Regulation of phospholipase D

Structural studies of plant and bacterial members of the phospholipase D (PLD) superfamily are providing information about the role of the conserved HKD domains in the structure of the catalytic center and the catalytic mechanism of mammalian PLD isozymes (PLD1 and PLD2). Mutagenesis and sequence comparison studies have also defined the presence of pleckstrin homology and phox homology domains in the N-terminus and have demonstrated that a conserved sequence at the C-terminus is required for catalysis. The N- and C-terminal regions of PLD1 also contain interaction sites for protein kinase C, which can directly activate the enzyme through a non-phosphorylating mechanism. Small G proteins of the Rho and ADP-ribosylation factor families also directly regulate the enzyme, with RhoA binding to a sequence in the C-terminus. Certain tyrosine kinases and members of the Ras subfamily of small G proteins can activate the enzyme, but the mechanisms appear to be indirect. The mechanisms by which agonists activate PLD in vivo probably involve multiple pathways.     

Catalytic mechanism of phosphorylase kinase probed by mutational studies.

The contributions to catalysis of the conserved catalytic aspartate (Asp149) in the phosphorylase kinase catalytic subunit (PhK; residues 1-298) have been studied by kinetic and crystallographic methods. Kinetic studies in solvents of different viscosity show that PhK, like cyclic AMP dependent protein kinase, exhibits a mechanism in which the chemical step of phosphoryl transfer is fast and the rate-limiting step is release of the products, ADP and phosphoprotein, and possibly viscosity-dependent conformational changes. Site-directed mutagenesis of Asp149 to Ala and Asn resulted in enzymes with a small increase in K(m) for glycogen phosphorylase b (GPb) and ATP substrates and dramatic decreases in k(cat) (1.3 x 10(4) for Asp149Ala and 4.7 x 10(3) for Asp149Asn mutants, respectively). Viscosometric kinetic measurements with the Asp149Asn mutant showed a reduction in the rate-limiting step for release of products by 4.5 x 10(3) and a significant decrease (possibly as great as 2.2 x 10(3)) in the rate constant characterizing the chemical step. The date combined with the crystallographic evidence for the ternary PhK-AMPPNP-peptide complex [Lowe et al. (1997) EMBO J. 6, 6646-6658] provide powerful support for the role of the carboxyl of Asp149 in binding and orientation of the substrate and in catalysis of phosphoryl transfer. The constitutively active subunit PhK has a glutamate (Glu182) residue in the activation segment, in place of a phosphorylatable serine, threonine, or tyrosine residue in other protein kinases that are activated by phosphorylation. Site-directed mutagenesis of Glu182 and other residues involved in a hydrogen bond network resulted in mutant proteins (Glu182Ser, Arg148Ala, and Tyr206Phe) with decreased catalytic efficiency (approximate average decrease in k(cat)/K(m) by 20-fold). The crystal structure of the mutant Glu182Ser at 2.6 A resolution showed a phosphate dianion about 2.6 A from the position previously occupied by the carboxylate of Glu182. There was no change in tertiary structure from the native protein, but the activation segment in the region C-terminal to residue 182 showed increased disorder, indicating that correct localization of the activation segment is necessary in order to recognize and present the protein substrate for catalysis.     

Domain interactions in protein tyrosine kinase Csk.

