EP0267918A1 - Process for the production of pure receptors and/or ligands and/or antibodies, materials thus produced and their use - Google Patents

Abstract

A method of producing pure bioactive receptors comprises incubating solubilized receptors bound to ligands with antibodies to ligands (AK I) bound to a support, for example an antibody binding buffer, followed by incubating the receptor-ligand-ligand antibody-immobilized support complex thus obtained, according to a known method, with for example a ligand dissociation buffer, and the dissolution of the bond between the receptors and the ligands. The released and non-immobilized receptors are then separated according to a known method and, where appropriate, the receptors obtained are purified according to a known method. A variant of the method comprises the incubation of the receptor-ligand-antibody complex of ligands with a support linked according to a known method to antibodies which specifically bind to antibodies to ligands (AK II). The receptors are separated by incubation according to a known method, with a ligand dissociation buffer for example, the receptors of the immobilized ligand-antibody I-antibody II-support complex are separated according to a known method and the pure receptors obtained are purified if necessary. if necessary according to a known method.

Description

 Process for the production of pure receptors and / or ligands and / or antibodies, materials produced according to them and their use

The invention relates to methods for the production of native receptors and / or ligands and ligand antibodies binding to them, the use of the pure ligands, receptors or ligand antibodies produced and ligands, receptors and antibodies.

The production of pure, native receptors from these containing materials, such as tissues, cells and cell components, i.e. biological material, as well as native, binding ligands for such receptors is for the investigation of biological receptor-ligand interactions and for the therapeutic replacement of ligands or Intervention in these is extremely important, and is also of great importance for the production of medicaments (ligands are, for example, peptide hormones or the like, but can also be foreign materials, such as viruses, chemotherapeutics or the like). Likewise, ligand antibodies that selectively recognize and bind native ligands are very important for the study of and intervention in ligand / receptor interactions.

An examination of the receptor / ligand interactions or a representation of partial areas of the receptor or also an examination of native groups of the same is only possible if there are certainly biologically bindable, intact receptors. So far, receptors from biological material have been obtained by attaching a carrier material such as Sephadex or the like. bound ligand was brought into contact with the receptor-containing material and, after incubation with it, the specific receptors bound to the immobilized ligands were isolated from the mixture. The immobilized ligands can be placed, for example, in columns through which the biological material runs. The receptors were then separated from the ligands bound to the support material by incubation with a buffer which led to the dissociation of the receptors from the ligands (Fujicka, T. et al., Biochem. Biophys. Res. Comrnun., Vol. 131 (1985 ), Pp. 640-646).

The previous method was disadvantageous in that an already modified ligand was used, of which it was not exactly known whether it binds to its receptor with the same specificity and sensitivity as the native ligand. Due to its connection to the carrier material, the modified ligand is additionally structurally changed, so that it cannot be said with certainty whether it binds to the desired receptor in this modified form or whether it occupies another binding site. The receptors produced according to the state of the art were therefore always subject to changes in the molecule. Up to now, the investigation and structure elucidation of peptide ligands has been carried out exclusively by using peptide ligands which have been isolated from biological materials by chromatographic methods and which, after their synthesis, have been tested for their receptor binding capacity under various conformation changes. However, these methods do not allow sufficient statements regarding the requirements for an optimal receptor binding of the ligand in order to be able to produce peptide-ligands and ligand analogs which largely correspond in their receptor binding ability to that of the native receptor-bound ligand, it is necessary to pure and the native, formerly receptor-bound ligand bioactive in order to be able to determine its conformation parameters (3-dimensional conformation, acetylation, sulfation), which are extremely important for the binding capabilities to its specific receptor.

