EP1294926A2

EP1294926A2 - Test system for determining the activity of cyclo-nucleotide-dependent protein kinases and vasp phosphatases

Info

Publication number: EP1294926A2
Application number: EP01938257A
Authority: EP
Inventors: Peter DRÜCKES; Thomas Jarchau; Ulrich Walter; Benjamin Bader
Original assignee: Vasopharm Biotech GmbH
Current assignee: Verinos Operations GmbH
Priority date: 2000-06-14
Filing date: 2001-06-12
Publication date: 2003-03-26
Also published as: WO2001096594A2; AU2001263956A1; DE10029210A1; US20030166005A1; WO2001096594A3

Abstract

The invention relates to an HTS-appropriate test system for detecting the activity of cyclo-nucleotide-dependent protein kinases (cNPK) containing: a) at least one test compound; b) at least one appropriate cNPK substrate; c) at least one composition, which is to be incubated and which contains cNPK and ATP, optionally, phosphorylation reaction stoppers, and; d) an appropriate detection system for quantifying the phosphorylation of the cNPK substrate. The invention also relates to an HTS-appropriate test system for detecting the activity of VASP phosphatases containing: e) at least one test compound; f) at least one appropriate VASP phosphatase substrate; g) at least one composition, which is to be incubated and which contains VASP phosphatase, and; h) an appropriate detection system for quantifying the dephosphorylation of the VASP phosphatase substrate. The described test systems can be used for locating compounds, which modulate the activity of a cNPK or of a VASP phosphatase, from chemical or natural substance libraries.

Description

description

Test system for determining the activity of cyclo-nucleotide-dependent protein kinases and VASP phosphatases

The present invention relates to a test system for the detection of the activity of cyclo-nucleotide-dependent protein kinases or of phosphatases which dephosphorylate the vasodilator-stimulated phosphoprotein (“VASP”), process for its production and its use in (high throughput) screening processes ,

Cyclo-nucleotide-dependent protein kinases ("cNPK"), their substrates ("cNPKS"), and the corresponding protein phosphatases are part of important physiologically, pathophysiologically and pharmacologically relevant cellular signaling pathways (see citations 1, 2 and 3). The cNPK include cAMP-dependent protein kinases ("cAK") and cGMP-dependent protein kinases ("cGK"). In addition to other cGMP effector systems, e.g. cGMP-regulated phosphodiesterases and ion channels, cGK in particular is an important mediator of cGMP-mediated signal transmission.

For the signals that lead to an increase in the intracellular cGMP level, a distinction is made between those that cause this by membrane-bound guanylyl cyclases (GC-A, GC-B, GC-C), such as, for example, sodium peptides (short: ANP, BNP, CNP) and enterotoxin / guanylin, and those that activate soluble guanylyl cyclase (GC-S). One of the most important agonists of soluble guanylyl cyclase is the nitrogen monoxide (NO) formed by the NO synthases (NOS III-III). The established effects caused by an increase in cGMP include relaxation of smooth muscle cells (SMCs) and inhibition of platelet activation. These cGMP effects are mediated by the cGK (type I) (see citations 1-3). This could be confirmed in corresponding mouse models with cGK-1 deficiency (see citations 4 and 5). cGK are known as homodimers, from which a soluble (monomer 76 kDa; cGK I) and a membrane-based form (monomer 86 kDa; cGK II) can be distinguished. The membrane anchorage of the cGK II is mediated via the N-terminal myristoylation (cf. citations 1-3). There are two isoforms of cGK I and cGK Iß of cGK I. Interestingly, cGK I, which is generally referred to as soluble form, is predominantly present in platelets and partially in smooth muscle cells. A particularly high expression of cGK I can be found in human blood platelets and in smooth muscle cells. Activation of cGK-1 in these cells leads to the effects already described above, such as lowering the intracellular Ca (2+) level, inhibiting blood platelets and the contraction of smooth muscle cells.

The known substrates of cGK include, among others, e.g. the inositol 1, 4,5-triphosphate receptor (IP3R) and the VASP, as well as p25, cystic fibrosis transmembrane regulator (CFTR) and 6-pyruvoyl tetrahydro-pterine synthase (PTPS).

