in the sectioning process can also produce artifactual loss of chromosomal material. Consequently, chromosomal gains are often a more reliable indicator of the presence of neoplastic cells.
Cutoff values for individual chromosomal gains and losses must be determined when choosing a probe combination. The term “cutoff value” is intended to mean the value of a parameter associated with chromosomal aberration that divides a population of specimens into two groups—those specimens above the cutoff value and those specimens below the cutoff value. For example, the parameter may be the absolute number or percentage of cells in a population that have genetic aberrations (e.g., losses or gains for target regions). If the number or percentage of cells in the specimen harboring losses or gains for a particular probe is higher than the cutoff value, the sample is determined to be positive for endometrial carcinoma.
Useful probe combinations are discussed in detail in the Example below. In exemplary combinations, one or more of a gain at one of more of 1q24, 8q24, CEP18, and 20q13 are indicative of endometrial carcinoma, as are (i) one or more of a gain at one of more of 1q25, 8q24, CEP18, and 20q13 and (ii) one or more of a 20q13 gain, a 1q24 gain, a CEP10 imbalance, and a 10q26 gain. Also of note are that different genomic changes were observed when comparing endometrioid and non-endometrioid subtypes. Gains in chromosomal arms 1q, 10p and 10q were common in endometrioid carcinomas. Multiple gains across the genome were identified in non-endometrioid carcinomas with the most common gains seen in 3q, 8q and 20q.

Probe Hybridization

Conditions for specifically hybridizing the probes to their nucleic acid targets generally include the combinations of conditions that are employable in a given hybridization procedure to produce specific hybrids, the conditions of which may easily be determined by one of skill in the art. Such conditions typically involve controlled temperature, liquid phase, and contact between a chromosomal probe and a target. Hybridization conditions vary depending upon many factors including probe concentration, target length, target and probe G-C content, solvent composition, temperature, and duration of incubation. At least one denaturation step may precede contact of the probes with the targets. Alternatively, both the probe and nucleic acid target may be subjected to denaturing conditions together while in contact with one another, or with subsequent contact of the probe with the biological sample. Hybridization may be achieved with subsequent incubation of the probe/sample in, for example, a liquid phase of about a 50:50 volume ratio mixture of 2-4.times. SSC and formamide, at a temperature in the range of about 25 to about 55° C. for a time that is illustratively in the range of about 0.5 to about 96 hours, or more preferably at a temperature of about 32 to about 40° C. for a time in the range of about 2 to about 16 hours. In order to increase specificity, use of a blocking agent such as unlabeled blocking nucleic acid as described in U.S. Pat. No. 5,756,696 (the contents of which are herein incorporated by reference in their entirety, and specifically for the description of the use of blocking nucleic acid), may be used in conjunction with the methods of the present invention. Other conditions may be readily employed for specifically hybridizing the probes to their nucleic acid targets present in the sample, as would be readily apparent to one of skill in the art.
Upon completion of a suitable incubation period, non-specific binding of chromosomal probes to sample DNA may be removed by a series of washes. Temperature and salt concentrations are suitably chosen for a desired stringency. The level of stringency required depends on the complexity of a specific probe sequence in relation to the genomic sequence, and may be determined by systematically hybridizing probes to samples of known genetic composition. In general, high stringency washes may be carried out at a temperature in the range of about 65 to about 80° C. with about 0.2× to about 2×SSC and about 0.1% to about 1% of a non-ionic detergent such as Nonidet P-40 (NP40). If lower stringency washes are required, the washes may be carried out at a lower temperature with an increased concentration of salt.

Detection of Probe Hybridization Patterns

The hybridization probes can be detected using any means known in the art. Label-containing moieties can be associated directly or indirectly with chromosomal probes. Different label-containing moieties can be selected for each individual probe within a particular combination so that each hybridized probe is visually distinct from the others upon detection. Where FISH is employed, the chromosomal probes can conveniently be labeled with distinct fluorescent label-containing moieties. In such embodiments, fluorophores, organic molecules that fluoresce upon irradiation at a particular wavelength, are typically directly attached to the chromosomal probes. A large number of fluorophores are commercially available in reactive forms suitable for DNA labeling.
Attachment of fluorophores to nucleic acid probes is well known in the art and may be accomplished by any available means. Fluorophores can be covalently attached to a particular nucleotide, for example, and the labeled nucleotide incorporated into the probe using standard techniques such as nick translation, random priming, PCR labeling, and the like. Alternatively, the fluorophore can be covalently attached via a linker to the deoxycytidine nucleotides of the probe that have been transaminated. Methods for labeling probes are described in U.S. Pat. No. 5,491,224 and Molecular Cytogenetics: Protocols and Applications (2002), Y.-S. Fan, Ed., Chapter 2, “Labeling Fluorescence In Situ Hybridization Probes for Genomic Targets,” L. Morrison et al., p. 21-40, Humana Press, both of which are herein incorporated by reference for their descriptions of labeling probes.
Exemplary fluorophores that can be used for labeling probes include TEXAS RED (Molecular Probes, Inc., Eugene, Oreg.), CASCADE blue aectylazide (Molecular Probes, Inc., Eugene, Oreg.), SPECTRUMORANGE™ (Abbott Molecular, Des Plaines, Ill.) and SPECTRUMGOLD™ (Abbott Molecular).
One of skill in the art will recognize that other agents or dyes can be used in lieu of fluorophores as label-containing moieties. Suitable labels that can be attached to probes include, but are not limited to, radioisotopes, fluorophores, chromophores, mass labels, electron dense particles, magnetic particles, spin labels, molecules that emit luminescence, electrochemically active molecules, enzymes, cofactors, and enzyme substrates. Luminescent agents include, for example, radioluminescent, chemiluminescent, bioluminescent, and phosphorescent label containing moieties. Alternatively, detection moieties that are visualized by indirect means can be used. For example, probes can be labeled with biotin or digoxygenin using routine methods known in the art, and then further processed for detection. Visualization of a biotin-containing probe can be achieved via subsequent binding of avidin conjugated to a detectable marker. The detectable marker may be a fluorophore, in which case visualization and discrimination of probes may be achieved as described above for FISH.
Chromosomal probes hybridized to target regions may alternatively be visualized by enzymatic reactions of label moieties with suitable substrates for the production of insoluble color products. Each probe may be discriminated from other probes within the set by choice of a distinct label moiety. A biotin-containing probe within a set may be detected via subsequent incubation with avidin conjugated to alkaline phosphatase (AP) or horseradish peroxidase (HRP) and a suitable substrate. 5-bromo-4-chloro-3-indolylphosphate and nitro blue tetrazolium (NBT) serve as substrates for alkaline phosphatase, while diaminobenzidine serves as a substrate for HRP.
In embodiments where fluorophore-labeled probes or probe compositions are used, the detection method can involve fluorescence microscopy, flow cytometry, or other means for determining probe hybridization. Any suitable microscopic imaging method may be used in conjunction with the methods of the present invention for observing multiple fluorophores. In the case where fluorescence microscopy is employed, hybridized samples may be viewed under light suitable for excitation of each fluorophore and with the use of an appropriate filter or filters. Automated digital imaging systems such as the MetaSystems, BioView or Applied Imaging systems may alternatively be used.
In array CGH, the probes are not labeled, but rather are immobilized at distinct locations on a substrate, as described in WO 96/17958. In this context, the probes are often referred to as the “target nucleic acids.” The sample nucleic acids are typically labeled to allow detection of hybridization complexes. The sample nucleic acids used in the hybridization may be detectably labeled prior to the hybridization reaction. Alternatively, a detectable label may be selected which binds to the hybridization product. In dual- or multi-color aCGH, the target nucleic acid array is hybridized to two or more collections of differently labeled nucleic acids, either simultaneously or serially. For example, sample nucleic acids (e.g., from endometrial carcinoma biopsy) and reference nucleic acids (e.g., from normal endometrium) are each labeled with a separate and distinguishable label. Differences in intensity of each signal at each target nucleic acid spot can be detected as an indication of a copy number difference. Although any suitable detectable label can be employed for aCGH, fluorescent labels are typically the most convenient.
Preferred methods of visualizing signals are described in WO 93/18186, which is hereby incorporated by reference for this description. To facilitate the display of results and to improve the sensitivity of detecting small differences in fluorescence intensity, a digital image analysis system can be used. An exemplary system is QUIPS (an acronym for quantitative image processing system), which is an automated image analysis system based on a standard fluorescence microscope equipped with an automated stage, focus control and filterwheel (Ludl Electronic Products, Ltd., Hawthorne, N.Y.). The filterwheel is mounted in the fluorescence excitation path of the microscope for selection of the excitation wavelength. Special filters (Chroma Technology, Brattleboro, Vt.) in the dichroic block allow excitation of the multiple dyes without image registration shift. The microscope has two camera ports, one of which has an intensified CCD camera (Quantex Corp., Sunnyvale, Calif.) for sensitive high-speed video image display which is used for finding interesting areas on a slide as well as for focusing. The other camera port has a cooled CCD camera (model 200 by Photometrics Ltd., Tucson, Ariz.) which is used for the actual image acquisition at high resolution and sensitivity. The cooled CCD camera is interfaced to a SUN 4/330 workstation (SUN Microsystems, Inc., Mountain View, Calif.) through a VME bus. The entire acquisition of multicolor images is controlled using an image processing software package SCIL-Image (Delft Centre for Image Processing, Delft, Netherlands).

Screening and Diagnosis of Patients for Endometrial Carcinoma

The detection methods of the invention include obtaining a biological sample from a subject having endometrial carcinoma or suspected of having endometrial carcinoma. The biological sample can be a cytology specimen, (e.g, uterine brushing, washing, or swab). In particular embodiments, the biological sample is a frozen or fixed specimen, such as formalin-fixed and paraffin embedded specimen. The sample is contacted with one or more chromosomal probe(s) to selectively detect endometrial carcinoma in the sample, if any, under conditions for specifically hybridizing the probes to their nucleic acid targets present in the sample. Probes of a combination can be hybridized concurrently or sequentially with the results of each hybridization imaged digitally, the probe or probes stripped, and the sample thereafter hybridized with the remaining probe or probes. Multiple probe combinations can also be hybridized to the sample in this manner.
The biological sample can be from a patient suspected of having endometrial carcinoma or from a patient diagnosed with endometrial carcinoma, e.g., for confirmation of diagnosis or establishing a clear margin, or for the detection of endometrial carcinoma cells in other tissues such as lymph nodes. The biological sample can also be from a subject with an ambiguous diagnosis in order to clarify the diagnosis. The biological sample can also be from a subject with a histopathologically benign lesion to confirm the diagnosis. Biological samples can be obtained using any of a number of methods known in the art.
As noted, a biological sample can be treated with a fixative such as formaldehyde and embedded in paraffin and sectioned for use in the methods of the invention. Alternatively, fresh or frozen tissue can be pressed against glass slides to form monolayers of cells known as touch preparations, which contain intact nuclei and do not suffer from the truncation artifact of sectioning. These cells may be fixed, e.g., in alcoholic solutions such as 100% ethanol or 3:1 methanol:acetic acid. Nuclei can also be extracted from thick sections of paraffin-embedded specimens to reduce truncation artifacts and eliminate extraneous embedded material. Typically, biological samples, once obtained, are harvested and processed prior to hybridization using standard methods known in the art. Such processing typically includes protease treatment and additional fixation in an aldehyde solution such as formaldehyde.

