Backbone resonance assignments of the <Emphasis Type="Italic">Escherichia coli</Emphasis> 62 kDa protein,Hsp31

Dimeric Hsp31 protein was first characterized as a holding chaperone of Escherichia coli (E. coli), and has been suggested as having protease activity due to the presence of a potential catalytic triad, Cys185, His186, and Asp214. However, it has recently been reported that Hsp31 displays a relatively strong glyoxalase III activity that can decompose reactive carbonyl species (methylglyoxal and glyoxal) in the absence of additional cofactor. Hsp31 is a representative member of the DJ-1/ThiJ/PfpI protein superfamily, and the importance of DJ-1 protein in Parkinson’s disease has been well known. The structural flexibility of the long loop region, which encompasses from the P- to the A-domain, is important for the chaperone activity of Hsp31. The backbone chemical shifts (CSs) would be useful for studying the structural changes of Hsp31 that are critical for the holding chaperone activity, and also for deciphering the switching mechanism between the glyoxalase III and the chaperone. Here, we report the backbone CSs (H^N, N, CO, C_α, and C_β) of the deuterated Hsp31 protein (62 kDa). The CS analysis showed that the predicted regions of secondary structures are in good agreement with those observed in the previous crystal structure of Hsp31.     

Zinc-mediated Reversible Multimerization of Hsp31 Enhances the Activity of Holding Chaperone

Hsp31 protein, belonging to the DJ-1/ThiJ/PfpI superfamily, increases the survival of Escherichia coli under various stresses. While it was reported as a holding chaperone, Hsp31 was also shown to exhibit the glyoxalase III activity in subsequent study. Here, we describe our finding that Hsp31 undergoes a Zn^+ 2-mediated multimerization (HMW_Zinc), resulting in an enhanced chaperone activity. Furthermore, it was shown that the formation of HMW_Zinc is reversible such that the oligomer dissociates into the native dimer by EDTA incubation. We attempted to determine the structural change involving the transition between the native dimer and HMW_Zinc by adding Ni^+ 2, which is Zn^+ 2-mimetic, producing a potential intermediate structure. An analysis of this intermediate revealed a structure with hydrophobic interior exposed, due to an unfolding of the N-terminal loop and the C-terminal β-to-α region. A treatment with hydrogen peroxide accelerated HMW_Zinc formation, so that the Hsp31^C185E mutant rendered the formation of HMW_Zinc even at 45 °C. However, the presence of Zn^+ 2 in the catalytic site antagonizes the oxidation of C185, implying a negative role. Our results suggest an unprecedented mechanism of the enhancing chaperone activity by Hsp31, in which the reversible formation of HMW_Zinc occurs in the presence of heat and Zn^+ 2 ion.     

Peptidase activity of the Escherichia coli Hsp31 chaperone

Hsp31, the Escherichia coli hcha gene product, is a molecular chaperone whose activity is inhibited by ATP at high temperature. Its crystal structure reveals a putative Cys(184), His(185), and Asp(213) catalytic triad similar to that of the Pyrococcus horikoshii protease PH1704, suggesting that it should display a proteolytic activity. A preliminary report has shown that Hsp31 has an exceedingly weak proteolytic activity toward bovine serum albumin and a peptidase activity toward two peptide substrates with small amino acids at their N terminus (alanine or glycine), but the physiological significance of this observation remains unclear. In this study, we report that Hsp31 does not diplay any significant proteolytic activity but has peptidolytic activity. The aminopeptidase cleavage preference of Hsp31 is Ala > Lys > Arg > His, suggesting that Hsp31 is an aminopeptidase of broad specificity. Its aminopeptidase activity is inhibited by the thiol reagent iodoacetamide and is completely abolished in a C185A mutant, which is consistent with Hsp31 being a cysteine peptidase. The aminopeptidase activity of Hsp31 is also inhibited by EDTA and 1,10-phenanthroline, in concordance with the importance of the putative His(85), His(122), and Glu(90) metal-binding site revealed by crystallographic studies. An Hsp31-deficient mutant accumulates more 8-12-mer peptides than its parental strain, and purified Hsp31 can transform these peptides into smaller peptides, suggesting that Hsp31 has an important peptidase function both in vivo and in vitro. Proteins interacting with Hsp31 have been identified by reverse purification of a crude E. coli extract on an Hsp31-affinity column, followed by SDS-polyacrylamide electrophoresis and mass spectrometry. The ClpA component of the ClpAP protease, the chaperone GroEL, elongation factor EF-Tu, and tryptophanase were all found to interact with Hsp31, thus substantiating the role of Hsp31 as both chaperone and peptidase.     

