Exploring the effect of D61G mutation on SHP2 cause gain of function activity by a molecular dynamics study

Noonan syndrome (NS) is a common autosomal dominant congenital disorder which could cause the congenital cardiopathy and cancer predisposition. Previous studies reported that the knock-in mouse models of the mutant D61G of SHP2 exhibited the major features of NS, which demonstrated that the mutation D61G of SHP2 could cause NS. To explore the effect of D61G mutation on SHP2 and explain the high activity of the mutant, molecular dynamic simulations were performed on wild type (WT) of SHP2 and the mutated SHP2-D61G, respectively. The principal component analysis and dynamic cross-correlation mapping, associated with secondary structure, showed that the D61G mutation affected the motions of two regions (residues Asn 58-Thr 59 and Val 460-His 462) in SHP2 from β to turn. Moreover, the residue interaction networks analysis, the hydrogen bond occupancy analysis and the binding free energies were calculated to gain detailed insight into the influence of the mutant D61G on the two regions, revealing that the major differences between SHP2-WT and SHP2-D61G were the different interactions between Gly 61 and Gly 462, Gly 61 and Ala 461, Gln 506 and Ile 463, Gly 61 and Asn 58, Ile 463 and Thr 466, Gly 462 and Cys 459. Consequently, our findings here may provide knowledge to understand the increased activity of SHP2 caused by the mutant D61G.     

Inter-domain interactions influence the stability and catalytic activity of the bi-domain protein tyrosine phosphatase PTP99A

The two protein tyrosine phosphatase (PTP) domains in bi-domain PTPs share high sequence and structural similarity. However, only one of the two PTP domains is catalytically active. Here we describe biochemical studies on the two tandem PTP domains of the bi-domain PTP, PTP99A. Phosphatase activity, monitored using small molecule as well as peptide substrates, revealed that the inactive (D2) domain activates the catalytic (D1) domain. Thermodynamic measurements suggest that the inactive D2 domain stabilizes the bi-domain (D1-D2) protein. The mechanism by which the D2 domain activates and stabilizes the bi-domain protein is governed by few interactions at the inter-domain interface. In particular, mutating Lys990 at the interface attenuates inter-domain communication. This residue is located at a structurally equivalent location to the so-called allosteric site of the canonical single domain PTP, PTP1B. These observations suggest functional optimization in bi-domain PTPs whereby the inactive PTP domain modulates the catalytic activity of the bi-domain enzyme.     

Structural mechanism associated with domain opening in gain-of-function mutations in SHP2 phosphatase

The SHP2 phosphatase plays a central role in a number of signaling pathways were it dephosphorylates various substrate proteins. Regulation of SHP2 activity is, in part, achieved by an intramolecular interaction between the PTP domain of the protein, which contains the catalytic site, and the N-SH2 domain leading to a "closed" protein conformation and autoinhibition. Accordingly, "opening" of the N-SH2 and PTP domains is required for the protein to become active. Binding of phosphopeptides to the N-SH2 domain is known to induce the opening event, while a number of gain-of-function (GOF) mutants, implicated in Noonan's Syndrome and childhood leukemias, are thought to facilitate opening. In the present study, a combination of computational and experimental methods are used to investigate the structural mechanism of opening of SHP2 and the impact of three GOF mutants, D61G, E76K, and N308D, on the opening mechanism. Calculated free energies of opening indicate that opening must be facilitated by effector molecules, possibly the protein substrates themselves, as the calculated free energies preclude spontaneous opening. Simulations of both wild type (WT) SHP2 and GOF mutants in the closed state indicate GOF activity to involve increased solvent exposure of selected residues, most notably Arg362, which in turn may enhance interactions of SHP2 with its substrate proteins and thereby aid opening. In addition, GOF mutations cause structural changes in the phosphopeptide-binding region of the N-SH2 domain leading to conformations that mimic the bound state. Such conformational changes are suggested to enhance binding of phosphopeptides and/or decrease interactions between the PTP and N-SH2 domains thereby facilitating opening. Experimental assays of the impact of effector molecules on SHP2 phosphatase activity against both small molecule and peptide substrates support the hypothesized mechanism of GOF mutant action. The present calculations also suggest a role for the C-SH2 domain of SHP2 in stabilizing the overall conformation of the protein in the open state, thereby aiding conformational switching between the open active and closed inactive states.     