So far, the isolation and pure presentation of specific Ligana antibodies has been carried out by

Affinity chromatography, the ligand attached to a

Carrier material is bound and that

Serum containing ligand antibodies is incubated with it. The remaining serum components are washed by washing the immobilized antibody-ligand-ligand-antibody

Complex removed. Then the ligand-bound

Ligand antibody detached from the ligand by elution. There with the binding of the ligand to the carrier material, its binding ability and specificity to its specific antibody can be reduced and also ligand antibodies can be bound which bind their native or synthetic ligand only to a reduced extent (e.g. the conformity parameters of the native peptide ligand are used for antibody recognition and retention may be of importance, cannot be taken into account sufficiently because they are not sufficiently known).

The receptors and ligands produced by the method according to the prior art were therefore always subject to changes in the molecule.

It is therefore an object of the invention, pure ligands and

To produce receptors and antibodies for them, which for the first time enable studies on native material.

The task is solved according to the invention by the features listed in the characterizing part of patent claim 1.

Another advantageous method according to the invention is characterized by the features listed in the characterizing part of patent claim 2. Here, “antibody II” is understood to mean material which is capable of binding to the ligand antibody, which also includes substances such as protein A or protein G.

In principle, according to the invention, initially

Ligand / receptor complexes are prepared which are incubated with a ligand-antibody-linked support material. This removes receptors that have no binding sites for the ligand from the mixture. The ligand-bound receptors are then labeled with a

Dissociation buffer detached from its ligands and separated from the rest of the material by dialysis. This makes it possible for the first time to obtain only bioactive receptors that were previously capable of binding with unmodified ligands.

A preferred variant of the method according to the invention for producing bindable ligands comprises the incubation of solubilized cell membranes to whose receptors the native ligand is bound, carrier material linked to a ligand antibody and the removal of non-binding receptors by washing. Incubation and washing are done with an antibody binding buffer. The receptor is detached from its native ligand by incubation with a dissociation buffer. The native ligand is now separated from its antibody by elution and separated from the rest of the material by dialysis or molecular exclusion chromatography. In a preferred embodiment, the method according to the invention for the production of ligand antibodies includes the connection of receptors which are shown purely according to the invention and which may already be linked to their specific ligands, with a carrier material and subsequently with a specific ligand, which can be native or synthetic. This complex is incubated with sera that contain ligand antibodies and were obtained in a conventional manner. This results in a stable carrier-receptor-ligand-ligand-antibody complex to be removed. The specific ligand antibody is then separated in a manner known per se from its receptor-bound ligand by elution with a buffer and the antibody with coeluted ligands is separated, for example by molecular exclusion chromatography or dialysis or similar suitable methods, as is familiar to any person skilled in the art in this field.

Before carrying out the method steps described above, it may be advisable to enrich the receptors in the biological material by incubating the biological material beforehand with an elution or dissociation buffer in order to thereby detach the native, receptor-bound ligand. The detached ligand can be separated from the receptors by dialysis or centrifugation. Removal of ligand binding sites with binding constants other than the receptors, such as materials that synthesize, transport and / or store the ligand, can also be achieved from the biological material. The biological material is incubated with ligand antibody-linked carrier material.

The ligand-binding materials with a greater ligand binding capacity than the receptor are bound to the immobilized ligand antibodies and the ligand-free receptors whose native ligand has been detached by treatment with a dissociation or elution buffer remain in solution. This ligand-free receptor material can then be subjected to one of the further methods according to the invention.

The receptor-ligand bonds can be stabilized in a known manner by cnemic cross-linking ("crosslinking", S. Brenner, VB et al., Cell Vol. 40 (1985), pp. 183-190). The linkage can take place between primary and secondary aliphatic amines on the receptor and ligand side (Tesser, GI et al. Hoppe. Seyler's Z. Physiol. Chem. Vol. 355 (1975) pp. 1624-1629). The use of dithiobis (succinimidyl) propionate (DSP; "cross-linker") which has an internally reducible disulfide bond can achieve a stable receptor-ligand bond which can be achieved under reduction conditions (e.g. dithiothreitoi or Mercaptoethanol) is cleavable again. However, as is known, the incubation with the reducing agents also cleaves disulfide bonds in the receptor molecule and ligand molecule, which can impair the bioactivity of the receptor or ligand if they are essential for its function.

