Identification of electrostatic interactions that determine the phosphorylation site specificity of the cAMP-dependent protein kinase

"Charged-to alanine" scanning mutagenesis of the catalytic subunit of the Saccharomyces cerevisiae cAMP-dependent protein kinase (C1) identified three glutamate residues, E171, E214, and E274, that are involved in the recognition of a peptide substrate, kemptide (Leu1Arg2Arg3Ala4Ser5Leu6Gly7). These glutamate residues are conserved or conservatively substituted with asparate in the serine/threonine protein kinases that have a requirement for basic residues on the N-terminal side of their phosphorylation sites. Alanine replacement mutants in C1 were subjected to kinetic analysis using alanine-substituted peptides as substrates. The additivity or nonadditivity of the effects of the alanine substitutions on the catalytic efficiency (kcat/Km) was analyzed. This allowed the identification of electrostatic interactions between the three glutamate residues in the enzyme and the two arginine residues present in the peptide substrate. The data suggest that E171 interacts with Arg2 in the substrate and that E214 and E274 both interact with Arg3. This may be a general method for identifying simple intermolecular interactions involving proteins when there is no three-dimensional structure available of the complex of interacting species. The identification of these interactions provides the potential for rational protein engineering of enzymes with alternative specificities.     

Mutagenesis of two acidic active site residues in human muscle creatine kinase: implications for the catalytic mechanism

Creatine kinase (CK) catalyzes the reversible phosphorylation of the guanidine substrate, creatine, by MgATP. Although several X-ray crystal structures of various isoforms of creatine kinase have been published, the detailed catalytic mechanism remains unresolved. A crystal structure of the CK homologue, arginine kinase (AK), complexed with the transition-state analogue (arginine-nitrate-ADP), has revealed two carboxylate amino acid residues (Glu225 and Glu314) within 2.8 A of the proposed transphosphorylation site. These two residues are the putative catalytic groups that may promote nucleophilic attack by the guanidine amino group on the gamma-phosphate of ATP. From primary sequence alignments of arginine kinases and creatine kinases, we have identified two homologous creatine kinase acidic amino acid residues (Glu232 and Asp326), and these were targeted for examination of their potential roles in the CK mechanism. Using site-directed mutagenesis, we have made several substitutions at these two positions. The results indicate that of these two residues the Glu232 is the likely catalytic residue while Asp326 likely performs a role in properly aligning substrates for catalysis.     

E230Q mutation of the catalytic subunit of cAMP-dependent protein kinase affects local structure and the binding of peptide inhibitor

The active site of the mammalian cAMP-dependent protein kinase catalytic subunit (C-subunit) has a cluster of nonconserved acidic residues-Glu127, Glu170, Glu203, Glu230, and Asp241-that are crucial for substrate recognition and binding. Studies have shown that the Glu230 to Gln mutant (E230Q) of the enzyme has physical properties similar to the wild-type enzyme and has decreased affinity for a short peptide substrate, Kemptide. However, recent experiments intended to crystallize ternary complex of the E230Q mutant with MgATP and protein kinase inhibitor (PKI) could only obtain crystals of the apo-enzyme of E230Q mutant. To deduce the possible mechanism that prevented ternary complex formation, we used the relaxed-complex method (Lin, J.-H., et al. J Am Chem Soc 2002, 24, 5632-5633) to study PKI binding to the E230Q mutant C-subunit. In the E230Q mutant, we observed local structural changes of the peptide binding site that correlated closely to the reduced PKI affinity. The structural changes occurred in the F-to-G helix loop and appeared to hinder PKI binding. Reduced electrostatic potential repulsion among Asp241 from the helix loop section and the other acidic residues in the peptide binding site appear to be responsible for the structural change.     