Disorders of the ANF / NO / cGMP pathway are known for the various forms of atherosclerosis and hypertension, and the so-called "endothelial dysfunction", a disturbed endothelium-mediated vasodilation, is an early feature of vascular diseases associated with atherosclerosis, hypertension and diabetes (see citations 6 and 7.) Current evidence shows that the activation and / or expression of soluble guanylyl cyclase in particular is pathologically reduced in these vascular diseases (see citations 8-10) NO / cGMP signaling pathways are of major therapeutic importance, as evidenced by the success of NO donors such as nitroprusside, nitroglycerin, molsidomines, and more recently by NO-independent sGC activators such as YC-1 and derivatives, which have been tried and tested There is a great need for additional, new substances because there are unsolved problems (tolerance development ng, toxic side effects etc). It would therefore be desirable to activate the cGK directly, preferably cGK-1, since this is still expressed in pathologically altered vascular sections (cf. citation 10-11). The fact that not all effects caused by NO or cGMP are mediated by cGK has the potential that only some of the otherwise broadly specific ones Allow effects of this signal path to be influenced and some undesirable side effects are therefore avoided. So far, only cell membrane permeable cGMP analogs (e.g. 8-Br-cGMP, 8-pCPT-cGMP) have been described as activators of cGK, while certain cGMP analogs (Rp-8Br-PET-cGMPS, Rp-8-pCPT-cGMPS) and isoquinolinesulfonamide derivatives (KT 5823, H8 and H89) which inhibit cGK (cf. quote 12).

A high-throughput screening approach for the systematic search for direct cGK activators and / or inhibitors or for direct activators and / or inhibitors of VASP phosphatase has not yet been carried out. Peptide-cNPK substrates and inhibitors are used to find complex combinatorial peptide libraries (cf. quote 13).

In the prior art, cNPK assays are usually carried out by incorporating radioactive phosphorus isotopes ( ³² P or ³³ P) in peptide substrates and then separating these reaction products from the starting materials, for example by immobilizing them on a carrier substance (citation 16) or by separating them Reaction products using gel electrophoresis and radio- or immunochemical detection after protein transfer to membranes in the presence of product-specific antibodies (such as in a Western blot, WO 99 / 24,473). In the latter case, quantification of the product concentrations formed is technically particularly complex and less reliable only as a semiquantitative relative determination to a selected standard and is therefore not feasible for the exact determination of enzyme activities. The supply and disposal of radioactive isotopes in the quantities required for this, which represents a cost-intensive and safety-related burden, can be disadvantageous. On the other hand, the measurement of radioactive samples with the required accuracy takes a relatively long time. In particular, gels are materially complex and time-consuming to process.

Since the methods known in the prior art include separation and washing steps, they are unsuitable for the analysis of a large number of test compounds using automated systems. It has emerged as a particular advantage of the present invention that the test system described (synonym: assay or diagnostic) is suitable for the effect on a large number of (test) compounds, preferably from chemical or natural substance libraries, in a simple manner to be able to investigate the activity of a cNPK [so-called. High Throughput Screening (short: HTS)].

Another particular advantage of the present invention has been found that the test system can be used to test a large number of (test) compounds from chemical or natural substance libraries in a simple and effective manner for their effect on the activity of a VASP phosphatase [ so-called. High Throughput Screening (short: HTS)].

It has now been found that in the test system described, even without separating the products and without the use of radioactive phosphorus isotopes ( ³² P or ³³ P), it is possible to demonstrate the activity of a cNPK or a protein phosphatase, which has the disadvantages described above in the prior art overcomes the technology and is therefore suitable for the HTS, for example in an automated system.

The present invention therefore relates to an HTS-suitable test system for detecting the activity of a cNPK containing a) at least one test compound b) at least one suitable cNPK substrate (cNPKS) c) at least one composition to be incubated containing cNPK and ATP, and d) a suitable detection system for the quantitative determination of the amount of the phosphorylated cNPK substrate.

The present invention therefore furthermore relates to an HTS-suitable test system for detecting the activity of the VASP phosphatase containing e) at least one test compound, f) at least one suitable VASP phosphatase substrate, g) at least one composition to be incubated containing VASP phosphatase , and h) a suitable detection system for the quantitative determination of the amount of dephosphorylated VASP phosphatase substrate.

Both objects mentioned are referred to below as the test system according to the invention.

