Synthesis and characterization of 5'-p-fluorosulfonylbenzoyl-2' (or 3')-(biotinyl)adenosine as an activity-based probe for protein kinases

Most of the kinase inhibitors that are approved for therapeutic uses or that are undergoing clinical trials are directed toward the adenosine triphosphate (ATP) binding site of protein kinases. 5'-Fluorosulfonylbenzoyl 5'-adenosine (FSBA) is an activitybased probe (ABP) that covalently modifies a conserved lysine present in the nucleotide binding site of most kinases. Here the authors describe synthesis of FSBA derivatives, 2'-biotinyl-FSBA and 3'-biotinyl-FSBA as kinase ABPs, and delineate a Western blot method to screen and validate ATP competitive protein kinase inhibitors using biotinyl-FSBA as a nonselective activity-based probe for protein kinases.     

Kinetic mechanism and ATP-binding site reactivity of p38gamma MAP kinase

Activated p38gamma MAP kinase exhibited significant basal ATPase activity in the absence of a kinase substrate, and addition of a phosphoacceptor substrate increased k(cat)/K(m)20-fold. AMP-PCP was competitive with ATP binding and non-competitive with phosphoacceptor substrate binding. The nucleotide binding site affinity label 5'-(p-fluorosulfonylbenzoyl)adenosine (FSBA) bound stoichiometrically at Lys-56 in the ATP site of both unphosphorylated and activated p38gamma. AMP-PCP only protected the activated enzyme from FSBA inactivation, implying that AMP-PCP does not bind unphosphorylated p38gamma. Basal ATPase activities were also observed for activated p38alpha, ERK2 and JNK3 suggesting that the enzymatic mechanism may be similar for all classes of MAP kinases.     

The nucleotide-binding site of human sphingosine kinase 1

Sphingosine kinase catalyzes the formation of sphingosine 1-phosphate, a lipid second messenger that has been implicated in a number of agonist-driven cellular responses including mitogenesis, anti-apoptosis, and expression of inflammatory molecules. Despite the importance of sphingosine kinase, very little is known regarding its structure or mechanism of catalysis. Moreover, sphingosine kinase does not contain recognizable catalytic or substrate-binding sites, based on sequence motifs found in other kinases. Here we have elucidated the nucleotide-binding site of human sphingosine kinase 1 (hSK1) through a combination of site-directed mutagenesis and affinity labeling with the ATP analogue, FSBA. We have shown that Gly(82) of hSK1 is involved in ATP binding since mutation of this residue to alanine resulted in an enzyme with an approximately 45-fold higher K(m)((ATP)). We have also shown that Lys(103) is important in catalysis since an alanine substitution of this residue ablates catalytic activity. Furthermore, we have shown that this residue is covalently modified by FSBA. Our data, combined with amino acid sequence comparison, suggest a motif of SGDGX(17-21)K is involved in nucleotide binding in the sphingosine kinases. This motif differs in primary sequence from all previously identified nucleotide-binding sites. It does, however, share some sequence and likely structural similarity with the highly conserved glycine-rich loop, which is known to be involved in anchoring and positioning the nucleotide in the catalytic site of many protein kinases.     

Alternative binding modes of an inhibitor to two different kinases.

Protein kinases are targets for therapeutic agents designed to intervene in signaling processes in the diseased state. Most kinase inhibitors are directed towards the conserved ATP binding site. Because the essential features of this site are conserved in all eukaryotic protein kinases, it is generally assumed that the same compound will bind in a similar manner to different protein kinases. The inhibitor 4,5,6,7-tetrabromobenzotriazole (TBB) is a selective inhibitor for the protein kinase CK2 (IC50 1.6 micro m) (Sarno et al. (2001) FEBS Letts.496, 44-48). Three other kinases [cyclin-dependent protein kinase 2 (CDK2), phosphorylase kinase and glycogen synthase kinase 3beta] exhibit approximately 10-fold weaker affinity for TBB than CK2. We report the crystal structure of TBB in complex with phospho-CDK2-cyclin A at 2.2 A resolution and compare the interactions with those observed for TBB bound to CK2. TBB binds at the ATP binding site of both kinases. In CDK2, each of the four bromine atoms makes polar contacts either to main chain oxygens in the hinge region of the kinase or to water molecules, in addition to several van der Waals contacts. The mode of binding of TBB to CDK2 is different from that to CK2. TBB in CDK2 is displaced more towards the hinge region between the N- and C-terminal lobes and rotated relative to TBB in CK2. The ATP binding pocket is wider in CDK2 than in CK2 resulting in fewer van der Waals contacts but TBB in CK2 does not contact the hinge. The structures show that, despite the conservation of the ATP binding pocket, the inhibitor is able to exploit different recognition features so that the same compound can bind in different ways to the two different kinases.     