Role of P225 and the C136-C201 disulfide bond in tissue plasminogen activator

The protease domain of tissue plasminogen activator (tPA), a key fibrinolytic enzyme, was expressed in Escherichia coli with a yield of 1 mg per liter of media. The recombinant protein was titrated with the Erythrina caraffa trypsin inhibitor (ETI) and characterized in its interaction with plasminogen and the natural inhibitor plasminogen activator inhibitor-1 (PAI-1). Analysis of the catalytic properties of tPA using a library of chromogenic substrates carrying substitutions at P1, P2, and P3 reveals a strong preference for Arg over Lys at P1, unmatched by other serine proteases like thrombin or trypsin. In contrast to these proteases and plasmin, tPA shows little or no preference for Pro over Gly at P2. A specific inhibition of tPA by Cu2+ was discovered. The divalent cation presumably binds to H188 near D189 in the primary specificity pocket and inhibits substrate binding in a competitive manner with a Kd = 19 microM. In an attempt to engineer Na+ binding and enhanced catalytic activity in tPA, P225 was replaced with Tyr, the residue present in Na+-dependent allosteric serine proteases. The P225Y mutation did not result in cation binding, but caused a significant loss of specificity (up to 100-fold) toward chromogenic substrates and plasminogen and considerably reduced the inhibition by PAI-1 and ETI. Interestingly, the P225Y substitution enhanced the ability of Cu2+ to inhibit the enzyme. Elimination of the C136-C201 disulfide bond, that is absent in all Na+-dependent allosteric serine proteases, significantly enhanced the yield (5 mg per liter of media) of expression in E. coli, but caused no changes in the properties of the enzyme whether residue 225 was Pro or Tyr. These findings point out an unanticipated crucial role for residue 225 in controlling the catalytic activity of tPA, and suggest that engineering of a Na+-dependent allosteric enhancement of catalytic activity in this enzyme, must involve substantial changes in the region homologous to the Na+ binding site of allosteric serine proteases.     

Asparagine-84, a regulatory allosteric site residue,helps maintain the quaternary structure of Campylobacter jejuni dihydrodipicolinate synthase

Dihydrodipicolinate synthase (DHDPS) from Campylobacter jejuni is a natively homotetrameric enzyme that catalyzes the first unique reaction of (S)-lysine biosynthesis and is feedback-regulated by lysine through binding to an allosteric site. High-resolution structures of the DHDPS-lysine complex have revealed significant insights into the binding events. One key asparagine residue, N84, makes hydrogen bonds with both the carboxyl and the α-amino group of the bound lysine. We generated two mutants, N84A and N84D, to study the effects of these changes on the allosteric site properties. However, under normal assay conditions, N84A displayed notably lower catalytic activity, and N84D showed no activity. Here we show that these mutations disrupt the quaternary structure of DHDPS in a concentration-dependent fashion, as demonstrated by size-exclusion chromatography, multi-angle light scattering, dynamic light scattering, small-angle X-ray scattering (SAXS) and high-resolution protein crystallography.     

Alleviation of intrasteric inhibition by the pathogenic activation domain mutation,D444N,in human cystathionine beta-synthase

Human cystathionine beta-synthase is a heme protein that catalyzes the condensation of serine and homocysteine to form cystathionine in a pyridoxal phosphate-dependent reaction. Mutations in this enzyme are the leading cause of hereditary hyperhomocysteinemia with attendant cardiovascular and other complications. The enzyme is activated approximately 2-fold by the allosteric regulator S-adenosylmethionine (AdoMet), which is presumed to bind to the C-terminal regulatory domain. The regulatory domain exerts an inhibitory effect on the enzyme, and its deletion is correlated with a 2-fold increase in catalytic activity and loss of responsiveness to AdoMet. A mutation in the C-terminal regulatory domain, D444N, displays high levels of enzyme activity, yet is pathogenic. In this study, we have characterized the biochemical penalties associated with this mutation and demonstrate that it is associated with a 4-fold lower steady-state level of cystathionine beta-synthase in a fibroblast cell line that is homozygous for the D444N mutation. The activity of the recombinant D444N enzyme mimics the activity of the wild-type enzyme seen in the presence of AdoMet and can be further activated approximately 2-fold in the presence of supraphysiolgical concentrations of the allosteric regulator. The mutation increases the K(act) for AdoMet from 7.4 +/- 0.2 to 460 +/- 130 microM, thus rendering the enzyme functionally unresponsive to AdoMet under physiological concentrations. These results indicate that the D444N mutation partially abrogates the intrasteric inhibition imposed by the C-terminal domain. We propose a model that takes into account the three kinetically distinguishable states that are observed with human cystathionine beta-synthase: "basal" (i.e., wild-type enzyme as isolated), "activated" (wild-type enzyme + AdoMet or the D444N mutant as isolated), and superactivated (D444N mutant + AdoMet or wild-type enzyme lacking the C-terminal regulatory domain).     