As a gel-free test system, the test system according to the invention enables a large number of quantitative individual determinations and, by dispensing with gel electrophoretic separation steps, fulfills special requirements with regard to speed, sample size and material consumption. Reproducibility, robustness, solvent tolerance and automation are also guaranteed.

The test system according to the invention allows the search for one or more, the same or different test compounds.

The cNPK used is preferably a cGK or cAK or a functional variant with the activity of a cNPK. Such protein kinases can be used in purified form or as a crude extract, in particular as a component in protein mixtures from homogenates of biological origin, preferably of human origin.

The VASP phosphatase used can also be a functional variant with the activity of a VASP phosphatase. VASP phosphatases can be used in purified form or as a crude extract, in particular as a component in protein mixtures from homogenates of biological origin, preferably of human origin.

VASP is very particularly preferred as a suitable cNPK substrate according to feature (b) - according to SEQ ID No. 1 (described in C. Haffner et al. In EMBO J., 14 (1), 19-27 (1995)) —containing preferably usable phosphorylation sites, namely: serine-157, serine-239 and threonine-278. Basically, cNPK can phosphorylate all three residues, but the cAMP-dependent protein kinase serine 157 is preferred as the main phosphorylation site, while the cGMP-dependent protein kinase Serine-239 preferred. Threonine-278 is phosphorylated by both kinases with a comparable specificity.

Very particularly preferred as a suitable VASP phosphatase substrate according to feature (b) is phosphorylated VASP, corresponding to SEQ ID No. 1, which is phosphorylated at the preferred operable phosphorylation sites, namely: Serin-157, Serin-239 and Threonin-278.

Within the scope of the test system according to the invention, such peptide or polypeptide variants or peptoids can also be used as functional variants of a cNPK substrate or a VASP phosphatase substrate, which preferably contain amino acid sequences from VASP, which are present in the vicinity of the phosphorylation or dephosphorylation sites mentioned and although not finally particularly preferably the pentamers with the amino acids 155-159 and / or 237-241 and / or 276-280 according to SEQ ID No. 1 or preferably the decamers with the amino acids 152-161 and / or 234-243 and / or 273-282 from SEQ ID No. 1 or other suitable partial sequences (e.g. see in Fig. 1).

Such peptides phosphorylated according to the invention can be detected particularly advantageously with suitable antibodies in terms of features (d) or (h), preferably monoclonal antibodies.

According to the invention, the monoclonal antibody 16C2, which is selected and obtainable from the hybridoma cell line DSM ACC2330, is very particularly preferably used (WO 99/24473). This antibody or a functional variant thereof specifically detects a phosphorylation event, very particularly preferably it recognizes an epitope which contains the phosphorylated serine 239 of the VASP sequence. A functional variant relates in particular to those antibodies with an agreement of preferably 90-99% or 70-90% in the amino acid sequence of 16C2 with the homologous function of quantitatively determining a reaction product in the sense of feature (d) or (h). The test system according to the invention can be run both heterogeneously (for example after immobilization of the reaction products) but preferably homogeneously. Depending on the method of implementation, the immunological detection in the sense of features (d) or (h) can be carried out according to the methods known to the person skilled in the art, such as, for example, coupled enzyme reaction (alkaline phosphatase or luciferase) or general sandwich technologies (for example ELISA), and fluorimetric methods (fluorescence , time-resolved fluorescence, fluorescence resonance energy transfer (FRET)).

Easily detectable radioactively labeled or particularly preferably non-radioactively labeled, in particular fluorescence-labeled, antibodies are preferred. Lanthanide chelates are particularly suitable. The time-resolved fluorescence resonance energy transfer technique can also be accessed particularly advantageously (FIG. 1). Such TR-FRET systems are described in WO 97/29373 and WO 98/15830 and are commercially available from Wallac Oy (Turku, FI). See also "Miniaturization of a Lance ™ Assay" and "Use of Generic Reagent in Lance ™" published by Wallac Oy, Turku, FI.

However, the test system according to the invention can preferably be automated as a homogeneous HTS and is therefore suitable for 96, 384, 1536-well plates and more.

To carry out the tests, it is preferred to use other aids, such as. B. use buffer solutions, stabilizers and / or energy equivalents, especially ATP.

