The interaction between E-tropomodulin and thymosin beta-10 rescues tumor cells from thymosin beta-10 mediated apoptosis by restoring actin architecture

Thymosin beta-10 (TB10) is a small G-actin binding protein that induces depolymerization of intracellular F-actin pools by sequestering actin monomers. Previously, we demonstrated that overexpression of TB10 in ovarian tumor cells increased the rate of cell death. As an initial step to define molecular mechanism of TB10-dependent apoptotic process in ovarian tumor cells, we searched a human ovary cDNA library for a novel TB10 binding protein using a yeast two-hybrid system. The selected protein was human E-tropomodulin (E-Tmod), another component of the actin binding proteins. Subsequently, two interacting protein components were determined quantitatively. Results showed that the full-length TB10 is required to bind with E-Tmod, and the TB10 binding site on E-Tmod partially overlaps with the actin binding site on E-Tmod. Moreover, introduction of E-Tmod cDNA into a tumor cell line reversed TB10 mediated apoptosis and restored actin architectures. These results may suggest that TB10 regulates apoptotic homeostasis by not only just binding to actin but also competing or blocking the protein complex formation of E-Tmod with actin.     

Estimation of pH effect on the structure and stability of kinase domain of human integrin-linked kinase

Integrin-linked kinase (ILK) is an evolutionarily conserved Ser/Thr protein kinase, involved in many physiological functions such as signal transduction, actin rearrangement, cell proliferation, migration, polarisation, angiogenesis and apoptosis. An increased expression of ILK is associated with different cancers and thus considered as an attractive target for cancer therapy. We have successfully cloned, expressed and purified the kinase domain (193–446 residues) of ILK. To see the effect of pH on the structure and conformation, we performed circular diachroism, fluorescence and absorbance measurements in a wide range of pH conditions. We observed that within the range of pH 7.5–11.0, ILK_193–446 maintains its both secondary and tertiary structures. While visible aggregates were observed under the acidic pH 2.0–5.5 conditions, in order to complement these observations, we have performed molecular dynamics simulations of this kinase domain by mimicking diverse pH conditions which enabled us to see conformational preferences of the protein under such conditions. A significant correlation between the spectroscopic and molecular dynamics simulation was observed. These findings are useful to understand the conformation of ILK protein under certain pH condition which may be further implicated in the drug design and discovery.     

Secondary structures without backbone: an analysis of backbone mimicry by polar side chains in protein structures.

Backbone mimicry by the formation of closed-loop C7, C10 and C13 (mimics of gamma-, beta- and alpha-turns) conformations through side chain-main chain hydrogen bonds by polar groups is a frequent observation in protein structures. A data set of 250 non-homologous and high-resolution protein crystal structures was used to analyze these conformations for their characteristic features. Seven out of the nine polar residues (Ser, Thr, Asn, Asp, Gln, Glu and His) have hydrogen bonding groups in their side chains which can participate in such mimicry and as many as 15% of all these polar residues engage in such conformations. The distributions of dihedral angles of these mimics indicate that only certain combinations of the dihedral angles involved aid the formation of these mimics. The observed examples were categorized into various classes based on these combinations, resulting in well defined motifs. Asn and Asp residues show a very high capability to perform such backbone secondary structural mimicry. The most highly mimicked backbone structure is of the C10 conformation by the Asx residues. The mimics formed by His, Ser, Thr and Glx residues are also discussed. The role of such conformations in initiating the formation of regular secondary structures during the course of protein folding seems significant.     

NCX-4016, a nitro-derivative of aspirin,inhibits EGFR and STAT3 signaling and mdulates Bcl-2 proteins in cisplatin-resistant human ovarian cancer cells and xenografts