Csk (C-terminal Src kinase) is a protein tyrosine kinase that phosphorylates Src family member C-terminal tails, resulting in downregulation of Src family members. It is composed of three principal domains: an SH3 (Src homology 3) domain, an SH2 (Src homology 2) domain, and a catalytic domain. The impact of the noncatalytic domains on kinase catalysis was investigated. The Csk catalytic domain was expressed in Escherichia coli as a recombinant glutathione S-transferase-fusion protein and demonstrated to have 100-fold reduced catalytic efficiency. Production of the catalytic domain by proteolysis of full-length Csk afforded a similar rate reduction. This suggested that the reduction in catalytic efficiency of the recombinant catalytic domain was intrinsic to the sequence and not an artifact related to faulty expression. This rate reduction was similar for peptide and protein substrates and was due almost entirely to a reduced k(cat) rather than to effects on substrate K(m)s. Viscosity experiments on the catalytic fragment kinase reaction demonstrated that the chemical (phosphoryl transfer) step had a reduced rate. While the Csk SH2 domain had no intermolecular effect on the kinase activity of the Csk catalytic domain, the SH3 domain and SH3-SH2 fragment led to a partial rescue (4-5-fold) of the lost kinase activity. This rescue was not achieved with two other SH3 domains (lymphoid cell kinase, Abelson kinase). The extrapolated K(d) of interaction for the Csk catalytic domain with the Csk SH3 domain was 2.2 microM and that of the Csk catalytic domain with the Csk SH3-SH2 fragment was 8.8 microM. Taken together, these findings suggest that there is likely an intramolecular interaction between the catalytic and SH3 domains in full-length Csk that is important for efficient catalysis. By employing a Csk SH3 specific type II polyproline helix peptide and carrying out site-directed mutagenesis, it was established that the SH3 surface that interacts with the catalytic domain was distinct from the surface that binds type II polyproline helix peptides. This finding suggests a novel mode of protein-protein interaction for an SH3 domain. The implications for Csk substrate selectivity, regulation, and function are discussed.     

Kinetic analysis of the cyclin-dependent kinase-activating kinase (Cak1p) from budding yeast

Cak1p, the Cyclin-dependent kinase-activating kinase from budding yeast, is an unusual protein kinase that lacks many of the highly conserved motifs observed among members of the protein kinase superfamily. Cak1p phosphorylates and activates Cdc28p, the major cyclin-dependent kinase (CDK) in yeast, and is thereby required for passage through the yeast cell cycle. In this paper, we explore the kinetics of CDK phosphorylation by Cak1p, and we examine the role of the catalytic step in the reaction mechanism. Cak1p proceeds by a sequential reaction mechanism, binding to both ATP and CDK2 with reasonable affinities, exhibiting K(d) values of 7.2 and 0.6 microm, respectively. Interestingly, these values are approximately the same as the K(M) values, indicating that the binding of substrates is fast with respect to catalysis and that the most likely reaction mechanism is rapid equilibrium random. Cak1p is a slow enzyme, with a catalytic rate of only 4.3 min(-)(1). The absence of a burst phase indicates that product release is not rate-limiting. This result, and a solvent isotope effect, suggests that a catalytic step is rate-limiting.     

Catalytic mechanism and substrate specificity of the beta-subunit of the voltage-gated potassium channel

The beta-subunits of voltage-gated potassium (Kv) channels are members of the aldo-keto reductase (AKR) superfamily. These proteins regulate inactivation and membrane localization of Kv1 and Kv4 channels. The Kvbeta proteins bind to pyridine nucleotides with high affinity; however, their catalytic properties remain unclear. Here we report that recombinant rat Kvbeta2 catalyzes the reduction of a wide range of aldehydes and ketones. The rate of catalysis was slower (0.06-0.2 min(-1)) than those of most other AKRs but displayed the expected hyperbolic dependence on substrate concentration, with no evidence of allosteric cooperativity. Catalysis was prevented by site-directed substitution of Tyr-90 with phenylalanine, indicating that the acid-base catalytic residue, identified in other AKRs, has a conserved function in Kvbeta2. The protein catalyzed the reduction of a broad range of carbonyls, including aromatic carbonyls, electrophilic aldehydes and prostaglandins, phospholipids, and sugar aldehydes. Little or no activity was detected with carbonyl steroids. Initial velocity profiles were consistent with an ordered bi-bi rapid equilibrium mechanism in which NADPH binding precedes carbonyl binding. Significant primary kinetic isotope effects (2.0-3.1) were observed under single- and multiple-turnover conditions, indicating that the bond-breaking chemical step is rate-limiting. Structure-activity relationships with a series of para-substituted benzaldehydes indicated that the electronic interactions predominate during substrate binding and that no significant charge develops during the transition state. These data strengthen the view that Kvbeta proteins are catalytically active AKRs that impart redox sensitivity to Kv channels.     

