Quantitative, high-throughput cell-based assays for inhibitors of trkA receptor.

Two quantitative, high-throughput cell-based assays for evaluating inhibitors of NGF-stimulated trkA phosphorylation in trkA-transfected NIH3T3 cells have been established. Both assays involve capture of the trkA receptor from cell lysates in microtiter plates coated with an anti-trk antibody. The amount of trkA phosphorylation is then measured using either an anti-phosphotyrosine antibody with a colorimetric readout or a lanthanide (europium)-labeled anti-phosphotyrosine antibody with a fluorometric detection. The two assay formats exhibited at least a fivefold increase in phosphorylated trkA signal in trkA-transfected cells compared to vector control. Inhibition plots generated for trkA kinase inhibitors using the two detection systems yielded comparable IC(50) values. Overall, the two assays represent a marked improvement over the standard gel-based/western blot method in terms of throughput, quantitation, and amenability to automation.

Kinetics of trkA tyrosine kinase activity and inhibition by K-252a.

The kinetic mechanism of the trk receptor-linked tyrosine kinase was determined using a baculovirus expressed trk kinase domain and a bacterially expressed phospholipase C-gamma/glutathione S-transferase (PLC-gamma/ GST) fusion protein as substrate. Product and dead-end inhibition studies indicate an ordered association of substrates to trkA kinase with the nucleotide ATP binding prior to the exogenous substrate PLC-gamma/GST, followed by release of the phosphorylated PLC-gamma/GST product prior to release of ADP (sequential ordered bi-bi mechanism). This is in contrast to the reported kinetic mechanisms of closely related EGF receptor and insulin receptor kinases which appear to proceed via a rapid equilibrium random mechanism. The indolocarbazole K-252a, which was previously shown to be a potent and relatively selective inhibitor of trk kinase activity, acts as a competitive inhibitor with respect to ATP. The data suggest that potent and selective kinase inhibitors can be rationally designed by exploring subtle variations surrounding the nucleotide binding sites of receptor tyrosine kinases.

CEP-751 inhibits TRK receptor tyrosine kinase activity in vitro exhibits anti-tumor activity.

The present report describes the in vitro and in vivo profile of CEP-751, a novel receptor tyrosine kinase inhibitor. CEP-751 at 100 nM inhibits the receptor tyrosine kinase activity of the neurotrophin receptors trkA, trkB and trkC. CEP-751 has no effect on activity of receptors for EGF, IGF-I, insulin or on erbB2; inhibition of receptors for PDGF and bFGF was observed but occurred with lesser potency than inhibition of trk. CEP-751 exhibited anti-tumor efficacy against tumors derived from NIH3T3 cells transfected with trkA. Inhibition of trk phosphorylation could also be measured in these tumors, suggesting that anti-tumor efficacy of CEP-751 is related to inhibition of trk receptor tyrosine kinase activity. CEP-751 was found to be without effect when administered to nude mice bearing SK-OV-3 tumors, which overexpress erbB2 receptors, providing further evidence that inhibition of tumor growth may be related to inhibition of trk receptor tyrosine kinase activity. Our data indicate that CEP-751 is a potent trk inhibitor which possesses anti-tumor activity.

Neurotrophic 3,9-bis[(alkylthio)methyl]-and-bis(alkoxymethyl)-K-252a derivatives.

A series of 3,9 disubstituted [(alkylthio)methyl]- and (alkoxymethyl)-K-252a derivatives was synthesized with the aim of enhancing and separating the neurotrophic properties from the undesirable NGF (trk A kinase) and PKC inhibitory activities of K-252a. Data from this series reveal that substitution in the 3- and 9-positions of K-252a with these groups reduces trk A kinase inhibitory properties approximately 100- to > 500-fold while maintaining or in certain cases enhancing the neurotrophic activity. From this research, 3,9-bis[(ethylthio)methyl]-K-252a (8) was identified as a potent and selective neurotrophic agent in vitro as measured by enhancement of choline acetyltransferase activity in embryonic rat spinal cord and basal forebrain cultures. Compound 8 was found to have weak kinase inhibitory activity for trk A, protein kinase C1 protein kinase A, and myosin light chain kinase. On the basis of the in vitro profile, 8 was evaluated in in vivo models suggestive of neurological diseases. Compound 8 was active in preventing degeneration of cholinergic neurons of the nucleus basalis magnocellularis (NBM) and reduced developmentally programmed cell death (PCD) of female rat spinal nucleus of the bulbocavernosus motoneurons and embryonic chick lumbar motoneurons.

