Interaction between γC87 and γR242 residues participates in energy coupling between catalysis and proton translocation in Escherichia coli ATP synthase

Functioning as a nanomotor, ATP synthase plays a vital role in the cellular energy metabolism. Interactions at the rotor and stator interface are critical to the energy transmission in ATP synthase. From mutational studies, we found that the γC87K mutation impairs energy coupling between proton translocation and nucleotide synthesis/hydrolysis. An additional glutamine mutation at γR242 (γR242Q) can restore efficient energy coupling to the γC87K mutant. Arrhenius plots and molecular dynamics simulations suggest that an extra hydrogen bond could form between the side chains of γC87K and β_TPE381 in the γC87K mutant, thus impeding the free rotation of the rotor complex. In the enzyme with γC87K/γR242Q double mutations, the polar moiety of γR242Q side chain can form a hydrogen bond with γC87K, so that the amine group in the side chain of γC87K will not hydrogen-bond with βE381. As a conclusion, the intra-subunit interaction between positions γC87 and γR242 modulates the energy transmission in ATP synthase. This study should provide more information of residue interactions at the rotor and stator interface in order to further elucidate the energetic mechanism of ATP synthase.     

Two-dimensional NMR as a probe of structural similarity applied to mutants of cytochrome c

Using site-directed mutagenesis, it is possible to prepare many mutants of a protein in a short time, and to uncover differences in function. To understand the changes in function, it is essential to understand the effect(s) of the mutation in terms of structural and dynamic changes. It is particularly important to establish a rapid method for comparing the structure of the mutants with that of the wild-type protein. We propose that a combination of overlayed and difference two-dimensional NOE spectra between the wild-type and mutant protein provide a rapid method for determination of structural similarity. The observation of differences other than those due directly to the field effects of the exchanged side chain allow both local and distant conformational changes to be assessed. Here we compare NOESY spectra from a mutant of yeast iso-1-ferrocytochrome c in which the invariant residue Phe-82 has been changed to a Tyr. We conclude that NMR can show subtle changes in protein structure. Specifically, we show the change must involve the reorientation of the side chain of Leu-85 which is proximal to the mutation. The dynamics of the aromatic side chain at position 82 are shown not to give rise to measurable differences between the wild-type and mutant protein. Structural changes are not propagated to a measurable degree in other parts of the protein.     

Critical molecular regions for elicitation of the sweetness of the sweet-tasting protein, thaumatin I

Thaumatin is an intensely sweet-tasting protein. To identify the critical amino acid residue(s) responsible for elicitation of the sweetness of thaumatin, we prepared mutant thaumatin proteins, using Pichia pastoris, in which alanine residues were substituted for lysine or arginine residues, and the sweetness of each mutant protein was evaluated by sensory analysis in humans. Four lysine residues (K49, K67, K106 and K163) and three arginine residues (R76, R79 and R82) played significant roles in thaumatin sweetness. Of these residues, K67 and R82 were particularly important for eliciting the sweetness. We also prepared two further mutant thaumatin I proteins: one in which an arginine residue was substituted for a lysine residue, R82K, and one in which a lysine residue was substituted for an arginine residue, K67R. The threshold value for sweetness was higher for R82K than for thaumatin I, indicating that not only the positive charge but also the structure of the side chain of the arginine residue at position 82 influences the sweetness of thaumatin, whereas only the positive charge of the K67 side chain affects sweetness.     

Structural insights into substrate and coenzyme preference by SDR family protein Gox2253 from Gluconobater oxydans

Gox2253 from Gluconobacter oxydans belongs to the short‐chain dehydrogenases/reductases family, and catalyzes the reduction of heptanal, octanal, nonanal, and decanal with NADPH. To develop a robust working platform to engineer novel G. oxydans oxidoreductases with designed coenzyme preference, we adopted a structure based rational design strategy using computational predictions that considers the number of hydrogen bonds formed between enzyme and docked coenzyme. We report the crystal structure of Gox2253 at 2.6 Å resolution, ternary models of Gox2253 mutants in complex with NADH/short‐chain aldehydes, and propose a structural mechanism of substrate selection. Molecular dynamics simulation shows that hydrogen bonds could form between 2′‐hydroxyl group in the adenosine moiety of NADH and the side chain of Gox2253 mutant after arginine at position 42 is replaced with tyrosine or lysine. Consistent with the molecular dynamics prediction, Gox2253‐R42Y/K mutants can use both NADH and NADPH as a coenzyme. Hence, the strategies here could provide a practical platform to engineer coenzyme selectivity for any given oxidoreductase and could serve as an additional consideration to engineer substrate‐binding pockets. Proteins 2014; 82:2925–2935. © 2014 Wiley Periodicals, Inc.     