We have previously reported the inhibitory effect of NCX-4016, a nitro derivative of aspirin, on the proliferation of cisplatin-resistant human ovarian cancer cells, in vitro (Bratasz et al., Proc Natl Acad Sci USA 2006; 103:3914-9). In this report we present the results of our study on the mechanistic aspects of drug action including the molecular and signaling pathways involved in an in vitro cell line, as well as in a murine tumor xenograft. We report, for the first time, that NCX-4016 significantly inhibited the growth of cisplatin-resistant human ovarian cancer xenografts in mice. We observed that the inhibitory effect of NCX-4016 on cell proliferation was associated with G1 phase cell-cycle arrest with increased activity of p53, p21 and p27 proteins. NCX-4016 modulated the Bcl-2 family of proteins, and induced apoptosis by activating Bax and cytochrome c release in a time-dependent manner. In addition, NCX-4016 selectively down-regulated the phosphorylated forms of EGFR (Tyr845, Tyr992), pAkt (Ser473, Thr305), and STAT3 (Tyr705, Ser727), in vitro and in vivo. Taken together, the results clearly suggested that NCX-4016 causes significant induction of cell-cycle arrest and apoptosis in cisplatin-resistant human ovarian cancer cells via down-regulation of EGFR/PI3K/STAT3 signaling and modulation of Bcl-2 family proteins. Thus, NCX-4016 appears to be a potential therapeutic agent for treating recurrent human ovarian carcinoma.     

Theoretical studies of the ATP hydrolysis mechanism of myosin

The ATP hydrolysis mechanism of myosin was studied using quantum chemical (QM) and molecular dynamics calculations. The initial model compound for QM calculations was constructed on the basis of the energy-minimized structure of the myosin(S1dc)-ATP complex, which was determined by molecular mechanics calculations. The result of QM calculations suggested that the ATP hydrolysis mechanism of myosin consists of a single elementary reaction in which a water molecule nucleophilically attacked gamma-phosphorus of ATP. In addition, we performed molecular dynamics simulations of the initial and final states of the ATP hydrolysis reaction, that is, the myosin-ATP and myosin-ADP.Pi complexes. These calculations revealed roles of several amino acid residues (Lys185, Thr186, Ser237, Arg238, and Glu459) in the ATPase pocket. Lys185 maintains the conformation of beta- and gamma-phosphate groups of ATP by forming the hydrogen bonds. Thr186 and Ser237 are coordinated to a Mg(2+) ion, which interacts with the phosphates of ATP and therefore contributes to the stabilization of the ATP structure. Arg238 and Glu459, which consisted of the gate of the ATPase pocket, retain the water molecule acting on the hydrolysis at the appropriate position for initiating the hydrolysis.     

N-linked glycosylation of a beetle (Apriona germari) cellulase Ag-EGase II is necessary for enzymatic activity

We previously reported that the beta-1,4-endoglucanase (EGase) belonging to glycoside hydrolase family (GHF) 45 of the mulberry longicorn beetle, Apriona germari (Ag-EGase II), has three potential N-linked glycosylation sites; these sites are located at amino acid residues 56-59 (NKSG), 99-102 (NSTF), and 237-239 (NYSstop). In the present study, we analyze the functional role of these potential N-linked glycosylation sites. Tunicamycin treatment completely abolished the enzymatic activity of Ag-EGase II. To further elucidate the functional role of the N-linked glycosylation sites in Ag-EGase II, we have assayed the cellulase enzyme activity in Ser58Gln, Thr101Gln, or Ser239Gln mutants. Lack of N-linked glycosylation site at residues 99-102 (NSTF), the site of which is conserved in known beetle GHF 45 cellulases, showed loss of enzyme activity and reduced the molecular mass of the enzyme. In contrast, mutations in Ser58Gln or Ser239Gln affected neither the activity nor the apparent molecular mass of the enzyme, indicating that these sites did not lead to N-linked glycosylation. The present study demonstrates that N-linked glycosylation at residues 99-102 (NSTF), while not essential for secretion, is required for Ag-EGase II enzyme activity.     

Ser/Thr Motifs in Transmembrane Proteins: Conservation Patterns and Effects on Local Protein Structure and Dynamics

We combined systematic bioinformatics analyses and molecular dynamics simulations to assess the conservation patterns of Ser and Thr motifs in membrane proteins, and the effect of such motifs on the structure and dynamics of α-helical transmembrane (TM) segments. We find that Ser/Thr motifs are often present in β-barrel TM proteins. At least one Ser/Thr motif is present in almost half of the sequences of α-helical proteins analyzed here. The extensive bioinformatics analyses and inspection of protein structures led to the identification of molecular transporters with noticeable numbers of Ser/Thr motifs within the TM region. Given the energetic penalty for burying multiple Ser/Thr groups in the membrane hydrophobic core, the observation of transporters with multiple membrane-embedded Ser/Thr is intriguing and raises the question of how the presence of multiple Ser/Thr affects protein local structure and dynamics. Molecular dynamics simulations of four different Ser-containing model TM peptides indicate that backbone hydrogen bonding of membrane-buried Ser/Thr hydroxyl groups can significantly change the local structure and dynamics of the helix. Ser groups located close to the membrane interface can hydrogen bond to solvent water instead of protein backbone, leading to an enhanced local solvation of the peptide.     