Mechanistic effects of autophosphorylation on receptor tyrosine kinase catalysis: enzymatic characterization of Tie2 and phospho-Tie2

Activation of receptor tyrosine kinases by autophosphorylation is one of the most common and critical transformations in signal transduction, yet its role in catalysis remains controversial. Autophosphorylation of the angiogenic receptor tyrosine kinase Tie2 was studied in terms of the autophosphorylation sites, sequence of phosphorylation at these sites, kinetic effects, and mechanistic consequences. Isoelectric focusing electrophoresis and mass spectrometric analysis of a Tie2 autophosphorylation time course showed that Tyr992 on the putative activation loop was phosphorylated first followed by Tyr1108 in the C-terminal tail (previously unidentified autophosphorylation site). Autophosphorylation of Tie2 to produce pTie2 resulted in a 100-fold increase in k(cat) and a 460-fold increase in k(cat)/K(m). Viscosity studies showed that the unphosphorylated Tie2 was partially limited by product diffusion ((k(cat))(eta) = 0.67 +/- 0.06), while product release was more rate-limiting ((k(cat))(eta) = 0.94 +/- 0.08) for autophosphorylated Tie2 (pTie2). Furthermore, autophosphorylation did not significantly affect the phosphoacceptor dissociation constants. There was a significant (k(cat))(H)/(k(cat))(D) solvent isotope effect (SIE) for unphosphorylated Tie2 (2.42 +/- 0.12) and modest SIE (1.28 +/- 0.04) for pTie2, which is consistent with the chemistry step being more rate-limiting for Tie2 as compared to pTie2. The pH-rate profiles of Tie2 and pTie2 revealed a >0.5 unit shift in the pK(a) values of catalytically relevant ionizable residues upon autophosphorylation. The shift in rate-limiting step will result in a different distribution of enzyme pools (e.g., E, E*S, E*P, etc.) which may modulate the susceptibility to inhibition. Tie2 and pTie2 were profiled with a panel of known ATP-competitive kinase inhibitors. Tie2 activation perturbs catalytic residue ionizations, shifts the rate-limiting step to almost exclusive diffusion-control, and transforms the kinase into a more perfect catalyst.     

Identification of Molecular Switch Regulating Interactions of Janus Kinase 3 with Cytoskeletal Proteins

Janus kinase 3 (Jak3) is a nonreceptor tyrosine kinase expressed in both hematopoietic and nonhematopoietic cells. Although mutations that abrogate Jak3 functions cause different immunological disorders, its constitutive activation leads to various types of cancer. Previously, we demonstrated that Jak3 interacted with actin-binding protein villin, thereby facilitating cytoskeletal remodeling and wound repair. In this study, we characterize the structural determinants that regulate the interactions between Jak3 and cytoskeletal proteins of the villin/gelsolin family. Functional reconstitution of kinase activity by recombinant full-length (wt) Jak3 using Jak3-wt or villin/gelsolin-wt as substrate showed that Jak3 autophosphorylation was the rate-limiting step during interactions between Jak3 and cytoskeletal proteins. Determination of kinetic parameters showed that phosphorylated (P) Jak3-wt binds to P-villin-wt with a dissociation constant (K_d) of 23 nm and a Hill''s coefficient of 3.7. Pairwise binding between Jak3 mutants and P-villin-wt showed that the FERM domain of Jak3 was sufficient for binding to P-villin-wt with a K_d of 40.0 nm. However, the SH2 domain of Jak3 prevented P-villin-wt from binding to the FERM domain of nonphosphorylated protein. We demonstrate that the intramolecular interaction between the FERM and SH2 domains of nonphosphorylated Jak3 prevented Jak3 from binding to villin and that tyrosine autophosphorylation of Jak3 at the SH2 domain decreased these intramolecular interactions and facilitated binding of the FERM domain to villin. Thus we demonstrate the molecular mechanism of interactions between Jak3 and cytoskeletal proteins where tyrosine phosphorylation of the SH2 domain acted as an intramolecular switch for the interactions between Jak3 and cytoskeletal proteins.     