A nuclear‐localized rice glyoxalase I enzyme,OsGLYI‐8, functions in the detoxification of methylglyoxal in the nucleus

The cellular levels of methylglyoxal (MG), a toxic byproduct of glycolysis, rise under various abiotic stresses in plants. Detoxification of MG is primarily through the glyoxalase pathway. The first enzyme of the pathway, glyoxalase I (GLYI), is a cytosolic metalloenzyme requiring either Ni²⁺ or Zn²⁺ for its activity. Plants possess multiple GLYI genes, of which only some have been partially characterized; hence, the precise molecular mechanism, subcellular localization and physiological relevance of these diverse isoforms remain enigmatic. Here, we report the biochemical properties and physiological role of a putative chloroplast‐localized GLYI enzyme, OsGLYI‐8, from rice, which is strikingly different from all hitherto studied GLYI enzymes in terms of its intracellular localization, metal dependency and kinetics. In contrast to its predicted localization, OsGLYI‐8 was found to localize in the nucleus along with its substrate, MG. Further, OsGLYI‐8 does not show a strict requirement for metal ions for its activity, is functional as a dimer and exhibits unusual biphasic steady‐state kinetics with a low‐affinity and a high‐affinity substrate‐binding component. Loss of AtGLYI‐2, the closest Arabidopsis ortholog of OsGLYI‐8, results in severe germination defects in the presence of MG and growth retardation under salinity stress conditions. These defects were rescued upon complementation with AtGLYI‐2 or OsGLYI‐8. Our findings thus provide evidence for the presence of a GLYI enzyme and MG detoxification in the nucleus.     

Crystal structure of Staphylococcus aureus Zn-glyoxalase I: new subfamily of glyoxalase I family

The crystal structures of protein SA0856 from Staphylococcus aureus in its apo-form and in complex with a Zn²⁺-ion have been presented. The 152 amino acid protein consists of two similar domains with α + β topology. In both crystalline state and in solution, the protein forms a dimer with monomers related by a twofold pseudo-symmetry rotation axis. A sequence homology search identified the protein as a member of the structural family Glyoxalase I. We have shown that the enzyme possesses glyoxalase I activity in the presence of Zn²⁺, Mg²⁺, Ni²⁺, and Co²⁺, in this order of preference. Sequence and structure comparisons revealed that human glyoxalase I should be assigned to a subfamily A, while S. aureus glyoxalase I represents a new subfamily B, which includes also proteins from other bacteria. Both subfamilies have a similar protein chain fold but rather diverse sequences. The active sites of human and staphylococcus glyoxalases I are also different: the former contains one Zn-ion per chain; the latter incorporates two of these ions. In the active site of SA0856, the first Zn-ion is well coordinated by His58, Glu60 from basic molecule and Glu40*, His44* from adjacent symmetry-related molecule. The second Zn3-ion is coordinated only by residue His143 from protein molecule and one acetate ion. We suggest that only single Zn1-ion plays the role of catalytic center. The newly found differences between the two subfamilies could guide the design of new drugs against S. aureus, an important pathogenic micro-organism.     