Residue 259 in protein-tyrosine phosphatase PTP1B and PTPalpha determines the flexibility of glutamine 262

To study the flexibility of the substrate-binding site and in particular of Gln262, we have performed adiabatic conformational search and molecular dynamics simulations on the crystal structure of the catalytic domain of wild-type protein-tyrosine phosphatase (PTP) 1B, a mutant PTP1B(R47V,D48N,M258C,G259Q), and a model of the catalytically active form of PTPalpha. For each molecule two cases were modeled: the Michaelis-Menten complex with the substrate analogue p-nitrophenyl phosphate (p-PNPP) bound to the active site and the cysteine-phosphor complex, each corresponding to the first and second step of the phosphate hydrolysis. Analyses of the trajectories revealed that in the cysteine-phosphor complex of PTP1B, Gln262 oscillates freely between the bound phosphate group and Gly259 frequently forming, as observed in the crystal structure, a hydrogen bond with the backbone oxygen of Gly259. In contrast, the movement of Gln262 is restricted in PTPalpha and the mutant due to interactions with Gln259 reducing the frequency of the oscillation of Gln262 and thereby delaying the positioning of this residue for the second step in the catalysis, as reflected experimentally by a reduction in k(cat). Additionally, in the simulation with the Michaelis-Menten complexes, we found that a glutamine in position 259 induces steric hindrance by pushing the Gln262 side chain further toward the substrate and thereby negatively affecting K(m) as indicated by kinetic studies. Detailed analysis of the water structure around Gln262 and the active site Cys215 reveals that the probability of finding a water molecule correctly positioned for catalysis is much larger in PTP1B than in PTP1B(R47V,D48N,M258C,G259Q) and PTPalpha, in accordance with experiments.     

Structural mechanisms of the degenerate sequence recognition by Bse634I restriction endonuclease

Restriction endonuclease Bse634I recognizes and cleaves the degenerate DNA sequence 5'-R/CCGGY-3' (R stands for A or G; Y for T or C, '/' indicates a cleavage position). Here, we report the crystal structures of the Bse634I R226A mutant complexed with cognate oligoduplexes containing ACCGGT and GCCGGC sites, respectively. In the crystal, all potential H-bond donor and acceptor atoms on the base edges of the conserved CCGG core are engaged in the interactions with Bse634I amino acid residues located on the α6 helix. In contrast, direct contacts between the protein and outer base pairs are limited to van der Waals contact between the purine nucleobase and Pro203 residue in the major groove and a single H-bond between the O2 atom of the outer pyrimidine and the side chain of the Asn73 residue in the minor groove. Structural data coupled with biochemical experiments suggest that both van der Waals interactions and indirect readout contribute to the discrimination of the degenerate base pair by Bse634I. Structure comparison between related enzymes Bse634I (R/CCGGY), NgoMIV (G/CCGGC) and SgrAI (CR/CCGGYG) reveals how different specificities are achieved within a conserved structural core.     

The human topoisomerase 1B Arg634Ala mutation results in camptothecin resistance and loss of inter-domain motion correlation

Human topoisomerase 1B, the unique target of the natural anticancer compound camptothecin, catalyzes the unwinding of supercoiled DNA by introducing transient single strand nicks and providing covalent protein–DNA adducts. The functional properties and the drug reactivity of the single Arg634Ala mutant have been investigated in comparison to the wild type enzyme. The mutant is characterized by an identical relaxation and cleavage rate but it displays resistance to camptothecin as indicated by a viability assay of the yeast cells transformed with the mutated protein. The mutant also displays a very fast religation rate that is only partially reduced by the presence of the drug, suggesting that this is the main reason for its resistance. A comparative analysis of the structural–dynamical properties of the native and mutant proteins by molecular dynamics simulation indicates that mutation of Arg634 brings to a loss of motion correlation between the different domains and in particular between the linker and the C-terminal domain, containing the catalytic tyrosine residue. These results indicate that the loss of motion correlation and the drug resistance are two strongly correlated events.     

