EP1516187A2 - Hts-capable method and testing system for determining the interaction between a c-reactive protein and constituents that bind to a c-reactive protein - Google Patents

Abstract

The invention relates to an HTS-capable method and testing system for determining the interaction between a C-reactive protein (CRP) or C1q and constituents that bind to a CRP or C1q in order to determine the concentration of a solution containing CRP or C1q and to identify substances that influence the interaction between CRP or C1q and constituents that bind thereto, particularly the interaction between CRP and C1q.

Description

description

HTS-capable method and test system for determining the interaction between C-reactive protein and components that bind to C-reactive protein

The present invention relates to a HTS-capable method and test system for determining the interaction between C-reactive protein (CRP) or C1q and components binding to CRP or C1 q, for determining the concentration of a solution containing CRP or C1q and for determining of substances that influence the interaction of CRP or C1 q and components that bind to it.

The C-reactive protein (CRP) is an acute-phase plasma protein whose concentration in the serum increases rapidly and to a great extent after an infection or tissue injury (Volanakis (2001), Molecular Immunology 38, 189-197). In the presence of Ca ²⁺ ions, CRP binds to phosphocholine (PCh). The latter is widespread in polysaccharides of pathogenic organisms and in cell membranes of damaged and necrotic cells. CRP bound to PCh can activate the classic complement cascade by binding to protein C1q.

The complement is part of the immune system and mainly involved in the antibody-mediated immune system. The three physiological functions of the complement are the defense against bacterial infections, the connection of innate and acquired immunity and the elimination of immune complexes and apoptical cells. A distinction is made between the classic, the alternative and the mannose ^• lectin complement cascade (Walport (2001), N Engl J Med 344, 1058-1066). The classic complement cascade leads to the lysis of bacterial cells and begins with the association of C1q with an antibody binding to the cell surface or CRP bound to PCh.

C-reactive protein is used as a marker and also as a predictor of coronary artery disease, the leading cause of death in industrialized countries (Rifai and Ridker (2001), Clinical Chemistry 47, 403-411). Based on new studies (Jialal et al (2001), Circulation 103, 1933-1935) it is believed that lowering the CRPr level or blocking the CRP-mediated effector functions, for example complement activation by binding to C1q, is useful for prevention and treatment which can be coronary artery disease.

It is therefore desirable, on the one hand, to provide a method which allows the concentration of CRP and / or C1q in blood plasma to be determined in a simple manner and which furthermore allows substances to be identified which are modulatory - activating or inhibiting - act on the interaction of CRP and / or C1 q with other components, in particular on the interaction between CRP and C1q.

Methods for determining the binding of CRP to C1q have been described, for example, by Jiang et al. (1991), J. Immunol. 146, 2324-2330. and Agrawal et al. (2001), J. Immunol. 166, 3998-4004. An ELISA procedure is used in both publications. These are very time-consuming and material-consuming, multi-stage inhomogeneous processes. To carry out the process, one of the reactants must always be immobilized on a solid phase. In addition, numerous washing steps are necessary.

Lebdue et al. (1998), Ann Clin Biochem 35, 745-753 describe a method for the immunonephelometric detection of CRP. For this purpose, the sample is incubated with antibodies against CRP, which are loaded with polystyrene particles. A decisive disadvantage of this method is that you have to have a nephelometer available to carry it out and you have to use a relatively large amount of sample.

It was therefore an object of the present invention to provide a method which allows the concentration of CRP or C1q in blood plasma to be determined in a simple manner and which furthermore allows substances to be identified which have a modulating, activating or inhibiting effect the interaction of CRP or C1q with other components, especially on the interaction act between C1q and CRP, the method being advantageous compared to the prior art in that it is more sensitive, less expensive, less material, easier and / or faster to carry out than the previously described methods.

