DE10061200A1 - Diagnosis kit for the detection of prion-protein, for the diagnosis of infection Spongiform Encephalopathies, has a micro-particle with an antibody and a second antibody specific to a native prion-protein with a flow cytometer - Google Patents

Abstract

The diagnosis system to detect the presence of prions uses a micro-particle (1) with an antibody (2) specific to prion-protein (3), and a flow cytometer. The diagnosis system, to detect prions, has a second antibody (4) specific to a prion-protein for detection. The antibody has at least one fluorescent marker (5). The micro-particle is paramagnetic, with a diameter of 0.1-8.0 mu m. The system has at least one further antibody against a native prion-protein. Two types of micro-particles are used, in terms of size and color. The system can use a polyclonal or monoclonal antibody specific to prion-protein. An Independent claim is included for a diagnosis kit, with an antibody against a native prion-protein as an internal control.

Description

The invention relates to a method and a kit for the detection of transferable spongiform encephalopathies.

All transmissible spongiform encephalopathies (transmissible spongiform encephalopathy (TSE)) or prion diseases becomes a group called neurodegenerative diseases, which in contrast to genes similar diseases caused by table infection by pathogenic Proteins (prions or prion proteins) are triggered (Prusiner, 1982). These include Creutzfeld-Jakob disease in humans (CJD), Kuru, scrapie in sheep and Bovine spongiform encephalopathy (BSE) in cattle.

Prions (hereinafter also prion proteins) are native infectious isoforms ubiquitous proteins (PrP), their physiological importance is still unknown. It differs from the native protein by a deviation in the amino acid sequence that makes them insoluble, heat resistant and also inaccessible for complete proteolytic degradation does (Forloni et al., 1993).

Pathogenic prion proteins have a small N-terminal section (PrP106-126), which - in contrast to the native protein with an α-helix - Structure - has a stable β-sheet structure. They tend to aggregate with other similar peptides to fibrils (Tagliavini et al., 1991). These fibrils are native to a cell after infection To convert proteins in their structure, which in turn also become pathogenic (Horwich and Weissman, 1997). It comes down to this Way to clump a variety of pathogenic proteins. This ver Lumps are also known as amyloid plaques in the brain of diseased individuals known and put - similar to comparable neurodegenerative Diseases such as B. Altzheimer or Veitstanz (Huntington's chorea) - the  primary cause of the death of essential brain regions (Tagliavini et al., 1991).

In all mammals, the pathology of prion diseases proceeds parable. Due to the highly conserved structure of the prions Prions from plaques of sick individuals not only individuals of their own, but also infect a foreign species. This has been through experimentation with cattle and primates (macaque) (Collinge et al., 1996). The Transmission of prion disease (scrapie) from sheep to cattle and from cattle (BSE) to humans is therefore very likely.

In humans, this transmission path is associated with the new variant of Creutzfeld-Jacob disease, which, in contrast to the classic disease, already occurs in young adults. People are particularly susceptible to this if their PrP protein has a methionine at position 129 . This group represents approximately 11% of the total population.

After the increased incidence of BSE cases in the UK in the middle of the There are strict controls on the origin and use of Slaughter cattle in Europe. A complete epidemiological control spon giform encephalopathies, however, is only due to the complete examination complete livestock and the entire slaughter cattle possible. Therefore a rapid test is required, which routinely shows all animals for slaughter Spongiform encephalopathies are examined before the meat enters the Trade.

Post mortem procedures are used to detect spongiform encephalopathies known, while reliable in vivo tests are not yet available hen. The post mortem procedures are essentially based on an immu biological detection of the prion proteins, which is determined by means of prion protein-specific monoclonal antibody. Serve as a reference  microscopic examination of brain sections, in particular the Electron microscopy (Scott et al., 1992; Stack et al., 1991) and the Immunohistochemistry on formalin-fixed samples (Schulz-Schaeffer et al., 2000; Van Eversbroeck et al., 1999) can be used successfully. The at The latter methods bring highly precise and reliable results nisse. Because of the required work intensity and the necessary Personnel qualifications are the standard method in the context of a routine bulk handling, however, unsuitable.

There are also efforts to develop BSE detection systems based on fluo to establish resence spectroscopic methods. For example the method known as fluorescence correlation spectroscopy (FCS) that's usually attracted to the study of dynamic processes serves monomeric proteins (Bieschke et al., 2000). First results indicate for a high sensitivity of this procedure also in the diagnosis of priority diseases. However, this procedure also requires training personnel and currently stands for routine use in practice are not available.