Molecular dynamics simulations of the Bcl-2 protein to predict the structure of its unordered flexible loop domain

B-cell lymphoma (Bcl-2) protein is an anti-apoptotic member of the Bcl-2 family. It is functionally demarcated into four Bcl-2 homology (BH) domains: BH1, BH2, BH3, BH4, one flexible loop domain (FLD), a transmembrane domain (TM), and an X domain. Bcl-2’s BH domains have clearly been elucidated from a structural perspective, whereas the conformation of FLD has not yet been predicted, despite its important role in regulating apoptosis through its interactions with JNK-1, PKC, PP2A phosphatase, caspase 3, MAP kinase, ubiquitin, PS1, and FKBP38. Many important residues that regulate Bcl-2 anti-apoptotic activity are present in this domain, for example Asp34, Thr56, Thr69, Ser70, Thr74, and Ser87. The structural elucidation of the FLD would likely help in attempts to accurately predict the effect of mutating these residues on the overall structure of the protein and the interactions of other proteins in this domain. Therefore, we have generated an increased quality model of the Bcl-2 protein including the FLD through modeling. Further, molecular dynamics (MD) simulations were used for FLD optimization, to predict the flexibility, and to determine the stability of the folded FLD. In addition, essential dynamics (ED) was used to predict the collective motions and the essential subspace relevant to Bcl-2 protein function. The predicted average structure and ensemble of MD-simulated structures were submitted to the Protein Model Database (PMDB), and the Bcl-2 structures obtained exhibited enhanced quality. This study should help to elucidate the structural basis for Bcl-2 anti-apoptotic activity regulation through its binding to other proteins via the FLD.     

Structural constraints on protein self-processing in L-aspartate-alpha-decarboxylase

Aspartate decarboxylase, which is translated as a pro-protein, undergoes intramolecular self-cleavage at Gly24-Ser25. We have determined the crystal structures of an unprocessed native precursor, in addition to Ala24 insertion, Ala26 insertion and Gly24-->Ser, His11-->Ala, Ser25-->Ala, Ser25-->Cys and Ser25-->Thr mutants. Comparative analyses of the cleavage site reveal specific conformational constraints that govern self-processing and demonstrate that considerable rearrangement must occur. We suggest that Thr57 Ogamma and a water molecule form an 'oxyanion hole' that likely stabilizes the proposed oxyoxazolidine intermediate. Thr57 and this water molecule are probable catalytic residues able to support acid-base catalysis. The conformational freedom in the loop preceding the cleavage site appears to play a determining role in the reaction. The molecular mechanism of self-processing, presented here, emphasizes the importance of stabilization of the oxyoxazolidine intermediate. Comparison of the structural features shows significant similarity to those in other self-processing systems, and suggests that models of the cleavage site of such enzymes based on Ser-->Ala or Ser-->Thr mutants alone may lead to erroneous interpretations of the mechanism.     

Phospho-Bcl-xL(Ser62) plays a key role at DNA damage-induced G2 checkpoint

Accumulating evidence suggests that Bcl-xL, an anti-apoptotic member of the Bcl-2 family, also functions in cell cycle progression and cell cycle checkpoints. Analysis of a series of phosphorylation site mutants reveals that cells expressing Bcl-xL(Ser62Ala) mutant are less stable at the G₂ checkpoint and enter mitosis more rapidly than cells expressing wild-type Bcl-xL or Bcl-xL phosphorylation site mutants, including Thr41Ala, Ser43Ala, Thr47Ala, Ser56Ala and Thr115Ala. Analysis of the dynamic phosphorylation and location of phospho-Bcl-xL(Ser62) in unperturbed, synchronized cells and during DNA damage-induced G₂ arrest discloses that a pool of phospho-Bcl-xL(Ser62) accumulates into nucleolar structures in etoposide-exposed cells during G₂ arrest. In a series of in vitro kinase assays, pharmacological inhibitors and specific siRNAs experiments, we found that Polo kinase 1 and MAPK9/JNK2 are major protein kinases involved in Bcl-xL(Ser62) phosphorylation and accumulation into nucleolar structures during the G₂ checkpoint. In nucleoli, phospho-Bcl-xL(Ser62) binds to and co-localizes with Cdk1(cdc2), the key cyclin-dependent kinase required for entry into mitosis. These data indicate that during G₂ checkpoint, phospho-Bcl-xL(Ser62) stabilizes G₂ arrest by timely trapping of Cdk1(cdc2) in nucleolar structures to slow mitotic entry. It also highlights that DNA damage affects the dynamic composition of the nucleolus, which now emerges as a piece of the DNA damage response.     