Substrate binding to Src: A new perspective on tyrosine kinase substrate recognition from NMR and molecular dynamics

Most signal transduction pathways in humans are regulated by protein kinases through phosphorylation of their protein substrates. Typical eukaryotic protein kinases are of two major types: those that phosphorylate‐specific sequences containing tyrosine (~90 kinases) and those that phosphorylate either serine or threonine (~395 kinases). The highly conserved catalytic domain of protein kinases comprises a smaller N lobe and a larger C lobe separated by a cleft region lined by the activation loop. Prior studies find that protein tyrosine kinases recognize peptide substrates by binding the polypeptide chain along the C‐lobe on one side of the activation loop, while serine/threonine kinases bind their substrates in the cleft and on the side of the activation loop opposite to that of the tyrosine kinases. Substrate binding structural studies have been limited to four families of the tyrosine kinase group, and did not include Src tyrosine kinases. We examined peptide‐substrate binding to Src using paramagnetic‐relaxation‐enhancement NMR combined with molecular dynamics simulations. The results suggest Src tyrosine kinase can bind substrate positioning residues C‐terminal to the phosphoacceptor residue in an orientation similar to serine/threonine kinases, and unlike other tyrosine kinases. Mutagenesis corroborates this new perspective on tyrosine kinase substrate recognition. Rather than an evolutionary split between tyrosine and serine/threonine kinases, a change in substrate recognition may have occurred within the TK group of the human kinome. Protein tyrosine kinases have long been therapeutic targets, but many marketed drugs have deleterious off‐target effects. More accurate knowledge of substrate interactions of tyrosine kinases has the potential for improving drug selectivity.     

Protein kinase activity of FSV (Fujinami sarcoma virus) P130gag-fps shows a strict specificity for tyrosine residues

A number of oncogenic viruses encode transforming proteins with protein kinase activities apparently specific for tyrosine residues. Recent evidence has raised questions as to the substrate specificity of these kinases in general and the physiological relevance of tyrosine phosphorylation in particular. The P130gag-fps transforming protein of Fujinami sarcoma virus (FSV) is strongly phosphorylated at 2 tyrosine residues in FSV-transformed cells of which 1 (Tyr-1073) is also the major site of P130gag-fps intermolecular autophosphorylation in vitro. We have investigated the specificity of the protein kinase activity intrinsic to FSV P130gag-fps by using site-directed mutagenesis to change the codon for Tyr-1073 to those for the other commonly phosphorylated hydroxyamino acids, serine and threonine. This approach has some advantages over the use of synthetic peptides to define protein kinase recognition sites in that the protein containing the altered target site can be expressed in intact cells. In addition it allows higher order as well as primary structure of the enzyme recognition site to be considered. Neither serine nor threonine were phosphorylated when substituted for tyrosine at position 1073 of P130gag-fps indicating a stringent specificity for tyrosine as a substrate of the P130gag-fps protein kinase autophosphorylating activity. Consistent with the suggestion that tyrosine phosphorylation is of functional significance we find that these and other FSV Tyr-1073 mutants have depressed enzymatic and oncogenic capacities.     

Dicyclohexylcarbodiimide cross-links two conserved residues, Asp-184 and Lys-72, at the active site of the catalytic subunit of cAMP-dependent protein kinase

In the absence of MgATP, the catalytic subunit of cAMP-dependent protein kinase is irreversibly inhibited by the hydrophobic carbodiimide dicyclohexylcarbodiimide, and this inhibition is most likely due to the formation of a cross-link between a carboxyl group and a lysine residue in the active site (Toner-Webb & Taylor, 1987). In order to identify these cross-linked residues, the catalytic subunit was modified by dicyclohexylcarbodiimide and then treated with acetic anhydride and digested with trypsin. The resulting peptides were resolved by high-performance liquid chromatography. One major absorbing tryptic peptide and one smaller peptide consistently and reproducibly showed a decrease in absorbance after the catalytic subunit had been treated with DCCD. These peptides correspond to residues 166-190 and 57-93, respectively. A unique peptide was isolated from the modified catalytic subunit, and the sequence of this peptide established that the cross-linking occurred between Asp-184 and Lys-72. The cross-linking of these two residues, which were both identified previously as essential residues, confirms the likelihood that each plays a role in the functioning of this enzyme. The fact that Asp-184 and Lys-72 appear to be invariant in all protein kinases further supports the hypothesis that these two residues, located close to one another at the active site of the enzyme, play essential roles in catalysis.     