Inhibition of multidrug resistance-linked P-glycoprotein (ABCB1) function by 5'-fluorosulfonylbenzoyl 5'-adenosine: evidence for an ATP analogue that interacts with both drug-substrate-and nucleotide-binding sites

5'-Fluorosulfonylbenzonyl 5'-adenosine (FSBA) is an ATP analogue that covalently modifies several residues in the nucleotide-binding domains (NBDs) of several ATPases, kinases, and other proteins. P-glycoprotein (P-gp, ABCB1) is a member of the ATP-binding cassette (ABC) transporter superfamily that utilizes energy from ATP hydrolysis for the efflux of amphipathic anticancer agents from cancer cells. We investigated the interactions of FSBA with P-gp to study the catalytic cycle of ATP hydrolysis. Incubation of P-gp with FSBA inhibited ATP hydrolysis (IC(50 )= 0.21 mM) and the binding of 8-azido[α-(32)P]ATP (IC(50) = 0.68 mM). In addition, (14)C-FSBA cross-links to P-gp, suggesting that FSBA-mediated inhibition of ATP hydrolysis is irreversible due to covalent modification of P-gp. However, when the NBDs were occupied with a saturating concentration of ATP prior to treatment, FSBA stimulated ATP hydrolysis by P-gp. Furthermore, FSBA inhibited the photo-cross-linking of P-gp with [(125)I]iodoarylazidoprazosin (IAAP; IC(50) = 0.17 mM). As IAAP is a transport substrate for P-gp, this suggests that FSBA affects not only the NBDs but also the transport-substrate site in the transmembrane domains. Consistent with these results, FSBA blocked efflux of rhodamine 123 from P-gp-expressing cells. Additionally, mass spectrometric analysis identified FSBA cross-links to residues within or nearby the NBDs but not in the transmembrane domains, and docking of FSBA in a homology model of human P-gp NBDs supports the biochemical studies. Thus, FSBA is an ATP analogue that interacts with both the drug-binding and ATP-binding sites of P-gp, but fluorosulfonyl-mediated cross-linking is observed only at the NBDs.     

Unique MAP Kinase binding sites

Map kinases are drug targets for autoimmune disease, cancer, and apoptosis-related diseases. Drug discovery efforts have developed MAP kinase inhibitors directed toward the ATP binding site and neighboring "DFG-out" site, both of which are targets for inhibitors of other protein kinases. On the other hand, MAP kinases have unique substrate and small molecule binding sites that could serve as inhibition sites. The substrate and processing enzyme D-motif binding site is present in all MAP kinases, and has many features of a good small molecule binding site. Further, the MAP kinase p38alpha has a binding site near its C-terminus discovered in crystallographic studies. Finally, the MAP kinases ERK2 and p38alpha have a second substrate binding site, the FXFP binding site that is exposed in active ERK2 and the D-motif peptide induced conformation of MAP kinases. Crystallographic evidence of these latter two binding sites is presented.     

Mechanisms of p34cdc2 regulation.

The kinase activity of human p34cdc2 is negatively regulated by phosphorylation at Thr-14 and Tyr-15. These residues lie within the putative nucleotide binding domain of p34cdc2. It has been proposed that phosphorylation within this motif ablates the binding of ATP to the active site of p34cdc2, thereby inhibiting p34cdc2 kinase activity (K. Gould and P. Nurse, Nature [London] 342:39-44, 1989). To understand the mechanism of this inactivation, various forms of p34cdc2 were tested for the ability to bind nucleotide. The active site of p34cdc2 was specifically modified by the MgATP analog 5'-p-fluorosulfonylbenzoyladenosine (FSBA). The apparent Km for modification of wild-type, monomeric p34cdc2 was 148 microM FSBA and was not significantly affected by association with cyclin B. Tyrosine-phosphorylated p34cdc2 was modified by FSBA with a slightly higher Km (241 microM FSBA). FSBA modification of both tyrosine-phosphorylated and unphosphorylated p34cdc2 was competitively inhibited by ATP, and half-maximal inhibition in each case occurred at approximately 250 microM ATP. In addition to being negatively regulated by phosphorylation, the kinase activity of p34cdc2 was positively regulated by the cyclin-dependent phosphorylation of Thr-161. Mutation of p34cdc2 at Thr-161 resulted in the formation of an enzymatically inactive p34cdc2/cyclin B complex both in vivo and in vitro. However, mutation of Thr-161 did not significantly affect the ability of p34cdc2 to bind nucleotide (FSBA). Taken together, these results indicate that inhibition of p34cdc2 kinase activity by phosphorylation of Tyr-15 (within the putative ATP binding domain) or by mutation of Thr-161 involves a mechanism other than inhibition of nucleotide binding. We propose instead that the defect resides at the level of catalysis.     