Phospho-Bcl-xL(Ser62) plays a key role at DNA damage-induced G2 checkpoint

Accumulating evidence suggests that Bcl-xL, an anti-apoptotic member of the Bcl-2 family, also functions in cell cycle progression and cell cycle checkpoints. Analysis of a series of phosphorylation site mutants reveals that cells expressing Bcl-xL(Ser62Ala) mutant are less stable at the G₂ checkpoint and enter mitosis more rapidly than cells expressing wild-type Bcl-xL or Bcl-xL phosphorylation site mutants, including Thr41Ala, Ser43Ala, Thr47Ala, Ser56Ala and Thr115Ala. Analysis of the dynamic phosphorylation and location of phospho-Bcl-xL(Ser62) in unperturbed, synchronized cells and during DNA damage-induced G₂ arrest discloses that a pool of phospho-Bcl-xL(Ser62) accumulates into nucleolar structures in etoposide-exposed cells during G₂ arrest. In a series of in vitro kinase assays, pharmacological inhibitors and specific siRNAs experiments, we found that Polo kinase 1 and MAPK9/JNK2 are major protein kinases involved in Bcl-xL(Ser62) phosphorylation and accumulation into nucleolar structures during the G₂ checkpoint. In nucleoli, phospho-Bcl-xL(Ser62) binds to and co-localizes with Cdk1(cdc2), the key cyclin-dependent kinase required for entry into mitosis. These data indicate that during G₂ checkpoint, phospho-Bcl-xL(Ser62) stabilizes G₂ arrest by timely trapping of Cdk1(cdc2) in nucleolar structures to slow mitotic entry. It also highlights that DNA damage affects the dynamic composition of the nucleolus, which now emerges as a piece of the DNA damage response.     

Influence of the g− conformation of Ser and Thr on the structure of transmembrane helices

In order to study the influence of Ser and Thr on the structure of transmembrane helices we have analyzed a database of helix stretches extracted from crystal structures of membrane proteins and an ensemble of model helices generated by molecular dynamics simulations. Both complementary analyses show that Ser and Thr in the g? conformation induce and/or stabilize a structural distortion in the helix backbone. Using quantum mechanical calculations, we have attributed this effect to the electrostatic repulsion between the side chain Oγ atom of Ser and Thr and the backbone carbonyl oxygen at position i ? 3. In order to minimize the repulsive force between these negatively charged oxygens, there is a modest increase of the helix bend angle as well as a local opening of the helix turn preceding Ser/Thr. This small distortion can be amplified through the helix, resulting in a significant displacement of the residues located at the other side of the helix. The crystal structures of aquaporin Z and the β₂-adrenergic receptor are used to illustrate these effects. Ser/Thr-induced structural distortions can be implicated in processes as diverse as ligand recognition, protein function and protein folding.     

Mutational analysis of the three conserved valine residues of insulin and a proposal of "isosteric residue"

To further understand the role of the three conserved Val residues in insulin, B12Val, B18Val, and A3Val, five insulin mutants-[A3Ser]insulin, [B12Thr]insulin, (desB30)[B12Ser]insulin, [B18Thr] insulin, and [B18Leu]insulin--were obtained by means of site-directed mutagenesis and their receptor-binding activities as well as in vivo biological potencies were measured. The two B18 mutants, [B18Thr]insulin and [B18Leu]insulin, both retained relatively high receptor-binding activities (70% and 30% of native porcine insulin, respectively) as well as relatively high in vivo biological potencies. The receptor-binding activities of [B12Thr]insulin and (desB30)[B12Ser]insulin were 5.1% and 0.2%, respectively. However the in vivo biological potency of [B12Thr]insulin was still about 50% of native insulin, whereas that of (desB30)[B12Ser]insulin decreased drastically. The [A3Ser]insulin retained 1.4% of the receptor-binding activity and low in vivo biological potency. These results, together with previous reports showed that when the three conserved Val residues were replaced by residues containing a beta-branched side-chain, such as Thr or Ile, the insulin mutants retained higher biological activities than those mutants replaced by other residues. Here we propose that Val, Thr, and Ile are "isosteric residues' because they all contain a beta-branched side-chain. This proposal may have perhaps general significance in protein design and protein engineering.     