The object is achieved by a method for determining a binding event of two components which bind directly or via one or more components to CRP or C1 q, comprising the following steps: (a) presentation of a CRP or C1q-containing solution, (b) Addition of at least one donor component or a group of

Components which contain at least one donor component to the CRP- or C1 q-containing solution, the donor component being a component which comprises at least one compound or group of compounds which, after excitation by a light source, emit a signal can (donor group), and wherein the donor component is capable of binding directly or via one or more components from the group of components mentioned to CRP or C1 q,

(c) adding at least one acceptor component or a group of components which contains at least one acceptor component to the CRP or C1q-containing solution, the acceptor component being a

Component which comprises at least one compound or group of compounds which can receive the signal emitted by the compound or group of compounds according to (b) and emit it in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is capable of this to bind directly or via one or more components from the group of components mentioned to CRP or C1q,

(d) excitation of the at least one compound or group of compounds according to (b) (donor group) by a light source,

(e) Detection of the electromagnetic radiation emitted by the at least one compound or group of compounds according to (c) (acceptor group) in order to detect the binding event. The electromagnetic radiation emitted according to (c) is preferably fluorescence radiation. The light source according to (d) can be, for example, a laser or a lamp, for example a helium or halogen lamp. The detection of the electromagnetic radiation according to (e) can take place, for example, with the aid of a photomultiplier.

The components to be used according to the invention are or preferably comprise polypeptides. In a particularly preferred embodiment according to the invention, at least one of the components is an antibody. The antibody can be a monoclonal or polyclonal antibody.

If a group of components is used, these are preferably able to bind spatially in succession to CRP or C1 q or to one another. The binding takes place in the form of a binding cascade, such as is achieved, for example, by the sequential binding of antibodies (primary antibodies, secondary antibodies, etc.). The components which bind directly to CRP or C1 q according to (b) and (c) are preferably components which each bind to a specific binding region or to a specific epitope of CRP or C1 q, the component bound to CRP or C1q according to (b) binds to a different binding site than the component binding to CRP or C1q according to (c).

In a further preferred embodiment of the method according to the invention, one of the components binding directly to CRP or C1q is a naturally occurring binding partner of CRP or C1q. In the case of the CRP, this is particularly preferably C1 q and vice versa. If the donor or acceptor component is bound directly to CRP or C1 q, then in this case it is accordingly either the donor or the acceptor component that is C1 q or CRP, comprising a donor or

Acceptor. If a group of components is used that can form a binding cascade, it is C1q or CRP correspondingly around the first component binding to CRP or C1q, via which either the donor or the acceptor component can be bound to CRP or C1q. The other components of the group of components are particularly preferably antibody molecules.

If, for example, a CRP-containing solution is presented, then in this embodiment either the donor or acceptor component itself preferably comprises C1 q or the donor or acceptor component is bound to CRP via C1 q. The donor or acceptor component can then comprise an anti-C1 q antibody or a secondary antibody attached to the anti-C1 q

Can bind antibodies. Accordingly, the respective other component (acceptor or donor component) then comprises an anti-CRP antibody or an antibody which can bind to the anti-CRP antibody or a tertiary antibody directed against the latter.

In a preferred embodiment, the at least one compound or group of compounds according to (b) (donor group) and / or according to (c) (acceptor group) are localized on particles, the average diameter of the particles preferably being between 150 and 250 nm, particularly preferably at is about 200 nm. The particles are then removed from the donor or

Acceptor components included. The particles can be made of a polymeric material.

The method according to the invention is an HTS (high throughput screening) -capable method which can be carried out homogeneously in the form of a one-step method.

In a preferred embodiment, the method according to the invention is carried out according to the “mix and measure” principle, which leads to considerable time savings and greater accuracy of the measured values. The method according to the invention allows the measurement of the binding of CRP to C1q, and thus the identification of substances that influence this binding, and the measurement of the concentration of CRP or C1q in complex media in less than 10 percent of the time using the previously described , inhomogeneous methods had to be used.

A special characteristic of the new process is that the binding between the two proteins can be followed in solution, since none of the reactants has to be immobilized on a solid phase. The measurement can also be carried out directly with the proteins obtained from biological sources, without having to modify CRP or C1q, for example by binding a fluorophore. A particular advantage of the method is therefore that the protein can be subjected to the test in its native state and the risk of denaturation, which would exist if the protein was immobilized and / or modified, is eliminated.