The invention further relates to the use of such pure ligands, receptors or ligands; For example, the receptors according to the invention for the production of poly- or monoclonal receptor antibodies for the isolation and identification of receptor cDNA clones from clone mixtures ("clone immunoprecipitated probes"), such as for the isolation and identification of human glucocorticoid and estrogen receptors (Weinberger , D. et al., Science, Vol. 228 (1985), pp. 740-742 and Walter, P. et al., Proc. Natl. Acad. Sci. USA, Vol. 82 (1985), p. 7889-7893) by formation of a clone-receptor-antibody-protein-ASepharose-4B complex. However, the receptor clones can also be isolated and characterized as such by formation of a clone-ligand-ligand antibody-Sepharose-4B complex according to the invention - it also being possible to use the ligands and ligand antibodies according to the invention. This complex formation for clone isolation is unknown up to now. In addition, the ligand antibodies according to the invention can be used to isolate and characterize ligand cDNA clones by forming a clone-ligand antibody-protein-A-Sepharose-4B complex (Young TA et al., Science, Vol. 222 (1983), p. 86- 88; Mayo, KE et al. Nature, Vol. 306 (1983) pp. 86-88; Helfman, DM et al., Proc. Natl. Acad. Sci. USA, Vol. 8o (1983), pp. 31- 35) can be used.

The receptors, ligands and ligand antibodies according to the invention can also be used to distinguish normal and pathologically modified biological material by conventional methods (RIA) or immunohistochemical methods and the like. are used, with the pure bioactive native substances according to the invention for the first time having a very high specificity and sensitivity.

Specific ligand binding sites on receptors and ligands can also be determined and poly- or monoclonal antibodies against these ligand or receptor binding sites can be produced.

With the help of the pure, bioactive, native according to the invention

Receptors, ligands and ligand antibodies can be used to simplify and more reliably elucidate the mechanisms of action of synthetic or natural active substances and their derivatives (for example tests for

Binding ability of different ligands through receptor blockade via specific receptor antibodies). Specific cell populations, including for example a certain group of T lymphocytes, can be determined via fluorescence activated cell sorter (FACS) or immunoprecipitation (Brenner, MB et al, Nature Vol. 322 (1986), pp. 145-149) using specific receptor antibodies, which are produced by using receptors according to the invention, are isolated. In addition, FACS and immunoprecipitation analyzes can be carried out with the aid of ligands and ligand antibodies according to the invention which are labeled.

Of course, the invention also extends to medicaments which are receptors, ligands or ligand antibodies produced according to the invention, for example poly- or monoclonal antibodies against receptors according to the invention, receptor binding sites or ligand binding sites (for example for blocking receptors on cell surfaces).

Furthermore, the structure of peptide ligands can be elucidated by substances produced according to the invention. So far, peptide ligands have been isolated chromatographically from biological materials and post-synthesized, after synthesis they have been tested for various conformational changes and receptor binding behavior.

Advantageous developments of the features listed in the claims result from the subclaims. In the documents here, "antibody II" means any material that specifically binds to "antibody I", the ligand antibody, including proteins such as protein A or protein G.

By first binding unchanged receptors and unchanged ligands to one another and isolating only receptors / ligands that were securely linked to a receptor prior to their isolation, it can be excluded that ligands or receptors that were not capable of binding are isolated .

The production of the pure receptors opens up a wealth of possibilities, for example to investigate synthetic ligands; to investigate the presence of receptor sites by producing native ligands.

The invention is explained in more detail below with the aid of examples and the accompanying drawing, in which:

FIG. 1 shows a schematic representation of a method according to the invention for producing native receptors, FIG. 2 shows a schematic representation of a variant of the method according to the invention for producing bindable ligands,

3 shows a further preferred embodiment of the method according to the invention for the production of ligand antibodies (I), and

Figure 4 shows a pre-cleaning step of the inventive method for the

Source material.