The rad50 signature motif: essential to ATP binding and biological function

The repair of double-strand breaks in DNA is an essential process in all organisms, and requires the coordinated activities of evolutionarily conserved protein assemblies. One of the most critical of these is the Mre11/Rad50 (M/R) complex, which is present in all three biological kingdoms, but is not well-understood at the biochemical level. Previous structural analysis of a Rad50 homolog from archaebacteria illuminated the catalytic core of the enzyme, an ATP-binding domain related to the ABC transporter family of ATPases. Here, we present the crystallographic structure of the Rad50 mutant S793R. This missense signature motif mutation changes the key serine residue in the signature motif that is conserved among Rad50 homologs and ABC ATPases. The S793R mutation is analogous to the mutation S549R in the cystic fibrosis transmembrane conductance regulator (CFTR) that results in cystic fibrosis. We show here that the serine to arginine change in the Rad50 protein prevents ATP binding and disrupts the communication among the other ATP-binding loops. This structural change, in turn, alters the communication between Rad50 monomers and thus prevents Rad50 dimerization. The equivalent mutation was made in the human Rad50 gene, and the resulting mutant protein did form a complex with Mre11 and Nbs1, but was specifically deficient in all ATP-dependent enzymatic activities. This signature motif structure-function homology extends to yeast, because the same mutation introduced into the Saccharomyces cerevisiae RAD50 gene generated an allele that failed to complement a rad50 deletion strain in DNA repair assays in vivo. These structural and biochemical results extend our understanding of the Rad50 catalytic domain and validate the use of the signature motif mutant to test the role of Rad50 ATP binding in diverse organisms.     

A G577R mutation in the human AR P box results in selective decreases in DNA binding and in partial androgen insensitivity syndrome

We have characterized a novel mutation of the human AR, G577R, associated with partial androgen insensitivity syndrome. G577 is the first amino acid of the P box, a region crucial for the selectivity of receptor/DNA interaction. Although the equivalent amino acid in the GR (also Gly) is not involved in DNA interaction, the residue at the same position in the ER (Glu) interacts with the two central base pairs in the PuGGTCA motif. Using a panel of 16 palindromic probes that differ in these base pairs (PuGNNCA) in gel shift experiments with either the AR DNA-binding domain or the full length receptor, we observed that the G577R mutation does not induce binding to probes that are not recognized by the wild-type AR. However, binding to the four PuGNACA elements recognized by the wild-type AR was affected to different degrees, resulting in an altered selectivity of DNA response element recognition. In particular, AR-G577R did not interact with PuGGACA palindromes. Modeling of the complex between mutant AR and PuGNACA motifs indicates that the destabilizing effect of the mutation is attributable to a steric clash between the C beta of Arg at position 1 of the P box and the methyl group of the second thymine residue in the TGTTCPy arm of the palindrome. In addition, the Arg side chain can interact with G or T at the next position (PuGCACA and PuGAACA elements, respectively). The presence of C is not favorable, however, because of incompatible charges, abrogating binding to the PuGGACA element. Transactivation of several natural or synthetic promoters containing PuGGACA motifs was drastically reduced by the G577R mutation. These data suggest that androgen target genes may be differentially affected by the G577R mutation, the first natural mutation characterized that alters the selectivity of the AR/DNA interaction. This type of mutation may thus contribute to the diversity of phenotypes associated with partial androgen insensitivity syndrome.     

Exposure of hydrophobic core in human prion protein pathogenic mutant H187R

Pathogenesis studies have revealed that H187R mutation of human prion protein (huPrP) is related to GSS type of TSE diseases. Its pathogenic mechanism is still unclear. We here studied the globular domain of this mutant protein by molecular dynamics simulations. Compared to the wide-type protein, the mutant has similar dynamics and stability profiles in our simulation. Conformational rearrangements are concentrated around the mutation site, due to the introduction the positively charged side chain of Arg187. The strong electrostatic repulsion between Arg156 and Arg187 drives both side chains away from their original positions, leaving its hydrophobic core to be solvent accessible. Such a unfavorable conformational change may destabilize the mutant protein and make it more susceptible to unfolding.     