A radioactive binding assay for inhibitors of trkA kinase.

The high-affinity receptor for nerve growth factor (NGF), trkA, is a receptor-linked tyrosine kinase. The binding of NGF to trkA, depending on the context of its environment, can cause beneficial or deleterious responses in the target cells. For example, the activation of trkA in sympathetic and sensory neurons causes the subsequent survival and differentiation of these cells. On the other hand, the activation of trkA by NGF in other cells has been implicated in several pathologies including inflammation-induced hyperalgesia and several cancers. A radioactive binding assay to evaluate inhibitors of the kinase domain of trkA has been developed and validated. The assay monitors the specific binding of an inhibitor of trkA kinase activity, the indolocarbazole K-252a, to the trkA receptor. [3H]K-252a binds with high affinity to one site on the cytoplasmic kinase domain of the trkA receptor. Binding is saturable and reversible with a dissociation constant (Kd) of 1.5 nM. The binding assay has been used in competition binding experiments to determine the inhibition constants for other indolocarbazole compounds. The IC50 values for compounds obtained in the binding assay correlate very well with the IC50 values obtained in an enzyme-linked immunosorbent assay for trkA tyrosine kinase activity.

Enzyme-linked immunosorbent assay for trkA tyrosine kinase activity.

A 96-well microtiter enzyme-linked immunosorbent assay was developed to assay the activity of the cytoplasmic domain of trkA tyrosine kinase. The assay involves immobilization of phospholipase C- gamma/glutathione S-transferase fusion protein on a microtiter plate, addition of the kinase reaction mixture, and detection by an antibody to phosphotyrosine followed by an alkaline phosphatase-conjugated second antibody. The substrate used in this system, phospholipase C-gamma, is one of several biologically important substrates for the phosphorylation reaction of receptor-linked tyrosine kinases. The assay was then used to characterize kinase inhibitory activities of various small molecules including analogs of K-252a.

Aspects of antibody-catalyzed primary amide hydrolysis.

Because there are many known C-terminally amidated peptides of biological importance, there is great potential in medicine and organic synthesis for antibodies that catalyze primary amide bond hydrolysis or formation. We characterized a catalytic antibody, 13D11, raised to a phosphinate hapten, that hydrolyzed the primary amide of a dansyl-alkylated derivative of (R)-phenylalaninamide (DNS-(R)F-NH2). At pH 9.0, 13D11 hydrolyzed DNS-(R)F-NH2 with a kcat of 1.65 x 10(-7) s-1 (kcat/kuncat = 132) and a Km of 432 microM, and was stereospecifically hapten-inhibited (Ki = 14.0 microM). Control experiments indicated that the catalytic activity was not the result of a contaminating protease. In accordance with the hapten being a transition-state analog of base hydrolysis, the rate of DNS-(R)F-NH2 hydrolysis increased with hydroxide concentration to an optimum pH of 9.5. Above pH 9.5, activity declined rapidly suggesting the antibody was inactivated during the long incubation period. This work demonstrates the feasibility of generating catalytic antibodies to hydrolyze unactivated amide bonds without cofactor assistance.

Use of steady state kinetic methods to elucidate the kinetic and chemical mechanisms of retroviral proteases.

Despite the current plethora of structural data of HIV-1 protease and the availability of potent inhibitors, whose structures are based in part on the presumed mechanism of action of this enzyme, our actual understanding of its chemical mechanism has been until now based largely on the precedents of the mammalian and fungal aspartic proteases and static three-dimensional data. The available steady state kinetic data of the protease, as reviewed here, constitute a first step in a detailed description of the mechanism of the enzyme to complement the structural data.

Mechanism-based catalytic antibody inactivation.

Studies of alternative substrates of the catalytic monoclonal antibodies 18H4, 7D4, and 45A11 provided us with a better understanding of the mechanism of ester hydrolysis employed by these isoabzymes. The antibodies were studied with analogs of the substrate, phenyl acetate; N-acetylglycine phenyl ester 3 and N-carbobenzoxy-glycine phenyl ester 4. All three antibodies catalyzed 3 hydrolysis with kinetic constants similar to those seen with phenyl acetate hydrolysis. However, 4 was found to be a mechanism-based (suicide) inactivator of 18H4 with a kinact of 0.29 min-1 and a K' of 64 microM. Antibody 18H4 was inactivated by 4 after 3.6 turnovers resulting in the acylation of 1.6 tyrosines per combining site. The data conform to a mechanism in which an inactive O-ZGly-tyrosyl-antibody is formed via a Michaelis complex.