Alternatively, ELISA methods for the diagnosis of prion Diseases, especially BSE used (Grathwohl et al., 1997; Meyer et al., 1999). For this purpose, the antigens, i.e. prion proteins, fibrils or Sections thereof from the prepared brain or spinal fluid sample the cattle first on surfaces such. B. immobilized by microtiter plates become. The immunological detection is then carried out using a first specific and a second enzyme-coupled antibody, or other color reactions. This is an indirect test because the prion proteins themselves are not detected.

Currently, the detection of BSE in cattle for the purposes of veterinary medical control is mostly carried out using Western blot methods (Rubenstein et al., 1987; Doi et al., 1988; Lee et al., 2000). The detection principle takes advantage of the fact that the native prion protein PrP ^c is degradable by proteases, while after a protease treatment the pathogenic prion protein PrP ^sc remains as a digestion-resistant fragment. The fragment is then detected via an immunoblot, ie after electrophoretic separation of the sample in a polyacrylamide gel, the remaining PrP ^sc fragment is transferred to a membrane and bound with a prion protein-specific antibody. The final detection of the second antibody is usually coupled with an enzyme that mediates a color reaction or is radioactively labeled.

The well-known immunoblot method uses a sufficiently high concentration tration of pathogenic prion proteins in the test sample, which - according to current knowledge - about 6 months before the first appearance clinical symptoms, but no earlier than 30 months after infection of the tie res in brain samples or in the spinal fluid. Because of for the detectable enrichment required for the immunoblot can accordingly BSE can only be reliably detected at a time when that sick animal has long been infectious and therefore a danger to the Represents consumers. For the consumers concerned and especially for the This is a significant disadvantage for farmers.

In addition, the processing time for one of these - currently as Known rapid test - immunoblots about 6 to 7 hours and also sets trained personnel ahead. This time factor is mainly due to the new legal obligation to review everyone Slaughter animals are a significant obstacle to fast, reliable and complete routine veterinary control. In addition, this procedure is not for parallel examinations of a variety of pros ben and suitable for automation. The latter is especially high infectious material desirable for occupational safety reasons.  

The invention is therefore based on the object, the known immunological methods of detection of prion diseases, especially of BSE, and thus improve a procedure and an investigation package (also called kit below), the most sensitive, easy to do handle and perform quickly. The procedure should be possible feasible without lengthy training of the staff and therefore be largely accessible to automation.

The object is achieved with a method according to the main claim. Advantageous further developments are the subject of the subclaims.

The invention is based on the idea that the prion protein-specific binding antibodies to microparticles and an antibody per / prion protein binding with a second prion protein-specific anti body.

The particular advantage of the method according to the invention is that to be able to accumulate the prion proteins on the surface of the microparticles. With this enrichment, the detection limit of the pathogenic prionpro teine in the test samples and thus the sensitivity of the Test significantly increased. By using microparticles you can also the smallest sample volumes are analyzed, which in turn is the Occupational safety serves.

Microparticles (also microbeads or microspheres) are Instruments of biochemistry known for almost two decades, the successfully used for the detection of extracellular proteins (Lisi et al., 1982; Kempfer et al., 1999; lannelli et al., 1997). They represent fixed or semi-solid particles with a diameter of up to a maximum of 100 µm preferably up to 10 µm. Microparticles are particularly suitable Size up to 8 µm. They are usually made of polystyrene or latex; Microparticles based on silicates are also possible. On their surfaces  proteins - including antibodies - can be boxyl groups be covalently bound. For binding specific antibodies the known so-called carbodiimide method is available on microparticles (Molday et al., 1975). In addition, however, the use is also according to the invention of unmodified microparticles or of microparticles with specific ones Ligands possible.

In a particularly advantageous embodiment, paramagnetic microparticles are used according to the invention which contain, for example, iron ions in the form of Fe ₂ O ₃ or Fe ₃ O ₄ . They enable simple and easy handling, which can be automated with the help of appropriate magnets. The automation of work steps is particularly important with highly infectious material. The method according to the invention thus makes it possible to use a robot with which the paramagnetic microparticles can be transferred to a next sample solution, for example by means of electromagnetic pins which are immersed in sample solutions. With increasing automation, the need for qualified personnel decreases.