Identification of novel glycogen synthase kinase-3beta substrate-interacting residues suggests a common mechanism for substrate recognition

Substrate recognition and specificity are essential for the reliability and fidelity of protein kinase function. GSK-3 has a unique substrate specificity that requires prior phosphorylation of its substrates. However, how the enzyme selects its phosphorylated substrates is unknown. Here, we combined in silico modeling with mutagenesis and biological studies to identify GSK-3-substrate interaction sites located within its binding cleft. Protein-protein docking of GSK-3beta and the phosphorylated cAMP responsive element binding protein (pCREB) (using the available experimentally determined structures), identified Phe67, Gln89, and Asn95 of GSK-3beta as putative binding sites interacting with the CREB phosphorylation motif. Mutations of these residues to alanine impaired GSK-3beta phosphorylation of several substrates, without abrogating its autocatalytic activity. Subsequently, expression of the GSK-3beta mutants in cells resulted in decreased phosphorylation of substrates CREB, IRS-1, and beta-catenin, and prevented their suppression of glycogen synthase activity as compared with cells expressing the wild-type GSK-3beta. Our studies provide important additional understanding of how GSK-3beta recognizes its substrates: In addition to prior phosphorylation typically required in GSK-3 substrates, substrate recognition involves interactions with GSK-3beta residues: Phe67, Gln89, and Asn95, which confer a common basis for substrate binding and selectivity, yet allow for substrate diversity.     

Crystal structure of the E230Q mutant of cAMP-dependent protein kinase reveals an unexpected apoenzyme conformation and an extended N-terminal A helix

Glu230, one of the acidic residues that cluster around the active site of the catalytic subunit of cAMP-dependent protein kinase, plays an important role in substrate recognition. Specifically, its side chain forms a direct salt-bridge interaction with the substrate's P-2 Arg. Previous studies showed that mutation of Glu230 to Gln (E230Q) caused significant decreases not only in substrate binding but also in the rate of phosphoryl transfer. To better understand the importance of Glu230 for structure and function, we solved the crystal structure of the E230Q mutant at 2.8 A resolution. Surprisingly, the mutant preferred an open conformation with no bound ligands observed, even though the crystals were grown in the presence of MgATP and the inhibitor peptide, IP20. This is in contrast to the wild-type protein that, under the same conditions, prefers the closed conformation of a ternary complex. The structure highlights the importance of the electrostatic surface not only for substrate binding and catalysis, but also for the mechanism for closing the active site cleft. This surface mutation clearly disrupts the recognition and binding of substrate peptide so that the enzyme prefers an open conformation that cannot trap ATP. This is consistent with the reinforcing concepts of conformational dynamics and the synergistic binding of ATP and substrate peptide. Another unusual feature of the structure is the observation of the entire N terminus (Gly1-Thr32) assumes an extended alpha-helix conformation. Finally, based on temperature factors, this mutant structure is more stable than the wild-type C-subunit in the apo state.     

Evolutionary constraints associated with functional specificity of the CMGC protein kinases MAPK, CDK, GSK, SRPK, DYRK, and CK2alpha

Amino acid residues associated with functional specificity of cyclin-dependent kinases (CDKs), mitogen-activated protein kinases (MAPKs), glycogen synthase kinases (GSKs), and CDK-like kinases (CLKs), which are collectively termed the CMGC group, were identified by categorizing and quantifying the selective constraints acting upon these proteins during evolution. Many constraints specific to CMGC kinases correspond to residues between the N-terminal end of the activation segment and a CMGC-conserved insert segment associated with coprotein binding. The strongest such constraint is imposed on a "CMGC-arginine" near the substrate phosphorylation site with a side chain that plays a role both in substrate recognition and in kinase activation. Two nearby buried waters, which are also present in non-CMGC kinases, typically position the main chain of this arginine relative to the catalytic loop. These and other CMGC-specific features suggest a structural linkage between coprotein binding, substrate recognition, and kinase activation. Constraints specific to individual subfamilies point to mechanisms for CMGC kinase specialization. Within casein kinase 2alpha (CK2alpha), for example, the binding of one of the buried waters appears prohibited by the side chain of a leucine that is highly conserved within CK2alpha and that, along with substitution of lysine for the CMGC-arginine, may contribute to the broad substrate specificity of CK2alpha by relaxing characteristically conserved, precise interactions near the active site. This leucine is replaced by a conserved isoleucine or valine in other CMGC kinases, thereby illustrating the potential functional significance of subtle amino acid substitutions. Analysis of other CMGC kinases similarly suggests candidate family-specific residues for experimental follow-up.     