Regulation of the catalytic function of coagulation factor VIIa by a conformational linkage of surface residue Glu 154 to the active site

Coagulation factor VIIa is an allosterically regulated trypsin-like serine protease that initiates the coagulation pathways upon complex formation with its cellular receptor and cofactor tissue factor (TF). The analysis of a conformation-sensitive monoclonal antibody directed to the macromolecular substrate exosite in the VIIa protease domain demonstrated a conformational link from this exosite to the catalytic cleft that is independent of cofactor-induced allosteric changes. In this study, we identify Glu 154 as a critical surface-exposed exosite residue side chain that undergoes conformational changes upon active site inhibitor binding. The Glu 154 side chain is important for hydrolysis of scissile bond mimicking peptidyl p-nitroanilide substrates, and for inhibition of VIIa's amidolytic function upon antibody binding. This exosite residue is not linked to the catalytic cleft residue Lys 192 which plays an important role in thrombin's allosteric coupling to exosite I. Allosteric linkages between VIIa's active site and the cofactor binding site or between the cofactor binding site and the macromolecular substrate exosite were not influenced by mutation of Glu 154. Glu 154 thus only influences the linkage of the macromolecular substrate binding exosite to the catalytic center. These data provide novel evidence that allosteric regulation of VIIa's catalytic function involves discrete and independent conformational linkages and that allosteric transitions in the VIIa protease domain are not globally coupled.     

Functional organization and evolution of mammalian hexokinases: mutations that caused the loss of catalytic activity in N-terminal halves of type I and type III isozymes.

Mammalian hexokinases are believed to have evolved from a 100-kDa hexokinase which itself is a product of duplication and fusion of an ancestral gene encoding a 50-kDa glucose 6-phosphate-sensitive hexokinase. Type II hexokinase has been shown to possess two distinct functional active sites, one in each half, which functionally resemble the original 100-kDa hexokinase, whereas type I and III isozymes possess only one active site in the C-terminal halves. This study was conducted to identify which mutations caused the loss of catalytic activity in the N-terminal halves of type I and III isozymes. Arg 174 and Ser 447 in type I isozyme and Asp 244 in type III isozyme are speculated to be the cause, because they reside adjacent to the "catalytic" site and corresponding residues, Gly 174, Asp 447, and Gly 231, are conserved in the N-terminal half of type II isozyme as well as all other 50-kDa units that possess catalytic activity. Mutations G174R and D447S in the N-terminal half of type II isozyme reduced specific activity by approximately 79 and 57%, respectively. Therefore, neither mutation alone can account for the inactivation of the N-terminal active site in type I isozyme. Either mutation, G174R or D447S, had moderate effects on Michaelis constants, K(m), for glucose and ATP. Mg(2+). Intriguingly, mutation D447S introduced a novel inhibition by unchelated ATP (K(i) = 68 microM ATP, competitive vs ATP. Mg(2+)) to the N-terminal active site of type II isozyme. Mutation G231D caused instability to type II hexokinase and near complete loss of catalytic activity (95%), suggesting that mutation G231D not only hinders catalysis at the N-terminal active site but also leads to structural instability in type II hexokinase.     

Modulation of SHP‐1 phosphatase activity by monovalent and bivalent SH2 phosphopeptide ligands