Prescreening of Samples

Prior to detection, cell samples may be optionally pre-selected based on apparent cytologic abnormalities. Pre-selection identifies suspicious cells, thereby allowing the screening to be focused on those cells. Pre-selection allows for faster screening and increases the likelihood that a positive result will not be missed. During pre-selection, cells from a biological sample can be placed on a microscope slide and visually scanned for cytologic abnormalities commonly associated with dysplastic and neoplastic cells. Such abnormalities include abnormalities in nuclear size, nuclear shape, and nuclear staining, as assessed by counterstaining nuclei with nucleic acid stains or dyes such as propidium iodide or 4,6-diamidino-2-phenylindole dihydrochloride (DAPI) usually following hybridization of probes to their target DNAs. Typically, neoplastic cells harbor nuclei that are enlarged, irregular in shape, and/or show a mottled staining pattern. Propidium iodide, typically used at a concentration of about 0.4 .mu.g/ml to about 5 .mu.g/ml, is a red-fluorescing DNA-specific dye that can be observed at an emission peak wavelength of 614 nm. DAPI, typically used at a concentration of about 125 ng/ml to about 1000 ng/ml, is a blue fluorescing DNA-specific stain that can be observed at an emission peak wavelength of 452 nm. In this case, only those cells pre-selected for detection are subjected to counting for chromosomal losses and/or gains. Preferably, pre-selected cells on the order of at least 20, and more preferably at least 30-40, in number are chosen for assessing chromosomal losses and/or gains. Preselection of a suspicious region on a tissue section may be performed on a serial section stained by conventional means, such as H&E or PAP staining, and the suspect region marked by a pathologist or otherwise trained technician. The same region can then be located on the serial section stained by FISH and nuclei enumerated within that region. Within the marked region, enumeration may be limited to nuclei exhibiting abnormal characteristics as described above.
Alternatively, cells for detection may be chosen independent of cytologic or histologic features. For example, all non-overlapping cells in a given area or areas on a microscope slide may be assessed for chromosomal losses and/or gains. As a further example, cells on the slide, e.g., cells that show altered morphology, on the order of at least about 50, and more preferably at least about 100, in number that appear in consecutive order on a microscope slide may be chosen for assessing chromosomal losses and/or gains.

Hybridization Pattern

In Situ Hybridization
The hybridization pattern for the set of chromosomal probes to the target regions is detected and recorded for cells chosen for assessment of chromosomal losses and/or gains. Hybridization is detected by the presence or absence of the particular signals generated by each of the chromosomal probes. The term “hybridization pattern” is intended to refer to the quantification of chromosomal losses/gains for those cells chosen for such assessment, relative to the number of the same in an evenly matched control sample, for each probe throughout a chosen cell sample. The quantification of losses/gains can include determinations that evaluate the ratio of one locus to another on the same or a different chromosome. Once the number of target regions within each cell is determined, as assessed by the number of regions showing hybridization to each probe, relative chromosomal gains and/or losses may be quantified.
The relative gain or loss for each probe is determined by comparing the number of distinct probe signals in each cell to the number expected in a normal cell, i.e., where the copy number should be two. Non-neoplastic cells in the sample, such as keratinocytes, fibroblasts, and lymphocytes, can be used as reference normal cells. More than the normal number of probe signals is considered a gain, and fewer than the normal number is considered a loss. Alternatively, a minimum number of signals per probe per cell can be required to consider the cell abnormal (e.g., 5 or more signals). Likewise for loss, a maximum number of signals per probe can be required to consider the cell abnormal (e.g., 0 signals, or one or fewer signals).
The percentages of cells with at least one gain and/or loss are to be recorded for each locus. A cell is considered abnormal if at least one of the identified genetic aberrations identified by a probe combination of the present invention is found in that cell. A sample may be considered positive for a gain or loss if the percentage of cells with the respective gain or loss exceeds the cutoff value for any probes used in an assay. Alternatively, two or more genetic aberrations can be required in order to consider the cell abnormal with the effect of increasing specificity. For example, wherein gains are indicative of a endometrial carcinoma, a sample is considered positive if it contains, for example, at least four cells showing gains of at least two or more probe-containing regions.
aCGH
Array CGH can be carried out in single-color or dual- or multi-color mode. In single-color mode, only the sample nucleic acids are labeled and hybridized to the nucleic acid array. Copy number differences can be detected by detecting a signal intensity at a particular target nucleic acid spot on the array that differs significantly from the signal intensity observed at one or more spots corresponding to one or more loci that are present in the sample nucleic acids at a normal copy number. To facilitate this determination, the array can include target elements for one or more loci that are not expected to show copy number difference(s) in endometrial carcinoma.
In dual- or multi-color mode, signal corresponding to each labeled collection of nucleic acids (e.g., sample nucleic acids and normal, reference nucleic acids) is detected at each target nucleic acid spot on the array. The signals at each spot can be compared, e.g., by calculating a ratio. For example, if the ratio of sample nucleic acid signal to reference nucleic acid signal exceeds 1, this indicates a gain in the sample nucleic acids at the locus corresponding to the target nucleic acid spot on the array. Conversely, if t if the ratio of sample nucleic acid signal to reference nucleic acid signal is less than 1, this indicates a loss in the sample nucleic acids at the corresponding locus.
Other Methods of Detecting Copy Number Variations Associated with Endometrial Carcinoma
Those of skill in the art appreciate that copy number variations at any of the loci described herein can be detected using other methods, including amplification-based methods and high-throughput DNA sequencing.
Amplification-Based Detection
In amplification-based assays, the target nucleic acids act as template(s) in amplification reaction(s) (e.g., Polymerase Chain Reaction (PCR)). In a quantitative amplification, the amount of amplification product is proportional to the amount of template in the original sample. Detailed protocols for quantitative PCR are provided in Innis et al. (1990) PCR Protocols, A Guide to Methods and Applications, Academic Press, Inc. N.Y.). A number of commercial quantitative PCR systems are available, for example the TaqMan system from Applied Biosystems.
Other suitable amplification methods include, but are not limited to, ligase chain reaction (LCR) (see Wu and Wallace (1989) Genomics 4: 560; Landegren et al. (1988) Science 241: 1077; and Barringer et al. (1990) Gene 89: 117), multiplex ligation-dependent probe amplification (MLPA), transcription amplification (Kwoh et al. (1989) Proc. Natl. Acad. Sci. USA 86: 1173), self-sustained sequence replication (Guatelli et al. (1990) Proc. Nat. Acad. Sci. USA 87: 1874), dot PCR, and linker adapter PCR, etc.
Amplification is typically carried out using primers that specifically amplify one or more loci within each chromosome or chromosomal subregion to be queried. Detection can be carried out by any standard means, including a target-specific probe, a universal probe that binds, e.g., to a sequence introduced into all amplicons via one or both primers, or a double-stranded DNA-binding dye (such as, e.g., SYBR Green). In illustrative embodiments, padlock probes or molecular inversion probes are employed for detection.
High-Throughput DNA Sequencing
In particular embodiments, amplification methods are employed to produce amplicons suitable for high-throughput (i.e., automated) DNA sequencing. Generally, amplification methods that provide substantially uniform amplification of target nucleotide sequences are employed in preparing DNA sequencing libraries having good coverage. In the context of automated DNA sequencing, the term “coverage” refers to the number of times the sequence is measured upon sequencing. The counts obtained are typically normalized relative to a reference sample or samples to determine relative copy number. Thus, upon performing automated sequencing of a plurality of target amplicons, the normalized number of times the sequence is measured reflects the number of target amplicons including that sequence, which, in turn, reflects the number of copies of the target sequence in the sample DNA.
Amplification for sequencing may involve emulsion PCR isolates in which individual DNA molecules along with primer-coated beads are present in aqueous droplets within an oil phase. Polymerase chain reaction (PCR) then coats each bead with clonal copies of the DNA molecule followed by immobilization for later sequencing. Emulsion PCR is used in the methods by Marguilis et al. (commercialized by 454 Life Sciences), Shendure and Porreca et al. (also known as “Polony sequencing”) and SOLiD sequencing, (developed by Agencourt, now Applied Biosystems). Another method for in vitro clonal amplification for sequencing is bridge PCR, where fragments are amplified upon primers attached to a solid surface, as used in the Illumina Genome Analyzer. Some sequencing methods do not require amplification, for example, the single-molecule method developed by the Quake laboratory (later commercialized by Helicos). This method uses bright fluorophores and laser excitation to detect pyrosequencing events from individual DNA molecules fixed to a surface. Pacific Biosciences has also developed a single molecule sequencing approach that does not require amplification.
After in vitro clonal amplification (if necessary), DNA molecules that are physically bound to a surface are sequenced. Sequencing by synthesis, like dye-termination electrophoretic sequencing, uses a DNA polymerase to determine the base sequence. Reversible terminator methods (used by Illumina and Helicos) use reversible versions of dye-terminators, adding one nucleotide at a time, and detect fluorescence at each position in real time, by repeated removal of the blocking group to allow polymerization of another nucleotide. Pyrosequencing (used by 454) also uses DNA polymerization, adding one nucleotide species at a time and detecting and quantifying the number of nucleotides added to a given location through the light emitted by the release of attached pyrophosphates.
Pacific Biosciences Single Molecule Real Time (SMRT™) sequencing relies on the processivity of DNA polymerase to sequence single molecules and uses phospholinked nucleotides, each type labeled with a different colored fluorophore. As the nucleotides are incorporated into a complementary DNA strand, each is held by the DNA polymerase within a detection volume for a greater length of time than it takes a nucleotide to diffuse in and out of that detection volume. The DNA polymerase then cleaves the bond that previously held the fluorophore in place and the dye diffuses out of the detection volume so that fluorescence signal returns to background. The process repeats as polymerization proceeds.
Sequencing by ligation uses a DNA ligase to determine the target sequence. Used in the Polony method and in the SOLiD technology, this method employs a pool of all possible oligonucleotides of a fixed length, labeled according to the sequenced position. Oligonucleotides are annealed and ligated; the preferential ligation by DNA ligase for matching sequences results in a signal informative of the nucleotide at that position.
Probe Combinations and Kits for Use in Diagnostic and/or Prognostic Applications
The invention includes highly specific and sensitive combinations of probes, as described herein, that can be used to detect endometrial carcinoma and kits for use in diagnostic, research, and prognostic applications. Kits include probe combinations and can also include reagents such as buffers and the like. The kits may include instructional materials containing directions (i.e., protocols) for the practice of the methods of this invention. While the instructional materials typically include written or printed materials they are not limited to such. Any medium capable of storing such instructions and communicating them to an end user is contemplated by this invention. Such media include, but are not limited to electronic storage media (e.g., magnetic discs, tapes, cartridges, chips), optical media (e.g., CD ROM), and the like. Such media may include addresses to internet sites that provide such instructional materials.