Differential labeling of the catalytic subunit of cAMP-dependent protein kinase with acetic anhydride: substrate-induced conformational changes

In order to identify regions that are sensitive to substrate-induced perturbations, the catalytic subunit of cAMP-dependent protein kinase was differentially labeled with [3H]acetic anhydride. Treatment of the catalytic subunit with acetic anhydride in the absence of substrates led to the irreversible inhibition of activity, and MgATP protected against inactivation. After development of a purification protocol for the lysine-containing peptides, the reactivity of each lysine in the native enzyme was calculated. The reactivity profile of lysines in the apoenzyme revealed three distinct regions. In general, the lysines within the amino-terminal segment (residues 1-83) and the carboxy-terminal segment (192-345) were relatively reactive. In contrast, the five lysines in the middle of the protein (Lys-92, -105, -111, -168, and -189) were very unreactive, indicating that these groups are sequestered from the aqueous solvent. The reactivity of each lysine was then determined in the presence of MgATP and in the presence of MgATP and a 20-residue inhibitor peptide. Most of the substrate-induced changes in lysine reactivity were localized in the amino-terminal segment, while the reactivities of lysines in the carboxy-terminal region were not altered significantly by MgATP or inhibitor peptide. MgATP affords substantial protection to three residues in particular. Lys-72, predicted previously to be essential for nucleotide binding was relatively reactive in the apoenzyme, whereas labeling was nearly abolished in the presence of MgATP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reverse two-hybrid screening identifies residues of JNK required for interaction with the kinase interaction motif of JNK-interacting protein-1

The development of specific inhibitors for the c-Jun N-terminal kinase (JNK) family of mitogen-activated protein kinases (MAPKs) has been a recent research focus because of the association of JNK with cell death in conditions such as stroke and neurodegeneration. We have demonstrated previously the presence of critical inhibitory residues within an 11-mer peptide (TI-JIP) based on the sequence of JNK-interacting protein-1 (JIP-1). However, the corresponding region of JNK bound by this JIP-1-based peptide was unknown. To identify this region, we used a novel reverse two-hybrid approach with TI-JIP as bait. We screened a library of JNK1 mutants that had been generated by random PCR mutagenesis and found three mutants of JNK1 that failed to interact with TI-JIP. The mutations in JNK1 were L131R, R309W, and Y320H. Of these mutated residues, Leu-131 and Tyr-320 were located on a common face of the JNK protein close to other residues implicated previously in the interactions of MAPKs with substrates, phosphatases, and scaffolds. To test whether these JNK1 mutants were thus affected in their regulation, we evaluated their activation in mammalian cells in response to hyperosmolarity or cotransfection with a constitutively active upstream kinase or their direct phosphorylation by either MAPK kinase (MKK)4 or MKK7. In each situation, all three JNK mutants were not activated or phosphorylated to the same level as wild-type JNK. Therefore, the results of our unbiased reverse two-hybrid screening approach have identified residues of JNK responsible for binding JIP-1-based peptides as well as MKK4 or MKK7.     