Site-directed mutagenesis at the active site of Escherichia coli TEM-1 beta-lactamase. Suicide inhibitor-resistant mutants reveal the role of arginine 244 and methionine 69 in catalysis.

Arginine 244 is a highly conserved residue in Class A beta-lactamases, while methionine 69 is not. Informational suppression experiments show that replacement of M69 by a leucine, or that of R244 by most other amino acids lead to clavulanic acid-resistant phenotypes. The arginyl 244 side chain is tightly held in a network of interactions within the active site. Its replacement by a glutamine or a threonine perturbs the enzyme kinetics but to a smaller extent than would have been predicted if it were directly involved in substrate binding. Clavulanic acid and sulbactam still interact specifically with the mutant enzymes but are much less efficiently metabolized. Substitutions at position 244 also unveil interactions between the C6 substituent of substrates and the Asn132/Glu104 region of the active site. Methionine 69 is located in a region of strong structural constraints and presents an unusual conformation. Molecular dynamics simulation showed that its replacement by a leucine does not release the strain in this area and induces only minor structural changes. Accordingly, the kinetic behavior of the mutant is only marginally perturbed, except for suicide inhibitors. Both clavulanic acid and sulbactam are well degraded by the mutant enzyme, while irreversible inactivation is dramatically decreased. The contribution of both residues to catalysis is discussed in the light of the kinetic and structural data.     

Crystal structures of penicillin acylase enzyme-substrate complexes: structural insights into the catalytic mechanism

The crystal structure of penicillin G acylase from Escherichia coli has been determined to a resolution of 1.3 A from a crystal form grown in the presence of ethylene glycol. To study aspects of the substrate specificity and catalytic mechanism of this key biotechnological enzyme, mutants were made to generate inactive protein useful for producing enzyme-substrate complexes. Owing to the intimate association of enzyme activity and precursor processing in this protein family (the Ntn hydrolases), most attempts to alter active-site residues lead to processing defects. Mutation of the invariant residue Arg B263 results in the accumulation of a protein precursor form. However, the mutation of Asn B241, a residue implicated in stabilisation of the tetrahedral intermediate during catalysis, inactivates the enzyme but does not prevent autocatalytic processing or the ability to bind substrates. The crystal structure of the Asn B241 Ala oxyanion hole mutant enzyme has been determined in its native form and in complex with penicillin G and penicillin G sulphoxide. We show that Asn B241 has an important role in maintaining the active site geometry and in productive substrate binding, hence the structure of the mutant protein is a poor model for the Michaelis complex. For this reason, we subsequently solved the structure of the wild-type protein in complex with the slowly processed substrate penicillin G sulphoxide. Analysis of this structure suggests that the reaction mechanism proceeds via direct nucleophilic attack of Ser B1 on the scissile amide and not as previously proposed via a tightly H-bonded water molecule acting as a "virtual" base.     

应用进化踪迹及分子动力学模拟研究beta2肾上腺素受体突变活性

β2肾上腺素受体(β2adrenergic receptor,β2AR)是G蛋白耦联受体(G protein coupled receptors,GPCRs)超家族中的一员,也是研究治疗哮喘的关键药物受体靶标.采用进化踪迹(evolutionary trace,ET)方法分析肾上腺素受体家族跨膜区片段序列,识别出了44个保守的残基,然后将β2肾上腺素受体以及受体D130N活性突变体、D79N失活突变体进行分子动力学模拟,试图找出与受体不同功能状态相关的结构动力学特征.发现受体DRY motif中的D130远离R131而转向K149残基这一结构特征与受体活性高度关联,此外,从残基相互作用的变化推断出了受体helix 2,4 and 6伴随着受体活化而发生的运动.这些研究结果对进一步探索β2肾上腺素受体突变体的激活机制以及所诱发疾病的分子机理提供了依据.     