Isoabzymes: structurally and mechanistically similar catalytic antibodies from the same immunization.

Mechanistic and structural comparisons of five catalytic monoclonal antibodies generated from the same hybridoma fusion indicated that all five hydrolyze phenyl acetate by subtle variations of the same mechanism. All of the antibodies showed a pre-steady-state multi-turnover burst in which kcat and Km declined but kcat/Km did not change. The burst of one of the antibodies, 20G9, has previously been found to result from inhibition by the product, phenol. Although all of the antibodies showed the burst, their individual values for kcat, Km, and hapten Ki differed substantially. Three of the antibodies that were investigated for the effect of pH on kcat showed an acid limb pK of 9.5-9.6. Substrate inhibition was seen in four of the five antibodies. Variable region nucleotide sequencing of the heavy and light chains confirmed that all five antibodies were structurally similar and also revealed several potentially critical tyrosines. Despite their structural similarities, analysis of their sequences suggested that the antibodies are products of distinct, independent rearrangements of immunoglobulin gene segments that took place in different progenitor B cells. A plot of Ki for hapten inhibition vs Km/kcat for substrate hydrolysis for the mechanistically related antibodies ("isoabzymes") gave a linear relationship suggesting a catalytic role for transition-state complementarity. Taken together with previous work [Martin et al. (1991) Biochemistry 30, 9757-9761], the data conform to a mechanism in which the antibodies exploit both transition-state complementarity and an acyl-tyrosyl intermediate during phenyl acetate hydrolysis.

Use of nitrogen-15 kinetic isotope effects to elucidate details of the chemical mechanism of human immunodeficiency virus 1 protease.

We have used 15N kinetic isotope effects of the HIV-1 protease-catalyzed peptidolysis of Ac-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2 to characterize the chemical mechanism of this enzyme. In addition, the multiple isotope effects have been determined by measuring the 15N kinetic isotope effects in both H2O and D2O. The isotope effects, measured on values of V/K, were determined by the incorporation of a radiolabel (tritium and 14C in peptides bearing the heavy and light isotopes, respectively) at a position remote from the isotopically labeled scissile peptide bond, such that the isotope effect was determined by measurement of the change in the 14C/3H ratio in recovered substrates at various fractions of reaction. At pH = 6.0 (37 degrees C), the nitrogen isotope effects were slightly, but significantly, inverse in both solvents: 15(V/K)H2O = 0.995 +/- 0.002, and 15(V/K)D2O = 0.992 +/- 0.003. The observation of an inverse nitrogen kinetic isotope effect implies that bonding to the nitrogen atom is becoming stiffened in a reaction transition state, and since this inverse isotope effect is enhanced in D2O, this isotope effect likely arises from protonation of the proline nitrogen atom.(ABSTRACT TRUNCATED AT 250 WORDS)

Solvent isotope partitioning: a new kinetic tool for the determination of desorption rates of reactant water from enzyme-substrate complexes in proteases.

The rates of desorption of the substrate water from the binary enzyme-H2O and ternary enzyme-H2O-(peptide)substrate complexes for the two hydrolases, porcine pepsin and thermolysin, have been investigated using a novel technique, solvent isotope partitioning. The experimental design of this method was based on the protocol of Rose et al. [Rose, I. A., O'Connell, E. L., Litwin, S., & BarTana, J. (1974) J. Biol. Chem. 249, 5163-5168] wherein the binary enzyme-H2(18)O complex established in the "pulse" solution was diluted into a "chase" solution containing variable concentrations of peptide substrates in a large pool of H2(16)O. The extent of trapping of H2(18)O within the respective E-H2(18)O and E-H2(18)O-(peptide)substrate complexes was determined from mass spectrometric analysis of the hydrolytic products. Our data have shown that the substrate water molecule of pepsin is not exclusively retained in the catalytic cycle and it desorbs from the apo- and substrate-bound complexes at rates that are at least 10 and 4 times faster, respectively, than that of product formation. Similarly, the low trapping of H2(18)O in the carboxylic product of the thermolysin reaction is a consequence of the ready desorption of H2(18)O from the ternary E-H2(18)O-(peptide)substrate complex and the binary E-H2(18)O complex. We attribute these results to the loss of the reactant water molecule due to desolvation of the enzyme's active site upon substrate binding.