The present invention also relates to a method for producing a test system, in which at least one compound to be examined and at least one composition containing cNPK, ATP and cNPK substrate, optionally a phosphorylation reaction stopper, at least one suitable detection system, such as an antibody, including an immunological detection agent and if necessary, other aids are put together

The present invention also relates to a method for producing a test system, in which at least one compound to be examined, at least a composition containing VASP phosphatase and at least one suitable detection system for quantifying the dephosphorylation of a VASP phosphatase substrate are put together.

Preferred embodiments of the individual components have already been described in more detail above.

The present invention further provides an HTS-suitable method for finding one or more active compounds which modulates the activity of the cNPK, comprising the steps: i) bringing the compound to be investigated or a multiplicity of compounds to be investigated into contact with cNPK, ATP and a suitable cNPK substrate, and j) quantification of the phosphorylated cNPK substrate with a suitable detection system, if necessary after termination of the phosphorylation reaction with a suitable phosphorylation reaction stopper.

The present invention furthermore relates to an HTS-suitable method for finding one or more active compounds which modulate the activity of VASP phosphatase, comprising the steps: k) bringing the compound to be investigated or a multiplicity of compounds to be investigated into contact VASP phosphatase and a suitable VASP phosphatase substrate, and I) quantification of the dephosphorylated VASP phosphatase substrate with a suitable detection system, if necessary after termination of the dephosphorylation reaction with a suitable dephosphorylation reaction stopper

In a preferred embodiment, the method for finding a chemical compound as described above takes place in a microtiter plate. The microtiter plate can contain different numbers of vessels. For example, it may contain 96, 384, 768, 1536, 3072 or more vessels. Preferred individual components of the method according to the invention have already been described in more detail above. The active (test) compound can be a pharmaceutically active compound in the function of a modulator - such as (hyper) activator / or (total) inhibitor - for the activity of a cNPK or a natural product in the broadest sense, in particular a raw extract, or a component contained therein. The substance to be examined is generally a naturally occurring, a naturally occurring and chemically modified and / or a synthetic substance. In particular, so-called combinatorial substance libraries can be searched particularly easily and quickly with the methods according to the invention.

Such a connection is very particularly preferably suitable which, bypassing the NO / cGMP signal path, directly modulates - activates or inhibits a cNPK; optionally modulated selectively - activated or inhibited.

The invention therefore also relates to a method in which the pharmaceutically active compound modulates a cNPK signaling pathway.

The introduction to the description has already indicated that various diseases can be attributed to a disorder of the cyclo-nucleotide-dependent protein kinases (cNPK). The present invention is therefore also suitable for diagnosing a disease.

Another object of the present invention is therefore a method for diagnosis by the direct and gel electrophoresis-independent determination of the cNPK activity from samples, comprising the steps: m) incubating a sample in the presence of at least one composition containing suitable cNPKS and possibly ATP, n ) Adding at least one suitable detection system to the composition to quantify the phosphorylation of the cNPKS; and o) determining the activity of the cNPK, in particular in blood / cell or tissue extracts or in the form of permeabilized and / or intact cells.

Another object of the invention is a method for diagnosis by the direct and gel electrophoresis-independent determination of the VASP phosphatase activity from samples, comprising the steps: p) incubating a sample in the presence of at least one composition containing a suitable VASP phosphatase substrate q) adding at least one suitable detection system to the composition to quantify the dephosphorylation of the VASP phosphatase substrate; and r) determination of the activity of VASP phosphatase, in particular in blood / cell or tissue extracts or in the form of permeabilized and / or intact cells.

The diseases to be diagnosed are preferably cardiovascular diseases and diseases with associated vascular damage, e.g. Hypertension, thrombosis and endothelial dysfunction syndrome, e.g. in arteriosclerosis, diabetes, vasculitis and diseases of hematopoietic cells such as acute leukaemias, myeloproliferative diseases, myelodysplasias (see quote 17).

The following figures and examples are intended to describe the invention in more detail without restricting it.

FIG. 1 shows a preferred embodiment of the test system according to the invention. The cGK activity assay is based on the observation of the in vitro phosphorylation of a biotinylated substrate peptide by activated cGK (cf. FIG. 1A). The VASP substrate peptide consists of a partial sequence of the amino acid sequence of human VASP (vasodilator stimulated phosphoprotein), a natural cGK substrate protein. The phosphorylated VASP substrate peptide was surprisingly detectable with the aid of a detection system based on time-resolved fluorescence resonance energy transfer (FRET) (compare FIG. 1B). Main components with the following chemical properties were present in a special mixing ratio in the detection system:

1. The anti-pSer239-VASP (mAb 16C2) monoclonal antibody, which surprisingly specifically recognized the phosphorylated VASP substrate peptide (and left non-phosphorylated VASP substrate peptide undetected).