Hsp70核苷酸结合域突变体影响酶活的分子动力学模拟研究

分子伴侣蛋白Hsp70氮端核苷酸结合域（NBD, nucleotide-binding domain）的ATP酶活性变化对其行使分子伴侣功能具有重要作用。本文采用分子动力学模拟方法研究酵母分子伴侣Hsp70氮端NBD内残基A17,R23,G32和R167点突变对其ATP酶活性区域构象影响及功能关系。结果表明,突变体A17V,T23H,G32S的ATP结合口袋袋口的loopl（第一个转角,连接p1与p2）结构柔性增强,活性残基T11侧链明显向内移动,从而更加接近ATP的γ-磷酸基团,更容易使ATP水解。这可能蕞终导致ATP酶活性增强,从而引起分子伴侣功能的变化。     

Mutant DnaA proteins defective in duplex opening of oriC, the origin of chromosomal DNA replication in Escherichia coli

We characterized three mutant DnaA proteins with an amino acid substitution of R334H, R342H and E361G that renders chromosomal replication cold (20 degrees C) sensitive. Each mutant DnaA protein was highly purified from overproducers, and replication activities were assayed in in vitro oriC replication systems. At 30 degrees C, all three mutant proteins exhibited specific activity similar to that seen with the wild-type protein, whereas at 20 degrees C, there was much less activity in a replication system using a crude replicative extract. Regarding the affinity for ATP, the dissociation rate of bound ATP and binding to oriC DNA, the three mutant DnaA proteins showed a capacity indistinguishable from that of the wild-type DnaA protein. Activity for oriC DNA unwinding of the two mutant DnaA proteins, R334H and R342H, was more sensitive to low temperature than that of the wild-type DnaA protein. We propose that R334H and R342H have a defect in their potential to unwind oriC DNA at low temperatures, the result being the cold-sensitive phenotype in oriC DNA replication. The two amino acid residues of DnaA protein, located in a motif homologous to that of NtrC protein, may play a role in the formation of the open complex. The E361 residue may be related to interaction with another protein present in a crude cell extract.     

Roles of Met-34, Cys-64, and Arg-75 in the assembly of human connexin 26. Implication for key amino acid residues for channel formation and function

Connexins form a family of membrane proteins that assemble into communication channels and directly connect the cytoplasms of adjoining cells. Malfunctioning of connexin channels often cause disease, such as the mutations M34T and R75W in human connexin 26, which are associated with hereditary deafness. Another residue known to be essential for normal channel activity in the connexin is Cys-64. To obtain structural and functional insights of connexin 26, we studied the roles of these three residues by expressing mutant connexins in insect Sf9 and HeLa cells. The M34T and M34A mutants both formed gap junction plaques, but dye transfer assays showed that the M34A mutant had a significantly reduced permeability, suggesting that for proper channel function a side chain of adequate size is required at this position. We propose that Met-34 is located in the innermost helix of the channel, where it ensures a fully open channel structure via interactions with other transmembrane helices. Gap junction channels formed by the R75W and R75D mutants dissociated upon solubilization in dodecyl maltoside, whereas the R75A mutant remained hexameric. All gap junctions formed by Arg-75 mutants also showed only negligible activity in dye transfer experiments. These results suggest that residue Arg-75 plays a role in subunit interactions needed to retain a functional and stable connexin hexamer. The C64S mutant was suggested to be defective in oligomerization and/or protein folding even in the presence of wild-type connexin.     

Effect of tryptophan mutation on the structure of LOV1 domain of phototropin1 protein of Ostreococcus tauri: A combined molecular dynamics simulation and biophysical approach

BackgroundLight, oxygen and voltage (LOV) proteins detect blue light by formation of a covalent ‘photoadduct’ between the flavin chromophore and the neighboring conserved cysteine residue. LOV proteins devoid of this conserved photoactive cysteine are unable to form this ‘photoadduct’ upon light illumination, but they can still elicit functional response via the formation of neutral flavin radical. Recently, tryptophan residue has been shown to be the primary electron donors to the flavin excited state.MethodsPhotoactive cysteine (Cys42) and tryptophan (Trp68) residues in the LOV1 domain of phototropin1 of Ostreococcus tauri (OtLOV1) was mutated to alanine and threonine respectively. Effect of these mutations have been studied using molecular dynamics simulation and spectroscopic techniques.ResultsMolecular dynamics simulation indicated that W68T did not affect the structure of OtLOV1 protein, but C42A leads to some structural changes. An increase in the fluorescence lifetime and quantum yield values was observed for the Trp68 mutant.ConclusionsAn increase in the fluorescence lifetime and quantum yield of Trp68 mutant compared to the wild type protein suggests that Trp68 residue participates in quenching of the flavin excited state followed by photoexcitation.General significanceEnhanced photo-physical properties of Trp68 OtLOV1 mutant might enable its use for the optogenetic and microscopic applications.     