Both monoclonal and polyclonal antibodies with a specificity against epitopes of the native or pathogenic prion proteins or fibrils are used. If a second antibody for the detection of the first antibody or the binding of the prion protein to the first antibody is required, this can ent neither with a chromogen detectable by an enzyme reaction, or a directly detectable chromophore or fluorescent protein, such as Phycoerythrin or Allophycocyanin coupled. Also a radioactive one Marking or other markings are possible.

The method according to the invention can also be based on the known method ELISA procedures are carried out. However, there is an immobilization the antigens on a membrane or surface of the reaction vessels  (usually the microtiter plates) are no longer required. Much more can the microparticles coupled with antibodies into the wells of the micro titre plates recorded and there with the prepared sample material be incubated. After treatment with a second antibody, if necessary and the subsequent color reaction, the detection with the help of a übli Chen evaluation device.

In a particularly preferred embodiment, prion protein-specific antibodies are bound to paramagnetic microparticles ( FIG. 1). The antibodies are preferably directed against the fibrillar prion proteins. The qualitative detection of the prion proteins is carried out with a second fluorescence-labeled antibody which is directed against another epitope of the fibrils. This ensures that proteins which are not specifically bound to the microparticles are not detected. The quantitative detection of the bound prions is carried out by evaluating the fluorescence signals in a fluorescence detection device, e.g. B. a flow cytometer.

The use of a flow cytometer is a particularly preferred embodiment of the method according to the invention. The advantages of flow cytometry are, in particular, that 100 fluorescent molecules per particle can be detected with simple devices, which corresponds approximately to the high sensitivity of a radioactive assay. On the other hand, up to 1000 particles per second can be measured. In this way, the measurement of a large number of samples can be guaranteed within a very short time.

In a further advantageous embodiment, an internal control be carried along. This can be that in addition to the micro particles for the detection of pathogenic prion proteins microparticles with anti bodies against the native prion protein can be used. These serve the Control of complete proteolysis of the native prion protein. Provided  namely after an incubation with a second, also against the native Protein-directed, fluorescence-labeled antibody in one fluorescence is to be detected is evidence of incomplete proteolysis provided. This is important for the assessment of possible false positives Results due to incomplete digestion. The The reliability of the test can therefore be shown by these internal controls Lich increased.

For the purpose of internal control can be used for evaluation in the through Flow cytometry also uses various microparticles that can if necessary, differentiate in size or color. The advantage of the flow Cytometry is that these microparticles in one process but can be analyzed separately from each other at the same time.

The method according to the invention in the embodiment with paramagneti microparticles and flow cytometry as a detection method fluorescence-labeled prion protein-specific antibody also offers the Advantage of simple and easy full automation.

In the following, the invention is illustrated with reference to one in the drawings presented embodiment of the nourish explained. In it show:

Fig. 1 shows a schematic representation of the detection of prion proteins using the method according to the invention and

Fig. 2 histogram of a fluorescence detection according to the inventive method by means of a flow cytometry

Fig. 1. shows a schematic of a preferred embodiment of the inventive method. Thereafter, prion protein-specific antibodies are bound to a paramagnetic microparticle, which in turn bind to the prion protein. The binding of the prion protein to the first antibody is detected by means of a second fluorescence-labeled specific antibody. The quantitative evaluation is then carried out in a flow cytometer.

FIG. 2 shows an example of a flow cytometric analysis. For this purpose, paramagnetic microparticles with coupled anti-prion antibodies were measured in the flow cytometer after the addition of BSA (A) and after the addition of prionic fibrils (B). The fluorescence staining was carried out by adding another anti-prion antibody which was coupled with phy coerythrin.

The orange fluorescence measured per microparticle is as a histogram shown. If it is low, a histogram appears on the left edge. is however, if it goes up, it moves to the right.

example 1. Preparation of the sample material

100 mg of a brain sample from a slaughtered cattle are in 900 µl Lysis buffer (100 mM NaCl, 10 mM EDTA, 0.5% NP-40, 0.5% sodium deoxycholate, 10 mM Tris pH 7.4) and 100 µl Proteinase K (1 mg / ml) transfer. The sample is then held in the ultrathorax (Sigma, St. Louis, IL, USA). The proteolytic digestion takes place with 37 ° C for 30 min. To stop the enzymatic reaction, 10 µl 0.5 M PMSF (pH 6.8) is added and the sample mix for 10 min cooked.