2. A Europium-labeled anti-mouse IgG secondary antibody that can specifically bind to the anti-pSer239-VASP (mAb 16C2). 3. Fluorescence-labeled streptavidin (SA-APC) that can bind the biotin group of the VASP substrate peptide.

With a special mixing ratio of all three components and the phosphorylated VASP substrate peptide and with suitable light excitation (340 nm) of the Europium-labeled antibody, a fluorescence resonance energy transfer (FRET) to the second fluorescence component, SA-APC, was found Light emission at 660 nm could be observed. This test system had the interesting properties observed in the following figures and examples.

FIG. 2 shows the kinetics of the phosphorylation of the biotinylated substrate peptide by the cGK. The ordinate of FIG. 2 shows the measured FRET signal in cps. The VASP substrate peptide is only phosphorylated in the presence of the cGK and its activator cGMP (tube A). No signal change was observed without cGMP and with cGK (tube B) and without cGK and with cGMP (tube C).

FIG. 3 shows the activation of the cGK with the natural activator cGMP and a cGMP-analogous molecule (8-pCPT-cGMP), measured with the test system described. The enzyme activity (in cps / min) is plotted against the activator concentration (in mol / l).

FIG. 4 shows the surprising finding that with the test system according to the invention, the enzyme activity of the cGK contained in platelet extracts in this complex biological protein mixture can be observed and quantitatively measured. FIG. 4A shows no difference between the phosphorylation kinetics without (D) and with the specific cAK inhibitor PKI (x). FIG. 4B shows the influence of 100 nmol / l PKI on the phosphorylation of the VASP substrate peptide by purified cGK (0.3 nmol / l) without (D) and with PKI (x) and the influence of PKI on purified cAK (catalytic subunit, 3 nmol / l) without (O) and with PKI (•). Example 1: FRET detection system and titration of the measuring range with phosphopeptide

To establish and optimize the detection system, a synthetic phosphopeptide (phosphorylated version of the VASP substrate peptide) was used as a "reaction product" instead of a kinase reaction and quantified with a detection mix. In order to determine the linear measuring range, different mixtures of non-phosphorylated peptide and phosphopeptide were produced. The total concentration of peptide was kept constant at 500 nmol / l. 50 μl of these mixtures were placed in the wells of a “96 well” microtest plate and 200 μl each of a detection mix containing the following reagents, diluted in PBS:

anti-pSer239-VASP (mAb 16C2) 1 nmol / l anti-mouse-Eu (W1024, PE Wallac) 1 nmo / l

Streptavidin-APC 2 g / ml

Bovine serum albumin 0J g / l

The measurement of the time-resolved FRET signal when the Europium fluorescence was excited at 340 nm and the emission of the APC fluorescence at 660 nm was carried out after 1 hour of incubation at 20 ° C using a PerkinElmer Wallac fluorescence meter (Victor ² ). The following table shows an almost linear increase between 0-100 nmol / l phosphopeptide. At 160 nmol / l phosphopeptide, the signal cannot be increased further.

Table 1: Titration of the measuring range with phosphopeptide

The signal-to-background ratio, defined by the quotient of the maximum signal and the signal without phospho-peptide, was about 5. For the detection in "384 well" plates, there was an optimal signal / background ratio when 20 μ \ of a solution containing 500 nmol / l VASP substrate peptide were mixed with 40 μ of a detection mix containing the above-mentioned concentrations of the detection reagents. This protocol was used in all further experiments.

Example 2: Quantification of enzyme activity

The linearity of the measuring range in titration with the help of synthetically produced phosphopeptide found in Example 1, Table 1 enables the standardization and quantification of the enzymatic kinase reactions based on the test system according to the invention. The measurement signal, expressed in cps, can be converted directly into molar concentration of phosphorylated peptide, as a result of which the activity measured with the test system described can be converted into international enzyme units (1 unit = 1 μmol / min).