REFERENCES

1. Int J Mol Med. 2003 November; 12(5):727-31. 11q23-24 loss is associated with chromosomal instability in endometrial cancer. Kawasaki K, Suchiro Y, Umayahara K, Morioka H, Ito T, Saito T, Tsukamoto N, Sugino N, Kato H, Sasaki K.
2. Hum Genet. 1997 October; 100(5-6):629-36. Frequent gains on chromosome arms 1q and/or 8q in human endometrial cancer. Suzuki A, Fukushige S, Nagase S, Ohuchi N, Satomi S, Horii A.
3. Cancer Genet Cytogenet. 2008 February; 181(1):25-30. Recurrent gene amplifications in human type I endometrial adenocarcinoma detected by fluorescence in situ hybridization. Samuelson E, Levan K, Adamovic T, Levan G, Horvath G.
4. Cytogenet Genome Res. 2006; 115(1):16-22. Chromosomal alterations in 98 endometrioid adenocarcinomas analyzed with comparative genomic hybridization. Levan K, Partheen K, Osterberg L, Helou K, Horvath G.
5. Eur J Obstet Gynecol Reprod Biol. 2005 May 1; 120(1):107-14. Genetic imbalances in endometrial hyperplasia and endometrioid carcinoma detected by comparative genomic hybridization. Muslumanoglu H M, Oner U, Ozalp S, Acikalin M F, Yalcin O T, Ozdemir M, Artan S.
6. Am J Clin Pathol. 2004 October; 122(4):546-51. Overrepresentation of 8q in carcinosarcomas and endometrial adenocarcinomas. Schulten H J, Gunawan B, Enders C, Donhuijsen K, Emons G, Füzesi L.
7. Hum Genet. 1997 October; 100(5-6):629-36. Frequent gains on chromosome arms 1q and/or 8q in human endometrial cancer. Suzuki A, Fukushige S, Nagase S, Ohuchi N, Satomi S, Horii A.
8. Genes Chromosomes Cancer. 1997 February; 18(2):115-25. Detection of DNA gains and losses in primary endometrial carcinomas by comparative genomic hybridization. Sonoda G, du Manoir S, Godwin A K, Bell D W, Liu Z, Hogan M, Yakushiji M, Testa J R.
9. U.S. Pat. No. 5,713,369 entitled “Uterine endometrial tissue sample brush.”
10. U.S. Pat. No. 4,227,537 entitled “Endometrial brush with slidable protective sleeve.”
11. Guido R S, Kanbour-Shakir A, Rulin M C, Christopherson W A. Pipelle endometrial sampling. Sensitivity in the detection of endometrial cancer. J Reprod Med 1995; 40(8):553-5.
12. Critchley H O, Warner P, Lee A J, Brechin S, Guise J, Graham B. Evaluation of abnormal uterine bleeding: comparison of three outpatient procedures within cohorts defined by age and menopausal status. Health Technol Assess 2004; 8(34):iii-iv, 1-139.
13. Del Priore G, Williams R, Harbatkin C B, Wan L S, Mittal K, Yang G C. Endometrial brush biopsy for the diagnosis of endometrial cancer. J Reprod Med 2001; 46(5):439-43.
14. Kipp B R, Medeiros F, Campion M B, Distad T J, Peterson L M, Keeney G L, et al. Direct uterine sampling with the Tao brush sampler using a liquid-based preparation method for the detection of endometrial cancer and atypical hyperplasia: a feasibility study. Cancer 2008; 114(4):228-35.
15. Maksem J A. Performance characteristics of the Indiana University Medical Center endometrial sampler (Tao Brush) in an outpatient office setting, first year's outcomes: recognizing histological patterns in cytology preparations of endometrial brushings. Diagn Cytopathol 2000; 22(3):186-95.
16. Williams A R, Brechin S, Porter A J, Warner P, Critchley H O. Factors affecting adequacy of Pipelle and Tao Brush endometrial sampling. Bjog 2008; 115(8):1028-36.
17. Yang G C, Wan L S. Endometrial biopsy using the Tao Brush method. A study of 50 women in a general gynecologic practice. J Reprod Med 2000; 45(2):109-14.

All publications cited herein are explicitly incorporated by reference.

EXAMPLES

The following examples are offered to illustrate, but not to limit the claimed invention.

Example 1

Array CGH Studies

Study Design
In a collaborative study of Abbott Molecular and Mayo Clinic carried out in 2007-2009, fresh-frozen, biopsy from proven endometrial carcinoma specimens from 62 patients were obtained with informed consent at the time of surgery from Rochester Methodist Hospital at Mayo Clinic, Rochester, Minn. Serial 5-μm sections were cut from the collected tissue and sections were stained with hematoxylin and eosin (H&E) for histological analysis. Specimens with greater than 70% tumor were selected for aCGH analysis and remaining sections were left unstained for future clinical studies.
DNA from the selected specimens was extracted and amplified prior to CGH analysis by the GenoSensor™ system. Vysis GenoSensor DNA microarray slides obtained from Abbott Molecular (Des Plaines, Ill.) were used for CGH analysis. The microarray slides contained 287 DNA targets consisting of known oncogenes, tumor suppressor genes, and regions of gain, loss, or loss of heterozygosity commonly associated with cancer (Attachment 1). The targets were arrayed in triplicate from BAC libraries.
Test and normal reference DNA samples were random-prime labeled, using Vysis GeneSensor labeling reagents, with Cyanine-3-dCTP, and Cyanine-5-dCTP (Perkin Elmer/NEN), respectively. Random priming refers to the process whereby synthetic DNA octamers of random sequence bind to complementary DNA sequences (along a DNA template) and serve as templates for DNA synthesis and elongation by DNA Polymerase I (Klenow Fragment). Following additional purification, test and reference DNA were mixed in equal proportion (in hybridization buffer), denatured, and hybridized against the Vysis GenoSensor™ Array 300 human genomic DNA microarray. Hybridization proceeded at 30° C. for 72 hours, followed by washing and scanning of arrays. Array images were analyzed with GenoSensor™ software, which segments and identifies each target using the blue (DAPI) image plane. The software measures mean intensities from the green and red image planes, subtracts background, determines mean ratio of green/red signal, and calculates the ratio most representative of the modal DNA copy number of the sample DNA. Gender mismatched (male/female or female/male) hybridizations provided control with respect to the detection of autosomal copy number imbalances. Arrays were hybridizes at Mayo Clinic and aCGH data obtained was analyzed by Abbott Molecular.
In total, data for 57 Cancer specimens (44 endometrioid and 13 non-endometrioid) and 9 normal specimens was available for analysis.
Results
The CGH data revealed several promising genomic targets for these investigational FISH probe sets (FIG. 1). The most frequent gains observed in all endometrial carcinomas included areas on chromosomal arms 1q, 2p, 3q, 8q, and 20q. Most common losses seen in all carcinomas included 9p, 9q, 16q, 17p, 18q, and 22q. Interestingly, different genomic changes were observed when comparing endometrioid and non-endometrioid subtypes. Gains in chromosomal arms 1q, 10p and 10q were common in endometrioid carcinomas. Multiple gains across the genome were identified in non-endometrioid carcinomas with the most common gains seen in 3q, 8q and 20q.
Gross analysis of chromosomal changes demonstrated that most frequent changes, of all cancers analyzed, were as follows:
1. Gains on 1q31-qtel (20-30%)
2. Gains on 3q, 8q and 10q (about 20%)
3. Gain on 2p (about 15%)
4. Losses on 9q (about 18%)
5. Losses on 15q11-q13 (about 18%)
6. Losses on 18q21.3 and 19ptel (about 18-19%)
7. Losses 16q and 17p (about 12%)
Table 1 provides details of the most frequently affected loci (by array clone).

TABLE 1

Loci with the frequently of genomic copy number imbalance of >10% in cancer specimens.

					FREQ	FREQ	FREQ	FREQ	FREQ	FREQ	FREQ
			FREQ	FREQ	GAIN	LOSS	IMBAL	GAIN	LOSS	GAIN	LOSS
Clone		Cyto	GAIN	LOSS	Ca	Ca	Ca	EN	EN	NE	NE
#	Clone Name	Location	(%)	(%)	(%)	(%)	(%)	(%)	(%)	(%)	(%)

8	AMC2	q25-q31	7.27	.00	1.58	.00	1.58	4.09	.00	3.08	.00
0	GFB2	q41	2.73	.00	6.32	.00	6.32	1.82	.00	.69	.00
7	I-5663,	q21	1.21	.00	4.56	.00	4.56	7.27	.00	5.38	.00
	I-13414
1	KT3	q44	2.73	.00	4.56	.00	4.56	9.55	.00	.69	.00
2	HGC-18290	q tel	2.73	.00	4.56	.00	4.56	9.55	.00	.69	.00
36	29F16/SP6	9p tel	.03	6.67	.51	9.30	2.81	.27	8.18	.69	3.08
3	QTEL10	q tel	6.67	.00	9.30	.00	9.30	5.00	.00	.00	.00
6	YCN(N-myc)	p24.1	2.12	.55	4.04	.26	9.30	.82	.82	8.46	.00
4	FI2	q tel	6.67	.00	9.30	.00	9.30	1.36	.00	6.15	.00
10	YC	q24.12-	6.67	.00	9.30	.00	9.30	.82	.00	1.54	.00
		q24.13
11	TK2	q24-qter	6.67	.00	9.30	.00	9.30	.82	.00	1.54	.00
22	SC1	q34	.52	5.15	.75	7.54	9.30	.27	.09	.00	6.15
35	GFR2	0q26	6.67	.00	9.30	.00	9.30	0.45	.00	5.38	.00
82	BE3A,	5q11-q13	.52	5.15	.75	7.54	9.30	.27	3.64	.00	0.77
	15S10
31	CC	8q21.3	.52	6.67	.75	7.54	9.30	.27	.82	.00	3.85
3	P63	q27-q29	5.15	.00	7.54	.00	7.54	.09	.00	6.15	.00
06	GFR1	p11.2-	2.12	.03	4.04	.51	7.54	.09	.27	0.77	.69
		p11.1
21	BCCR1	q33.2	.52	3.64	.75	5.79	7.54	.27	.82	.00	6.15
6	QTEL11	q tel	0.61	.55	0.53	.26	5.79	3.64	.27	.00	5.38
02	8S596	p tel	.58	.06	.77	.02	5.79	.82	.55	5.38	5.38
96	RA16D	6q23.2	.03	0.61	.51	2.28	5.79	.00	.09	5.38	3.08
70	F2	2q12.2	.58	.06	.77	.02	5.79	.82	.82	5.38	.69
71	DGFB(SIS)	2q13.1	.69	.15	.77	.02	5.79	.82	.27	5.38	3.08
9	TGS2(COX2)	q31.1	3.64	.00	5.79	.00	5.79	0.45	.00	.00	.00
7	SH2, KCNK12	p22.3-	3.64	.00	5.79	.00	5.79	3.64	.00	3.08	.00
		2p22.1
09	XT1	q24.11-	3.64	.00	5.79	.00	5.79	.82	.00	6.15	.00
		q24.13
12	HGC-3110	q tel	3.64	.00	5.79	.00	5.79	.55	.00	3.85	.00
6	1S2465,	p12	0.61	.52	2.28	.75	4.04	.82	.27	0.77	.00
	1S3402
99	ANCA	6q24.3	.52	0.61	.75	2.28	4.04	.27	.09	.00	3.08
0	L6	p21	2.12	.00	4.04	.00	4.04	1.36	.00	3.08	.00
01	8S504	p tel	.06	.06	.02	.02	4.04	.82	.55	.69	5.38
37	tSG27915	0q tel	2.12	.00	4.04	.00	4.04	5.91	.00	.69	.00
97	DH13	6q24.2-	.00	2.12	.00	4.04	4.04	.00	.09	.00	0.77
		q24.3
5	PTEL27	p tel	0.61	.00	2.28	.00	2.28	1.36	.00	5.38	.00
8	2S447	q tel	.06	.55	.02	.26	2.28	.09	.27	.00	5.38
5	ASSF1	p21.3	0.61	.00	2.28	.00	2.28	.09	.00	3.08	.00
7	4S2930	q tel	.03	.58	.51	.77	2.28	.55	.27	.00	0.77
8	84C11/T3	p tel	.09	.52	0.53	.75	2.28	.09	.00	5.38	.69
2	TR1B	q13	.09	.52	0.53	.75	2.28	.09	.27	5.38	.00
36	MBT1	0q25.3-	.09	.52	0.53	.75	2.28	3.64	.00	.00	.69
		q26.1
78	GH(D14S308)	4q tel	2.12	.00	2.28	.00	2.28	.09	.00	3.08	.00
08	17S125,	7p12-p11.2	.00	0.61	.00	2.28	2.28	.00	.55	.00	8.46
	17S61
10	LGL1	7p12-	.00	0.61	.00	2.28	2.28	.00	.82	.00	0.77
		17p11.2
48	OP1	0q12-q13.1	.09	.52	0.53	.75	2.28	.55	.27	0.77	.00
49	COA3(AIB1)	0q12	0.61	.00	2.28	.00	2.28	.27	.00	6.15	.00
57	PD52L2, TOM	0q tel	0.61	.00	2.28	.00	2.28	.55	.00	8.46	.00
69	CR	2q11.23	.55	.58	.51	.77	2.28	.00	.82	5.38	5.38