A Glutathione-independent Glyoxalase of the DJ-1 Superfamily Plays an Important Role in Managing Metabolically Generated Methylglyoxal in Candida albicans

Methylglyoxal is a cytotoxic reactive carbonyl compound produced by central metabolism. Dedicated glyoxalases convert methylglyoxal to d-lactate using multiple catalytic strategies. In this study, the DJ-1 superfamily member ORF 19.251/GLX3 from Candida albicans is shown to possess glyoxalase activity, making this the first demonstrated glutathione-independent glyoxalase in fungi. The crystal structure of Glx3p indicates that the protein is a monomer containing the catalytic triad Cys¹³⁶-His¹³⁷-Glu¹⁶⁸. Purified Glx3p has an in vitro methylglyoxalase activity (K_m = 5.5 mm and k_cat = 7.8 s⁻¹) that is significantly greater than that of more distantly related members of the DJ-1 superfamily. A close Glx3p homolog from Saccharomyces cerevisiae (YDR533C/Hsp31) also has glyoxalase activity, suggesting that fungal members of the Hsp31 clade of the DJ-1 superfamily are all probable glutathione-independent glyoxalases. A homozygous glx3 null mutant in C. albicans strain SC5314 displays greater sensitivity to millimolar levels of exogenous methylglyoxal, elevated levels of intracellular methylglyoxal, and carbon source-dependent growth defects, especially when grown on glycerol. These phenotypic defects are complemented by restoration of the wild-type GLX3 locus. The growth defect of Glx3-deficient cells in glycerol is also partially complemented by added inorganic phosphate, which is not observed for wild-type or glucose-grown cells. Therefore, C. albicans Glx3 and its fungal homologs are physiologically relevant glutathione-independent glyoxalases that are not redundant with the previously characterized glutathione-dependent GLO1/GLO2 system. In addition to its role in detoxifying glyoxals, Glx3 and its close homologs may have other important roles in stress response.     

The crystal structure of Escherichia coli heat shock protein YedU reveals three potential catalytic active sites

The mRNA of Escherichia coli yedU gene is induced 31-fold upon heat shock. The 31-kD YedU protein, also calls Hsp31, is highly conserved in several human pathogens and has chaperone activity. We solved the crystal structure of YedU at 2.2 A resolution. YedU monomer has an alpha/beta/alpha sandwich domain and a small alpha/beta domain. YedU is a dimer in solution, and its crystal structure indicates that a significant amount of surface area is buried upon dimerization. There is an extended hydrophobic patch that crosses the dimer interface on the surface of the protein. This hydrophobic patch is likely the substrate-binding site responsible for the chaperone activity. The structure also reveals a potential protease-like catalytic triad composed of Cys184, His185, and Asp213, although no enzymatic activity could be identified. YedU coordinates a metal ion using His85, His122, and Glu90. This 2-His-1-carboxylate motif is present in carboxypeptidase A (a zinc enzyme), and a number of dioxygenases and hydroxylases that utilize iron as a cofactor, suggesting another potential function for YedU.     

A glutathione responsive rice glyoxalase II,OsGLYII‐2, functions in salinity adaptation by maintaining better photosynthesis efficiency and anti‐oxidant pool

Glyoxalase II (GLY II), the second enzyme of glyoxalase pathway that detoxifies cytotoxic metabolite methylglyoxal (MG), belongs to the superfamily of metallo‐β‐lactamases. Here, detailed analysis of one of the uncharacterized rice glyoxalase II family members, OsGLYII‐2 was conducted in terms of its metal content, enzyme kinetics and stress tolerance potential. Functional complementation of yeast GLY II mutant (?GLO2) and enzyme kinetics data suggested that OsGLYII‐2 possesses characteristic GLY II activity using S‐lactoylglutathione (SLG) as the substrate. Further, Inductively Coupled Plasma Atomic Emission spectroscopy and modelled structure revealed that OsGLYII‐2 contains a binuclear Zn/Fe centre in its active site and chelation studies indicated that these are essential for its activity. Interestingly, reconstitution of chelated enzyme with Zn²⁺, and/or Fe²⁺ could not reactivate the enzyme, while addition of Co²⁺ was able to do so. End product inhibition study provides insight into the kinetics of GLY II enzyme and assigns hitherto unknown function to reduced glutathione (GSH). Ectopic expression of OsGLYII‐2 in Escherichia coli and tobacco provides improved tolerance against salinity and dicarbonyl stress indicating towards its role in abiotic stress tolerance. Maintained levels of MG and GSH as well as better photosynthesis rate and reduced oxidative damage in transgenic plants under stress conditions seems to be the possible mechanism facilitating enhanced stress tolerance.     