The invention is illustrated below using the example of the receptor / ligand system of dynorphin-dynorphin receptor, in particular the region of the octapeptide fragment dynorphin-A-1-8

(Tyr-Gly-Gly-Phe-Leu-Arg-Arg-Ile) - hereinafter abbreviated as DA8 - explained in more detail. Dynorphin is an opioid peptide with 17 amino acids, the receptors of which are widely used in the central and peripheral nervous system. DA8 has no internal disulfide bonds. The dynorphin 1-8 receptor is a

Opiate receptor (see Corbett, A.D. et al., Nature, Vol. 299, (1982) pp. 79f f.).

As already explained above, the invention can, however, also be applied to other ligand / receptor systems familiar to the person skilled in the art, such as cDNA / mRNA; Virus / cell surfaces etc. and in no way limited to this application. example 1

Production of carrier-bound receptors or antibodies:

2 g of activated Sepharose 4B was swollen as a carrier in 15 ml of ImM hydrochloric acid for 15 minutes, washed over a sintered glass filter with 500 ml of 1mM HCl (with 50 ml quantities) and then with 50 ml coupling buffer (50 ml 0.1 M sodium bicarbonate (pH 8.0 ), 0.5 M NaCl). Then immediately add 12 ml of coupling buffer with 5 mg of the peptis to be coupled (for example. DA8 antibody, DA8 receptors or porcine anti-rabbit immunoglobulin antibody) to the gel and incubated for 2 hours at 20 ° C. the coupling buffer was removed and the reaction was stopped with 15 ml of 0.2 M glycine (pH 8.0) at 20 ° C. for 2 h; then the gel thus provided with a coupled peptide was transferred to a 10 x 0.7 cm Econo column (BIORAD Laboratories, Ricnmonc, USA), at 20 degrees C three times with coupling buffer - alternating with 0.1 M sodium acetate pH 4.0 and 0.5 M etc.Cl been and cas gel at 4 degrees C in 50 mM TRIS-HCl pH 5, 7 with 0.05 wt. / vol. % Sodium azide saved.

Example 2

Peptide elution

2 ml of the gel was poured into a 10 x 0.7 cm column with

Washed 50 ml of a Tris buffer (50 mM TRIS-HCl, pH 7.6, 1 vol.% Triton X -100), 2 mg peptide (DA8-linked DA8 receptors or Dynorphin-A (1-8) antibodies) in 5 ml of 0.1M sodium bicarbonate (pH 8.0) and 0.5 M NaCl were applied to the column and incubated with recirculation for 16 h at 4 ° C (flow rate: 6-7 ml / h); the eluate was collected and the column was washed with 40 ml of a buffer solution (50 mM TRIS-HCl, pH 7.6 with 0.5 M NaCl, 0.1% by volume Triton X-100 and 1 mM PMSF), the peptide with 40 ml of an elution buffer A (0.1 M glycine-HCl, pH 5.0, with 1.5 mol NaCl, 0.1 mmol PMSF, 0.2 vol.% Triton X-100, 10 ug / ml leupeptin and 20 ug / ml aprotinin for DA8 receptors) or an elution buffer B (0.1M glycine -HCl, pH 2, 5, with 0.1 mM PSF and 0.2 vol.% Triton X-100 for DA8 antibodies) and the eluate in 0.5 ml fractions in 0.01 M phosphate buffer (pH 7.4 with elution buffer A and pH 8.3 neutralized with elution buffer B; neutralization buffer).