An ATP-linked structural change in protein kinase A precedes phosphoryl transfer under physiological magnesium concentrations

The kinetic mechanism for the catalytic subunit of protein kinase A was evaluated using physiological concentrations of free magnesium (0.5 mM) and a rapid quench flow technique. When the enzyme is pre-equilibrated with ATP, the peptide substrate, LRRASLG (Kemptide), is phosphorylated in a biphasic manner with a rapid, exponential "burst" phase (kb) followed by a slower, linear phase (kL) that corresponds to the steady-state kinetic rate. Both the amplitude and the substrate-rate dependence of the initial, burst phase indicate that the rate of phosphoryl transfer is fast (approximately 500 s-1) and does not limit turnover (45 s-1). Viscosity studies indicate that, while Kemptide is in rapid equilibrium, ATP does not exchange rapidly with the active site and kcat/KATP is limited by the rate constant for nucleotide encounter. When the pre-steady-state kinetic experiments are initiated with ATP, a lag phase is observed at low ATP concentrations consistent with rate-limiting association. At high ATP concentrations (>1 mM), a burst phase is observed but the rate and amplitude are low on the basis of the bimolecular rate constant for ATP association and the rate constant for phosphoryl transfer. The kinetic data indicate that the phosphoryl transfer step is fast at physiological magnesium concentrations, but an ATP-linked conformational change precedes this step, limiting the burst phase rate constant. Simulations of the pre-steady-state kinetic transients indicate that turnover (45 s-1) is limited both by net product release (70 s-1) and by this structural change (170 s-1). This structural change may also occur at high free magnesium concentrations, but it must be significantly faster than 170 s-1 and, consequently, not rate-limiting for turnover (kcat = 20 s-1 at 10 mM free Mg2+). We propose that this conformational event is an obligatory component of the kinetic pathway and includes a movement of the catalytic residues necessary for supporting phosphoryl group donation.     

Identification of genes required for Cf-dependent hypersensitive cell death by combined proteomic and RNA interfering analyses

Identification of hypersensitive cell death (HCD) regulators is essential to dissect the molecular mechanisms underlying plant disease resistance. In this study, combined proteomic and RNA interfering (RNAi) analyses were employed to identify genes required for the HCD conferred by the tomato resistance gene Cf-4 and the Cladosporium fulvum avirulence gene Avr4. Forty-nine proteins differentially expressed in the tomato seedlings mounting and those not mounting Cf-4/Avr4-dependent HCD were identified through proteomic analysis. Among them were a variety of defence-related proteins including a cysteine protease, Pip1, an operative target of another C. fulvum effector, Avr2. Additionally, glutathione-mediated antioxidation is a major response to Cf-4/Avr4-dependent HCD. Functional analysis through tobacco rattle virus-induced gene silencing and transient RNAi assays of the chosen 16 differentially expressed proteins revealed that seven genes, which encode Pip1 homologue NbPip1, a SIPK type MAP kinase Nbf4, an asparagine synthetase NbAsn, a trypsin inhibitor LeMir-like protein NbMir, a small GTP-binding protein, a late embryogenesis-like protein, and an ASR4-like protein, were required for Cf-4/Avr4-dependent HCD. Furthermore, the former four genes were essential for Cf-9/Avr9-dependent HCD; NbPip1, NbAsn, and NbMir, but not Nbf4, affected a nonadaptive bacterial pathogen Xanthomonas oryzae pv. oryzae-induced HCD in Nicotiana benthamiana. These data demonstrate that Pip1 and LeMir may play a general role in HCD and plant immunity and that the application of combined proteomic and RNA interfering analyses is an efficient strategy to identify genes required for HCD, disease resistance, and probably other biological processes in plants.     