A sequence derived from the epithelial receptor tyrosine kinase Ros (pY2267) represents a high‐affinity binding partner for protein tyrosine phosphatase SHP‐1 and was recently used as lead structure to analyze the recognition requirements for the enzyme's N‐SH2 domain. Here, we focused on a set of peptides comprising C‐terminally extended linear and conformationally constrained side chain‐bridged cyclic N‐SH2 ligands based on the consensus sequence LxpYhxh(h/b)(h/b) (x = any amino acid, h = hydrophobic, and b = basic residue). Furthermore, the bivalent peptides described were designed to modulate the activity of SHP‐1 through binding to both, the N‐SH2 domain as well as an independent binding site on the surface of the catalytic domain (PTP domain). Consistent with previous experimental findings, surface plasmon resonance experiments revealed dissociation constants of most compounds in the low micromolar range. One peptide, EGLNpYc[KVD]MFPAPEEE? NH₂, displayed favorable binding affinity, but reduced ability to stimulate SHP‐1. Docking experiments revealed that the binding of this ligand occurs in binding mode I, recently described to lead to an inhibited activation of SHP‐1. In summary, results presented in this study suggest that inhibitory N‐SH2 ligands of SHP‐1 may be obtained by designing bivalent compounds that associate with the N‐SH2 domain and simultaneously occupy a specific binding site on the PTP domain. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 102–112, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Backbone and side chain dynamics of mutant calmodulin-peptide complexes

The mechanism of long-range coupling of allosteric sites in calcium-saturated calmodulin (CaM) has been explored by characterizing structural and dynamics effects of mutants of calmodulin in complex with a peptide corresponding to the smooth muscle myosin light chain kinase calmodulin-binding domain (smMLCKp). Four CaM mutants were examined: D95N and D58N, located in Ca2+-binding loops; and M124L and E84K, located in the target domain-binding site of CaM. Three of these mutants have altered allosteric coupling either between Ca2+-binding sites (D58N and D95N) or between the target- and Ca2+-binding sites (E84K). The structure and dynamics of the mutant calmodulins in complex with smMLCKp were characterized using solution NMR. Analysis of chemical shift perturbations was employed to detect largely structural perturbations. 15N and 2H relaxation was employed to detect perturbations of the dynamics of the backbone and methyl-bearing side chains of calmodulin. The least median squares method was found to be robust in the detection of perturbed sites. The main chain dynamics of calmodulin are found to be largely unresponsive to the mutations. Three mutants show significantly perturbed dynamics of methyl-bearing side chains. Despite the pseudosymmetric location of Ca2+-binding loop mutations D58N and D95N, the dynamic response of CaM is asymmetric, producing long-range perturbation in D58N and almost none in D95N. The mutations located at the target domain-binding site have quite different effects. For M124L, a local perturbation of the methyl dynamics is observed, while the E84K mutation produces a long-range propagation of dynamic perturbations along the target domain-binding site.     

240s loop interactions stabilize the T state of Escherichia coli aspartate transcarbamoylase

Here the functional and structural importance of interactions involving the 240s loop of the catalytic chain for the stabilization of the T state of aspartate transcarbamoylase were tested by replacement of Lys-244 with Asn and Ala. For the K244A and K244N mutant enzymes, the aspartate concentration required to achieve half-maximal specific activity was reduced to 8.4 and 4.0 mm, respectively, as compared with 12.4 mM for the wild-type enzyme. Both mutant enzymes exhibited dramatic reductions in homotropic cooperativity and the ability of the heterotropic effectors to modulate activity. Small angle x-ray scattering studies showed that the unligated structure of the mutant enzymes, and the structure of the mutant enzymes ligated with N-phosphonacetyl-L-aspartate, were similar to that observed for the unligated and N-phosphonacetyl-L-aspartateligated wild-type enzyme. A saturating concentration of carbamoyl phosphate alone has little influence on the small angle x-ray scattering of the wild-type enzyme. However, carbamoyl phosphate was able to shift the structure of the two mutant enzymes dramatically toward R, establishing that the mutations had destabilized the T state of the enzyme. The x-ray crystal structure of K244N enzyme showed that numerous local T state stabilizing interactions involving 240s loop residues were lost. Furthermore, the structure established that the mutation induced additional alterations at the subunit interfaces, the active site, the relative position of the domains of the catalytic chains, and the allosteric domain of the regulatory chains. Most of these changes reflect motions toward the R state structure. However, the K244N mutation alone only changes local conformations of the enzyme to an R-like structure, without triggering the quaternary structural transition. These results suggest that loss of cooperativity and reduction in heterotropic effects is due to the dramatic destabilization of the T state of the enzyme by this mutation in the 240s loop of the catalytic chain.     