Example 3

Production of native DA8 ligands and DA8 receptors Slubilized cell membranes. Producible as described by Stephenson, FA et al. in Eur. J. Biochem. 123 (182), pp. 291-298, which do not contain any receptor-bound DA8, are 2 hours at 20 degrees C. with a ligand binding buffer (50 mM TRIS-HCl, pH 7.6, the 5 mmol Mg ²⁺ , 5 mmol EGTA and 1 mmol

Synthetic pig DA8 contains) incubated. The DA8 receptors are then dissolved in an antibody binding buffer (0.1 M sodium bicarbonate, pH 8.0 with 0.5 NaCl and 0.2% by volume Triton-X-100) and Sepharose-4B linked with DA8 for 16 hours at 4 degrees Celsius incubated. Then the DA8 receptors are incubated (30 min at 20 degrees Celsius) with a dissociation buffer (50mM TRIS-HCl, pH 7.5, with 5 µmol synthetic pig DA8, 5 mM Mg ²⁺ , 5 mM EGTA and 5 µmol 5 ' -Guanylylimido diphosphate (Gpp (NH) p) separated from synthetic DA8, the now free DA8 receptor can now be dialyzed from the rest of the material.

DA8-bound DA8 receptors can also be first used with free D A8 antibodies (diluted 1: 100 with an antibody binding buffer - 0.1M sodium bicarbonate, pH 8.0, with 0.5 M NaCl and 0.2 vol.% Triton X -100) for 15 hours Incubated 4 degrees C and the DA8-bound DAG antibodies are separated from the rest of the material by dialysis (see FIG. 1 of the drawing). This receptor-ligand-ligand antibody is subsequently described

Incubated complex with porcine anti-rabbit immunoglobulin antibody linked to Sepharose-4B (see Example 1). Protein-A-Sepharose-4B (Stephenson, F.a. et al. J. Neurochem. 46 (1986), pp. 854-861) can also be used instead of porcine anti-rabbit immunoglobulin antibody Sepharose 4B. The DA8 receptors are separated from the DA8, as described above, by the dissociation buffer.

In addition, the DA8 receptors can be separated with the elution buffer A in fractions of 500 μl from the DA8 and neutralized immediately with the same volume of the neutralization buffer (pH 7.6). The DA8 receptors can be removed from the coeluted material either by dialysis (if DA8 antibody-Seρharose-4B was used) or by

Dialysis and subsequent molecular exclusion chromatography (if porcine anti-rabbit immunoglobulin Sepharose-4B was used) are separated.

Incubation with DA8 can also take place before the production of cell membranes or before the cell membranes are solubilized.

Example 4

Isolation and display of DA8 and DA8 antibodies Solubilized cell membranes containing only the endogenous receptor-bound DA8 are treated with Sepharose 4B-linked DA8 antibodies in the presence of an antibody binding buffer (0.1M sodium bicarbonate, pH 8.0, with 0.5 M NaCl and 0.2 vol.% Triton X-100) for 16 hours. incubated at 4 degrees C. Thereafter, the DA8 receptors are incubated with the dissociation buffer (50mM TRIS-HCl, pH 7.6, with 5µM welding ne-DA8, 5mM Mg ²⁺ , 5mM EGTA and 5µMol Gpp (NH) p) for 30 min. at 20 degrees C separated from the native DA8.

The DA8 receptor detached from the endogenous DA8 can now be separated from the rest of the material by dialysis or molecular exclusion chromatography.

The endogenous DA8 is then detached from the Sepharose 48-linked DA8 antibodies by the elution buffer B, collected in fractions of 500 μl, immediately neutralized with the same volume of neutralization buffer and separated from the rest of the material by dialysis.