Importance of each residue within secretin for receptor binding and biological activity

Secretin is a linear 27-residue peptide hormone that stimulates pancreatic and biliary ductular bicarbonate and water secretion by acting at its family B G protein-coupled receptor. While, like other family members, the carboxyl-terminal region of secretin is most important for high affinity binding and its amino-terminal region is most important for receptor selectivity and receptor activation, determinants for these activities are distributed throughout the entire length of this peptide. In this work, we have systematically investigated changing each residue within secretin to alanine and evaluating the impact on receptor binding and biological activity. The residues most critical for receptor binding were His1, Asp3, Gly4, Phe6, Thr7, Ser8, Leu10, Asp15, Leu19, and Leu23. The residues most critical for biological activity included His1, Gly4, Thr7, Ser8, Glu9, Leu10, Leu19, Leu22, and Leu23, with Asp3, Phe6, Ser11, Leu13, Asp15, Leu26, and Val27 also contributing. While the importance of residues in positions analogous to His1, Asp3, Phe6, Thr7, and Leu23 is conserved for several closely related members of this family, Leu19 is uniquely important for secretin. We, therefore, have further studied this residue by molecular modeling and molecular dynamics simulations. Indeed, the molecular dynamics simulations showed that mutation of Leu19 to alanine was destabilizing, with this effect greater than that observed for the analogous position in the other close family members. This could reflect reduced contact with the receptor or an increase in the solvent-accessible surface area of the hydrophobic residues in the carboxyl terminus of secretin as bound to its receptor.     

Ser95, Asn97, and Thr78 are important for the catalytic function of porcine NADP-dependent isocitrate dehydrogenase

The mammalian mitochondrial NADP-dependent isocitrate dehydrogenase is a citric acid cycle enzyme and an important contributor to cellular defense against oxidative stress. The Mn(2+)-isocitrate complex of the porcine enzyme was recently crystallized; its structure indicates that Ser(95), Asn(97), and Thr(78) are within hydrogen-bonding distance of the gamma-carboxylate of enzyme-bound isocitrate. We used site-directed mutagenesis to replace each of these residues by Ala and Asp. The wild-type and mutant enzymes were expressed in Escherichia coli and purified to homogeneity. All the enzymes retain their native dimeric structures and secondary structures as monitored by native gel electrophoresis and circular dichroism, respectively. V(max) of the three alanine mutants is decreased to 24%-38% that of wild-type enzyme, with further decreases in the aspartate mutants. For T78A and S95A mutants, the major changes are the 10- to 100-fold increase in the K(m) values for isocitrate and Mn(2+). The results suggest that Thr(78) and Ser(95) function to strengthen the enzyme's affinity for Mn(2+)-isocitrate by hydrogen bonding to the gamma-carboxylate of isocitrate. For the Asn(97) mutants, the K(m) values are much less affected. The major change in the N97A mutant is the increase in pK(a) of the ionizable metal-liganded hydroxyl of enzyme-bound isocitrate from 5.23 in wild type to 6.23 in the mutant enzyme. The hydrogen bond between Asn(97) and the gamma-carboxylate of isocitrate may position the substrate to promote a favorable lowering of the pK of the enzyme-isocitrate complex. Thus, Thr(78), Ser(95), and Asn(97) perform important but distinguishable roles in catalysis by porcine NADP-specific isocitrate dehydrogenase.     

ATM mediates phosphorylation at multiple p53 sites, including Ser(46), in response to ionizing radiation

The p53 tumor suppressor protein preserves genome integrity by regulating growth arrest and apoptosis in response to DNA damage. In response to ionizing radiation (IR), ATM, the gene product mutated in ataxia telangiectasia, stabilizes and activates p53 through phosphorylation of Ser(15) and (indirectly) Ser(20). Here we show that phosphorylation of p53 on Ser(46), a residue important for p53 apoptotic activity, as well as on Ser(9), in response to IR also is dependent on the ATM protein kinase. IR-induced phosphorylation at Ser(46) was inhibited by wortmannin, a phosphatidylinositol 3-kinase inhibitor, but not PD169316, a p38 MAPK inhibitor. p53 C-terminal acetylation at Lys(320) and Lys(382), which may stabilize p53 and activate sequence-specific DNA binding, required Ser(15) phosphorylation by ATM and was enhanced by phosphorylation at nearby residues including Ser(6), Ser(9), and Thr(18). These observations, together with the proposed role of Ser(46) phosphorylation in mediating apoptosis, suggest that ATM is involved in the initiation of p53-dependent apoptosis after IR in human lymphoblastoid cells.     