Another advantage of the method according to the invention is that the sample volume of the method according to the invention is considerably reduced compared to conventional methods. In this way, volumes of less than 10 μl can be used, which minimizes the material expenditure. Highly dilute solutions can also be used

Concentrations of CRP or C1q of less than 1 nM, even less than 100 pM can be used. It is also a very sensitive process. Furthermore, because of the foregoing, it is the first method that enables high-throughput screening for substances that influence complement activation by binding CRP to C1q.

In a preferred embodiment of the method according to the invention, the signal transmission from the at least one compound or group of compounds according to (a) (donor group) to the at least one compound or group of compounds according to (b) (acceptor group) takes place by singlet oxygen. Here, the donor group preferably comprises a compound which can convert triplet oxygen into singlet oxygen after excitation by a laser, and the acceptor group comprises at least a first compound which can be excited by singlet oxygen and a second compound which is that of the can absorb energy absorbed by singlet oxygen excitable group without emissions and emit it in the form of fluorescent radiation.

The singlet oxygen formed can diffuse from the donor group to the acceptor group and react with the chemiluminescent substances located there. The energy released in the process is transferred to the fluorophores, which ultimately emit the energy in the form of fluorescent radiation, which can be detected with a photomultiplier. The prerequisite for a detectable signal is the spatial proximity of donor and acceptor beads, since the singlet oxygen is unstable and decays in aqueous solution. The binding components to be used in this process are therefore chosen such that when the binding event occurs, the distance between the donor and acceptor groups is preferably less than 200 nm, since at a greater distance effective energy transfer by means of singlet oxygen, due to the disintegration time of the singlet Oxygen, is not possible.

In this embodiment, the donor group and acceptor group are particularly preferably located on particles, the particles preferably having an average diameter of between 150 and 250 nm, particularly preferably of about 200 nm. The particles are preferably used in such a way that there is a final concentration of particles bearing donor groups of 1-40 μg / ml and a final concentration of particles bearing acceptor groups of 1-80 μg / ml. The binding capacity of the particles can be, for example, about 0.1 nM to 1 nM per μg / ml particle.

Alpha screen beads from Perkin-Elmer Life Sciences are particularly preferably used as particles for the method. In this embodiment, the donor group is excited by irradiation with a laser at a wavelength of 680 nm and the radiation emitted by the acceptor group can be detected at a wavelength between 520 and 600 nm.

The process can then be carried out accordingly in such a way that donor and acceptor beads which carry donor and acceptor groups are introduced. To the

Donor and acceptor beads are now bound to components that are able to bind to CRP or C1q either themselves or via additional components. As already mentioned, these components can either be C1q or CRP or an anti-CRP or anti-C1 q antibody or an anti-CRP or anti-C1 q antibody Act secondary antibodies.

In a further preferred embodiment of the method according to the invention, the signal transmission from the at least one compound or group of compounds according to (b) (donor group) to the at least one compound or group of compounds according to (b) (acceptor group) takes place by emission-free energy transfer, particularly preferably by fluorescence resonance energy transfer.

The method can be carried out, for example, such that the at least one compound or group of compounds according to (a) (donor group) is one

Europium salt-containing compound and the at least one compound or group of compounds according to (b) (acceptor group) comprises allophycocyanin (Grepin et al. (2000), Drug Discovery Today 5, 212). Or the donor and acceptor groups can be dyes that are suitable for emission-free energy transfer. Furthermore, all compounds known to the person skilled in the art can be used which are suitable for emission-free energy transfer, in particular for fluorescence resonance energy transfer (see, for example, Pope et al. (1999), Drug Discovery Today 4, 350).

In this embodiment, the binding components to be used are preferably chosen so that the distance between the donor and Acceptor groups after binding is less than 10 nm, since effective emission-free energy transfer is not possible at a greater distance.

In a preferred embodiment according to the invention, the method according to the invention is used to determine the concentration of a CRP or C1 q-containing solution of unknown CRP or C1 q content, this solution preferably being blood plasma or blood serum or by means of a suitable physiological Buffer or blood plasma or blood serum diluted with water. This method can be used, for example, for diagnostic purposes, in particular to determine the inflammatory state of an organism and / or to determine the risk of a heart attack and / or a stroke.