Homology modelling and site-directed mutagenesis studies of the epoxide hydrolase from Phanerochaete chrysosporium

Three-dimensional structural model of epoxide hydrolase (PchEHA) from Phanerochaete chrysosporium was constructed based on X-ray structure of Agrobacterium radiobacter AD1 sEH using SWISS-MODEL server. Conserved residues constituting the active site cavity were identified, of which the functional roles of 14 residues were determined by site-directed mutagenesis. In catalytic triad, Asp105 and His308 play a leading role in alkylation and hydrolysis steps, respectively. Distance between Asp105 and epoxide ring of substrate may determine the regiospecificity in the substrate docking model. Asp277 located at the entrance of substrate tunnel is concerned with catalysis but not essential. D307E had the highest activity and lower enantioselectivity among 14 mutants, suggesting Asp307 may be involved in choice of substrate configuration. Y159F and Y241F almost exhibited no activity, indicating that they are essential to bind substrate and facilitate opening of epoxide ring. Besides, His35-Gly36-Asn37-Pro38, Trp106 and Trp309 surrounding Asp105, may coordinate the integration of active site cavity and influence substrate binding. Especially, W106I reversed the enantioselectivity, perhaps due to more deteriorative impact on the preferred (R)-styrene oxide. Gly65 and Gly67 occurring at β-turns and Gly36 are vital in holding protein conformation. Conclusively, single conserved residue around the active sites has an important impact on catalytic properties.     

Location of glycine mutations within a bacterial collagen protein affects degree of disruption of triple-helix folding and conformation

The hereditary bone disorder osteogenesis imperfecta is often caused by missense mutations in type I collagen that change one Gly residue to a larger residue and that break the typical (Gly-Xaa-Yaa)(n) sequence pattern. Site-directed mutagenesis in a recombinant bacterial collagen system was used to explore the effects of the Gly mutation position and of the identity of the residue replacing Gly in a homogeneous collagen molecular population. Homotrimeric bacterial collagen proteins with a Gly-to-Arg or Gly-to-Ser replacement formed stable triple-helix molecules with a reproducible 2 °C decrease in stability. All Gly replacements led to a significant delay in triple-helix folding, but a more dramatic delay was observed when the mutation was located near the N terminus of the triple-helix domain. This highly disruptive mutation, close to the globular N-terminal trimerization domain where folding is initiated, is likely to interfere with triple-helix nucleation. A positional effect of mutations was also suggested by trypsin sensitivity for a Gly-to-Arg replacement close to the triple-helix N terminus but not for the same replacement near the center of the molecule. The significant impact of the location of a mutation on triple-helix folding and conformation could relate to the severe consequences of mutations located near the C terminus of type I and type III collagens, where trimerization occurs and triple-helix folding is initiated.     

Cross-talk between the allosteric effector-binding sites in mouse ribonucleotide reductase

We compared the allosteric regulation and effector binding properties of wild type R1 protein and R1 protein with a mutation in the "activity site" (D57N) of mouse ribonucleotide reductase. Wild type R1 had two effector-binding sites per polypeptide chain: one site (activity site) for dATP and ATP, with dATP-inhibiting and ATP-stimulating catalytic activity; and a second site (specificity site) for dATP, ATP, dTTP, and dGTP, directing substrate specificity. Binding of dATP to the specificity site had a 20-fold higher affinity than to the activity site. In all these respects, mouse R1 resembles Escherichia coli R1. Results with D57N were complicated by the instability of the protein, but two major changes were apparent. First, enzyme activity was stimulated by both dATP and ATP, suggesting that D57N no longer distinguished between the two nucleotides. Second, the two binding sites for dATP both had the same low affinity for the nucleotide, similar to that of the activity site of wild type R1. Thus the mutation in the activity site had decreased the affinity for dATP at the specificity site, demonstrating the interaction between the two sites.     

Investigating the reason for loss-of-function of Src homology 2 domain-containing protein tyrosine phosphatase 2 (SHP2) caused by Y279C mutation through molecular dynamics simulation