The activity of an enzyme reaction carried out in a volume of 100 / I, in which a signal of 9872 cps is measured within 2 minutes, corresponds to an activity which converts 2 pmol substrate in 2 minutes, which corresponds to an enzyme activity of 1 x 10 ^{" 6} U corresponds.

Example 3: Kinase reaction

In the usual radioactive kinase assays, high concentrations of VASP substrate peptide (50-100 mol / l) and enzyme are required (cf. quote 16). Using the test system described in FIG. 1, no kinase activity could be detected at high substrate peptide concentrations. By reducing the substrate concentration to 1 mol / l could also be measured for the first time with the FRET detection of enzyme kinetics (see FIG. 2).

However, the use of high enzyme concentrations with a low substrate concentration led to an increase in the non-stimulated basal activity of the kinase, that is to say activity was measured even without the specific activator cGMP, which could not be increased or could only be increased slightly by adding cGMP. This problem could be overcome by reducing the enzyme concentration to 50 ng / ml and less (see quote 14). The authentic enzyme activity of the cGK can thus be measured with the test system according to the invention.

The following components were mixed in three reaction vessels:

Tris / HCl, pH 7.4 20 mmol / l

MgCl ₂ 10 mmol / l β-mercaptoethanol 5 mmol / l

BSA 0.01 g / l biotinylated VASP substrate peptide (biotin-VASP 231-245) 1 μmol / l

Vessel A also contained 5 μmol / l cGMP and 25 ng / ml purified cGK. Vessel B also contained 25 ng / ml purified cGK. Vessel C also contained 5 μmol / l cGMP.

After pre-incubation of the tubes at 30 ° C for 5 minutes, the kinase reaction was started with 50 // mol / l ATP with further incubation at 30 ° C. All concentrations given above are to be understood as final concentrations in a volume of 500 μ \. At the times indicated, 50 μ \ were removed from the vessels at the end of the reaction and mixed with 50 μ \ of a 30 mmol / l EDTA solution. The phosphorylated substrate peptide was detected as described in Example 1 in the wells of a "384 well" microtest plate.

It can be seen from FIG. 2 that the VASP substrate peptide is phosphorylated only in the presence of the cGK and its activator cGMP (vessel A). Without cGMP and with cGK (tube B), without cGK and with cGMP (tube C), no signal change was observed.

Example 4: Suitability for the Carephone

The test system according to the invention is suitable in the form shown for high-throughput screening. With the help of commercially available pipetting robots (e.g. the Biomek systems from Beckman or the Genesis Workstation from Tecan), microtest plates in 96, 384 and even 1536 well format can be processed. The cGK assay could be implemented for such a robot system in 384 well format as follows for screening for activators of the cGK. The following are pipetted sequentially:

1. 20 ul of a solution containing buffer, cGK, substrate peptide

2. 5 μ \ of a test substance in DMSO

3. Start the reaction with 5 μ \ of an ATP solution

4. Stop the reaction by simultaneously adding EDTA and the detection reagents.

Most substances that are tested in the HTS are preferably dissolved in DMSO. However, many enzymes or test systems are very sensitive to DMSO. To determine the influence of DMSO on the test system according to the invention, phosphorylation kinetics, as described in Example 2 (cf. FIG. 2), were carried out in the presence of 0, 5, 10, 15 and 20% DMSO. Table 2 summarizes the enzyme activities obtained after an incubation time of 10 min. The test system according to the invention is very robust in this respect. Addition of up to 20 percent by volume of DMSO has no significant influence on the reaction. Table 2: Influence of DMSO on enzyme activity in the test system according to the invention

Example 5: Activation curve of the cGK

The dose-dependent activation of the cGK by the natural activator cGMP and a cGMP-analogous molecule (8-pCPT-cGMP) can be analyzed with the test system according to the invention. 8 kinase reactions (as described in Example 3, total volume 500 μ) were carried out, which contained the following components:

20 mmol / l Tris / HCl, pH 7.4

10 mmol / l MgCl ₂

5 mmol / l ß-mercaptoethanol

0.01 g / l BSA

1 μmol / l biotinylated VASP substrate peptide (biotin-VASP 231 -245)

25 ng / ml cGK

50 mol / I ATP different concentrations of cGMP or 8-pCPT-cGMP from 10 ^"9 - 10 ^{" 5} mol / l

After 0, 5, 10, 20, 60 minutes incubation at 30 ° C, partial volumes of 50 μ \ were removed and mixed with 50 μ \ 30 / mol / l EDTA. The phosphorylated substrate peptide was then detected as described in Example 2. From the Kineti Depending on the phosphorylation of the VASP substrate peptide, the respective initial velocities in cps / min were calculated at different activator concentrations. These are plotted against the activator concentration in FIG. 3.