As evident from FIG. 2, Non-Endometrioid (NE) tumors had overall greater number of genomic changes as compared to Endometrioid (EN) tumors. In addition, the pattern of changes was different between EN and NE tumors. For example, changes at 1q and 10q loci were more prevalent in EN tumors, while changes at 8q and 18q appeared more prevalent in NE tumors.
Sensitivity and Specificity Analysis
Analysis was carried out to determine changes in which loci are most abundant in cancers (both NE and EN) and give the highest sensitivity and specificity in detecting cancer.
First, analysis has been carried out on individual loci and the loci with the best sensitivity and specificity value as represented by the DFI parameter calculated as:
DFI=√{square root over ((1−SENS)²+(1−SPEC)²)}{square root over ((1−SENS)²+(1−SPEC)²)}
were selected. As shown below, the best performance was demonstrated by loci located on the long arm of chromosome 1.


	case

	#		SPEC vs	DFI vs
PROBE 1	specimens	SENS	norm	norm

LAMC2:18:1q25-q31	57	0.3158	1.0000	0.6842
TGFB2:20:1q41	57	0.2632	1.0000	0.7368
WI-5663, WI-	57	0.2456	1.0000	0.7544
13414:17:1q21
SHGC-18290:22:1q tel	57	0.2456	1.0000	0.7544
AKT3:21:1q44	57	0.2456	0.8889	0.7625

Then, we considered additional clones, and chosen a representative probe for a segment where several probes were located in one apparent contiguous region of rearrangement. It is evident (Table 2) that the sensitivity and specificity of the individual loci is low. Therefore, combinations of the loci listed below were evaluated.

TABLE 2

Individual clone performance for selected clones.

Case

Control

control

case

mark-

		# speci-		# speci-		SPEC	DFI vs	er	er	er	er
Clone		mens	SENS	mens	SENS	vs norm	norm	(s)+	(s)−	(s)+	(s)−	chi sq prob

LAMC2:18:1q25-q31	abnorm	9	0.0000	57	0.3158	1.0000	0.6842	18	39	0	9	4.8060E−02
MYCN(N-myc):26:2p24.1	abnorm	9	0.0000	57	0.1930	1.0000	0.8070	11	46	0	9	1.4883E−01
RASSF1:45:3p21.3	abnorm	9	0.0000	57	0.1228	1.0000	0.8772	7	50	0	9	2.6617E−01
TP63:53:3q27-q29	abnorm	9	0.0000	57	0.1754	1.0000	0.8246	10	47	0	9	1.7252E−01
IL6:90:7p21	abnorm	9	0.0000	57	0.1404	1.0000	0.8596	8	49	0	9	2.3056E−01
FGFR1:106:8p11.2-p11.1	abnorm	9	0.0000	57	0.1754	1.0000	0.8246	10	47	0	9	1.7252E−01
MYC:110:8q24.12-q24.13	abnorm	9	0.0000	57	0.1930	1.0000	0.8070	11	46	0	9	1.4883E−01
TSC1:122:9q34	abnorm	9	0.0000	57	0.1930	1.0000	0.8070	11	46	0	9	1.4883E−01
PTEN:134:10q23.3	abnorm	9	0.2222	57	0.0702	0.7778	0.9560	4	53	2	7	1.4034E−01
FGFR2:135:10q26	abnorm	9	0.0000	57	0.1930	1.0000	0.8070	11	46	0	9	1.4883E−01
UBE3A,	abnorm	9	0.0000	57	0.1930	1.0000	0.8070	11	46	0	9	1.4883E−01
D15S10:182:15q11-q13
FANCA:199:16q24.3	abnorm	9	0.0000	57	0.1404	1.0000	0.8596	8	49	0	9	2.3056E−01
DCC:231:18q21.3	abnorm	9	0.1111	57	0.1930	0.8889	0.8146	11	46	1	8	5.5398E−01
NCOA3(AIB1):249:20q12	abnorm	9	0.0000	57	0.1228	1.0000	0.8772	7	50	0	9	2.6617E−01
ZNF217(ZABC1):254:20q13.2	abnorm	9	0.0000	57	0.0702	1.0000	0.9298	4	53	0	9	4.1224E−01

Complementation between the selected loci, in all of the tested specimens is represented in FIG. 3.
Sensitivity and specificity in tumor detection was then evaluated using JMP 8.0 statistical analysis software (SAS Institute), utilizing Fit X by Y contingency table analysis. In this analysis, all 13 loci, and groups of 10, 9 and 8 complimentary clones were evaluated. A sample was called positive when either one of the loci (at least one locus) in the group was positive.
1. A Set of all 14 Clones:


	Pos/Neg 14 Loci

	ROW %	NEG	POS

Tumor	NORMAL	88.89	11.11
	TUMOR	28.07	71.93


Tests

N	DF	−Log Like	RSquare (U)

990	1	94.293904	0.1453

Test	ChiSquare	Prot > ChiSq

Likelihood Ratio	188.588	<.0001*
Pearson	186.366	<.0001*

Fisher′s
Exact Test	Prob	Alternative Hypothesis

Left	1.0000	Prob(Pos/Neg 14 Loci = POS)
		is greater for Tumor? = NORMAL than TUMOR
Right	<.0001*	Prob(Pos/Neg 14 Loci = POS)
		is greater for Tumor? = TUMOR than NORMAL
2-Tail	<.0001*	Prob(Pos/Neg 14 Loci = POS)
		is different across Tumor?

2. A Representative Subset of 10 Clones:

DCC FGFR2 IL6 LAMC2 MYC MYCN(N-myc)

PTEN RASSF1 TSC1 UBE3A, D15S10

Pos/Neg 10

	Row %	NEG	POS

Tumor?	NORMAL	66.67	33.33
	TUMOR	26.32	73.68


Tests

N	DF	−LogLike	RSquare (U)

924	1	37.838597	0.0655

Test	ChiSquare	Prob > ChiSq

Likelihood Ratio	75.677	<.0001*
Pearson	81.670	<.0001*

Fisher′s
Exact Test	Prob	Alternative Hypothesis

Left	1.0000	Prob(Pos/Neg 10 = POS)
		is greater for Tumor? = NORMAL than TUMOR
Right	<.0001*	Prob(Pos/Neg 10 = POS)
		is greater for Tumor? = TUMOR than NORMAL
2-Tail	<.0001*	Prob(Pos/Neg 10 = POS)
		is different across Tumor?

3. A Representative Subset of 9 Clones

DCC FGFR2 IL6 LAMC2 MYC MYCN(N-

myc) RASSF1 TSC1 UBE3A, D15S10

Pos/Neg 9

	Row %	NEG	POS

Tumor	NORMAL	88.89	11.11
	TUMOR	28.07	71.93


Tests

N	DF	−LogLike	RSquare (U)

924	1	88.007643	0.1453

Test	ChiSquare	Prob > ChiSq

Likelihood Ratio	176.015	<.0001 *
Pearson	173.942	<.0001 *

Fisher′s
Exact Test	Prob	Alternative Hypothesis

Left	1.0000	Prob(Pos/Neg 9 = POS)
		is greater for Tumor? = NORMAL than TUMOR
Right	<.0001 *	Prob(Pos/Neg 9 = POS)
		is greater for Tumor? = TUMOR than NORMAL
2-Tail	<.0001 *	Prob(Pos/Neg 9 = POS)
		is different across Tumor?

4. A Representative Subset of 8 Clones

FGFR2 IL6 LAMC2 MYC MYCN(N-myc)

RASSF1 TSC1 UBE3A, D15S10

Pos/Neg 8

	Row %	NEG	POS

Tumor?	NORMAL	100.00	0.00
	TUMOR	29.82	70.18


Tests

N	DF	−LogLike	RSquare (U)

924	1	133.24371	0.2151

Test	ChiSquare	Prob > ChiSq

Likelihood Ratio	266.487	<.0001 *
Pearson	224.453	<.0001 *

Fisher′s
Exact Test	Prob	Alternative Hypothesis

Left	1.0000	Prob(Pos/Neg 8 = POS)
		is greater for Tumor? = NORMAL than TUMOR
Right	<.0001 *	Prob(Pos/Neg 8 = POS)
		is greater for Tumor? = TUMOR than NORMAL
2-Tail	<.0001 *	Prob(Pos/Neg 8 = POS)
		is different across Tumor?

FISH Probe Set Selection
To select 4-color probe sets for further FISH experiments, we evaluated the selected loci in greater detail supplementing statistical analysis with literature review. From the further analysis, for the probe selection, we excluded loci that were previously implicated in benign endometrial diseases. In addition, we considered NCOA3 and ZNF217 to be potentially located on one segment of rearrangement and thus picked available probe, ZNF 217, for further FISH studies.


Clone on array:	Vysis FISH probe availability:

1q25-q31, LAMC2	1q25 probe
18q21.3, DCC: loss	probe available
1q24, MYC	probe available
10q26, FGFR2: gain	no probe/clone PTENq23.3
(10q23 in literature)
15q11, UBE3A: deletion	PWS probe
3q27-q29, TP63: gain	2 clones or substitute
(3q24-26.4 reported in literature)	by PIK3CA
3p21.3, RASSF1: gain	2 clones
7p21, IL6: gain	1 clone
2p24.1, MYCN: gain	SG, SO probes
8p11.2, FGFR1: gain/deletion	2 clones
9q33-34 (TSC1): loss
(found in endometriosis also)
20q12-q13 (NCOA3?): gain	20q11.2 HIRA, 20q13.2 ZNF217
(in literature q13.2)
16q24.2-q24.3: loss
(16q literature)

As evident from the results outlined above, CGH data produced by the Genosenor array yielded several preliminary chromosomal targets which included LAMC2 (1q25), NMYC (2p24.1), PIK3CA (3q27-q29), MYC (8q24), FGFR2 (10q26), centromeric region of chromosome 18 (CEP18), DCC (18q21), and ZNF217 (20q13). Of these eight probes, numerous potential four-probe combinations have been identified and probes were grouped in probe sets.
Contingency table analysis was used to assess probe combinations, and the combinations were ranked by a chi square p value and by the DFI value. As at least some of the loci (such as DCC) represent deletions, we first assessed 3-probe combinations to allow one Chromosome Enumerator Probe (CEP) to be added to the probe set if required, as a control for a deletion probe. Shown below is the list of best 3-probe combination in detecting endometrial cancer (Table 3) with chi square p value of <0.05.
The following probe sets were selected and used in FISH experiments using Table 3 above as a guide. New probes were designed and manufactured in Abbott Molecular R&D as indicated below.