The present invention therefore also relates to an HTS-capable diagnostic test system for determining a binding event between CRP or C1q and a component binding to CRP or C1q, comprising the following components:

(a) at least one donor component or a group of components which contains at least one donor component, the donor component being a component which has at least one compound or group of

Compounds comprising, which can emit a signal after excitation by a light source (donor group), and wherein the donor component is able to bind directly or via one or more components from the group of components mentioned to CRP or C1 q, ( b) at least one acceptor component or a group of components which contains at least one acceptor component, the acceptor component being a component which comprises at least one compound or group of compounds which corresponds to that of the compound or group of compounds according to (b ) can receive the transmitted signal and emit it in the form of electromagnetic radiation, and the acceptor component is able to bind to CRP or C1 q directly or via one or more components from the group of components mentioned. The HTS-capable test system preferably comprises the following additional components:

(c) blood serum or blood plasma or blood diluted with physiological buffer or water, (d) a light source for stimulating the at least one compound or group of compounds according to (a),

(e) a detection system for detecting the emitted electromagnetic radiation according to (b).

In a further preferred embodiment of the method according to the invention, before step (a) and / or before step (b) and / or before step (c) and / or before step

(d) added at least one test substance to observe whether this has an influence on the binding event. In this way, substances can be determined which have a modulating, inhibiting or activating effect on the interaction between CRP or C1 q and a binder, in particular on the interaction between CRP and C1q. For this purpose, a library of test substances is preferably screened in the HTS method in order to determine a substance with the desired properties.

The present invention therefore also relates to an HTS-capable device

Test system for determining active substances that have a modulating effect on the interaction between CRP or C1 q and a component that binds to CRP or C1q, comprising the following components:

(a) at least one donor component or a group of components which contains at least one donor component, the donor component being a component which comprises at least one compound or group of compounds which, after excitation by a light source, can emit a signal ( Donor group), and wherein the donor component is able to bind directly or via one or more components from the group of components mentioned to CRP or C1q,

(b) at least one acceptor component or a group of components which contains at least one acceptor component, wherein the Acceptor component is a component which comprises at least one compound or group of compounds which can receive the signal emitted by the compound or group of compounds according to (b) and emit it in the form of electromagnetic radiation, and which the acceptor component is capable of to bind directly or via one or more components from the group of components mentioned to CRP or C1q,

(c) at least one test compound.

This HTS-capable test system preferably comprises the following additional components:

(d) a light source for exciting the at least one compound or group of compounds according to (a),

(e) a detection system for detecting the emitted electromagnetic radiation according to (b), (f) a solution containing CRP or C1 q.

The HTS-capable test systems according to the invention are preferably used here to carry out the previously described methods according to the invention. Special embodiments of the components and components of the test systems therefore correspond to the aforementioned special embodiments which are used in the methods according to the invention.

The method described in the exemplary embodiment is shown schematically in Scheme 1. Here, an anti-C1 q antibody was used as the donor component, the donor group being located on particles which are bound to the anti-C1 q antibody. In the present case, the donor component can bind to the CRP via C1 q. In the present case, the acceptor component is an anti-rabbit secondary antibody, the acceptor group being located on particles which are bound to the anti-rabbit secondary antibody. In the present case, the acceptor component can bind to the CRP via an anti-CRP antibody from rabbits. Scheme 1

light

donor

Exemplary embodiment: binding assay for determining the binding of CRP to C1 q

The Alphascreen Detection Kit from Packard Bioscience was used to carry out the experiment. This includes donor and acceptor beads, the donor beads comprising compounds which, after excitation at a defined one

Wavelength can convert triplet oxygen to singlet oxygen, and the acceptor leads include compounds that can be excited by singlet oxygen, as well as compounds that take energy from the excited compounds in the form of an emission-free energy transfer and can then emit in the form of fluorescent radiation , The compounds mentioned are each embedded in a hydrogel matrix. The beads used had already been pre-coated by the manufacturer, namely the donor beads with streptavidin and the acceptor beads with anti-rabbit antibody.