The activation curves obtained with the test system according to the invention and the activation constants calculated therefrom for cGMP (0.26 μmol / l) and 8-pCPT-cGMP (0.10 μmol / l) are comparable to data published for these substances using conventional radioactive methods were determined (see citation 14).

Example 6: Determination of cGK activity in tissue extracts

The test system according to the invention is suitable for specifically measuring the activity of the cGK in tissue extracts or platelet lysates.

Platelets were prepared using a known method (cf. quote 15). After producing a soluble platelet extract, this was tested without activator and with 8-pCPT-cGMP (0.5 μmol / l) according to Example 3. In addition to 8-pCPT-cGMP, a third reaction vessel also contained 100 nmol / l PKI. This inhibitor specifically inactivates the cAMP-dependent protein kinase (cAK), which is also present in platelets. FIG. 4A shows no difference between the phosphorylation kinetics without and with PKI. FIG. 4B shows the influence of 100 nmol / l PKI on the phosphorylation of the VASP substrate peptide by purified cGK (0.3 nmol / l) and purified cAK (catalytic subunit, 3 nmol / I). The concentration of PKI used is sufficient to completely inhibit cAK. The activity of the cGK is not affected.

FIGS. 4A and 4B together therefore show that the test system according to the invention can very specifically measure the cGK activity in complex samples such as platelet lysates. Cross activity by the cAK can be excluded. Likewise, cGK activity could be measured in tissue homogenates from rat organs. Abbreviations used in the text and figures:

8-pCPT- = 8- (4-chlorophenylthio) - cAMP = cyclo-adenosine-3 ', 5'-monophosphate

APC = allophycocyanin

ATP = adenosine 5'-triphosphate

BSA = bovine serum albumin cAK = cAMP-dependent protein kinase cGK = cGMP-dependent protein kinases cGMP = cyclo-guanosine-3 ', 5'-monophosphate cNPKS = substrate for cyclo-nuceotide-dependent protein kinases cNPK = cyclo-nucleotide-dependent protein kinases

DMSO = dimethyl sulfoxide

Eu = Europium

HTS = high-throughput screening

LANCE = Lanthanide Chelate Excitation Technology mAb = monoclonal antibody

PKI = protein kinase A specific inhibitor

SA = streptavidin

TR-FRET = Time-Resolved-Fluorescence-Resonance-Energy-Transfer

VASP = Vasodilator-stimulated phosphoprotein

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Claims

claims:

1. HTS-suitable test system for detecting the activity of the cyclo-nucleotide-dependent protein kinases (cNPK) containing a) at least one test compound, b) at least one suitable cNPK substrate (cNPKS), c) at least one composition to be incubated containing cNPK and ATP , and d) a suitable detection system for the quantitative determination of the amount of the phosphorylated cNPK substrate.

2. HTS-suitable test system for detecting the activity of VASP phosphatase containing e) at least one test compound, f) at least one suitable VASP phosphatase substrate, g) at least one composition to be incubated containing VASP phosphatase, and h) a suitable detection system for quantitative determination of the amount of dephosphorylated VASP phosphatase substrate.

3. Test system according to claim 1 or 2, wherein the test system is automatable and heterogeneous with separation or immobilization of at least one of the reaction products or detection reagents.

4. Test system according to claim 1 or 2, wherein the test system can be automated and is homogeneous.

5. Test system according to one of claims 1 to 4, wherein the test system is non-radioactive.

6. Test system according to claim 1 or 2, characterized in that the cNPK substrate according to feature (b) or the VASP phosphatase substrate according to feature (f) is selected from SEQ ID No. 1 or a functional variant thereof.

7. Test system according to claim 6, characterized in that the cNPK substrate is a peptide, polypeptide or peptoid containing the pentamers with the amino acids 155-159 and / or 237-241 and / or 276-280 from SEQ ID No. 1 or the decamers with the amino acids 152-161 and / or 234-243 and / or 273-282 from SEQ ID No. 1.