Probe Set #1

	1q25	SpectrumGold
	DCC (18q21.2)	SpectrumRed
	CEP18	SpectrumGreen
	MYC (8q24)	SpectrumAqua

Probe Set #2

	MYCN (2p24.3)	SpectrumGreen (new probe)
	PIK3CA (2q26.32)	SpectrumGold
	FGFR2 (10q26.13)	SpectrumAqua (new probe)
	ZNF217 (20q13.2)	pectrumRed

Probe Set #3

	PTEN (10q23.3)	SpectrumOrange
	CEP10	SpectrumGreen
	FGFR1 (8p11.2)	SpectrumAqua (new probe)

TABLE 3

Selected best 3-probe combinations (p < 0.05)

Normal

Cancer

			#	#		marker	marker	#		SPEC	DFI vs	marker	marker	chi sq
PROBE
1	PROBE 2	PROBE 3	Probes	specimens	SENS	(s)+	(s)−	specimens	SENS	vs norm	norm	(s)+	(s)−	prob

LAMC2:18:1q25-q31	MYC:110:8q24.12-q24.13	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.5439	1.0000	0.4561	31	26	0.0024
LAMC2:18:1q25-q31	FGFR2:135:10q26	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.5439	1.0000	0.4561	31	26	0.0024
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	MYC:110:8q24.12-q24.13	3	9	0.0000	0	9	57	0.5263	1.0000	0.4737	30	27	0.0032
LAMC2:18:1q25-q31	MYC:110:8q24.12-q24.13	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.5263	1.0000	0.4737	30	27	0.0032
LAMC2:18:1q25-q31	FGFR1:106:8p11.2-p11.1	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.5263	1.0000	0.4737	30	27	0.0032
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	FGFR1:106:8p11.2-p11.1	3	9	0.0000	0	9	57	0.5088	1.0000	0.4912	29	28	0.0043
LAMC2:18:1q25-q31	FGFR1:106:8p11.2-p11.1	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.5088	1.0000	0.4912	29	28	0.0043
LAMC2:18:1q25-q31	FGFR1:106:8p11.2-p11.1	MYC:110:8q24.12-q24.13	3	9	0.0000	0	9	57	0.4912	1.0000	0.5088	28	29	0.0056
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.4912	1.0000	0.5088	28	29	0.0056
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.4737	1.0000	0.5263	27	30	0.0072
MYC:110:8q24.12-q24.1	FGFR2:135:10q26	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.4737	1.0000	0.5263	27	30	0.0072
LAMC2:18:1q25-q31	FGFR1:106:8p11.2-p11.1	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.4737	1.0000	0.5263	27	30	0.0072
LAMC2:18:1q25-q31	MYC:110:8q24.12-q24.13	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.4737	1.0000	0.5263	27	30	0.0072
LAMC2:18:1q25-q31	UBE3A, D15S10:182:15q11	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.4737	1.0000	0.5263	27	30	0.0072
LAMC2:18:1q25-q31	FGFR2:135:10q26	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.4561	1.0000	0.5439	26	31	0.0093
FGFR1:106:8p11.2-p11.	FGFR2:135:10q26	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.4386	1.0000	0.5614	25	32	0.0117
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.4386	1.0000	0.5614	25	32	0.0117
MYCN(N-myc):26:2p24.	FGFR1:106:8p11.2-p11.1	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.4211	1.0000	0.5789	24	33	0.0147
MYCN(N-myc):26:2p24.	MYC:110:8q24.12-q24.13	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.4211	1.0000	0.5789	24	33	0.0147
MYCN(N-myc):26:2p24.	FGFR2:135:10q26	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.4035	1.0000	0.5965	23	34	0.0182
MYCN(N-myc):26:2p24.	MYC:110:8q24.12-q24.13	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.3860	1.0000	0.6140	22	35	0.0225
FGFR2:135:10q26	UBE3A, D15S10:182:15q11	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3860	1.0000	0.6140	22	35	0.0225
LAMC2:18:1q25-q31	FGFR1:106:8p11.2-p11.1	DCC:231:18q21.3	3	9	0.1111	1	8	57	0.5088	0.8889	0.5036	29	28	0.0260
LAMC2:18:1q25-q31	MYC:110:8q24.12-q24.13	DCC:231:18q21.3	3	9	0.1111	1	8	57	0.5088	0.8889	0.5036	29	28	0.0260
LAMC2:18:1q25-q31	FGFR2:135:10q26	DCC:231:18q21.3	3	9	0.1111	1	8	57	0.5088	0.8889	0.5036	29	28	0.0260
LAMC2:18:1q25-q31	UBE3A, D15S10:182:15q11	DCC:231:18q21.3	3	9	0.1111	1	8	57	0.5088	0.8889	0.5036	29	28	0.0260
FGFR1:106:8p11.2-p11.	MYC:110:8q24.12-q24.13	FGFR2:135:10q26	3	9	0.0000	0	9	57	0.3684	1.0000	0.6316	21	36	0.0274
MYC:110:8q24.12-q24.1	FGFR2:135:10q26	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3684	1.0000	0.6316	21	36	0.0274
LAMC2:18:1q25-q31	MYCN(N-myc):26:2p24.1	DCC:231:18q21.3	3	9	0.1111	1	8	57	0.4912	0.8889	0.5208	28	29	0.0327
MYCN(N-myc):26:2p24.	FGFR1:106:8p11.2-p11.1	MYC:110:8q24.12-q24.13	3	9	0.0000	0	9	57	0.3509	1.0000	0.6491	20	37	0.0333
MYCN(N-myc):26:2p24.	FGFR1:106:8p11.2-p11.1	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.3509	1.0000	0.6491	20	37	0.0333
FGFR1:106:8p11.2-p11.	MYC:110:8q24.12-q24.13	UBE3A, D15S10:182:15q11-	3	9	0.0000	0	9	57	0.3509	1.0000	0.6491	20	37	0.0333
MYCN(N-myc):26:2p24.	FGFR2:135:10q26	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3509	1.0000	0.6491	20	37	0.0333
FGFR1:106:8p11.2-p11.	FGFR2:135:10q26	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3509	1.0000	0.6491	20	37	0.0333
MYCN(N-myc):26:2p24.	FGFR1:106:8p11.2-p11.1	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3333	1.0000	0.6667	19	38	0.0401
MYCN(N-myc):26:2p24.	MYC:110:8q24.12-q24.13	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3333	1.0000	0.6667	19	38	0.0401
MYC:110:8q24.12-q24.1	UBE3A, D15S10:182:15q11	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3333	1.0000	0.6667	19	38	0.0401
FGFR1:106:8p11.2-p11.	UBE3A, D15S10:182:15q11	ZNF217(ZABC1):254:20q13	3	9	0.0000	0	9	57	0.3158	1.0000	0.6842	18	39	0.0481

indicates data missing or illegible when filed

Probe sets #1 and 2 in relation to aCGH data are shown in FIG. 4. The plot illustrates that the probes were chosen in such a manner as to be able to detect both endometrioid and non-endometrioid tumors.
Fluorescence In Situ Hybridization studies
Study Design
A probe selection study is currently being performed to determine which four-probe combination of the eight FISH probes can most accurately detect endometrial carcinoma.
Archived formalin-fixed paraffin embedded endometrial tissue specimens taken from patients undergoing hysterectomy or Pipelle biopsy during 2000 to 2006 were utilized for this probe selection study. A variety of specimens diagnosed as endometrial carcinoma (endometrioid type and non-endometrioid type), simple and complex hyperplasia and normal endometrial epithelium were selected for FISH analysis (Table 4).
Ten histologically negative specimens from patients without a history of endometrial carcinoma were also evaluated as a normal value study. Six paraffin sectioned slides were prepared for each case, one was stained with hematoxylin and eosin (H&E) while five unstained slides were prepared for FISH analysis. The H&E slide was microscopically evaluated by a gynecologic pathologist and areas of interest (tumor in cancer specimens; normal epithelium in benign specimens) for FISH analysis were identified. This area of interest was concurrently marked on the unstained tissue slide and was hybridized with each of the two FISH probe sets (separate slides used for each of the two probe sets).

TABLE 4

Patient Population

Genosensor	Non Geno-
cases	sensor	Total

Normal

0	10	10
Simple Hyperplasia	0	5	5
Complex Hyperplasia	2	4	6
Endometrioid Grade 1	8	7	15
Endometrioid Grade 2	7	3	10
Endometrioid Grade 3	6	4	10
Serous	6	3	9
Clear Cell	1	1	2
MMMT	2	1	3
Total	32	38	70

Hybridized slides were evaluated using a fluorescence microscope. The area of interest was identified, 50 cells were evaluated (50 tumor cells for the cancer or pre-neoplastic cases and 50 normal cells for the normal cases) and the number of signals from each of the four probes was recorded. A representative example of endometrial cancer cells exhibiting multiple gains for these probes is shown in FIG. 5. A statistical analysis was performed by Abbott Molecular, Inc. using the signal patterns from all recorded cells. The ten histologically negative specimens were used to calculate the number of signals present in normal endometrial tissue. ROC curve analyses were performed to determine the optimal cutoff values used to discriminate chromosomal abnormalities (gains and losses) from cells with normal chromosomal content for each probe analyzed. Numerous different four-probe combinations were evaluated using this technique to determine the best probe combination to distinguish endometrial cancer from normal endometrial tissue and precursor lesions.
Results
Probe Sets #1 and #2
Two probe sets, #1 and #2, were evaluated on all specimens. FIG. 6 illustrates the proportion of cells with chromosomal abnormalities by histologic subtype for each of the eight probes. Normal endometrial specimens exhibited zero or very few cells with chromosomal gains and approximate 5-20% of cells showed a form of chromosomal loss. In additional very few (<10%) cells with chromosomal gains were identified in hyperplasia specimens.
The following FISH parameters were analyzed:

- 1. % Gain, percent of cells with a copy number gain (>2 copies per cell) of a locus out of 50 cells counted (50=100%)
- 2. % Loss, percent of cells with a copy number loss (<2 copies per cell) of a locus out of 50 cells counted (50=100%)
- 3. % Abnormal, percent of cells with either a copy number loss (<2 copies per cell) OR a copy number gain (>2 copies per cell) of a locus out of 50 cells counted (50=100%)

The conclusions drawn from FIG. 6 are: No gains were observed in Normal specimens for DCC, CEP18, MYC and 1q24. The increase in % cells with gains was observed from normal to hyperplasia to cancer, with most gains in Non-Endometrioid tumors. With losses, there is no clear separation between normal, hyperplasia and cancer. A trend is observed in the increase of % Abnormal from normal to hyperplasia to cancer, with the greatest number of abnormalities in Non-Endometrioid tumors. MYC and 1q24 appear to have the largest range of difference.
Probes directed to 1q25 and 8q24 had the highest percentage of abnormal cells in specimens with EN and NE cancers. All other probes detected approximately the same proportion of cells with gains in EN and NE cancers. For chromosomal losses, 18q (DCC) and CEP 18 exhibited the most cells with loss in EN and NE cancers, as well as normal and hyperplasia specimens.
A multivariate analysis was performed to determine which four-probe combination yielded the great combination of sensitivity and specificity for NE and NE caners. Using JMP 8.0 Statistical Analysis software (SAS Institute, 2008) 70 4-probe combinations of 8 probes were tested. “% Abnormal” was chosen as FISH parameter for analysis (see definitions) and Nominal Logistic Regression platform was utilized with the Test specimens chosen as “all cancers” and Control specimens as hyperplasia+normal. ROCs were constructed, and 20 best combinations with the highest AUC were selected. The combinatorial Excel program was run on the selected combinations to obtain high-resolution data on sensitivity and specificity. The program constructed contingency tables and calculated DFI values for the 4-probe combinations at each cutoff level of % “abnormal” for each probe.
The results of these analyses revealed numerous possible candidate four-probe sets (Table 5). The best probe set combination included DCC, 1q24, MYC, and CEP18 which had a AUC of 0.952 with a sensitivity of 1.000 and a specificity of 0.9048. Three other combinations had a sensitivity of 0.979 and a specificity of 0.900 which included (set 2) 1q24, MYC, FGFR2, CEP18, (set 3) DCC, 1q24, FGFR2, CEP18, and (set 4) 1q24, MYC, CEP18 and PIK3CA.

TABLE 5

Probe combinations that discriminate Cancer from Normal and Hyperplasia. Analyzed
% Cells with any abnormality (% abnormal) using JMP8.0 with combinatorial Excel
program (contingency table analysis).