Table 1: Overview of the materials used

Preparation of the reaction buffer

The following reaction buffer was used in the alpha screen system: 20 mM Tris-HCl, pH 7.2, 150 mM NaCl, 5 mM CaCl ₂ , 1 mM phosphorylcholine, 0.1% BSA. To prepare a stock solution of Tris-NaCl buffer, 3.15 g of Tris-HCl and 8.77 g of NaCl were dissolved in H ₂ 0, a pH of 7.2 was set using 1 M NaOH and then made up to 1 l with H ₂ 0. The buffer is kept at room temperature. The reaction buffer was prepared by adding 36.7 mg CaCl ₂ , 12.9 mg phosphorylcholine and 50 mg BSA to 50 ml Tris-NaCl buffer.

Biotinylation of the anti-C1q antibody

In order to allow the anti-C1q antibody to bind to the streptavidin-coated donor bead, it first had to be biotinylated. For this purpose, 100 μl of anti-C1 q polyclonal serum were dialyzed twice against 200 ml of PBS for one hour at room temperature. After adding 20 μl of 1.5 mM sulfo-NHS solution (in Milli-Q water), the solution was left to stand at room temperature for 30 minutes and then dialyzed again against PBS twice in order to remove excess biotinylation reagent.

Carrying out the assay

To carry out the assay, 2 μl donor bead / anti-CRP solution were introduced, then 2 μl C1q, 2 μl CRP and 2 μl acceptor bead / anti-CRP were added. The following final concentrations were hereby set: CRP: 1 nM; C1 q: 10 nM; Anti-CRP: 7.3 nM; Anti-C1 q: 1: 1500; Donor leads: 20 µg / ml; Acceptor leads: 40 μg / ml. Reaction buffers were used as a negative control instead of the CRP solution, instead of the C1q solution or instead of these two solutions. After 2 hours of incubation at room temperature, the data were read out using an AlphaQuest reader.

Results

The following intensities of the emitted radiation were measured at a CRP concentration of 1 nM and a C1 q concentration of 10 nM (the counts of the photomultiplier are given):

In the absence of CRP and in the absence of C1 q: 952

In the presence of CRP and absence of C1 q: 1255

In the absence of CRP and the presence of C1 q: 1114 In the presence of CRP and the presence of C1 q: 80376

As can be seen, the negative controls do not give a positive result, while a strong signal can be seen when a solution containing C1 q and CRP is combined.

Claims

claims

1. A method for determining a binding event of two components that bind directly to CRP or via one or more components, comprising the following steps:

(a) presentation of a CRP-containing solution,

(b) adding at least one donor component or a group of components containing at least one donor component to the CRP-containing solution, the donor component being a component which comprises at least one compound or group of compounds which according to Excitation by a light source can emit a signal (donor group), and wherein the donor component is able to bind to CRP directly or via one or more components from the group of components mentioned,

(c) adding at least one acceptor component or a group of components which contains at least one acceptor component to the CRP-containing solution, the acceptor component being a component which comprises at least one compound or group of compounds which comprise the can receive signal emitted by the connection or group of connections according to (b) and emit it in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is able to directly or via one or more components from the group of components mentioned To bind CRP

(d) excitation of the at least one compound or group of compounds according to (b) (donor group) by a light source, (e) detection of that of the at least one compound or group of

Compounds according to (c) (acceptor group) emitted electromagnetic radiation for the detection of the binding event.

2. A method for determining a binding event of two components that bind directly to C1q or via one or more components, comprising the following steps:

(a) presentation of a C1q-containing solution, (b) adding at least one donor component or a group of components containing at least one donor component to the C1q-containing solution, the donor component being a component comprising at least one compound or group of compounds which after excitation by a light source, can emit a signal (donor group), and the donor component is capable of binding to C1 q directly or via one or more components from the group of components mentioned,

(c) adding at least one acceptor component or a group of components containing at least one acceptor component to the C1 q-containing solution, the acceptor component being a component comprising at least one compound or group of compounds which can receive the signal emitted by the connection or group of connections according to (b) and emit it in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is able, directly or via one or more components from the group of components mentioned to bind to C1 q

(d) excitation of the at least one compound or group of compounds according to (b) (donor group) by a light source,

(e) Detection of the electromagnetic radiation emitted by the at least one compound or group of compounds according to (c) (acceptor group) in order to detect the binding event.