DA8-bound DA8 receptors can also be used beforehand

Incubate DA8 antibody-containing serum in the previously described manner in the antibody binding buffer. The receptor-native DA8 ligand-antibody complex is now incubated with porcine anti-rabbit immunoglobulin antibodies, which are linked to activated Sepharose-4B as described in Example 1, for 16 hours at 4 ° C. Instead of Porcine anti-rabbit immunoglobulin antibody Sepharose-4B can also be used Protein A-Sepharose-4B. The unbound serum components (eg nonimmune immunoglobulins) are thereby removed from the DA8-bound DA8 antibodies by extensive washing. The DA receptor is separated from the endogenous DA8 by incubation with the dissociation buffer as before. The DA8 receptor can be separated from the rest of the material by dialysis. The native DA8, which is still linked to the DA8 antibody, can now, together with the DA8 antibodies from the swine anti-rabbit immunoglobulin antibody linked Sepharose-4B with elution buffer (0.1M glycine-HCl, pH 2.5, with 0.1 mmol PMSF and 0.2 vol.% Triton X-100) can be removed. The eluate contains endogenous, formerly receptor-bound DA8 and specific DA8 antibodies. Subsequent dialysis can be used to display the serum-isolated specific DA8 antibodies and, by molecular exclusion chromatography, the native formerly receptor-blown DA8 α.

In addition, the endogenous DA8 can be separated from its DA8 receptor and its DA8 antibody by incubation with the elution buffer B (0.1 M glycine-HCl, pH 2.5, with 0.1 mmol PMSF and 0.2% by volume Triton X-100) with the neutralization buffer neutralized and separated from the coeluted material by molecular exclusion chromatography. Dialysis gives the DA8 receptor which, when using the elution buffer A is bioactive. Formerly receptor-bound, endogenous DA8, DA8 receptors and DA8 antibodies, which are specific for formerly receptor-bound DA8, have not yet been shown. Both the endogenous DA8 and the DA8 antibodies and the DA8 receptors according to the invention have high sensitivities and specificities.

Example 5

Production of purified DA8 antibodies

Solubilized DA8 receptors, which were connected to activated Seρharose-4B in the manner described above (Example 1), are incubated with the ligand binding buffer at 20 ° C. for 2 hours. Then the DA8-bound DA8 receptors are treated with a serum that is in the

Antibody binding buffer is dissolved, incubated (16 hours at 4 degrees C), which contains specific DA8 antibodies. The specifically DA8-bound DA8 antibodies are detached from DA8 with the elution buffer B (0.1M glycine-HCl, pH 2.5 with 0.1 mol PMSF and 0.2% pre-Triton X - 100) and immediately neutralized with the appropriate neutralization buffer.

Possibly. Coeluted DA8 can be separated from the DA8 antibodies by dialysis in the usual way. Incubation with synthetic or endogenous DA8 can also take place before the production of the cell membranes or before the solubilization of DA8 receptors. Furthermore, instead of solubilized DA8 receptors, DA8 can be bound to Sepharose 4B-linked, DA8 receptor-bearing, non-solubilized biological materials.

DA8 antibodies, which were purified according to the method presented here, show a higher specificity and sensitivity to synthetic pig DA8 than DA8 antibodies, which were purified in the usual way.

Before performing the procedures to make receptors,

DA8 antibodies and endogenous formerly receptor-bound DA8 may need to a) remove such biological material that

DA8 material synthesized, transported or stored. This is done by pre-incubating the biological material with the dissociation buffer (30 min at 20 degrees C). The biological material is then dissolved in the antibody binding buffer, incubated with DA8-antibody-linked Sepharose-4B for 16 hours at 4 ° C. and the unbound biological material is removed by washing. In the washing solution there is that for the purification of DA8 antibodies,

DA8 receptors and endogenous formerly receptor-bound DA8 usable material; b) previously the endogenous receptor-bound DA8 from

Separate DA8 receptor-bearing, non-solubilized cell membranes from its receptor by incubation with the dissociation buffer and then remove them by centrifugation (2x30 min, 20,000 g, 4 degrees C) and washing or by dialysis.

Example 7

Chemical cross-linking of DA8 receptor with DA8

DA8 receptor-DA8 complexes are incubated (30 min. At 20 degrees C) with 50 µg / ml DSP (in 0.01 M phosphate buffer, pH 8.0, with 0.5 M NaCl, 5 mM Mg ²⁺ and 0.1 vol.% Triton-X-100 is cross-linked.