2. Coupling the antibodies to the microparticles 2.1. Monoclonal antibodies

Magnetic microparticles. Monoclonal antibodies 3 F4 (M 7216, Dako, Hamburg) are covalently attached to the magnetic microparticles (CM-) in a ratio of 2: 1 using a coupling kit (Cat. No. 19539) from Polysciences (Warringden, PA, USA). 30-10) from Spherotech Inc. Libertyvill, IL, USA. The microparticles have a diameter of 3.5 µm.

2.2. Polyclonal antibodies

A polyclonal (rabbit) antibody (PA 1-750 , Dianova, Hamburg) is used for a qualitative detection of the fibrils. For this purpose, 10 µl of 1:50 diluted antibody is added to the microparticles (see section 2.1 .) And incubated at 4 ° C for 30 min

3. Incubation of the microparticles with sample preparation

100 µl of the sample batch are mixed with 10 µl of the sample according to 2.1 or according to section 2.1 . treated microparticles incubated. The incubation time is 1 h at 4 ° C. The microparticles are then washed twice with 1 ml PBS plus 0.1% BSA to saturate the free binding sites. The incubation solutions are exchanged using a magnetic stand (Promega).

4. Fluorescent labeling

The fluorescent labeling is carried out after repeated washing with PBS / BSA by adding 5 µl of phycoerythrin (PE) conjugated anti Rabbit antibody (RD I-711116152; Research Diagnostics, Flanders, NL) and a 30 minute incubation at 4 ° C. After one time Washing with 1 ml PBS and taking up in 1.5 ml PBS can help Samples are measured in the flow cytometer.  

5. Fluorescence detection

For this purpose, a PAS III flow cytometer from Partec (Münster) with FlowMax software is used. The device contains a 25 mW argon laser that generates a wavelength of 488 nm. The orange emission is measured with a 575-605 nm bandpass filter. The data are presented as a fluorescence histogram, with the average fluorescence intensity plotted against the number of particles. The average fluorescence intensity is proportional to the amount of prions bound ( Fig. 2).

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Display text Fig. 1

Scheme of the procedure for the detection of prions using microparties angles.

Fig. 2

Flow cytometric detection of prions. Paramagnetic micropar articles with coupled anti-prion antibodies were added after the addition of BSA (A) and measured after adding prionic fibrils (B) in the flow cytometer. The fluorescence staining was carried out by adding another anti-prion Antibody conjugated to phycoerythrin.

Claims (20)

1. Immunological method for binding prion proteins or Portions of this involve the coupling of a first prion protein specific antibody to a microparticle. 2. The method according to claim 1, characterized by the incubation of the Microparticles with a prion protein or prion protein sections ent holding sample to form an antibody / prion protein complex xes. 3. The method according to claim 2, characterized by a proof the antibody / prion protein complex by a second detection prion protein-specific antibodies. 4. The method according to claim 3, characterized in that the second Antibody has a fluorescent marker. 5. The method according to claim 4, characterized by a quantification tion of the fluorescence marker by a fluorescence reader. 6. The method according to claim 5, characterized by a flow cytometry. 7. The method according to any one of claims 1 to 6, characterized by paramagnetic microparticles. 8. The method according to claim 7, characterized by having microparticles a diameter of 0.1 to 8 µm.   9. The method according to any one of the preceding claims, characterized through an internal control. 10. The method according to claim 9, characterized by another Antibodies against a native prion protein. 11. The method according to any one of the preceding claims, characterized by at least two types in different size or color of micro particle. 12. The method according to any one of claims 1 to 11, characterized by polyclonal prion protein specific antibodies. 13. The method according to any one of claims 1 to 11, characterized by monoclonal prion protein specific antibodies. 14. Microparticles with a prion protein-specific antibody. 15. Microparticles according to claim 14, characterized by a PrP ^sc- specific antibody. 16. Use of a microparticle according to claim 14 or 15 for after white of prions. 17. Use of a microparticle according to claim 14 or 15 for after white spongiform encephalopathies. 18. Method for the detection of prion proteins according to one of the preceding claims, characterized by the use of blood, muscle, spinal fluid, urine or brain samples.   19. Diagnostic kit according to claim 17, characterized by a second prion protein specific antibodies. 20. Diagnostic kit according to claim 19, characterized in that the second antibody has a fluorescent marker.