Modulation of human cytidine deaminase by specific aminoacids involved in the intersubunit interactions

An investigation was made of the role exerted by some residues supposed to be involved in the intersubunit interaction and also in the catalytic site of homotetrameric human cytidine deaminase (T-CDA). Attention was focused on Y33, Y60, R68, and F137 residues that are a part of a conserved region in most T-CDAs. Hence, a series of site-directed mutagenesis experiments was set up obtaining seven mutants: Y60G, Y33G, Y33F Y33S, F137A, R68G, and R68Q. Each active purified mutant protein was characterized kinetically, with a series of substrates and inhibitors, and the effect of temperature on enzyme activity and stability was also investigated. Circular dichroism (CD) experiments at different temperatures and in presence of small amounts of sodium dodecyl sulphate (SDS) were performed in all the soluble mutant CDAs. The results obtained by site-directed mutagenesis studies were compared to the crystallographic data of B. subtilis CDA and E. coli CDA and to molecular modeling studies previously performed on human CDA. The mutation of Y60 to glycine produced an enzyme with a more compact quaternary structure with respect to the wild-type; this mutation did not have a dramatic effect on cytidine deamination, but it slightly affected the binding with the substrate. None of the mutant CDAs in Y33 showed enzymatic activity; they existed only as monomers, indicating that this residue, located at the intersubunit interface, may be responsible for the correct folding of human CDA. The insertion of an alanine instead of phenylalanine at position 137 led to a soluble but completely inactive enzyme unable to form a tetramer, suggesting that F137 residue may be important for the assembling of the tetramer and also for the arrangement of the CDA active site. Finally, R68G and R68Q mutations revealed that the presence of the amino group seems to be important for the catalytic process but not for substrate binding, as already shown in B. subtilis CDA. The quaternary structure of R68Q was not affected by the mutation, as shown by the SDS-induced dissociation experiments and CD studies, whereas R68G dissociated very easily in presence of small amounts of SDS. These experiments indicated that in the human CDA, the side chain of arginine 68 involved in the catalytic process in one subunit active site might come from another subunit. The data obtained from these studies confirmed the presence of a complicated set of intersubunit interactions in the active site of human CDA, as shown in other T-CDAs.     

Role of lysine-57 in the catalytic activities of Escherichia coli formamidopyrimidine-DNA glycosylase (Fpg protein).

The Escherichia coli Fpg protein is involved in the repair of oxidized residues. We examined, by targeted mutagenesis, the effect of the conserved lysine residue at position 57 upon the various catalytic activities of the Fpg protein. Mutant Fpg protein with Lys-57-->Gly (K57G) had dramatically reduced DNA glycosylase activity for the excision of 7,8-dihydro-8-oxo-guanine (8-oxoG). While wild type Fpg protein cleaved 8-oxoG/C DNA with a specificity constant ( k cat/ K M) of 0.11/(nM@min), K57G cleaved the same DNA 55-fold less efficiently. FpgK57G was poorly effective in the formation of Schiff base complex with 8-oxoG/C DNA. The efficiency in the binding of 8-oxoG/C DNA duplex for K57G mutant was decreased 16-fold. The substitution of Lys-57 for another basic amino acid Arg (K57R) had a slight effect on the 8-oxoG-DNA glycosylase activity and Schiff base formation. The DNA glycosylase activities of FpgK57G and FpgK57R using 2,6-diamino-4-hydroxy-5N-methylformamidopyrimidine residues as substrate were comparable to that of wild type Fpg. In vivo, the mutant K57G, in contrast to the mutant K57R and wild type Fpg, only partially restored the ability to prevent spontaneously induced transitions G/C-->T/A in E.coli BH990 ( fpg mutY ) cells. These results suggest an important role for Lys-57 in the 8-oxoG-DNA glycosylase activity of the Fpg protein in vitro and in vivo.