The cross-linking is separated after the Dynorphi nA (1-8) antibody has been bound by incubation with either 3 mM dithiotreitol or 5% mercaptoethanol (both dissolved in 0.01 M phosphate buffer with 0.5 M NaCl, 5 mM Mg ²⁺ and 0.1 vol.% Triton X-100).

Claims

PATENT CLAIMS

1. Process for the production of pure bioactive receptors characterized by a) incubation of solubilized ligand-bound receptors with ligand antibodies (AK I) linked to carrier material, for example in one

Anti-body buffer; b) Incubation of the immobilized receptor-ligand-ligand-antibody carrier material produced in this way Complexes in a manner known per se with a ligand dissociation buffer, for example, with the receptor-ligand binding being released; c) separating the non-immobilized released receptor in a manner known per se and d) optionally cleaning the illustrated receptor in a manner known per se.

2. Modification of the process for the production of pure bioactive receptors according to claim 1, characterized in that a) the receptor-ligand-ligand-antibody complex is incubated with a carrier material to which antibodies are bound in a manner known per se, which specifically binds the Bind ligand antibodies (AK II); b) the receptors are dissolved by incubation in a manner known per se, for example using a ligand dissociation buffer; c) the receptors of the immobilized ligand-antibody I-antibody II-carrier material complex are dissolved in a manner known per se and d) g g f. he r e i n d a rg e s te l l te r e ce tor i n a n i i c h is cleaned in a known manner.

3. Modification of the method for the production of pure, bioactive receptors according to claims 1 and 2 in that instead of AK II-linked Carrier material is a carrier material is used, to which a substance is bound that specifically binds the AK I.

4. Modification of the process for the production of pure, bioactive receptors according to claims 1, 2 and 3 in such a way that a) the detachment of the receptors from their ligands, for example in a manner known per se by a

Elution buffer takes place and that b) the receptors are optionally separated from the co-eluted peptides in a manner known per se.

5. Modification of the process for the production of pure, bioactive receptors according to claims 1 to 4 in such a way that the binding of the ligand takes place either in a manner known per se either before production of the cell membranes or before solubilization of the cell membranes.

6. A process for the production of specific, bioactive Dynorphin-A (1-8) receptors according to claims 1 to 5, characterized by the use of known Dynorphin-A (1-8) antibodies and

Dynorphi n-A (1-8) as ligands.

7. Use of the receptors produced according to claims 1 to 5 a) Production of poly- or monoclonal receptor antibodies including their use for

(1) isolation and identification of receptor cDNA clones,

(2) differentiation of normal or pathologically modified biological material using chemical or immunohistochemical methods,

(3) isolation and characterization of specific receptor and / or ligand binding sites including the production and use of poly- and / or monoclonal antibodies against these ligand and / or receptor binding sites,

(4) Development of test systems to elucidate mechanisms of action of synthetic and / or natural active substances and their derivatives,

(5) isolation of specific cell populations from a heterogeneous cell mixture; b) and as a medicament including poly- and / or monoclonal receptor antibodies and antibodies which are directed against specific ligand and / or receptor binding sites; c) and for the isolation of receptor cDNA clones from a clone mixture by specific binding of a specific ligand-AK I-support material complex according to claims from 1 to 5 to a clone (clone-ligand-AK

I-carrier material complex).

8. Use of the pure, bioactive dynorphin A (1-8) receptors produced according to claims 1 to 5 in accordance with the use claims listed in claim 7.

9. A process for the production of native, formerly receptor-bound bioactive ligands by modifying the process for the production of pure bioactive receptors according to claims 1 to 5 in such a way that a) cell membranes which have only the native receptor-bound ligand, AK I linked to carrier materials are incubated and b) the receptor is removed from the rest of the immobilized material, for example by incubation in a manner known per se with a ligand dissociation buffer and subsequent cleaning, or c) the ligand ospw. is dissolved from the receptor in a manner known per se by elution and d) is purified by in a manner known per se.