Reversal of enzyme regiospecificity with alternative substrates for aspartokinase I from Escherichia coli.

The substrate specificity of aspartokinase I has been examined by using both steady-state kinetic analyses and phosphorus-31 NMR spectroscopic studies. Analogues in which the alpha-amino group is either derivatized or replaced are not substrates or inhibitors for the enzyme, indicating the importance of the alpha-amino group as a binding determinant. The alpha-carboxyl group is not required for substrate recognition, and the alpha-amide or alpha-esters are competent alternative substrates. In addition, beta-derivatized structural analogues, such as the beta-hydroxamate, the beta-amide, or beta-esters, were found to be viable substrates. This was unexpected since the beta-carboxyl group is the usual site of phosphorylation. The nature of the acyl phosphate products obtained from these beta-derivatized alternative substrates has been characterized by coupled enzyme assays, oxygen-18-labeling studies, and phosphorus-31 NMR spectroscopy. These beta-derivatized analogues are capable of productive binding to aspartokinase through a reversal of regiospecificity to make the alpha-carboxyl group available as a phosphoryl acceptor. Many, but not all, of these alpha-acyl phosphates have also been shown to be viable substrates for the next two enzyme-catalyzed steps in this metabolic pathway. This raises the possibility of producing enzyme-generated alternative substrates that can serve as antimetabolites for the downstream reactions in this biosynthetic pathway.

The kinetic mechanisms of the bifunctional enzyme aspartokinase-homoserine dehydrogenase I from Escherichia coli.

The kinetic mechanisms of the reactions catalyzed by the two catalytic domains of aspartokinase-homoserine dehydrogenase I from Escherichia coli have been determined. Initial velocity, product inhibition, and dead-end inhibition studies of homoserine dehydrogenase are consistent with an ordered addition of NADPH and aspartate beta-semialdehyde followed by an ordered release of homoserine and NADP+. Aspartokinase I catalyzes the phosphorylation of a number of L-aspartic acid analogues and, moreover, can utilize MgdATP as a phosphoryl donor. Because of this broad substrate specificity, alternative substrate diagnostics was used to probe the kinetic mechanism of this enzyme. The kinetic patterns showed two sets of intersecting lines that are indicative of a random mechanism. Incorporation of these results with the data obtained from initial velocity, product inhibition, and dead-end inhibition studies at pH 8.0 are consistent with a random addition of L-aspartic acid and MgATP and an ordered release of MgADP and beta-aspartyl phosphate.

Aspartokinase-homoserine dehydrogenase I from Escherichia coli: pH and chemical modification studies of the kinase activity.

The pH variation of the kinetic parameters was examined for the kinase activity of the bifunctional enzyme aspartokinase--homoserine dehydrogenase I isolated from Escherichia coli. The V/K profile for L-aspartic acid indicates the loss of activity upon protonation of a cationic acid type group with a pK value near neutrality. Incubation of the enzyme with diethyl pyrocarbonate at pH 6.0 results in a loss of enzymic activity. The reversal of this reaction by neutral hydroxylamine, the appearance of a peak at 242 nm for the inactivated enzyme, and the observation of a pK value of 7.0 obtained from variation of the inactivation rate with pH all suggest that enzyme inactivation occurs by modification of histidine residues. The substrate L-aspartic acid protects one residue against inactivation, which implies that this histidine may participate in substrate binding or catalysis. Activity loss was also observed at high pH due to the ionization of a neutral acid group with a pK value of 9.8. The reactions of AK-HSD I with N-acetylimidazole and tetranitromethane have been investigated to obtain information about the functional role of tyrosyl residues in the enzyme. The acylation of tyrosines leads to inactivation of the enzyme, which can then be fully reversed by treatment with hydroxylamine. Incubation of the enzyme with tetranitromethane at pH 9.5 also leads to rapid inactivation, and the substrates of the kinase reaction provide substantial protection against inactivation. However, three tyrosines are protected by substrates, implying a structural role for these amino acids.