A goose-type lysozyme from ostrich (Struthio camelus) egg white: multiple roles of His101 in its enzymatic reaction

A goose-type lysozyme from ostrich egg white (OEL) was produced by Escherichia coli expression system, and the role of His101 of OEL in the enzymatic reaction was investigated by NMR spectroscopy, thermal unfolding, and theoretical modeling of the enzymatic hydrolysis of hexa-N-acetylchitohexaose, (GlcNAc)₆. Although the binding of tri-N-acetylchitotriose, (GlcNAc)₃, to OEL perturbed several backbone resonances in the ¹H–¹⁵N HSQC spectrum, the chemical shift of the backbone resonance of His101 was not significantly affected. However, apparent pK_a values of His101 and Lys102 determined from the pH titration curves of the backbone chemical shifts were markedly shifted by (GlcNAc)₃ binding. Thermal unfolding experiments and modeling study of (GlcNAc)₆ hydrolysis using a His101-mutated OEL (H101A-OEL) revealed that the His101 mutation affected not only sugar residue affinities at subsites ?3 and ?2 but also the rate constant for bond cleavage. His101 appears to play multiple roles in the substrate binding and the catalytic reaction.     

Methylglyoxal resistance in Bacillus subtilis: contributions of bacillithiol‐dependent and independent pathways

Methylglyoxal (MG) is a toxic by‐product of glycolysis that damages DNA and proteins ultimately leading to cell death. Protection from MG is often conferred by a glutathione‐dependent glyoxalase pathway. However, glutathione is absent from the low‐GC Gram‐positive Firmicutes, such as Bacillus subtilis. The identification of bacillithiol (BSH) as the major low‐molecular‐weight thiol in the Firmicutes raises the possibility that BSH is involved in MG detoxification. Here, we demonstrate that MG can rapidly and specifically deplete BSH in cells, and we identify both BSH‐dependent and BSH‐independent MG resistance pathways. The BSH‐dependent pathway utilizes glyoxalase I (GlxA, formerly YwbC) and glyoxalase II (GlxB, formerly YurT) to convert MG to d ‐lactate. The critical step in this pathway is the activation of the KhtSTU K⁺ efflux pump by the S‐lactoyl‐BSH intermediate, which leads to cytoplasmic acidification. We show that cytoplasmic acidification is both necessary and sufficient for maximal protection from MG. Two additional MG detoxification pathways operate independent of BSH. The first involves three enzymes (YdeA, YraA and YfkM) which are predicted to be homologues of glyoxalase III that converts MG to d ‐lactate, and the second involves YhdN, previously shown to be a broad specificity aldo‐keto reductase that converts MG to acetol.     

Chaperone Hsp31 Contributes to Acid Resistance in Stationary-Phase Escherichia coli

Hsp31, the product of the σ^S- and σ^D-dependent hchA gene, is a heat-inducible chaperone implicated in the management of protein misfolding at high temperatures. We show here that Hsp31 plays an important role in the acid resistance of starved Escherichia coli but that it has little influence on oxidative-stress survival.     

Synthesis of lucifensin by native chemical ligation and characteristics of its isomer having different disulfide bridge pattern

The antimicrobial 40‐amino‐acid‐peptide lucifensin was synthesized by native chemical ligation (NCL) using N‐acylbenzimidazolinone (Nbz) as a linker group. NCL is a method in which a peptide bond between two discreet peptide chains is created. This method has been applied to the synthesis of long peptides and proteins when solid‐phase synthesis is imcompatible. Two models of ligation were developed: [15 + 25] Ala‐Cys and [19 + 21] His‐Cys. The [19 + 21] His‐Cys method gives lower yield because of the lower stability of 18‐peptide‐His‐Nbz‐CONH₂ peptide, as suggested by density functional theory calculation. Acetamidomethyl‐deprotection and subsequent oxidation of the ligated linear lucifensin gave a mixture of lucifensin isomers, which differed in the location of their disulfide bridges only. The dominant isomer showed unnatural pairing of cysteines [C1?6], [C3?5], and [C2?4], which limits its ability to form α‐helical structure. The activity of isomeric lucifensin toward Bacillus subtilis, Staphylococcus aureus, and Micrococcus luteus was lower than that of the natural lucifensin. The desired product native lucifensin was prepared from this isomer using a one‐pot reduction with dithiotreitol and subsequent air oxidation in slightly alkaline medium. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Quinoprotein ethanol dehydrogenase from <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis>: the unusual disulfide ring formed by adjacent cysteine residues is essential for efficient electron transfer to cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>550</Subscript>