Tyrosine Hydroxylase Inactivation Following cAMP-Dependent Phosphorylation Activation

Tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis, is activated following phosphorylation by the cAMP-dependent protein kinase (largely by decreasing the K^m of the enzyme for its pterin co-substrate). Following its phosphorylation activation in rat striatal homogenates, we find that tyrosine hydroxylase is inactivated by two distinct processes. Because cAMP is hydrolyzed in crude extracts by a phospho-diesterase, cAMP-dependent protein kinase activity declines following a single addition of cAMP. When tyrosine hydroxylase is activated under these transient phosphorylation conditions, inactivation is accompanied by a reversion of the activated kinetic form (low apparent K^m for pterin co-substrate, ≤0.2 mM) to the kinetic form characteristic of the untreated enzyme (high apparent K^m, ≥1.0 mM). This inactivation is readily reversed by the subsequent addition of cAMP. When striatal tyrosine hydroxylase is activated under constant phosphorylation conditions (incubated with purified cAMP-dependent protein kinase catalytic subunit), however, it is also inactivated. This second inactivation process is irreversible and is characterized kinetically by a decreasing apparent V^max with no change in the low apparent K^m for pterin co-substrate (0.2 mM). The latter inactivation process is greatly attenuated by gel filtration which resolves a low-molecular-weight inactivating factor(s) from the tyrosine hydroxylase. These results are consistent with a regulatory mechanism for tyrosine hydroxylase involving two processes: in the first case, reversible phosphorylaton and dephos-phorylation and, in the second case, an irreversible loss of activity of the phosphorylated form of tyrosine hydroxylase.     

Interaction of guanylyl cyclase C with SH3 domain of Src tyrosine kinase. Yet another mechanism for desensitization

Protein-protein interactions mediated by the Src homology 3 (SH3) domain have been implicated in the regulation of receptor functions for subcellular localization of proteins and the reorganization of cytoskeleton. The experiments described in this article begin to identify the interaction of the SH3 domain of Src tyrosine kinase with the guanylyl cyclase C receptor after activation with Escherichia coli heat-stable enterotoxin (ST). Only one of two post-translationally modified forms of guanylyl cyclase C from T84 colonic carcinoma cells bind to GST-SH3 fusion protein of Src and Hck tyrosine kinases. Interestingly, the GST-Src-SH3 fusion protein showed 2-fold more affinity to native guanylyl cyclase C in solution than the GST-Hck-SH3 fusion protein. The affinity of the GST-Src-SH3 fusion protein to guanylyl cyclase C increased on desensitization of receptor in vivo. An in vitro cyclase assay in the presence of GST-Src-SH3 fusion protein indicated inhibition of the catalytic activity of guanylyl cyclase C. The catalytic domain recombinant protein (GST-GCD) of guanylyl cyclase C could pull-down a 60-kDa protein that reacted with Src tyrosine antibody and also showed autophosphorylation. These data suggest that SH3 domain-mediated protein-protein interaction with the catalytic domain of guanylyl cyclase C inhibited the cyclase activity and that such an interaction, possibly mediated by Src tyrosine kinase or additional proteins, might be pivotal for the desensitization phenomenon of the guanylyl cyclase C receptor.     

Functional characterization of peanut serine/threonine/tyrosine protein kinase: molecular docking and inhibition kinetics with tyrosine kinase inhibitors