Test = all cancers; Control = hyperplasia + normal

FIGS. 7 and 8 present Receiver Operator curves for the selected probe combination. It is evident from the figures that adding probes to a single-probe FISH assay improves sensitivity and specificity.
The distribution by tumor type and grade is shown below (Table 6):

TABLE 6

Tumor Type and Grade By FISH (4Best) % Abnormal: POS or NEG.
Cutoffs used as listed in FIG. 7.

Detection of positives in the complex hyperplasia specimens could be due to heterogeneity in this category and could reflect risk of progression to cancer.
Comparison of FISH to CGH Array Data
Performance of the 1q24, CEP16, DCC and MYC FISH probe set was compared by contingency analysis in JMP 8.0 to the aCGH Probe Selection Set #1:
DCC (18q21.3)—frequency of loss in all cancers ˜17%
Cep18—included for FISH probe set (detection of deletions)
LAMC2 (1q25)—frequency of gain in all cancers >20%
MYC (8q24.12-q24.13)—frequency of gain in all cancers ˜17%

Contingency Table Array (Ca vs N)

One of Loci Changed

Count
Row %	NEG	POS

	Ca/NoCa	Ca		28	29	57
			49.12	50.88
		N	8	1	9
			88.89	11.11
			36	30	66

Sensitivity = 50.88% (29 out of 57)
Specificity = 88.89% (8 out of 9)

Contingency TableFISH (Ca vs N + Hyperplasia)

FISH (4Best) % Imbal: POS or NEG

Count
Row %	NEG	POS

	Test or Ref?	Ca	0	49	49
			0.00	100.00
		N + Hyperplasia	19	2	21
			90.48	9.52
			19	51	70

Sensitivity = 100% (49 out of 49)
Specificity = 90.48% (19 out of 21)

It is apparent that FISH assay with probe designed based on microarray results has significantly improved on array performance. This is possibly due to influence of benign cells in the macro-dissected tumors that dilute the analyte tumor DNA and thus lead to lower sensitivity. This problem in microarray experiments could be overcome by careful selection of specimens with high percentage of tumor cells and by micro-dissection of the tumor area.
Analysis of Copy Number Gains Only, Best Combinations: Cancer Vs Normal+Hyperplasia
For a practical FISH application, an alternative probe combination was evaluated that avoids technically challenging detection of losses (looses and gains are considered in “% abnormal” parameter).
Following the procedure outlined above, all 4-probe combinations were analyzed, and best were selected (preliminary analysis using SD of % Cells in excel), Table 7 and FIG. 9.

TABLE 7

Best 4-probe combinations, Gains only.

PROBE	PROBE	PROBE	PROBE				CUTOFF	CUTOFF	CUTOFF	CUTOFF
1	2	3	4	SENS	SPEC	DFI		1	2	3	4

1q24	MYC	CEP18	20q13.2	0.84	0.95	0.17	41.30	8.36	7.91	4.46
1q24	CEP18	PIK3CA	20q13.2	0.84	0.95	0.17	8.36	7.91	18.47	4.46
1q24	CEP18	20q13.2	FGFR2	0.84	0.90	0.19	8.36	7.91	4.46	15.71

Interestingly, the combinations listed above have improved on specificity of cancer detection but have decreased sensitivity, especially to early-stage endometrioid tumors (FIG. 9 and Table 8).
The distribution of positive and negative specimens using the 1q24, MYC, CEP18 and 20q13 probe set is shown in Table 8.

TABLE 8

Tumor Type and Grade By FISH: Gains of MYC, CEP18, 1q24, 20q13.
Cutoffs used as listed in FIG. 9.

As evident from the table, this set (FISH gains) has lower sensitivity towards low-grade endometrial tumors.
Probe Set #3 Evaluation
Probe set #3 was evaluated on 16 early-stage endometrioid cancer specimens and 12 benign (normal and hyperplasia) specimens to determine whether it improves on sensitivity of detection of early-stage (grade 1 and 2) endometrioid tumors with the FISH assay that evaluates gains of MYC, CEP18, 1q24, 20q13.
The analysis of the FISH data has demonstrated that the addition of the PTEN loss to the selected probe set at a cutoff of 14% could increase the sensitivity of detection of endometrial cancer to 100%, however decreasing the specificity (FIG. 10). This finding is in agreement with aCGH data discussed above. In contrast, an addition of Chromosome 10 “% abnormal cells” to the selected probes at a cutoff of 10-12% of cells with any abnormality (gain or loss), allowed for increased sensitivity without sacrificing the specificity. Interestingly, a combination of CEP10 with MYC, CEP18, and 1q24 yielded the same 100% sensitivity for the 16 cancer specimens and 92% specificity against 12 normal+hyperplasia specimens. Therefore, an added assessment of aneusomy 10 to the FISH probe set could be a beneficial. Addition of FGFR1 did not significantly improve cancer detection, however, when used in combination with CEP10, 1q24 and MYC probes, FGFR1 gain at a cutoff of 2% cells yielded 100% sensitivity for the 16 cancer specimens and 92% specificity against 12 normal+hyperplasia specimens. However, when all the 70 specimens are considered (with limited data included for the probe set #3), the only probe that did not result in decrease in specificity when combined with the MYC, 1q24, 20q13, and CEP18 gain probes was FGFR1 at the cutoff of ≧2% cells with gain of the probe:

Test or Ref? By MYC gain, 1q24

gain, 20q13 gain, CEP18 gain, FGFR1 gain:

Count
Row %	NEG	POS	Total

Ca

2	47	49
	4.08	95.92
N + Hyperpl	19	2	21
	90.48	9.52
	21	49	70

Interestingly though, a combination of 20q13.2, 1q24, CEP10 and FGFR1 on all 70 specimens (with the data available thus far) demonstrated sensitivity and specificity of 96% and 91%, as shown below:

Test or Ref? By 20q13, CEP10, 1q24, FGFR1

Count
Row %	NEG	POS	Total

Ca

2	47	49
	4.08	95.92
N + Hyperpl	19	2	21
	90.48	9.52
	21	49	70

As data for all of the specimens is unavailable at this point for Probe Set #3, it appears feasible that the combination of 4 probes that evaluate 20q13 gain, 1q24 gain, CEP10 imbalance, and FGFR1 gain could prove to be superior to the 1q24, MYC, CEP8 and 20q13.2 probe set in future experiments.
Probe Set #4 Evaluation
Probe set #4 was evaluated on the same set of endometrioid cancer specimens, normal and hyperplasia specimens described above to determine whether it improves on sensitivity of detection of low grade (grade 1 and 2) endometrioid tumors above that obtained with the FISH assay that evaluates gains of MYC, CEP18, 1q25, 20q13.
The analysis of the FISH data demonstrates that the substitution of the FGFR1 gain (with a cutoff of 4%) for 20q in the MYC, 1q25, and CEP18 probe set provided a sensitivity of 90%, which was similar to the MYC, 1q25, CEP18 and 20q probe set. However, the addition of FGFR1, resulted in one additional complex hyperplasia specimen to be diagnosed as positive. (Table 9).
Interestingly, further analyses revealed that FGFR1 could significantly increase the sensitivity of the four probe set over 20q. When the cutoff of FGFR1 was reduced to 2%, the probe combination of FGFR1, MYC, 1q25, and CEP18 had a sensitivity and specificity of 96% and 81% respectively.

TABLE 9

Evaluation of additional probes (probe set 3) to improve sensitivity of endometrial cancer detection over that obtained with MYC, CEP 18, 1q25
and 20q13.




Table Abbreviations:
N = Normal; SH = Simple hyperplasia; CH = Complex hyperplasia; EG1 = Endometrioid Grade 1; EG2 = Endometrioid Grade 2; EG3 = Endometrioid Grade 3;
Carcinosarcoma/MMMT = C/M; S = Serous; POS = Number of cells with abnormal sign patterns identified met or exceeded the threshold for the probe;
NEG = Number of cells with abnormal sign patterns identified was less than the threshold for the probe

Analyses of other probes to increase the sensitivity of MYC, 1q25 and CEP18 are shown in Table 10. The addition of DCC, CEP10, PTEN, or FGFR1 increase the sensitivity of the combination probe set to 94-98%. However, the increase in sensitivity was achieved at the expense of decreased specificity (76-81%).

TABLE 10

Analysis of adding DCC, CEP10, PTEN or FGFR1 to a
probe set of MYC, 1q25 and CEP18 to increase
the sensitivity of endometrial cancer detection

Gains

	Probe	Probe	Probe	Losses
	1	2	3	Probe 4	Sensitivity	Specificity

Cutoff	MYC	1q25	CEP18	DCC/CEP18	98%	76%
	>4	>6	>4	>16
Cutoff	MYC	1q25	CEP18	CEP10		98%	81%
	>4	>6	>4	>10
Cutoff	MYC	1q25	CEP18	PTEN		96%	81%
	>4	>6	>4	>18
Cutoff	MYC	1q25	CEP18	FGFR1		94%	81%
	>4	>6	>4	>10 (gains
				and loss)

Additional analyses were performed to determine the optimal probe set with cutoffs to attain very high specificity for endometrial carcinoma. Results from this analysis can be seen in Table 11. Numerous probe and abnormality combinations achieved at least 95% specificity. Those that produced the highest sensitivity with greater than 95% specificity are highlighted in yellow at the top of Table 11. All of these combinations included the evaluation of locus loss or combination of loss and gains (imbal). The best performing probe set that only evaluated gains had a sensitivity of 84% and specificity of 95%, which included FGFR1, 1q25, CEP18 and 20q13 with cutoffs of 8%, 8%, 8% and 8% respectively (highlighted in blue). Two other probe sets containing 1q25, MYC, CEP18 and FGFR1 or 20q13 using cutoffs of 12%, 12%, 12%, and 12%, respectively, achieved a sensitivity of 80% and specificity of 95% (highlighted in green).
The most appealing probe set included 4 LSI probes of 1q25, MYC, FGFR1 and 20q13 using similar cutoffs also had a sensitivity and specificity of 80% and 95%, respectively (seen in red). This probe set is ideal due because it performs nearly as well as other probe sets while only analyzing specimens for chromosomal gains. Chromosomal gains are easier to identify by technologists and would likely have a higher inter-observer reproducibility than when evaluating chromosomal losses.

TABLE 11

Analysis of different probes and cutoffs to achieve specificity of >95% for endometrial cancer detection


Abbreviations: Probe = locus of interest; Abn = Type of abnormality; loss = evaluates only loss of locus; gain = evaluates only gain of locus;
imbal = evaluates gains or loss; cutoff = % of cells with abnormality to consider a specimen as positive.