3. The method according to claim 1 or 2, characterized in that it is fluorescent radiation in the electromagnetic radiation.

4. The method according to claim 1 or 2, characterized in that the light source according to (d) is a laser or a lamp.

5. The method according to claim 1 or 2, characterized in that the detection according to (e) is carried out with the aid of a photomultiplier.

6. The method according to claim 1, characterized in that the components of the group of components according to (b) and / or (c) can spatially sequentially bind to CRP or to each other.

7. The method according to claim 2, characterized in that the components of the group of components according to (b) and / or (c) can spatially sequentially bind to C1q or to each other.

8. The method according to any one of claims 1 to 7, characterized in that the components are polypeptides or these comprise a polypeptide.

9. The method according to claim 8, characterized in that at least one of the components is an antibody.

10. The method according to claim 9, characterized in that the antibody is a monoclonal or polyclonal antibody.

11. The method according to claim 1, characterized in that at least one of the components is a natural binding partner of the CRP.

12. The method according to claim 11, characterized in that the natural binding partner of the CRP is C1q.

13. The method according to claim 12, characterized in that the group of components according to claim 1 (a) or claim 1 (b) comprises C1 q and an anti-C1 q antibody.

14. The method according to claim 2, characterized in that it is a natural binding partner of C1 q in at least one of the components.

15. The method according to claim 14, characterized in that the natural binding partner is CRP.

16. The method according to claim 15, characterized in that the group of components according to claim 2 (a) or claim 2 (b) comprises CRP and an anti-CRP antibody.

17. The method according to claim 1 or 2, characterized in that the signal transmission from the at least one compound or group of compounds according to (b) (donor group) to the at least one compound or group of compounds according to (c) (acceptor group) by emission-free energy transfer he follows.

18. The method according to claim 17, characterized in that it is the emission-free energy transfer is a fluorescence resonance energy transfer.

19. The method according to claim 1 or 2, characterized in that the signal transmission is carried out by singlet oxygen.

20. The method according to claim 19, characterized in that the at least one compound or group of compounds according to claim 1 (b) or 2 (b) (donor group) comprises a compound which, after excitation by a laser triplet oxygen in singlet oxygen convert and the at least one compound or group of compounds according to claim 1 (b) or 2 (b)

(Acceptor group) comprises at least a first compound which can be excited by singlet oxygen and comprises at least a second compound which can absorb the energy absorbed by the compound which can be excited by singlet oxygen without emission and can emit it in the form of fluorescent radiation.

21. The method according to claim 20, characterized in that the donor group and / or the acceptor group are localized on particles.

22. The method according to claim 21, characterized in that the particles have an average diameter of about 200 nm.

23. The method according to any one of claims 1 to 22, characterized in that the method for determining the concentration of a CRP-containing solution of unknown CRP content is used.

24. The method according to any one of claims 1 to 22, characterized in that the method for determining the concentration of a C1q-containing solution of unknown C1 q content is used.

25. The method according to claim 23 or 24, characterized in that the solution is blood serum, blood plasma or by means of a physiological buffer or blood serum or blood plasma diluted by water.

26. The method according to claim 25, characterized in that it is a diagnostic method for determining the inflammatory state of a

Organism and / or to determine the risk of heart attack and / or stroke.

27. The method according to any one of the preceding claims, characterized in that it is an HTS-capable homogeneous method, which as a one-step

Procedure can be carried out.

28. The method of claim 1, comprising as an additional step that before step (a) and / or before step (b) and / or before step (c) and / or before step (d) at least one test substance is added in order to observe whether this influences the binding event between the CRP and the component that binds to the CRP.