Serine/threonine/tyrosine (STY) protein kinase from peanut is developmentally regulated and is induced by abiotic stresses. In addition, STY protein kinase activity is regulated by tyrosine phosphorylation. Kinetic mechanism of plant dual specificity protein kinases is not studied so far. Recombinant STY protein kinase occurs as a monomer in solution as shown by gel filtration chromatography. The relative phosphorylation rate of kinase against increasing enzyme concentrations follows a first-order kinetics indicating an intramolecular phosphorylation mechanism. Moreover, the active recombinant STY protein kinase could not transphosphorylate a kinase-deficient mutant of STY protein kinase. Molecular docking studies revealed that the tyrosine kinase inhibitors bind the protein kinase at the same region as ATP. STY protein kinase activity was inhibited by the tyrosine kinase inhibitors, and the inhibitor potency series against the recombinant STY protein kinase was tyrphostin > genistein > staurosporine. The inhibition constant (K(i)), and the IC(50) value of STY protein kinase for tyrosine kinase inhibitors with ATP and histone are discussed. All the inhibitors competed with ATP. Genistein was an uncompetitive inhibitor with histone, whereas staurosporine and tyrphostin were linear mixed type noncompetitive inhibitors with histone. Molecular docking and kinetic analysis revealed that Y148F mutant of the "ATP-binding loop" and Y297F mutant of the "activation loop" showed a dramatic increase in K(i) values for genistein and tyrphostin with respect to wild-type STY protein kinase. Data presented here provide the direct evidence on the mechanism of inhibition of plant protein kinases by tyrosine kinase inhibitors. This study also suggests that tyrosine kinase inhibitors may be useful in unraveling the plant tyrosine phosphorylation signaling cascades.     

Depression of Neuronal Protein Synthesis Initiation by Protein Tyrosine Kinase Inhibitors

Abstract— Growth factors stimulate cellular protein synthesis, but the intracellular signaling mechanisms that regulate initiation of mRNA translation in neurons have not been clarified. A rate-limiting step in the initiation of protein synthesis is the formation of the ternary complex among GTP, eukaryotic initiation factor 2 (elF-2), and the initiator tRNA. Here we report that genistein, a specific tyrosine kinase inhibitor, decreases tyrosine kinase activity and the content of phosphotyrosine proteins in cultured primary cortical neurons. Genistein inhibits protein synthesis by >80% in a dose-dependent manner (10–80 μg/ml) and concurrently decreases ternary complex formation by 60%. At the doses investigated, genistein depresses tyrosine kinase activity and concomitantly stimulates PKC activity. We propose that a protein tyrosine kinase participates in the initiation of protein synthesis in neurons, by affecting the activity of elF-2 directly or through a protein kinase cascade.     

Signaling pathways of magnolol-induced adrenal steroidogensis

This study focused on identifying the signalling mediating the effect of magnolol on corticosterone production. Magnolol-induced corticosterone production was completely inhibited by mitogen-activated protein kinase kinase (MEK)-inhibitor PD98059, tyrosine kinase (TK)-inhibitor genistein or Janus tyrosine kinase 2 (JAK2)-inhibitor AG490, suggesting that extracellular signal-regulated kinase (ERK) and JAK2 are both involved in this signaling cascade. Further, magnolol induced the transient phosphorylation of MEK, ERK, cAMP response-element binding protein (CREB) and the expression of 32 and 30 kDa steroidogenic acute regulatory protein (StAR) in a time-dependent manner. Inhibition of TK or JAK2 activities blocked magnolol-induced phosphorylation of MEK and ERK, again supporting the upstream role of JAK2. The activation of JAK2 or MEK apparently mediated the magnolol-induced phosphorylation of CREB and the upregulation of StAR. These findings demonstrate a novel pathway for magnolol to induce the expression of StAR, which regulates the rate-limiting step in sterodiogenesis.     

Poliovirus RNA-dependent RNA polymerase (3Dpol): pre-steady-state kinetic analysis of ribonucleotide incorporation in the presence of Mn2+