Contribution of an active site cation-pi interaction to the spectroscopic properties and catalytic function of protein tyrosine kinase Csk

Csk is a soluble protein tyrosine kinase that phosphorylates and negatively regulates protein tyrosine kinases of the Src family. The spectral properties of the intrinsic Trp fluorescence of Csk and their underlying structural features were investigated in combination with urea denaturation and site-specific mutagenesis. It was found that W352 contributed approximately 35% of the total Trp fluorescence of Csk even though seven other Trp residues were present. The enhanced contribution by W352 to Csk fluorescence was due to an interaction between its indole ring and the positively charged guanidino group of R318. W352 is located on the peptide substrate binding P+1 loop, and R318 is located on the catalytic loop. The W352-R318 interaction, called a cation-pi interaction, uniquely couples the two loops in the active site. Mutations that disrupted this coupling resulted in varying levels of decreases in Csk activity, and consistent and significant increases in K(m) values for its physiological substrate, Src protein tyrosine kinase. These results indicated that structural coupling between the two loops by the cation-pi interaction played an important role in Csk substrate binding. Since both R318 and W352 are highly conserved among protein tyrosine kinases, this cation-pi interaction is likely a signature structural feature of most, if not all, PTKs. These studies elucidated the roles of two conserved signature residues in Csk and formed a baseline for further structure-function studies of Csk and other PTKs.     

Systematic mutational analysis of cAMP-dependent protein kinase identifies unregulated catalytic subunits and defines regions important for the recognition of the regulatory subunit.

A library of mutants of the catalytic subunit of the Saccharomyces cerevisiae cAMP-dependent protein kinase was screened in vitro for mutants defective in the recognition of the regulatory subunit. The mutations identified were mapped onto the three-dimensional structure of the mouse catalytic subunit with a peptide inhibitor. Mutations defective in the recognition of both the regulatory subunit and the peptide substrate Leu-Arg-Arg-Ala-Ser-Leu-Gly (Kemptide) mapped to the peptide-binding site shared by all substrates and inhibitors of the catalytic subunit and functionally define the binding site for the autoinhibitor sequence in the hinge region of the regulatory subunit. Mutants defective only in the recognition of the regulatory subunit identified residues that comprise additional binding sites for the regulatory subunit. The majority of these residues are clustered on the surface of the catalytic subunit in a region flanking the distal portion of the autoinhibitor/peptide-binding site. The simultaneous substitution of Lys233, Asp237, Lys257, and Lys261 in this region caused a 260-fold decrease in affinity for the regulatory subunit, whereas the catalytic efficiency toward Kemptide decreased by only 1.8-fold. The substitution of autophosphorylated Thr241, also in this region, and the 3 residues interacting with the phosphate also caused an unregulated phenotype.     

Determinants for substrate phosphorylation by Dictyostelium myosin II heavy chain kinases A and B and eukaryotic elongation factor-2 kinase

The alpha kinases are a widespread family of atypical protein kinases characterized by a novel type of catalytic domain. In this paper the peptide substrate recognition motifs for three alpha kinases, Dictyostelium discoideum myosin heavy chain kinase (MHCK) A and MHCK B and mammalian eukaryotic elongation factor-2 kinase (eEF-2K), were characterized by incorporating amino acid substitutions into a previously identified MHCK A peptide substrate (YAYDTRYRR) (Luo X. et al. (2001) J. Biol. Chem. 276, 17836-43). A lysine or arginine in the P+1 position on the C-terminal side of the phosphoacceptor threonine (P site) was found to be critical for peptide substrate recognition by MHCK A, MHCK B and eEF-2K. Phosphorylation by MHCK B was further enhanced 8-fold by a basic residue in the P+2 position whereas phosphorylation by MHCK A was enhanced 2- to 4-fold by basic residues in the P+2, P+3 and P+4 positions. eEF-2K required basic residues in both the P+1 and P+3 positions to recognize peptide substrates. eEF-2K, like MHCK A and MHCK B, exhibited a strong preference for threonine as the phosphoacceptor amino acid. In contrast, the Dictyostelium VwkA and mammalian TRPM7 alpha kinases phosphorylated both threonine and serine residues. The results, together with a phylogenetic analysis of the alpha kinase catalytic domain, support the view that the metazoan eEF-2Ks and the Dictyostelium MHCKs form a distinct subgroup of alpha kinases with conserved properties.     