All pyrroloquinoline quinone (PQQ)-dependent alcohol dehydrogenases contain an unusual disulfide ring formed between adjacent cysteine residues. A mutant enzyme that is lacking this structure was generated by replacing Cys105 and Cys106 with Ala in quinoprotein ethanol dehydrogenase (QEDH) from Pseudomonas aeruginosa ATCC17933. Heterologously expressed quinoprotein ethanol dehydrogenase in which Cys-105 and Cys-106 have been replaced by Ala (Cys105Ala/Cys106Ala apo-QEDH) was successfully converted to enzymatic active holo-enzyme by incorporation of its cofactor PQQ in the presence of Ca²⁺. The enzymatic activity of the mutant enzyme in the artificial dye test with N-methylphenazonium methyl sulfate (PMS) and 2,6-dichlorophenol indophenol (DCPIP) at pH 9 did not depend on an activating amine which is essential for wild type activity under these conditions. The mutant enzyme showed increased Michaelis constants for primary alcohols, while the affinity for the secondary alcohol 2-propanol was unaltered. Surprisingly, for all substrates tested the specific activity of the mutant enzyme in the artificial dye test was higher than that found for wild type QEDH. On the contrary, in the ferricyanide test with the natural electron acceptor cytochrome c ₅₅₀ the activity of mutant Cys105Ala/Cys106Ala was 15-fold lower than that of wild type QEDH. We demonstrate for the first time unambiguously that the unusual disulfide ring is essential for efficient electron transfer at pH 7 from QEDH to its natural electron acceptor cytochrome c ₅₅₀.     

谷氨酸棒杆菌anti-σ因子CseE及其突变体与σ因子SigE的相互作用分析

[目的]谷氨酸棒杆菌是重要的氨基酸生产菌株,本研究针对SigE与ZAS家族蛋白CseE相互作用机制进行探索研究,重点分析CseE突变体影响与SigE结合能力的机制。[方法]本研究选择谷氨酸棒杆菌ATCC 13032来源的SigE和CseE蛋白为研究目标,利用遗传学方法获得过表达的重组谷氨酸棒杆菌,通过RT-qPCR研究SigE调控sigE和cseE的转录情况。同时,利用ITC和His pull-down实验验证ZAS家族的CseE蛋白与Zn²⁺及SigE的结合情况。之后对CseE蛋白进行功能域分析、多序列比对,研究功能域关键氨基酸位点对SigE结合能力的影响。其次对SigE和CseE蛋白进行分子对接和动力学模拟,分析关键氨基酸影响其结合的机制。[结果]谷氨酸棒杆菌SigE调控基因sigE和cseE的转录并且其活性受CseE蛋白控制。CseE蛋白为ZAS家族蛋白,具有Zn²⁺结合能力。CseE_His83A、CseE_cys87A和CseE_cys90A突变体不会影响与SigE的结合能力,而CseE_C87A-C90A和CseE_{His83A-C87A-C90A}突变体与SigE的结合能力略有下降。分子动力学模拟发现SigE-CseE_C87A-C90A和SigE-CseE_{His83A-C87A-C90A}之间的结合能量为-17.23 kcal/mol和-14.06 kcal/mol,分别比未突变体系结合能量降低22.8%及36.9%。[结论]谷氨酸棒杆菌SigE通过聚集RNA聚合酶来调控基因sigE和cseE的表达。CseE蛋白属于ZAS家族,具有Zn²⁺结合能力同时通过与SigE蛋白互作来抑制SigE活性。CseE_C87A-C90A及CseE_{His83A-C87A-C90A}突变体能影响与SigE结合的能力,减弱对SigE活性的控制。本研究产生的三维结构和确定的氨基酸关键位点为后续探索谷氨酸棒杆菌SigE和CseE响应环境压力机制提供了理论基础。     