ATTACHMENT 1. GeneSensor ™ 300 Array Clone List

		Cyto Loc,
		Locus Link	Utility

1	CEB108/T7	1p tel	Sub Tel
2	1PTEL06	1p tel	Sub Tel
3	CDC2L1(p58)	1p36	u DEL
4	PRKCZ	1p36.33	u DEL
5	TP73	1p36.33	u DEL/LOH
6	D1S2660	1p36.32	u DEL/LOH
7	D1S214	1p36.31	u DEL/LOH
8	D1S1635	1p36.22	LOH
9	D1S199	1p36.13	LOH
10	FGR(SRC2)	1p36.2-	AMP(1)
		p36.1
11	MYCL1(LMYC)	1p34.3	AMP(1)
12	D1S427, FAF1	1p32.3	LOH
13	D1S500	1p31.1	LOH
14	D1S418	1p13.1	LOH
15	NRAS	1p13.2	AMP(1)
16	D1S2465, D1S3402	1p12
17	WI-5663, WI-13414	1q21
18	LAMC2	1q25-q31	AMP(1)
19	PTGS2(COX2)	1q31.1
20	TGFB2	1q41
21	AKT3	1q44	AMP
22	SHGC-18290	1q tel	Sub Tel
23	1QTEL10	1q tel	Sub Tel
24	U32389	2p tel	Sub Tel
25	2PTEL27	2p tel	Sub Tel
26	MYCN(N-myc)	2p24.1	AMP(1)
27	MSH2, KCNK12	2p22.3-	LOH
		2p22.1
28	REL	2p13-p12	AMP(1)
29	GNLY	2p12-q11	M
30	SGC34236	2q13	M
31	BIN1	2q14	pTSG
32	LRP1B	2q21.2	pTSG
33	TBR1	2q23-q37	M
34	ITGA4	2q31-q32	M
35	CASP8	2q33-q34	LOH
36	ERBB4(HER-4)	2q33.3-q34	HER-2 homol
37	WI-6310	2q tel	Sub Tel
38	D2S447	2q tel	Sub Tel
39	3PTEL25	3p tel	Sub Tel
40	3PTEL01, CHL1	3p tel	Sub Tel
41	VHL	3p25-p26	TSG
42	RAF1	3p25	AMP(1)
43	THRB	3p24.3	LOH
44	MLH1	3p21.3-p23	Del
45	RASSF1	3p21.3	pTSG
46	FHIT	3p14.2	pTSG
47	p44S10	3p14.1
48	D3S1274, ROBO1	3p12-3p13	LOH
49	RBP1, RBP2	3q21-q22
50	TERC	3q26	AMP(1)
51	EIF5A2	3q26.2
52	PIK3CA	3q26.3	AMP(1)
53	TP63	3q27-q29	TSG
54	MFI2	3q tel	Sub Tel
55	3QTEL05	3q tel	Sub Tel
56	GS10K2/T7	4q tel	Sub Tel
57	SHGC4-207	4q tel	Sub Tel
58	D4S114	4p16.3	u DEL
59	WHSC1	4p16.3	u DEL
60	DDX15	4p15.3	M
61	KIT	4q11-q12	ONC
62	PDGFRA	4q11-q13	AMP(1)
63	EIF4E	4q24 (by	AMP
		ucsc)
64	PGRMC2	4q26
65	PDZ-GEF1	4q32.1	M
66	4QTEL11	4q tel	Sub Tel
67	D4S2930	4q tel	Sub Tel
68	C84C11/T3	5p tel	Sub Tel
69	D5S23	5p15.2	u DEL
70	D5S2064	5p15.2	u DEL
71	DAB2	5p13	pTSG
72	DHFR, MSH3	5q11.2-	gain/loss Ca
		q13.2
73	APC	5q21-q22	Del
74	EGR1	5q31.1	Del
75	CSF1R	5q33-q35	Del
76	NIB1408	5q tel	Sub Tel
77	5QTEL70	5q tel	Sub Tel
78	6PTEL48	6p tel	Sub Tel
79	PIM1	6p21.2	M
80	CCND3	6p21	AMP
81	D6S414	6p12.1-
		p21.1
82	HTR1B	6q13	M
83	D6S434	6q16.3	Del
84	D6S268	6q16.3-q21	LOH
85	MYB	6q22-q23	AMP(1)
86	D6S311	6q23-24	LOH
87	ESR1	6q25.1	AMP(1)
88	6QTEL54	6q tel	Sub Tel
89	G31341	7p tel	Sub Tel
90	IL6	7p21	M
91	EGFR	7p12.3-	AMP(1)
		p12.1
92	ELN	7q11.23	u DEL
93	RFC2, CYLN2	7q11.23	u DEL
94	ABCB1(MDR1)	7q21.1	AMP(1)
95	CDK6	7q21-q22	AMP
96	SERPINE1	7q21.3-q22	pTSG
97	MET	7q31	AMP(1)
98	TIF1	7q32-q34	M
99	stSG48460	7q tel	Sub Tel
100	7QTEL20	7q tel	Sub Tel
101	D8S504	8p tel	Sub Tel
102	D8S596	8p tel	Sub Tel
103	CTSB	8p22	AMP(1)
104	PDGRL	8p22-p21.3	Del
105	LPL	8p22	Del
106	FGFR1	8p11.2-	AMP(1)
		p11.1
107	MOS	8q11	AMP(1)
108	E2F5	8p22-q21.3	M
109	EXT1	8q24.11-	TSG, u DEL
		q24.13
110	MYC	8q24.12-	AMP(1)
		q24.13
111	PTK2	8q24-qter	AMP
112	SHGC-31110	8q tel	Sub Tel
113	U11829	8q tel	Sub Tel
114	AF170276	9p tel	Sub Tel
115	D9S913	9ptel	Sub Tel
116	MTAP	9p21.3	LOH
117	CDKN2A(p16), MTAP	9p21	TSG
118	AFM137XA11	9p11.2	M
119	D9S166	9p12-q21
120	PTCH	9q22.3	TSG
121	DBCCR1	9q33.2	TSG
122	TSC1	9q34	TSG
123	ABL1	9q34.1	AMP(1)
124	H18962	9q tel	Sub Tel
125	D9S325	9q tel	Sub Tel
126	10PTEL006	10p tel	Sub Tel
127	SHGC-44253	10p tel	Sub Tel
128	D10S249, D10S533	10p15	TSG
129	GATA3	10p15
130	WI-2389, D10S1260	10p14-p13	u DEL
131	BMI1	10p13	gain
132	D10S167	10p11-	near Cen
		10q11
133	EGR2	10q21.3	M
134	PTEN	10q23.3	TSG
135	FGFR2	10q26	AMP(1)
136	DMBT1	10q25.3-
		q26.1
137	stSG27915	10q tel	Sub Tel
138	10QTEL24	10q tel	Sub Tel
139	11PTEL03	11p tel	Sub Tel
140	INS	11p tel	Sub Tel
141	HRAS	11p15.5	AMP(1)
142	CDKN1C(p57)	11p15.5	TSG
143	WT1	11p13	TSG
144	KAI1	11p11.2
145	D11S461	11q12.2	near cen
146	MEN1	11q13
147	CCND1	11q13	AMP(1)
148	FGF4, FGF3	11q13	AMP(1)
149	EMS1	11q13	AMP(1)
150	GARP	11q13.5-q14	AMP(1)
151	PAK1	11q13-q14	AMP(1)
152	RDX	11q22.3	LOH
153	ATM	11q22.3	LOH
154	MIL	11q23	AMP(1)
155	WI-6509	11q tel	Sub Tel
156	AF240622	11q tel	Sub Tel
157	8M16/SP6	12p tel	Sub Tel
158	SHGC-5557	12p tel	Sub Tel
159	CCND2	12p13	AMP(1)
160	CDKN1B(p27)	12p13.1-p12	TSG
161	KRAS2	12p11.2	AMP(1)
162	WNT1(INT1)	12q12-q13	AMP(1)
163	CDK2, ERBB3	12q13	AMP
164	GLI	12q13.2-	AMP(1)
		q13.3
165	SAS, CDK4	12q13-q14	AMP(1)
166	MDM2	12q14.3-q15	AMP(1)
167	DRIM, ARL1	12q23
168	stSG8935	12q tel	Sub Tel
169	U11838	12q tel	Sub Tel
170	BRCA2	13q12-q13	TSG
171	RB1	13q14	TSG
172	D13S319	13q14.2	LOH
173	D13S25	13q14.3	LOH
174	D13S327	13q tel	Sub Tel
175	PNN(DRS)	14q13
176	TCL1A	14q32.1	gain/loss
177	AKT1	14q32.32	AMP(1)
178	IGH(D14S308)	14q tel	Sub Tel
179	IGH(SHGC-36156)	14q tel	Sub Tel
180	D15S11	15q11-q13	u DEL
181	SNRPN	15q12	u DEL
182	UBE3A, D15S10	15q11-q13	u DEL
183	GABRB3	15q11.2-q12	u DEL
184	MAP2K5	15q23
185	FES	15q26.1	AMP(1)
186	IGF1R	15q25-q26	AMP(1)
187	PACE4C	15q tel	Sub Tel
188	WI-5214	15q tel	Sub Tel
189	16PTEL03	16p tel	Sub Tel
190	stSG48414	16p tel	Sub Tel
191	CREBBP	16p13.3	u DEL
192	EMP2	16p13.3
193	ABCC1(MRP1)	16p13.1	AMP(1)
194	CYLD	16q12-q13	TSG
195	CDH1	16q22.1	LOH
196	FRA16D	16q23.2
197	CDH13	16q24.2-	LOH
		q24.3
198	LZ16	16q24.2	Del
199	FANCA	16q24.3
200	stSG30213	16q tel	Sub Tel
201	16QTEL013	16q tel	Sub Tel
202	282M15/SP6	17p tel	Sub Tel
203	WI-14673	17p tel	Sub Tel
204	HIC1	17p13.3	LOH
205	D17S379, MNT	17p13.3	u DEL/ LOH
206	PAFAH1B1(LIS1)	17p13.3	u DEL
207	TP53(p53)	17p13.1	TSG
208	D17S125, D17S61	17p12-p11.2	u Del/u Dup
209	D17S1296, D17S1523	17p12-p11.2	u Del/u Dup
210	LLGL1	17p12-	u DEL
		17p11.2
211	FLI, TOP3A	17p12-	u DEL
		17p11.2
212	NF1 5′	17q11.2
213	NF1 3′	17q11.2
214	BRCA1	17q21	TSG
215	PPARBP(PBP)	17q12	AMP
216	ERBB2(HER-2)	17q11.2-	AMP(1)
		17q12
217	THRA	17q11.2	AMP
218	TOP2A	17q21-q22	AMP
219	NME1(NME23)	17q21.3	LOH?
220	RPS6KB1(STK14A)	17q23	AMP(1)
221	D17S1670	17q23
222	TK1	17q23.2-	AMP?
		q25.3
223	SHGC-103396	17q tel	Sub Tel
224	AFM217YD10	17q tel	Sub Tel
225	D18S552	18p tel	Sub Tel
226	SHGC17327	18p tel	Sub Tel
227	YES1	18p11.31-	AMP(1)
		P11.21
228	TYMS(TS)	18p11.32	AMP
229	LAMA3	18q11.2
230	FRA18A(D18S978)	18q12.3
231	DCC	18q21.3	Del
232	MADH4(DPC4)	18q21.1	TSG
233	BCL2 3′	18q21.3	AMP
234	CTDP1, SHGC-145820	18q tel	Sub Tel
235	18QTEL11	18q tel	Sub Tel
236	129F16/SP6	19p tel	Sub Tel
237	stSG42796	19p tel	Sub Tel
238	INSR	19p13.2	AMP(1)
239	JUNB	19p13.2	AMP(1)
240	CCNE1	19q12	AMP(1)
241	AKT2	19q13.1-	LOH
		q13.2
242	GLTSCR2, SULT2A1	19q13.32
243	D19S238E	19 q tel	Sub Tel
244	20PTEL18	20p tel	Sub Tel
245	SOX22	20p tel	Sub Tel
246	JAG1	20p12.1-	uDel
		p11.23
247	MKKS, SHGC-79896	20p12.1-	uDel
		p11.23
248	TOP1	20q12-q13.1	AMP(1)
249	NCOA3(AIB1)	20q12	AMP(1)
250	MYBL2	20q13.1	AMP(1)
251	CSEI1L(CAS)	20q13	AMP(1)
252	PTPN1	20q13.1-	AMP(1)
		q13.2
253	STK6(STK15)	20q13.2-	AMP(1)
		q13.3
254	ZNF217(ZABC1)	20q13.2	AMP(1)
255	CYP24	20q13.2	AMP
256	TNFRSF6B(DCR3)	20q13	AMP
257	TPD52L2, TOM	20q tel	Sub Tel
258	20QTEL14	20q tel	Sub Tel
259	D21S378	21q11.2	M
260	RUNX1(AML1)	21q22.3	AMP(1)
261	DYRK1A	21q22	gain
262	D21S341, D21S342	21q22.3	gain
263	PCNT2(KEN)	21q tel	Sub Tel
264	21QTEL08	21q tel	Sub Tel
265	D22S543	22q11	M
266	GSCL	22q11.21	u DEL
267	HIRA(TUPLE1)	22q11.21	u DEL
268	TBX1	22q11.2	u DEL
269	BCR	22q11.23	AMP(1)
270	NF2	22q12.2	TSG
271	PDGFB(SIS)	22q13.1	AMP(1)
272	ARHGAP8	22q13.3
273	ARSA	22q tel	Sub Tel
274	22QTEL31	22q tel	Sub Tel
275	DXYS129	X/Yp tel	Sub Tel
276	STS 3′	Xp22.3	u DEL
277	STS 5′	Xp22.3	u DEL
278	KAL	Xp22.3	u DEL
279	DMD exon 45-51	Xp21.1
280	DXS580	Xp11.2
281	DXS7132	Xq12
282	AR 3′	Xq11-q12	AMP(1)
283	XIST	Xq13.2
284	OCRL1	Xq25
285	EST CDY16c07	X/Yq tel	Sub Tel
286	SRY	Yp11.3
287	AZFa region	Yq11