Creation of Rhizopus oryzae lipase having a unique oxyanion hole by combinatorial mutagenesis in the lid domain

Combinatorial libraries of the lid domain of Rhizopus oryzae lipase (ROL; Phe88Xaa, Ala91Xaa, Ile92Xaa) were displayed on the yeast cell surface using yeast cell-surface engineering. Among the 40,000 transformants in which ROL mutants were displayed on the yeast cell surface, ten clones showed clear halos on soybean oil-containing plates. Among these, some clones exhibited high activities toward fatty acid esters of fluorescein and contained non-polar amino acid residues in the mutated positions. Computer modeling of the mutants revealed that hydrophobic interactions between the substrates and amino acid residues in the open form of the lid might be critical for ROL activity. Based on these results, Thr93 and Asp94 were further combinatorially mutated. Among 6,000 transformants, the Thr93Thr, Asp94Ser and Thr93Ser, Asp94Ser transformants exhibited a significant shift in substrate specificity toward a short-chain substrate. Computer modeling of these mutants suggested that a unique oxyanion hole, which is composed of Thr85 Oγ and Ser94 Oγ, was formed and thus the substrate specificity was changed. Therefore, coupling combinatorial mutagenesis with the cell surface display of ROL could lead to the production of a unique ROL mutant.     

Diphosphorylated MRLC is required for organization of stress fibers in interphase cells and the contractile ring in dividing cells

Activity of nonmuscle myosin II is regulated by phosphorylation of its regulatory light chain (MRLC). Phosphoryration of MRLC at both Thr18 and Ser19 (diphosphorylation) results in higher MgATPase activity and in promotion of the assembly of myosin II filaments than does that of MRLC at Ser19 (monophosphorylation) in vitro. To determine the roles of the diphosphorylated MRLC in vivo, we transfected three kinds of MRLC mutants, unphosphorylated, monophosphorylated and diphosphorylated forms (MRLC2(T18AS19A), substitution of both Ser19 and Thr18 by Ala; MRLC2(T18AS19D), Ser19 by Asp and Thr18 by Ala; and MRLC2(T18DS19D), both Ser19 and Thr18 by Asp, respectively), into HeLa cells. Cells overexpressing the mutant MRLC2(T18DS19D) contained a larger number of actin filament bundles than did those overexpressing the mutant MRLC2(T18AS19D). Moreover, cells overexpressing the nonphosphorylatable mutant MRLC2(T18AS19A) showed a decrease in the number of actin filament bundles. Taken together, our data suggest that diphosphorylation of MRLC plays an important role in regulating actin filament assembly and reorganization in nonmuscle cells.     

Identification and characterization of the ATP-binding site in human pancreatic glucokinase

The central role of human pancreatic glucokinase in insulin secretion and, consequently, in maintenance of blood glucose levels has prompted investigation into identification of ATP-binding site residues and examination of ATP- and glucose-binding interactions. Because glucokinase has been resistant to crystallization, computer generated homology models were developed based on the X-ray crystal structure of the COOH-terminal domain of human brain hexokinase 1 bound to glucose and ADP or glucose and glucose-6-phosphate. Human pancreatic glucokinase mutants were designed based upon these models and on ATPase domain sequence conservation to identify and characterize potential glucose and ATP-binding sites. Specifically, mutants Asp78Ala, Thr82Ala, Lys90Ala, Lys102Ala, Gly227Ala, Thr228Ala, Ser336Leu, Ser411Ala, and Ser411Leu were constructed, expressed, purified, and kinetically characterized under steady-state conditions. Compared to their respective wild type controls, several mutants demonstrated dramatic changes in V(max), cooperativity of glucose binding and S(0.5) for ATP and glucose. Results suggest a role for Asp78, Thr82, Gly227, Thr228, and Ser336 in ATP binding and indicate these residues are essential for glucose phosphorylation by human pancreatic glucokinase.