29. The method of claim 2, comprising as an additional step that before step (a) and / or before step (b) and / or before step (c) and / or before step (d) at least one test substance is added in order to observe whether this has an influence on the binding event between C1 q and component binding to C1 q.

30. The method according to claim 28 or 29, characterized in that the method is used to determine substances which have a modulating, inhibiting or activating effect on the binding event.

31. HTS-capable, diagnostic test system for determining a

Binding event between CRP and a component binding to CRP, comprising the following components:

(a) at least one donor component or a group of components which contains at least one donor component, the donor component being a component which has at least one compound or group of

Compounds comprising, which can emit a signal after excitation by a light source (donor group), and wherein the donor component is capable of binding to CRP directly or via one or more components from the group of components mentioned, (b) at least one Acceptor component or a group of components which contains at least one acceptor component, the acceptor component being a component which comprises at least one compound or group of compounds which receive the signal emitted by the compound or group of compounds according to (b) and can emit in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is capable of binding to CRP either directly or via one or more components from said group of components.

32. HTS-capable diagnostic test system for determining a

Binding event between C1q and a component binding to C1 q, comprising the following components: (a) at least one donor component or a group of components which contains at least one donor component, the donor component being a component which comprises at least one compound or group of compounds which, after excitation by a light source, can emit a signal ( Donor group), and wherein the donor component is capable of binding to C1q directly or via one or more components from the group of components mentioned,

(b) at least one acceptor component or a group of components which contains at least one acceptor component, the acceptor component being a component which comprises at least one compound or group of compounds which corresponds to that of the compound or group of compounds according to ( b) receive the emitted signal and emit it in the form of electromagnetic radiation (acceptor group), and the acceptor component being able to bind to C1q either directly or via one or more components from the group of components mentioned.

33. HTS-capable test system according to claim 31 or 32, comprising the following further components: (c) blood serum or blood plasma or in physiological buffer or blood serum or blood plasma diluted with water,

(d) a light source for exciting the at least one compound or group of compounds according to (a) (donor group),

(e) a detection system for detecting the emitted electromagnetic radiation according to (b).

34. HTS-capable test system for the determination of active substances which have a modulating effect on the interaction between CRP and a component binding to CRP, comprising the following components: (a) at least one donor component or a group of components which contains at least one donor component, wherein it the donor component is a component which contains at least one compound or group of Compounds comprising, which can emit a signal after excitation by a light source (donor group), and wherein the donor component is capable of receiving the signal emitted by the compound or group of compounds according to (a) and emitting it in the form of electromagnetic radiation wherein the donor component is capable of directly or through one or more

Bind components from the group of components mentioned to CRP,

(b) at least one acceptor component or a group of components which contains at least one acceptor component, the acceptor component being a component which comprises at least one compound or group of compounds which corresponds to that of the compound or group of compounds according to ( b) receive emitted signal and emit it in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is able to bind to CRP either directly or via one or more components from the group of components mentioned,

(c) at least one test compound.

35. HTS-capable test system for determining active substances which have a modulating effect on the interaction between C1 q and a component which binds to C1q, comprising the following components:

(a) at least one donor component or a group of components which contains at least one donor component, the donor component being a component which comprises at least one compound or group of compounds which, after excitation by a light source, can emit a signal ( Donor group), and wherein the donor component is capable of receiving the signal emitted by the compound or group of compounds according to (a) and emitting it in the form of electromagnetic radiation, the donor component being able, directly or via a to bind one or more components from said group of components to C1 q, (b) at least one acceptor component or a group of components which contains at least one acceptor component, the acceptor component being a component which has at least one compound or group of compounds which can receive the signal emitted by the compound or group of compounds according to (b) and emit it in the form of electromagnetic radiation (acceptor group), and wherein the acceptor component is capable of doing this either directly or via an or bind several components from the group of components mentioned to C1q,

(c) at least one test compound.

36. HTS-capable test system according to claim 34 or 35, comprising the following further components:

(d) a light source for exciting the at least one compound or group of compounds according to (a) (donor group),

(e) a detection system for detecting the emitted electromagnetic radiation according to (b).