The use of Mn(2+) as the divalent cation cofactor in polymerase-catalyzed reactions instead of Mg(2+) often diminishes the stringency of substrate selection and incorporation fidelity. We have solved the complete kinetic mechanism for single nucleotide incorporation catalyzed by the RNA-dependent RNA polymerase from poliovirus (3D(pol)) in the presence of Mn(2+). The steps employed during a single cycle of nucleotide incorporation are identical to those employed in the presence of Mg(2+) and include a conformational-change step after nucleotide binding to achieve catalytic competence of the polymerase-primer/template-nucleotide complex. In the presence of Mn(2+), the conformational-change step is the primary determinant of enzyme specificity, phosphoryl transfer appears as the sole rate-limiting step for nucleotide incorporation, and the rate of phosphoryl transfer is the same for all nucleotides: correct and incorrect. Because phosphoryl transfer is the rate-limiting step in the presence of Mn(2+), it was possible to determine that the maximal phosphorothioate effect in this system is in the range of 8-11. This information permitted further interrogation of the nucleotide-selection process in the presence of Mg(2+), highlighting the capacity of this cation to permit the enzyme to use the phosphoryl-transfer step for nucleotide selection. The inability of Mn(2+) to support a reduction in the efficiency of phosphoryl transfer when incorrect substrates are employed is the primary explanation for the loss of fidelity observed in the presence of this cofactor. We propose that the conformational change involves reorientation of the triphosphate moiety of the bound nucleotide into a conformation that permits binding of the second metal ion required for catalysis. In the presence of Mg(2+), this conformation requires interactions with the enzyme that permit a reduction in catalytic efficiency to occur during an attempt to incorporate an incorrect nucleotide. Adventitious interactions in the cofactor-binding site with bound Mn(2+) may diminish fidelity by compensating for interaction losses used to modulate catalytic efficiency when incorrect nucleotides are bound in the presence of Mg(2+).     

Characterization of Itk tyrosine kinase: contribution of noncatalytic domains to enzymatic activity.

Itk is a Tec family tyrosine kinase found in T cells that is activated upon ligation of the T cell receptor (TCR/CD3), CD2, or CD28. Itk contains five domains in addition to the catalytic domain: pleckstrin homology, Tec homology which contains a proline-rich region, Src homology 3, and Src homology 2. To provide a basis for understanding the contribution of these various domains to catalysis, recombinant Itk was purified and its substrate specificity determined by steady-state kinetic methods. Measurements of the rates of phosphorylation of various protein substrates, including Src associated in mitosis 68K protein (SAM68), CD28, linker for activation of T cells, and CD3 zeta, at a fixed concentration indicated that SAM68 was phosphorylated most rapidly. Wild-type Itk and three Itk mutants were characterized by comparing their activity (k(cat)) using the SAM68 substrate. A deletion mutant removing the pleckstrin homology domain and part of the Tec homology domain (Itk(Delta152)) had approximately 10-fold less activity than wild type, a mutant with an altered proline-rich domain (P158A,P159A) had a more dramatic 100-fold loss of activity, and the catalytic domain alone was essentially inactive. Itk(Delta152) had K(m) values for ATP and SAM68 nearly identical to those of the wild-type enzyme, while Itk(P158A,P159A) had approximately 3-fold higher K(m) values for each substrate. SAM68 phosphorylation by the wild-type and mutant enzymes in the presence of several tyrosine kinase inhibitors were compared using a homogeneous time-resolved fluorescence assay. Both the Itk(Delta152) deletion mutant and the Itk(P158A,P159A) mutant had IC(50) values similar to those of the wild-type enzyme for staurosporine, PP1, and damnacanthal. These comparisons, taken together with the similar K(m) values for ATP and SAM68 substrate between the wild-type and the mutant enzymes, indicate that the amino acids in the N-terminal 152 residues and proline-rich domains enhance catalysis by affecting turnover rate rather than substrate binding.     