Abstract

Noonan syndrome with multiple lentigines (NSML), formerly known as LEOPARD syndrome (LS), is an autosomal dominant inherited multisystemic disorder. Most patients involve mutation in SHP2 encoded by tyrosine-protein phosphatase non-receptor type 11 (PTPN11) gene. Studies have shown that NSML-associated Y279C mutation exhibited the reduced phosphatase activity, leading to loss-of-function (LOF) of SHP2. However, the effect of the Y279C mutation on the SHP2 at the molecular level is unclear. In this study, molecular dynamics simulations of SHP2 wild-type (SHP2^WT) and Y279C mutant (SHP2^Y279C) were performed to investigate the structural differences in proteins after Y279C mutation and to find out the reason for loss-of-function of SHP2. Through a series of post-dynamic analyses, it was found that the protein occupied a smaller phase space after Y279C mutation, showing reduced flexibility. Specifically, due to the mutation of Y279C, the secondary structures of these two regions (residues Lys70-Ala72 and Gly462-Arg465) were significantly transformed from Turn to α-helix and β-strand. Furthermore, by calculating the residue interaction network, hydrogen bond occupancy and binding free energy, it was further revealed that the conformational differences between SHP2^WT and SHP2^Y279C systems were mainly caused by the differences in the interaction between Arg465–Phe469, Ile463–Gly467, Cys279–Lys70, Cys459–Ala72, Gly464–Phe71, Phe71–Ile463, Ile463–Ala505 and Arg465–Glu361. Consequently, this finding is expected to provide a new insight into the reason for loss-of-function of SHP2 caused by Y279C mutation.

Communicated by Ramaswamy H. Sarma     

Mutations in Ser174 and the glycine-rich sequence (Gly149, Gly150, and Thr156) in the beta subunit of Escherichia coli H(+)-ATPase.

A sequence motif in the beta subunit of Escherichia coli F1 (Gly-Gly-Ala-Gly-Val-Gly-Lys-Thr, residue 149-156, where conserved residues are underlined) is one of the glycine-rich sequences found in many nucleotide binding proteins. In this study, we constructed a plasmid carrying all the F0F1 genes. This plasmid gave the highest membrane ATPase activity so far reported. Substitution of beta Gly149 by Ser suppressed the effect of the beta Ser174----Phe mutation (defective H(+)-ATPase), but beta Gly150----Ser substitution did not have this effect. A single mutation (beta Gly149----Ser or beta Gly150----Ser) gave active enzyme with altered divalent cation dependency and azide sensitivity: the beta Gly149----Ser mutant enzyme had 100-fold lower azide sensitivity and essentially no Ca(2+)-dependent activity, but had the wild-type level of Mg(2+)-dependent activity with active oxidative phosphorylation. Introduction of a beta Gly149----Ser or beta Gly150----Ser mutation with the beta Ser174----Phe mutation also lowered the Ca(2+)-dependent activity and azide sensitivity. Consistent with our previous findings (Takeyama, M., Ihara, K., Moriyama, Y., Noumi, T., Ida, K., Tomioka, N., Itai, A., Maeda, M., and Futai, M. (1990) J. Biol. Chem. 265, 21279-21284), a beta Thr156----Ala or Cys mutation impaired ATPase activity, suggesting that the hydroxyl moiety at position 156 is essential for the catalytic activity. The possible location of the catalytic site including divalent cation binding site(s) is discussed.     

Crystal structure of human protein tyrosine phosphatase SHP-1 in the open conformation

SHP‐1 belongs to the family of non‐receptor protein tyrosine phosphatases (PTPs) and generally acts as a negative regulator in a variety of cellular signaling pathways. Previously, the crystal structures of the tail‐truncated SHP‐1 and SHP‐2 revealed an autoinhibitory conformation. To understand the regulatory mechanism of SHP‐1, we have determined the crystal structure of the full‐length SHP‐1 at 3.1 Å. Although the tail was disordered in current structure, the huge conformational rearrangement of the N‐SH2 domain and the incorporation of sulfate ions into the ligand‐binding site of each domain indicate that the SHP‐1 is in the open conformation. The N‐SH2 domain in current structure is shifted away from the active site of the PTP domain to the other side of the C‐SH2 domain, resulting in exposure of the active site. Meanwhile, the C‐SH2 domain is twisted anticlockwise by about 110°. In addition, a set of new interactions between two SH2 domains and between the N‐SH2 and the catalytic domains is identified, which could be responsible for the stabilization of SHP‐1 in the open conformation. Based on the structural comparison, a model for the activation of SHP‐1 is proposed. J. Cell. Biochem. 112: 2062–2071, 2011. © 2011 Wiley‐Liss, Inc.     