Mapping of the ATP-binding domain of human fructosamine 3-kinase-related protein by affinity labelling with 5'-[p-(fluorosulfonyl)benzoyl]adenosine

The modification of proteins by reducing sugars through the process of non-enzymatic glycation is one of the principal mechanisms by which hyperglycaemia may precipitate the development of diabetic complications. Fn3K (fructosamine 3-kinase) and Fn3KRP (Fn3K-related protein) are two recently discovered enzymes that may play roles in metabolizing early glycation products. However, although the activity of these enzymes towards various glycated substrates has been established, very little is known about their structure-function relationships or their respective mechanisms of action. Furthermore, their only structural similarities noted to date with members of other kinase families has been with the bacterial aminoglycoside kinases. In the present study, we employed affinity labelling with the ATP analogue FSBA {5'-p-[(fluorosulfonyl)benzoyl]adenosine} to probe the active-site topology of Fn3KRP as an example of this enigmatic family of kinases. FSBA was found to modify Fn3KRP at five distinct sites; four of these were predicted to be localized in close proximity to its ATP-binding site, based on alignments with the aminoglycoside kinase APH(3')-IIIa, and examination of its published tertiary structure. The results of the present studies provide evidence that Fn3KRP possesses an ATP-binding domain that is structurally related to that of both the aminoglycoside kinases and eukaryotic protein kinases.     

ATP analog specificity of cAMP-dependent protein kinase, cGMP-dependent protein kinase, and phosphorylase kinase

The ATP analog specificities of the homogeneous cGMP-dependent protein kinase and the catalytic subunit of cAMP-dependent protein kinase have been compared by the ability of 27 analogs to compete with ATP in the protein kinase reaction. Although the data suggest general similarities between the ATP sites of the two homologous cyclic-nucleotide-dependent protein kinases, specific differences especially in the adenine binding pocket are indicated. These differences in affinity suggest potentially useful ATP analog inhibitors of each kinase. For example, apparent autophosphorylation of the purified regulatory subunit of the cAMP-dependent protein kinase is blocked by nebularin triphosphate, suggesting that the phosphorylation is catalyzed by trace contamination of cGMP-dependent protein kinase. Some of the ATP analogs have also been tested using phosphorylase b kinase in order to compare this enzyme with the cyclic-nucleotide-dependent enzymes. All three protein kinases have high specificity for the purine moiety of ATP, and lower specificity for the ribose or triphosphate. The similarity between the ATP site of phosphorylase b kinase to that of the cyclic-nucleotide-dependent protein kinases suggests that it is related to them. The ATP analog specificities of enzymes examined in this study are different from those reported for several unrelated ATP-utilizing enzymes.     

The structure of CYP101D2 unveils a potential path for substrate entry into the active site

We describe in the present paper mutations of the catalytic subunit α of PKA (protein kinase A) that introduce amino acid side chains into the ATP-binding site and progressively transform the pocket to mimic that of Aurora protein kinases. The resultant PKA variants are enzymatically active and exhibit high affinity for ATP site inhibitors that are specific for Aurora kinases. These features make the Aurora-chimaeric PKA a valuable tool for structure-based drug discovery tasks. Analysis of crystal structures of the chimaera reveal the roles for individual amino acid residues in the binding of a variety of inhibitors, offering key insights into selectivity mechanisms. Furthermore, the high affinity for Aurora kinase-specific inhibitors, combined with the favourable crystallizability properties of PKA, allow rapid determination of inhibitor complex structures at an atomic resolution. We demonstrate the utility of the Aurora-chimaeric PKA by measuring binding kinetics for three Aurora kinase-specific inhibitors, and present the X-ray structures of the chimaeric enzyme in complex with VX-680 (MK-0457) and JNJ-7706621 [Aurora kinase/CDK (cyclin-dependent kinase) inhibitor].     