Molecular determinants for Csk-catalyzed tyrosine phosphorylation of the Src tail

Phosphorylation of a critical tail tyrosine residue in Src modulates its three-dimensional structure and protein tyrosine kinase activity. The protein tyrosine kinase Csk is responsible for catalyzing the phosphorylation of this key Src tyrosine residue, but the detailed molecular basis for Src recognition and catalysis is poorly understood. In this study, we investigate this phosphorylation event using purified recombinant Csk and Src proteins and mutants. It was shown that the apparent k(cat) and K(m) values for Csk phosphorylation of catalytically impaired Src (dSrc) are similar to the parameters for Csk-catalyzed phosphorylation of the Src family member Lck. The SH3 (Src homology 3) and SH2 (Src homology 2) domains of dSrc were fully dispensable with respect to rapid phosphorylation, indicating that the catalytic domain and tail of dSrc are sufficient for the high efficiency of dSrc as a substrate. Of the eight Src tail residues examined, only the fully conserved Glu (Y-3 position) and Gln (Y-1 position) investigated by alanine scanning mutagenesis caused large reductions (10--40-fold) in dSrc substrate efficiency. The Y-3 Glu requirement was stringent as conservative replacements with Asp or Gln were no better than Ala whereas replacement of the Y-1 Gln with Ile was readily tolerated. Interestingly, en bloc replacement of the tail with a seven amino acid consensus sequence derived from a peptide library analysis was no better than the wild-type sequence. Surprisingly, the dSrc Y527F protein, although not a Csk substrate, enhanced Csk-catalyzed phosphorylation of dSrc. These results and other data suggest that Src dimerization (or higher order oligomerization) is important for high-efficiency Csk-catalyzed phosphorylation of the Src tail.     

Vitamin D receptor agonists induce prostatic acid phosphatase to reduce cell growth and HER-2 signaling in LNCaP-derived human prostate cancer cells

We have previously shown that concentrations of 1alpha,25-dihydroxyvitamin D(3) (1,25D) that induce G(0)/G(1) cell cycle arrest in androgen-dependent LNCaP prostate cancer cells also decrease expression of c-Myc, a proto-oncogene that stimulates progression from G(1) to S phase of the cell cycle. Since both c-Myc expression and cell cycle progression are regulated by tyrosine kinase activation, we examined the ability of 1,25D to alter tyrosine kinase signaling in LNCaP cells and the androgen-independent LNCaP C81 (C81 LN) cell line. 1,25D selectively reduced protein tyrosine phosphorylation within both the LNCaP and C81 LN cells. This reduction in tyrosine kinase signaling appears to result from elevated levels of cellular prostatic acid phosphatase (PAcP). Western blots and biochemical assays revealed 1,25D increases the level of active PAcP in both cell lines. In addition, 1,25D decreased tyrosine phosphorylation of HER-2, an EGFR family member inactivated by PAcP, and the HER-2 downstream adaptor protein p52 Shc in C81 LN cells. Inhibition of HER-2 signaling by AG825 reduces growth of C81 LN cells and the parental LNCaP cells. These data therefore suggest that 1,25D-mediated decreases in LNCaP and C81 LN cell growth are in part due to decreases in tyrosine kinase signaling that result from up-regulation of PAcP.     

Functional analysis of BamHI DNA cytosine-N4 methyltransferase

We show that the kinetic mechanism of the DNA (cytosine-N(4)-)-methyltransferase M.BamHI, which modifies the underlined cytosine (GGATCC), differs from cytosine C(5) methyltransferases, and is similar to that observed with adenine N(6) methyltransferases. This suggests that the obligate order of ternary complex assembly and disassembly depends on the type of methylation reaction. In contrast, the single-turnover rate of catalysis for M.BamHI (0.10s(-1)) is closer to the DNA (cytosine-C(5)-)-methyltransferases (0.14s(-1)) than the DNA (adenine-N(6)-)-methyltransferases (>200s(-1)). The nucleotide flipping transition dominates the single-turnover constant for adenine N(6) methyltransferases, and, since the disruption of the guanine-cytosine base-pair is essential for both types of cytosine DNA methyltransferases, this transition may be a common, rate-limiting step for methylation for these two enzyme subclasses. The similar overall rate of catalysis by M.BamHI and other DNA methyltransferases is consistent with a common rate-limiting catalytic step of product dissociation. Our analyses of M.BamHI provide functional insights into the relationship between the three different classes of DNA methyltransferases that complement both prior structural and evolutionary insights.