Understanding and exploiting substrate recognition by protein kinases

Protein kinases play a virtually universal role in cellular regulation and are emerging as an important class of new drug targets, yet the cellular functions of most human kinases largely remain obscure. Aspects of substrate recognition common to all kinases in the ATP nucleotide binding site have been exploited in the generation of analog-specific mutants for exploring kinase function and discovering novel protein substrates. Likewise, understanding interactions with the protein substrate, which differ substantially between kinases, can also help to identify substrates and to produce tools for studying kinase pathways, including fluorescent biosensors. Principles of kinase substrate recognition are particularly valuable in guiding bioinformatics and phosphoproteomics approaches that impact our understanding of signaling pathways and networks on a global scale.     

Structural basis for the low affinities of yeast cAMP-dependent and mammalian cGMP-dependent protein kinases for protein kinase inhibitor peptides.

Affinities of the catalytic subunit (C1) of Saccharomyces cerevisiae cAMP-dependent protein kinase and of mammalian cGMP-dependent protein kinase were determined for the protein kinase inhibitor (PKI) peptide PKI(6-22)amide and seven analogues. These analogues contained structural alterations in the N-terminal alpha-helix, the C-terminal pseudosubstrate portion, or the central connecting region of the PKI peptide. In all cases, the PKI peptides were appreciably less active as inhibitors of yeast C1 than of mammalian C alpha subunit. Ki values ranged from 5- to 290-fold higher for the yeast enzyme than for its mammalian counterpart. Consistent with these results, yeast C1 exhibited a higher Km for the peptide substrate Kemptide. All of the PKI peptides were even less active against the mammalian cGMP-dependent protein kinase than toward yeast cAMP-dependent protein kinase, and Kemptide was a poorer substrate for the former enzyme. Alignment of amino acid sequences of these homologous protein kinases around residues in the active site of mammalian C alpha subunit known to interact with determinants in the PKI peptide [Knighton, D. R., Zheng, J., Ten Eyck, L. F., Xuong, N-h, Taylor, S. S., & Sowadski, J. M. (1991) Science 253, 414-420] provides a structural basis for the inherently lower affinities of yeast C1 and cGMP-dependent protein kinase for binding peptide inhibitors and substrates. Both yeast cAMP-dependent and mammalian cGMP-dependent protein kinases are missing two of the three acidic residues that interact with arginine-18 in the pseudosubstrate portion of PKI. Further, the cGMP-dependent protein kinase appears to completely lack the hydrophobic/aromatic pocket that recognizes the important phenylalanine-10 residue in the N-terminus of the PKI peptide, and binding of the inhibitor by the yeast protein kinase at this site appears to be partially compromised.     

Identification of a cDNA encoding an active asparaginyl endopeptidase of Schistosoma mansoni and its expression in Pichia pastoris

Novel affinity ligands, consisting of ATP-resembling part coupled with specificity determining peptide fragment, were proposed for purification of protein kinases. Following this approach affinity sorbents based on two closely similar ligands AdoC-Aoc-Arg4-Lys and AdoC-Aoc-Arg4-NH(CH2)6NH2, where AdoC stands for adenosine-5'-carboxylic acid and Aoc for amino-octanoic acid, were synthesized and tested for purification of recombinant protein kinase A catalytic subunit directly from crude cell extract. Elution of the enzyme with MgATP as well as L-arginine yielded homogeneous protein kinase A preparation in a single purification step. Also protein kinase A from pig heart homogenate was selectively isolated using MgATP as eluting agent. Protein kinase with acidic specificity determinant (CK2) as well as other proteins possessing nucleotide binding site (L-type pyruvate kinase) or sites for wide variety of different ligands (bovine serum albumin) did not bind to the column, pointing to high selectivity of the bi-functional binding mode of the affinity ligand.     