10. Modification of the process for the production of native, formerly receptor-bound ligands in such a way that a) the native, receptor-bound ligand is incubated in a manner known per se with a serum which contains the

AK I contains and that b) this receptor-ligand-AK I complex with an AK

I-linked antibody binding buffer is incubated, c) the receptor is detached from the native ligand, for example by incubation in a manner known per se with a ligand dissociation buffer, and is optionally removed in a manner known per se, or d) that in a manner known per se Way the receptor, together with the native ligand and the antibodies I, for example, is removed by elution and e) the native ligand is optionally purified in a manner known per se.

11. Modification of the process for the production of native, formerly receptor-bound ligands according to claim 10, so that instead of AK

II carrier material, a carrier material is used to which a substance is bound which specifically binds the AK 1.

12. Modification of the process for the production of native, formerly receptor-bound ligands and receptors according to claims 9 and 10 in such a way that a) for the purification of bioactive receptors, the receptor is dissolved from the native ligand, for example in a manner known per se, by a ligand dissociation buffer and b) the native ligand and the AK I from the immobilized AK II, for example in a manner known per se, by elution is separated, and c) optionally the receptor and ligand are purified in a manner known per se.

13. A method for the production of pure and bioactive Dynorphi n-A (1-8) receptors according to claims from 9 to 12, characterized by the use of known Dynorphi n-A (1-8) antibodies.

14. Use of the bioactive native ligands and bioactive receptors produced according to claims 9 to 12 in accordance with the use claims of claim 7.

15. Use of the native, formerly receptor-bound, bioactive dynorphin A (1-8), dynorphin A (1-8) receptors and dynorphin A (1-8) antibodies produced according to claims 9 to 12 in accordance with the use claims of claim 7.

16. A process for the preparation of purified AK I by modifying the process for the production of pure bioactive receptors according to claims 1 to 5 in such a way that a) receptor-linked receptor materials are linked to their ligand in a manner known per se and b) this Carrier material al-receptor-ligand complex with a serum containing AK I in a known per se Incubated and c) the AK I are eluted together with the ligand in a manner known per se and d) the AK I are separated from the coeluted ligands in a manner known per se.

17. A process for the preparation of purified dynorphin A (1-8) antibodies according to claim 16 by using Dynorphi nA (1-8) and those dynorphin A (1-8) receptors according to claims 1 to 5 and 9 to 13 were produced.

18. Use of the purified ligand antibodies prepared according to claim 16 in accordance with the use claims from claim 7 including the isolation and characterization of ligand cDNA clones.

19. Use of the purified dynorphin A (1-8) antibodies produced according to claim 16 according to the use claims from claim 7 including the isolation and characterization of

Dynorphin A (1-8) cDNA clones.

20. Process for the production of pure bioactive receptors,

Ligands or ligand antibodies according to one of the aforementioned methods, characterized in that the

Receptor-ligand complexes are chemically linked in a manner known per se.

21. A process for the production of pure bioactive receptors, ligands or ligand antibodies by one of the abovementioned processes, characterized in that the chemical bond according to claim 20 after formation of the receptor-ligand-ligand antibody-carrier material complex according to one of the abovementioned claims in a itself known way is solved again.

22. Amendment of claims 1 to 6, 9 to 13 and 16 to 17 to the effect that the biological material - which synthesizes, transports or stores the ligand - in a manner known per se by incubation with AK

I-connected carrier material is removed from the biological material.

23. Modification of methods 1 to 6, 9 to 13 and 16 to 17 in such a way that the biological material - the dynorphin-A (1-8) synthesizes, transports or stores - in a manner known per se by incubation with dynorphin-A (1-8) antibody-linked carrier material is removed from the biological material mixture.

24. Modification of claims 1 to 6, 9 to 13 and 16 to 17 in such a way that the native, receptor-bound ligand is previously detached from its receptor, for example in a manner known per se, using a ligand dissociation buffer or an elution buffer.