Sub Tel	Single copy sequence near the telomere
AMP(1)	Cancer Amplicon previously placed on AmpliOncl Chip
AMP	Cancer Amplicon not previously placed on AmpliOncl Chip
u DEL	Region lost in microdeletion syndrome
TSG	Tumor Supressor Gene
pTSG	putqtive Tumor Supressor Gene
M	Marker added to reduce genomic gaps
gain	Region gained in cancer
u Dup	Micro Duplication
LOH	Region of Loss of Heterozygosity
Del	Deletion Region
near Cen	Single copy sequence near the centromere

Claims

1. A method of detecting the presence of endometrial carcinoma in a biological sample from a subject, the method comprising:

contacting the sample with one or more probes for one or more chromosome regions selected from the group consisting of: 1q, 2p, 2q, 3p, 3q, 7p, 8p, 8q, 9p, 9q, the centromeric region of chromosome 10, 10q, 15q, 16q, 17p, the centromeric region of chromosome 18, 18q, 19p, 20q, and 22q;

incubating the one or more probes with the sample under conditions in which each probe binds selectively with a polynucleotide sequence on its target chromosome or chromosomal region to form a stable hybridization complex; and

detecting hybridization of the one or more probes, wherein a hybridization pattern showing at least one gain or loss or imbalance at a chromosomal region targeted by the probes is indicative of endometrial carcinoma.

2. The method of claim 1, wherein a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 1q, 2p, 3q, 8q, 10q, and 20q is indicative of endometrial carcinoma.

3. The method of claim 2, wherein a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 1q, 10p, and 10q is indicative of endometrioid carcinoma.

4. The method of claim 2, wherein a hybridization pattern showing a gain in one or more chromosome regions selected from the group consisting of: 3q, 8q, 18q, and 20q is indicative of non-endometrioid carcinoma.

5. The method of claim 1, wherein a hybridization pattern showing a gain in 1q31-qtel is indicative of endometrial carcinoma.

6. The method of claim 1, wherein a hybridization pattern showing a loss in one or more chromosome regions selected from the group consisting of: 9p, 9q, 15q, 16q, 17p, 18q, 19p, and 22q is indicative of endometrial carcinoma.

7. The method of claim 1, wherein a hybridization pattern showing a loss in one or more chromosome regions selected from the group consisting of: 15q11-q13, 18q21, and 19ptel is indicative of endometrial carcinoma.

8. The method of claim 1, wherein said one or more probes are for one or more chromosome subregions selected from the group consisting of: 1q25, 2p24, 2q26, 3p21, 3q27-q29, 7p21, 8p11, 8q24, 9q34, the centromeric region of chromosome 10, 10q23, 10q26, 15q11-q13, 16q24, the centromeric region of chromosome 18, 18q21, 20q12 and 20q13.

9. The method of claim 8, wherein said one or more probes are for one or more chromosome subregions selected from the group consisting of: 1q25-q31, 2p24, 3p21.3, 3q27-q29, 7p21, 8p11.2-p11.1, 8q24, 9q34, 10q23.3, 10q26, 15q11-q13, 16q24.3, 18q21.3, 20q12, and 20q13.2.

10. The method of claim 8, wherein said one or more probes are for one or more chromosome subregions selected from the group consisting of: 1q25, 10q23.3, 18q21.2, CEP10, CEP18, 8p11.2, 8q24, 2p24.3, 2q26.32, 10q26.13, and 20q13.2.

11. The method of claim 8, wherein the sample is contacted with a combination of at least 3 probes for a set of chromosome subregions selected from the group consisting of:

1q25, 8q24, 15q11-q13;

1q25, 10q26, 15q11-q13;

1q25, 2p24, 8q24

1q25, 8q24, 10q26;

1q25, 8p11, 15q11-q13;

1q25, 2p24, 8p11;

1q25, 8p11, 10q26;

1q25, 8p11, 8q24;

1q25, 2p24, 10q26;

1q25, 2p24, 15q11-q13;

8q24, 10q26, 15q11-q13;

1q25, 8p11, 20q13;

1q25, 8q24, 20q13;

1q25, 15q11-q13, 20q13;

1q25, 10q26, 20q13;

8p11, 10q26, 15q11-q13;

1q25, 2p24, 20q13;

2p24, 8p11, 10q26;

2p24, 8q24, 10q26;

2p24, 10q26, 15q11-q13;

2p24, 8q24, 15q11-q13;

10q26, 15q11-q13, 20q13;

1q25, 8p11, 18q21;

1q25, 8q24, 18q21;

1q25, 10q26, 18q21;

1q25, 15q11-q13, 18q21;

8p11, 8q24, 10q26;

8q24, 10q26, 20q13;

1q25, 2p24, 18q21;

2p24, 8p11, 8q24;

2p24, 8p11, 15q11-q13;

8p11, 8q24, 15q11-q13;

2p24, 10q26, 20q13;

8p11, 10q26, 20q13;

2p24, 8p11, 20q13;

2p24, 8q24, 20q13;

8q24, 15q11-q13, 20q13; and

8p11, 15q11-q13, 20q13.

12. The method of claim 11, wherein the sample is contacted with a combination of at least 3 probes for a set of chromosome subregions selected from the group consisting of:

1q25, 18q21, CEP18, 8q24;

2p24, 2q26, 10q26, 2q13; and

10q23, CEP10, and 8p11.

13. The method of claim 11, wherein the sample is contacted with a combination of at least 2 probes for a set of chromosome subregions selected from the group consisting of:

18q21, 1q24, 8q24, CEP18;

1q24, 8q24, 10q26, CEP18;

18q21, 1q24, 10q26, CEP18;

1q24, 8q24, CEP18, 3q27-q29;

18q21, 1q24, 8q24, 10q26;

1q24, 2p24, 10q26, CEP18;

1q24, 10q26, CEP18, 3q27-q29;

1q24, 10q26, CEP18, 20q13;

1q24, CEP18, 3q27-q29, 20q13;

1q24, 2p24, CEP18, 3q27-q29;

18q21, 1q24, 10q26, 20q13;

1q24, 8q24, CEP18;

18q21, 1q24, CEP18; and

1q24, CEP18.

14. The method of claim 11, wherein the sample is contacted with a combination of at least 4 probes for a set of chromosome subregions selected from the group consisting of:

1q24, 8q24, CEP18, 20q13;

1q24, CEP18, 3q27-q29, 20q13;

1q24, CEP18, 20q13, 10q26;

CEP10, 8q24, CEP18, 1q24;

10q26, CEP10, 1q24, 8q24;

8q24, 1q24, 20q13, CEP18; 10q26;

20q13, CEP10, 1q24, 10q26;

wherein a hybridization pattern showing a gain in one or more of these chromosome subregions is indicative of endometrial carcinoma.

15. The method of claim 14, wherein one or more of a gain at one of more of 1q24, 8q24, CEP18, and 20q13 are indicative of endometrial carcinoma.

16. The method of claim 14, wherein one or more of a 20q13 gain, a 1q24 gain, a CEP10 imbalance, and a 10q26 gain are indicative of endometrial carcinoma.

17. The method of claim 1, wherein the sample is contacted with a combination of at least 2 probes for a set of chromosome subregions selected from the group consisting of:

18q21, 1q25, 8q24, CEP18;

1q25, 8q24, 10q26, CEP18;

18q21, 1q25, 10q26, CEP18;

1q25, 8q24, CEP18, 3q27-q29;

18q21, 1q25, 8q24, 10q26;

1q25, 2p24, 10q26, CEP18;

1q25, 10q26, CEP18, 3q27-q29;

1q25, 10q26, CEP18, 20q13;

1q25, CEP18, 3q27-q29, 20q13;

1q25, 2p24, CEP18, 3q27-q29;

18q21, 1q25, 10q26, 20q13;

1q25, 8q24, CEP18;

18q21, 1q25, CEP18; and

1q25, CEP18.

18. The method of claim 1, wherein the sample is contacted with a combination of at least 4 probes for a set of chromosome subregions selected from the group consisting of:

1q25, 8q24, CEP18, 20q13;

1q25, CEP18, 3q27-q29, 20q13;

1q25, CEP18, 20q13, 10q26;

CEP10, 8q24, CEP18, 1q25;

10q26, CEP10, 1q25, 8q24;

8q24, 1q25, 20q13, CEP18; 10q26;

20q13, CEP10, 1q25, 10q26;

19. The method of claim 18, wherein one or more of a gain at one of more of 1q25, 8q24, CEP18, and 20q13 are indicative of endometrial carcinoma.

20. The method of claim 18, wherein one or more of a 20q13 gain, a 1q25 gain, a CEP10 imbalance, and a 10q26 gain are indicative of endometrial carcinoma.

21. The method of claim 1 wherein the probe combination distinguishes samples comprising endometrial carcinoma from samples that do not comprise endometrial carcinoma with a sensitivity of at least 93% and a specificity of at least 90%.

22. The method of claim 21, wherein the sensitivity is at least 95% and the specificity is at least 90.4%.

23. The method of claim 22, wherein the sensitivity is least 96% and the specificity is at least 91%.

24. The method of claim 1, wherein the probe combination comprises between 2 and 10 probes.

25. The method of claim 1, wherein the probe combination comprises between 3 and 8 probes.

26. The method of claim 1, wherein the probe combination comprises 4 probes.

27. The method of claim 1, wherein the method is carried out by array comparative genomic hybridization (aCGH) to probes immobilized on a substrate.

28. The method of claim 1, wherein the method is carried out by fluorescence in situ hybridization, and each probe in the probe combination is labeled with a different fluorophore.

29. The method of claim 1, wherein the sample comprises an endometrial brushing specimen or an endometrial biopsy specimen.

30. The method of claim 1, wherein, when the results of the method indicate endometrial carcinoma, the method additionally comprises treating the subject for endometrial carcinoma.

31. A combination of probes comprising between 2 and 10 probes selected from the group set forth in claim 1, wherein the combination of probes has a sensitivity of at least 93% and a specificity of at least 90% for distinguishing samples comprising endometrial carcinoma from samples that do not comprise endometrial carcinoma.

32-35. (canceled)

36. A kit for diagnosing endometrial carcinoma, wherein the kit comprises a combination of probes comprising between 2 and 10 probes selected from the group set forth in claim 1, wherein the combination of probes has a sensitivity of at least 93% and a specificity of at least 90% for distinguishing samples comprising endometrial carcinoma from samples that do not comprise endometrial carcinoma.

37-43. (canceled)