On the location and function of the noncatalytic sites on the bovine heart mitochondrial F1-ATPase

Modification of Tyr-345 at a catalytic site in a single beta subunit of the bovine heart mitochondrial F1-ATPase (MF1) by 5'-p-fluorosulfonylbenzoylinosine did not affect subsequent labeling of noncatalytic sites at Tyr-368 and His-427 in three copies of the beta subunit by 5'-p-fluorosulfonylbenzoyladenosine (FSBA). These results clearly show that the beta subunit contains at least parts of the catalytic and noncatalytic nucleotide binding sites. Inactivation of MF1 by 96% with FSBA was accompanied by a decrease in the endogenous ADP content from 1.86 to 0.10 mol per mol of MF1. Decrease in the endogenous ADP content during the inactivation of the enzyme with FSBA paralleled loss in activity in a manner which suggests that the reaction of FSBA with an open noncatalytic site promoted release of ADP from another noncatalytic site until the third site reacted with FSBA. Two pKa values of about 5.9 and 7.6 were observed on the acid side of the pH optimum in the pH-rate profile for ATP hydrolysis catalyzed by MF1 in neutral acid buffers. In contrast, a single pKa of 5.9 was present in the pH-rate profile for ITP hydrolysis catalyzed by the enzyme in the same buffers. The augmented rate observed for ATP hydrolysis at pH 8.0, over that observed at pH 6.5, was lost as the enzyme was inactivated by FSBA in a manner suggesting that modulation is lost as the third noncatalytic site is modified. This suggests that ATP hydrolysis by MF1 is modulated in a pH-dependent manner by ATP binding to an open noncatalytic site. Two other modulations associated with binding of adenine nucleotides to noncatalytic sites, ADP-induced hysteretic inhibition and apparent negative cooperativity reflected by the Hill coefficient for the hydrolysis of 50-3000 microM ATP at pH 8.0, also disappeared as the third noncatalytic site reacted with FSBA.     

Wortmannin inactivates phosphoinositide 3-kinase by covalent modification of Lys-802, a residue involved in the phosphate transfer reaction.

Wortmannin at nanomolar concentrations is a potent and specific inhibitor of phosphoinositide (PI) 3-kinase and has been used extensively to demonstrate the role of this enzyme in diverse signal transduction processes. At higher concentrations, wortmannin inhibits the ataxia telangiectasia gene (ATM)-related DNA-dependent protein kinase (DNA-PKcs). We report here the identification of the site of interaction of wortmannin on the catalytic subunit of PI 3-kinase, p110alpha. At physiological pH (6.5 to 8) wortmannin reacted specifically with p110alpha. Phosphatidylinositol-4,5-diphosphate, ATP, and ATP analogs [adenine and 5'-(4-fluorosulfonylbenzoyl)adenine] competed effectively with wortmannin, while substances containing nucleophilic amino acid side chain functions had no effect at the same concentrations. This suggests that the wortmannin target site is localized in proximity to the substrate-binding site and that residues involved in wortmannin binding have an increased nucleophilicity because of their protein environment. Proteolytic fragments of wortmannin-treated, recombinant p110alpha were mapped with anti-wortmannin and anti-p110alpha peptide antibodies, thus limiting the target site within a 10-kDa fragment, colocalizing with the ATP-binding site. Site-directed mutagenesis of all candidate residues within this region showed that only the conservative Lys-802-to-Arg mutation abolished wortmannin binding. Inhibition of PI 3-kinase occurs, therefore, by the formation of an enamine following the attack of Lys-802 on the furan ring (at C-20) of wortmannin. The Lys-802-to-Arg mutant was also unable to bind FSBA and was catalytically inactive in lipid and protein kinase assays, indicating a crucial role for Lys-802 in the phosphotransfer reaction. In contrast, an Arg-916-to-Pro mutation abolished the catalytic activity whereas covalent wortmannin binding remained intact. Our results provide the basis for the design of novel and specific inhibitors of an enzyme family, including PI kinases and ATM-related genes, that play a central role in many physiological processes.     