Role of the conserved acidic residue Asp21 in the structure of phosphatidylinositol 3-kinase Src homology 3 domain: circular dichroism and nuclear magnetic resonance studies

To elucidate a role of the Src homology 3 (SH3)-conserved acidic residue Asp21 of the phosphatidylinositol 3-kinase (PI3K) SH3 domain, structural changes induced by the D21N mutation (Asp21 --> Asn) were examined by circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopies. In the previous study, we demonstrated that environmental alterations occurred at the side chains of Trp55 and some Tyr residues from the comparison of the near-UV CD spectra of the PI3K SH3 domain with or without a D21N mutation [Okishio, N., et al. (2000) Biopolymers 57, 208-217]. In this work, the affected Tyr residues were identified as Tyr14 and Tyr73 by the CD analysis of a series of mutants, in which every single Tyr residue was replaced by a Phe residue with or without a D21N mutation. The (1)H and (15)N resonance assignments of the PI3K SH3 domain and its D21N mutant revealed that significant chemical shift changes occurred to the aromatic side-chain protons of Trp55 and Tyr14 upon the D21N mutation. All these aromatic residues are implicated in ligand recognition. In addition, the NMR analysis showed that the backbone conformations of Lys15-Asp23, Gly54-Trp55, Asn57-Gly58, and Gly67-Pro70 were affected by the D21N mutation. Furthermore, the (15)N[(1)H] nuclear Overhauser effect values of Tyr14, Glu19, and Glu20 were remarkably changed by the mutation. These results show that the D21N mutation causes structural deformation of more than half of the ligand binding cleft of the domain and provide evidence that Asp21 plays an important role in forming a well-ordered ligand binding cleft in cooperation with the RT loop (Lys15-Glu20).     

Biochemical characterization of the Arabidopsis protein kinase SOS2 that functions in salt tolerance

The Arabidopsis Salt Overly Sensitive 2 (SOS2) gene encodes a serine/threonine (Thr) protein kinase that has been shown to be a critical component of the salt stress signaling pathway. SOS2 contains a sucrose-non-fermenting protein kinase 1/AMP-activated protein kinase-like N-terminal catalytic domain with an activation loop and a unique C-terminal regulatory domain with an FISL motif that binds to the calcium sensor Salt Overly Sensitive 3. In this study, we examined some of the biochemical properties of the SOS2 in vitro. To determine its biochemical properties, we expressed and isolated a number of active and inactive SOS2 mutants as glutathione S-transferase fusion proteins in Escherichia coli. Three constitutively active mutants, SOS2T168D, SOS2T168D Delta F, and SOS2T168D Delta 308, were obtained previously, which contain either the Thr-168 to aspartic acid (Asp) mutation in the activation loop or combine the activation loop mutation with removal of the FISL motif or the entire regulatory domain. These active mutants exhibited a preference for Mn(2+) relative to Mg(2+) and could not use GTP as phosphate donor for either substrate phosphorylation or autophosphorylation. The three enzymes had similar peptide substrate specificity and catalytic efficiency. Salt overly sensitive 3 had little effect on the activity of the activation loop mutant SOS2T168D, either in the presence or absence of calcium. The active mutant SOS2T168D Delta 308 could not transphosphorylate an inactive protein (SOS2K40N), which indicates an intramolecular reaction mechanism of SOS2 autophosphorylation. Interestingly, SOS2 could be activated not only by the Thr-168 to Asp mutation but also by a serine-156 or tyrosine-175 to Asp mutation within the activation loop. Our results provide insights into the regulation and biochemical properties of SOS2 and the SOS2 subfamily of protein kinases.     

Identification of putative active site residues of ACAT enzymes

In this report, we sought to determine the putative active site residues of ACAT enzymes. For experimental purposes, a particular region of the C-terminal end of the ACAT protein was selected as the putative active site domain due to its high degree of sequence conservation from yeast to humans. Because ACAT enzymes have an intrinsic thioesterase activity, we hypothesized that by analogy with the thioesterase domain of fatty acid synthase, the active site of ACAT enzymes may comprise a catalytic triad of ser-his-asp (S-H-D) amino acid residues. Mutagenesis studies revealed that in ACAT1, S456, H460, and D400 were essential for activity. In ACAT2, H438 was required for enzymatic activity. However, mutation of D378 destabilized the enzyme. Surprisingly, we were unable to identify any S mutations of ACAT2 that abolished catalytic activity. Moreover, ACAT2 was insensitive to serine-modifying reagents, whereas ACAT1 was not. Further studies indicated that tyrosine residues may be important for ACAT activity. Mutational analysis showed that the tyrosine residue of the highly conserved FYXDWWN motif was important for ACAT activity. Furthermore, Y518 was necessary for ACAT1 activity, whereas the analogous residue in ACAT2, Y496, was not. The available data suggest that the amino acid requirement for ACAT activity may be different for the two ACAT isozymes.