8. Test system according to claim 1, characterized in that the cNPK, preferably a cAMP and / or cGMP kinase, or a functional variant thereof.

9. Test system according to claim 8, characterized in that the cNPK are present in purified form, in the form of Blu cell or tissue extracts or in the form of permeabilized and / or intact cells.

10. Test system according to one of claims 1 to 9, characterized in that the detection system for quantifying the phosphorylation of the cNPK substrate or the dephosphorylation of the VASP phosphatase substrate contains at least one suitable antibody for the phosphorylated product or for the dephosphorylated product.

11. Test system according to claim 10, characterized in that the antibody is formed by the hybridoma cell line DSM ACC2330, in particular the monoclonal antibody 16C2 or a functional variant thereof.

12. Test system according to claim 10 or 11, characterized in that the detection system has two antibodies, of which the first antibody is unlabeled and the second antibody is marked.

13. Test system according to claim 10 or 11, characterized in that the detection system has at least one labeled antibody, and a suitable system for detecting the label.

14. Test system according to claim 10 or 11, characterized in that the antibody contains a fluorophore.

15. Test system according to one of claims 1 to 14, characterized in that the detection system is based on fluorescence resonance energy transfer (FRET), with at least one labeled, preferably a fluorophore-labeled, first or second antibody and a corresponding acceptor - Or donor fluorophore, preferably on the cNPK substrate, can be used.

16. Test system according to claim 15, characterized in that the detection system is based on a time-resolved FRET system with lanthanide chelates, preferably europium chelates.

17. Test system according to one of claims 1 to 16, characterized in that buffer solutions, stabilizers and / or energy equivalents are used as further auxiliaries.

18. A method for producing a test system according to claim 1, characterized in that at least one compound to be examined and at least one composition containing cNPK and ATP, and at least one suitable detection system for the quantitative determination of the amount of the phosphorylated cNPK substrate are put together.

19. A method for producing a test system according to claim 2, characterized in that at least one compound to be investigated, at least one composition containing VASP phosphatase and at least one suitable detection system for the quantitative determination of the amount of dephosphorylated VASP phosphatase substrate are put together.

20. HTS-suitable method for finding one or more active compounds which modulate the activity of the cNPK, comprising the steps i) contacting the compound to be investigated or a multiplicity of compounds to be investigated with cNPK, ATP and suitable cNPK- Substrate, and j) quantification of the phosphorylated cNPK substrate with a suitable detection system.

21. HTS-suitable method for finding one or more active compounds which modulate the activity of VASP phosphatase, comprising the steps: k) contacting the compound to be investigated or a multiplicity of compounds to be investigated with VASP phosphatase and suitable VASP phosphatase substrate, and

I) Quantification of the dephosphorylated VASP phosphatase substrate using a suitable detection system.

22. The method according to any one of claims 20 to 21, characterized in that the compound to be examined is selected from a naturally occurring, naturally occurring and chemically modified and / or synthetic compound.

23. The method according to claim 22, characterized in that the compound to be examined is used in the form of a combinatorial substance library.

24. A method for diagnosis by direct and gel electrophoresis-independent determination of the cNPK activity from samples comprising the steps: m) incubating a sample in the presence of at least one composition containing suitable cNPKS and ATP, n) adding the composition with at least one suitable detection system for quantification phosphorylation of the cNPKS; and o) determining the activity of the cNPK, in particular in blood cell or tissue extracts or in the form of permeabilized and / or intact cells.

25. A method for diagnosis by direct and gel electrophoresis-independent determination of the VASP phosphatase activity from samples comprising the steps: p) incubating a sample in the presence of at least one composition containing a suitable VASP phosphatase substrate q) adding at least one suitable to the composition Detection system for quantifying the dephosphorylation of the VASP phosphatase substrate; and r) Determination of the activity of the VASP phosphatase, in particular in Blu cell or tissue extracts or in the form of permeabilized and / or intact cells.

26. The method according to claim 24 or 25, characterized in that it is the diagnosis of a disease which is selected from the spectrum of cardiovascular diseases and diseases with associated vascular damage, in particular hypertension, thrombosis, and the syndrome of endothelial dys- Function in arteriosclerosis, diabetes and vasculitis, or diseases of hematopoietic cells, such as acute leukemia, myeloproliferative diseases or myelodysplasias.