The ATP-binding site of brain phosphatidylinositol 4-kinase PI4K230 as revealed by 5'-p-fluorosulfonylbenzoyladenosine

The ATP-binding site of purified bovine brain phosphatidylinositol 4-kinase 230 (PI4K230) was studied by its reaction with 5'-p-fluorosulfonylbenzoyladenosine (FSBA), an ATP-like alkylating reagent. Four hundred to eight hundred micromolar FSBA inactivated PI4K230 specifically with apparently first-order kinetics and resulted in 50% loss of enzyme activity in 36--130 min. The specificity of the reaction with FSBA was demonstrated by the lack of inactivation with 5'-p-fluorosulfonylbenzoyl chloride and by protection with ATP and ATP analogues against inactivation. Most ATP analogues competed with FSBA inactivation in order of their increasing hydrophobicity, parallel to their inhibitory potency in activity measurements. The specific binding of FSBA to PI4K230 was demonstrated also by Western-blot experiments. These results suggest that FSBA-reactive group(s) involved in the enzyme activity are located near to the ATP-binding site in a hydrophobic region of native PI4K230. Experiments with site-directed mutagenesis indicate that the conserved Lys-1792 plays essential role in the enzyme activity and serves as one target of affinity labelling by FSBA. Prevention of both Lys-1792-directed and Lys-1792-independent binding of FSBA by Cibacron Blue 3GA suggest that these sites are located spatially close to each other.     

Peptide inhibitors of protein kinases-discovery, characterisation and use

Protein kinases are now the second largest group of drug targets, and most protein kinase inhibitors in clinical development are directed towards the ATP-binding site. However, these inhibitors must compete with high intracellular ATP concentrations and they must discriminate between the ATP-binding sites of all protein kinases as well the other proteins that also utilise ATP. It would therefore be beneficial to target sites on protein kinases other than the ATP-binding site. This review describes the discovery, characterisation and use of peptide inhibitors of protein kinases. In many cases, the development of these peptides has resulted from an understanding of the specific protein-binding partners for a particular protein kinase. In addition, novel peptide sequences have been discovered in library screening approaches and have provided new leads in the discovery and/or design of peptide inhibitors of protein kinases. These approaches are therefore providing exciting new opportunities in the development of ATP non-competitive inhibitors of protein kinases.     

Analysis of water patterns in protein kinase binding sites

Deregulation of protein kinases is associated with numerous diseases, making them important targets for drug discovery. The majority of drugs target the catalytic site of these proteins, but due to the high level of similarity within the ATP binding sites of protein kinases, it is often difficult to achieve the required pharmacological selectivity. In this study, we describe the identification and subsequent analysis of water patterns in the ATP binding sites of 171 protein kinase structures, comprising 19 different kinases from various branches of the kinome, and demonstrate that structurally similar binding sites often have significantly different water patterns. We show that the observed variations in water patterns of different, but structurally similar kinases can be exploited in the structure-based design of potent and selective kinase inhibitors.     

A single amino acid substitution makes ERK2 susceptible to pyridinyl imidazole inhibitors of p38 MAP kinase.

Mitogen-activated protein (MAP) kinases are serine/threonine kinases that mediate intracellular signal transduction pathways. Pyridinyl imidazole compounds block pro-inflammatory cytokine production and are specific p38 kinase inhibitors. ERK2 is related to p38 in sequence and structure, but is not inhibited by pyridinyl imidazole inhibitors. Crystal structures of two pyridinyl imidazoles complexed with p38 revealed these compounds bind in the ATP site. Mutagenesis data suggested a single residue difference at threonine 106 between p38 and other MAP kinases is sufficient to confer selectivity of pyridinyl imidazoles. We have changed the equivalent residue in human ERK2, Q105, into threonine and alanine, and substituted four additional ATP binding site residues. The single residue change Q105A in ERK2 enhances the binding of SB202190 at least 25,000-fold compared to wild-type ERK2. We report enzymatic analyses of wild-type ERK2 and the mutant proteins, and the crystal structure of a pyridinyl imidazole, SB203580, bound to an ERK2 pentamutant, I103L, Q105T, D106H, E109G. T110A. These ATP binding site substitutions induce low nanomolar sensitivity to pyridinyl imidazoles. Furthermore, we identified 5-iodotubercidin as a potent ERK2 inhibitor, which may help reveal the role of ERK2 in cell proliferation.     

Identification of the ATP binding sites of the carbamyl phosphate synthetase domain of the Syrian hamster multifunctional protein CAD by affinity labeling with 5'-[p-(fluorosulfonyl)benzoyl]adenosine.

The ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine (FSBA) was used to chemically modify the ATP binding sites of the carbamyl phosphate synthetase domain of CAD, the multifunctional protein that catalyzes the first steps in mammalian pyrimidine biosynthesis. Reaction of CAD with FSBA resulted in the inactivation of the ammonia- and glutamine-dependent CPSase activities but had no effect on its glutaminase, aspartate transcarbamylase, or dihydroorotase activities. ATP protected CAD against inactivation by FSBA whereas the presence of the allosteric effectors UTP and PRPP afforded little protection, which suggests that the ATP binding sites were specifically labeled. The inactivation exhibited saturation behavior with respect to FSBA with a K1 of 0.93 mM. Of the two ATP-dependent partial activities of carbamyl phosphate synthetase, bicarbonate-dependent ATPase was inactivated more rapidly than the carbamyl phosphate dependent ATP synthetase, which indicates that these partial reactions occur at distinct ATP binding sites. The stoichiometry of [14C]FSBA labeling showed that only 0.4-0.5 mol of FSBA/mol of protein was required for complete inactivation. Incorporation of radiolabeled FSBA into CAD and subsequent proteolysis, gel electrophoresis, and fluorography demonstrated that only the carbamyl phosphate synthetase domain of CAD is labeled. Amino acid sequencing of the principal peaks resulting from tryptic digests of FSBA-modified CAD located the sites of FSBA modification in regions that exhibit high homology to ATP binding sites of other known proteins. Thus CAD has two ATP binding sites, one in each of the two highly homologous halves of the carbamyl phosphate domain which catalyze distinct ATP-dependent partial reactions in carbamyl phosphate synthesis.     

Structural features of the protein kinase domain and targeted binding by small-molecule inhibitors

Protein kinases are key components in cellular signaling pathways as they carry out the phosphorylation of proteins, primarily on Ser, Thr, and Tyr residues. The catalytic activity of protein kinases is regulated, and they can be thought of as molecular switches that are controlled through protein–protein interactions and post-translational modifications. Protein kinases exhibit diverse structural mechanisms of regulation and have been fascinating subjects for structural biologists from the first crystal structure of a protein kinase over 30 years ago, to recent insights into kinase assemblies enabled by the breakthroughs in cryo-EM. Protein kinases are high-priority targets for drug discovery in oncology and other disease settings, and kinase inhibitors have transformed the outcomes of specific groups of patients. Most kinase inhibitors are ATP competitive, deriving potency by occupying the deep hydrophobic pocket at the heart of the kinase domain. Selectivity of inhibitors depends on exploiting differences between the amino acids that line the ATP site and exploring the surrounding pockets that are present in inactive states of the kinase. More recently, allosteric pockets outside the ATP site are being targeted to achieve high selectivity and to overcome resistance to current therapeutics. Here, we review the key regulatory features of the protein kinase family, describe the different types of kinase inhibitors, and highlight examples where the understanding of kinase regulatory mechanisms has gone hand in hand with the development of inhibitors.     

Imprint of evolutionary conservation and protein structure variation on the binding function of protein tyrosine kinases

MOTIVATION: According to the models of divergent molecular evolution, the evolvability of new protein function may depend on the induction of new phenotypic traits by a small number of mutations of the binding site residues. Evolutionary relationships between protein kinases are often employed to infer inhibitor binding profiles from sequence analysis. However, protein kinases binding profiles may display inhibitor selectivity within a given kinase subfamily, while exhibiting cross-activity between kinases that are phylogenetically remote from the prime target. The emerging insights into kinase function and evolution combined with a rapidly growing number of publically available crystal structures of protein kinases complexes have motivated structural bioinformatics analysis of sequence-structure relationships in determining the binding function of protein tyrosine kinases. RESULTS: In silico profiling of Imatinib mesylate and PD-173955 kinase inhibitors with protein tyrosine kinases is conducted on kinome scale by using evolutionary analysis and fingerprinting inhibitor-protein interactions with the panel of all publically available protein tyrosine kinases crystal structures. We have found that sequence plasticity of the binding site residues alone may not be sufficient to enable protein tyrosine kinases to readily evolve novel binding activities with inhibitors. While evolutionary signal derived solely from the tyrosine kinase sequence conservation can not be readily translated into the ligand binding phenotype, the proposed structural bioinformatics analysis can discriminate a functionally relevant kinase binding signal from a simple phylogenetic relationship. The results of this work reveal that protein conformational diversity is intimately linked with sequence plasticity of the binding site residues in achieving functional adaptability of protein kinases towards specific drug binding. This study offers a plausible molecular rationale to the experimental binding profiles of the studied kinase inhibitors and provides a theoretical basis for constructing functionally relevant kinase binding trees.