Two Clip Domain Family of Serine Proteases and a Serine Protease Homolog from the Fall Webworm, Hyphantria cunea; cDNA Cloning and Characterization

Two types of serine proteases and a serine protease homologue cDNAs were isolated from Hyphantria cunea larvae induced immune response due to an injection of a microorganism through RT‐PCR and cDNA library screening, and their characteristics were examined. The isolated cDNAs are composed 2.1 kb, 2.2 kb, and 2.5 kb nucleotide each, which encoded 388, 390, 580 amino acid residues, and were designated as HcPE‐1, HcPE‐2 and HcPE‐3, respectively. They were revealed as serine proteases or a serine protease homologue with the clip domain through a database search. The deduced amino acid sequence comparison showed high homology of 72‐78% among them. Six Cys residues of the N‐terminal clip domain forming the disulfide bond, Cys residues of the catalytic domain, and Cys residues forming inter‐bridge between clip domain and catalytic domain were also well preserved. Three amino acid residues, His, Asp, and Ser, within the active site were perfectly conserved in HcPE‐2 and HcPE‐3, however, His was replaced with Gln¹⁷⁸ in HcPE‐1. The Arg residues (HcPE‐1, Arg¹³²; HcPE‐2, Arg¹³⁴; HcPE‐3, Arg³²⁵) known as the activation sites by proteolytic cleavage were preserved well in all three types of protein. In case of HcPE‐3, three continuous clip‐like domains existed in the N terminal. As the result of phylogenetic analysis, three clip domain family of protein from H. cunea make groups with arthropod proclotting enzyme precursor. Northern blot analysis showed all three genes were induced through an injection of Escherichia coli, but expression patterns were varied.     

Identification of thermostable glyoxalase I in the fission yeast <Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>

Glyoxalase I is a ubiquitous enzyme that detoxifies methylglyoxal, which is derived from glycolysis but inhibits the growth of cells from microorganisms to mammals. Here, the structural gene for glyoxalase I (glo1⁺) from the fission yeast Schizosaccharomyces pombe was identified. Disruption of glo1⁺ enhanced susceptibility to methylglyoxal, while expression of glo1⁺ in a glo1 mutant of Saccharomyces cerevisiae restored tolerance to this aldehyde. The glo1⁺ gene product was purified. The glyoxalase I of S. pombe was a monomeric enzyme with a molecular weight of 34,000 and the k_cat/K_m value for methylglyoxal was 4.3×10⁷ M^–1 min^–1. Treatment of purified enzyme with EDTA in imidazole buffer completely abolished enzyme activity, whereas the EDTA-treated enzyme was reactivated by several divalent metal ions, such as Zn²⁺, Co²⁺, Ni²⁺ and Mn²⁺. The glyoxalase I of S. pombe exhibited fairly high thermal stability, and almost 100% activity was retained after incubating the enzyme at 60°C for 4 h.     

A unique Ni2+ ‐dependent and methylglyoxal‐inducible rice glyoxalase I possesses a single active site and functions in abiotic stress response

The glyoxalase system constitutes the major pathway for the detoxification of metabolically produced cytotoxin methylglyoxal (MG) into a non‐toxic metabolite d ‐lactate. Glyoxalase I (GLY I) is an evolutionarily conserved metalloenzyme requiring divalent metal ions for its activity: Zn²⁺ in the case of eukaryotes or Ni²⁺ for enzymes of prokaryotic origin. Plant GLY I proteins are part of a multimember family; however, not much is known about their physiological function, structure and metal dependency. In this study, we report a unique GLY I (OsGLYI‐11.2) from Oryza sativa (rice) that requires Ni²⁺ for its activity. Its biochemical, structural and functional characterization revealed it to be a monomeric enzyme, possessing a single Ni²⁺ coordination site despite containing two GLY I domains. The requirement of Ni²⁺ as a cofactor by an enzyme involved in cellular detoxification suggests an essential role for this otherwise toxic heavy metal in the stress response. Intriguingly, the expression of OsGLYI‐11.2 was found to be highly substrate inducible, suggesting an important mode of regulation for its cellular levels. Heterologous expression of OsGLYI‐11.2 in Escherichia coli and model plant Nicotiana tabacum (tobacco) resulted in improved adaptation to various abiotic stresses caused by increased scavenging of MG, lower Na⁺/K⁺ ratio and maintenance of reduced glutathione levels. Together, our results suggest interesting links between MG cellular levels, its detoxification by GLY I, and Ni²⁺ – the heavy metal cofactor of OsGLYI‐11.2, in relation to stress response and adaptation in plants.     