Discovery of cellular substrates for protein kinase A using a peptide array screening protocol

Post-translational modification of proteins is a universal form of cellular regulation. Phosphorylation on serine, threonine, tyrosine or histidine residues by protein kinases is the most widespread and versatile form of covalent modification. Resultant changes in activity, localization or stability of phosphoproteins drives cellular events. MS and bioinformatic analyses estimate that ~30% of intracellular proteins are phosphorylated at any given time. Multiple approaches have been developed to systematically define targets of protein kinases; however, it is likely that we have yet to catalogue the full complement of the phosphoproteome. The amino acids that surround a phosphoacceptor site are substrate determinants for protein kinases. For example, basophilic enzymes such as PKA (protein kinase A), protein kinase C and calmodulin-dependent kinases recognize basic side chains preceding the target serine or threonine residues. In the present paper we describe a strategy using peptide arrays and motif-specific antibodies to identify and characterize previously unrecognized substrate sequences for protein kinase A. We found that the protein kinases PKD (protein kinase D) and MARK3 [MAP (microtubule-associated protein)-regulating kinase 3] can both be phosphorylated by PKA. Furthermore, we show that the adapter protein RIL [a product of PDLIM4 (PDZ and LIM domain protein 4)] is a PKA substrate that is phosphorylated on Ser(119) inside cells and that this mode of regulation may control its ability to affect cell growth.     

Deciphering the Arginine-binding preferences at the substrate-binding groove of Ser/Thr kinases by computational surface mapping

Protein kinases are key signaling enzymes that catalyze the transfer of γ-phosphate from an ATP molecule to a phospho-accepting residue in the substrate. Unraveling the molecular features that govern the preference of kinases for particular residues flanking the phosphoacceptor is important for understanding kinase specificities toward their substrates and for designing substrate-like peptidic inhibitors. We applied ANCHORSmap, a new fragment-based computational approach for mapping amino acid side chains on protein surfaces, to predict and characterize the preference of kinases toward Arginine binding. We focus on positions P-2 and P-5, commonly occupied by Arginine (Arg) in substrates of basophilic Ser/Thr kinases. The method accurately identified all the P-2/P-5 Arg binding sites previously determined by X-ray crystallography and produced Arg preferences that corresponded to those experimentally found by peptide arrays. The predicted Arg-binding positions and their associated pockets were analyzed in terms of shape, physicochemical properties, amino acid composition, and in-silico mutagenesis, providing structural rationalization for previously unexplained trends in kinase preferences toward Arg moieties. This methodology sheds light on several kinases that were described in the literature as having non-trivial preferences for Arg, and provides some surprising departures from the prevailing views regarding residues that determine kinase specificity toward Arg. In particular, we found that the preference for a P-5 Arg is not necessarily governed by the 170/230 acidic pair, as was previously assumed, but by several different pairs of acidic residues, selected from positions 133, 169, and 230 (PKA numbering). The acidic residue at position 230 serves as a pivotal element in recognizing Arg from both the P-2 and P-5 positions.     

Role of leucine 66 in the asymmetric recognition of substrates in chicken muscle adenylate kinase

Adenylate kinase has two distinct binding sites for nucleotide substrates, MgATP and AMP. To identify the location of the site that specifically interacts with the adenine ring of AMP, we have substituted Ala, Gly, Val, Gln, and Trp for Leu66 of the recombinant chicken muscle enzyme by site-directed mutagenesis. All the purified Leu66 mutant enzymes exhibited an essentially identical circular dichroism spectrum and had thermal stabilities similar to the wild-type enzyme. Steady state kinetic analysis showed that the Leu66 mutant enzymes have significantly decreased Vmax values and markedly large Km values only for AMP. These results show that the binding site for the adenine ring of AMP in adenylate kinase is presumably located close to Leu66, which is invariant in all the enzymes so far sequenced. Significant inhibition of activities of the mutant enzymes and quenching of the Trp66 fluorescence by substrates suggest that in some Leu66 mutant enzymes, MgATP also binds to the AMP-binding site. Thus, Leu66 of adenylate kinase might play a role in the asymmetric recognition of the adenine ring of AMP from that of MgATP. Furthermore, the hydrophobicity of the residue at position 66 appears to be important for the positive cooperativity of substrate binding.