Hsp31 Is a Stress Response Chaperone That Intervenes in the Protein Misfolding Process

The Saccharomyces cerevisiae heat shock protein Hsp31 is a stress-inducible homodimeric protein that is involved in diauxic shift reprogramming and has glyoxalase activity. We show that substoichiometric concentrations of Hsp31 can abrogate aggregation of a broad array of substrates in vitro. Hsp31 also modulates the aggregation of α-synuclein (αSyn), a target of the chaperone activity of human DJ-1, an Hsp31 homolog. We demonstrate that Hsp31 is able to suppress the in vitro fibrillization or aggregation of αSyn, citrate synthase and insulin. Chaperone activity was also observed in vivo because constitutive overexpression of Hsp31 reduced the incidence of αSyn cytoplasmic foci, and yeast cells were rescued from αSyn-generated proteotoxicity upon Hsp31 overexpression. Moreover, we showed that Hsp31 protein levels are increased by H₂O₂, in the diauxic phase of normal growth conditions, and in cells under αSyn-mediated proteotoxic stress. We show that Hsp31 chaperone activity and not the methylglyoxalase activity or the autophagy pathway drives the protective effects. We also demonstrate reduced aggregation of the Sup35 prion domain, PrD-Sup35, as visualized by fluorescent protein fusions. In addition, Hsp31 acts on its substrates prior to the formation of large aggregates because Hsp31 does not mutually localize with prion aggregates, and it prevents the formation of detectable in vitro αSyn fibrils. These studies establish that the protective role of Hsp31 against cellular stress is achieved by chaperone activity that intervenes early in the protein misfolding process and is effective on a wide spectrum of substrate proteins, including αSyn and prion proteins.     

Structural, functional, and bioinformatics studies reveal a new snake venom homologue phospholipase A₂ class

Phospholipases A₂ (PLA₂s) are enzymes responsible for membrane disruption through Ca²⁺‐dependent hydrolysis of phospholipids. Lys49‐PLA₂s are well‐characterized homologue PLA₂s that do not show catalytic activity but can exert a pronounced local myotoxic effect. These homologue PLA₂s were first believed to present residual catalytic activity but experiments with a recombinant toxin show they are incapable of catalysis. Herein, we present a new homologue Asp49‐PLA₂ (BthTX‐II) that is also able to exert muscle damage. This toxin was isolated in 1992 and characterized as presenting very low catalytic activity. Interestingly, this myotoxic homologue Asp49‐PLA₂ conserves all the residues responsible for Ca²⁺ coordination and of the catalytic network, features thought to be fundamental for PLA₂ enzymatic activity. Previous crystallographic studies of apo BthTX‐II suggested this toxin could be catalytically inactive since a distortion in the calcium binding loop was observed. In this article, we show BthTX‐II is not catalytic based on an in vitro cell viability assay and time‐lapse experiments on C2C12 myotube cell cultures, X‐ray crystallography and phylogenetic studies. Cell culture experiments show that BthTX‐II is devoid of catalytic activity, as already observed for Lys49‐PLA₂s. Crystallographic studies of the complex BthTX‐II/Ca²⁺ show that the distortion of the calcium binding loop is still present and impairs ion coordination even though Ca²⁺ are found interacting with other regions of the protein. Phylogenetic studies demonstrate that BthTX‐II is more phylogenetically related to Lys49‐PLA₂s than to other Asp49‐PLA₂s, thus allowing Crotalinae subfamily PLA₂s to be classified into two main branches: a catalytic and a myotoxic one. Proteins 2010. © 2010 Wiley‐Liss, Inc.