Your search keyword '"Thiosulfate Sulfurtransferase chemistry"' showing total 224 results

1. Kinetic and thermodynamic investigation of Rhodanese synthesized by enhanced Klebsiella oxytoca JCM 1665 strain: a comparative between the free and immobilized enzyme entrapped in alginate beads.

Author

Itakorode BO, Itakorode DI, Torimiro N, and Okonji RE

Subjects

Kinetics, Enzyme Stability, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Fermentation, Klebsiella oxytoca enzymology, Klebsiella oxytoca genetics, Enzymes, Immobilized chemistry, Enzymes, Immobilized metabolism, Thermodynamics, Alginates chemistry, Thiosulfate Sulfurtransferase metabolism, Thiosulfate Sulfurtransferase chemistry

Abstract

Klebsiella oxytoca JCM 1665 was subjected to extracellular rhodanese production using a submerged fermentation technique. The organism was further engineered for higher cyanide tolerance and rhodanese yield using ethylmethanesulfonate as a mutagen. Mutagenesis resulted in an improved mutant with high cyanide tolerance (100 mM) and rhodanese yield (26.7 ± 0.67 U/mL). This yield was 4.34-fold higher than the wild strain (6.15 ± 0.65 U/mL). At temperatures ranging from 30 to 80 °C, the first-order thermal denaturation constant ( K d ) for free enzyme increases from 0.00818 to 0.0333 min -1 while the immobilized enzyme increases from 0.003 to 0.0204 min -1 . The equivalent half-life reduces from 99 to 21 minutes and 231 to 35 minutes, respectively. Residual activity tests were used to assess the thermodynamic parameters for both enzyme preparations. For the free enzyme, the parameters obtained were enthalpy (29.40 to 29.06 kJ.mol -1 ), entropy (-194.24 to -197.50 J.mol -1 K -1 ) and Gibbs free energy (90.20 to 98.80 kJ.mol -1 ). In addition, for immobilized rhodanese, we obtained enthalpy (40.40 to 40.07 kJ.mol -1 ), entropy (-164.21 to - 165.20 J.mol -1 K -1 ) and Gibbs free energy (91.80 to 98.40 kJ.mol -1 . Regarding its operational stability, the enzyme was able to maintain 63% of its activity after being used for five cycles. Immobilized K. oxytoca rhodanese showed a marked resistance to heat inactivation compared to free enzyme forms; making it of utmost significance in many biotechnological applications.

Published

2024

2. Physicochemical and thermodynamic properties of purified rhodanese from A. welwitschiae LOT1 and the cyanide detoxification potential of the enzyme.

Author

Lawal OT and Sanni DM

Subjects

Hydrogen-Ion Concentration, Kinetics, Substrate Specificity, Temperature, Fungal Proteins metabolism, Fungal Proteins chemistry, Fungal Proteins isolation & purification, Fermentation, Cyanides metabolism, Thiosulfate Sulfurtransferase metabolism, Thiosulfate Sulfurtransferase chemistry, Biodegradation, Environmental, Enzyme Stability, Thermodynamics, Aspergillus enzymology, Aspergillus metabolism

Abstract

Rhodanese, the primary cyanide-detoxifying enzyme, plays a crucial role in mitigating the harmful effects of cyanide present in various industrial waste materials, such as battery manufacturing effluents. The bioremediation of cyanide-contaminated environments relies on efficient detoxification mechanisms, making rhodanese a valuable enzyme for biotechnological applications. This research aimed to investigate the biochemical properties of purified rhodanese produced by Aspergillus welwitschiae LOT1, a fungal strain with promising cyanide detoxification capabilities. The purified rhodanese was obtained through fermentation, precipitation, and chromatographic separations, resulting in a homogeneous band of approximately 58 kDa with a specific activity of 374 RU/mg, 28-fold purification, and 14% recovery. The enzyme exhibited optimal cyanide detoxification at pH 7 and 60 °C, with stability observed between 30 and 50 °C and pH 8-10. All metal ions examined except for Cu 2+ enhanced the cyanide-degrading ability of rhodanese. Notably, the enzyme demonstrated a high substrate preference for Na 2 S 2 O 3 and followed a first-order kinetic model and free energy, ΔG of 61.3 kJ/mol, making it a promising candidate for biotechnological applications. Overall, this study provides valuable insights into the biochemical properties of rhodanese from A. welwitschiae LOT1, highlighting its potential for efficient cyanide detoxification and bioremediation., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

3. Structural and biochemical characterization of an encapsulin-associated rhodanese from Acinetobacter baumannii.

Author

Benisch R and Giessen TW

Subjects

Crystallography, X-Ray, Models, Molecular, Acinetobacter baumannii enzymology, Acinetobacter baumannii chemistry, Acinetobacter baumannii metabolism, Acinetobacter baumannii genetics, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins genetics

Abstract

Rhodanese-like domains (RLDs) represent a widespread protein family canonically involved in sulfur transfer reactions between diverse donor and acceptor molecules. RLDs mediate these transsulfuration reactions via a transient persulfide intermediate, created by modifying a conserved cysteine residue in their active sites. RLDs are involved in various aspects of sulfur metabolism, including sulfide oxidation in mitochondria, iron-sulfur cluster biogenesis, and thio-cofactor biosynthesis. However, due to the inherent complexity of sulfur metabolism caused by the intrinsically high nucleophilicity and redox sensitivity of thiol-containing compounds, the physiological functions of many RLDs remain to be explored. Here, we focus on a single domain Acinetobacter baumannii RLD (Ab-RLD) associated with a desulfurase encapsulin which is able to store substantial amounts of sulfur inside its protein shell. We determine the 1.6 Å x-ray crystal structure of Ab-RLD, highlighting a homodimeric structure with a number of unusual features. We show through kinetic analysis that Ab-RLD exhibits thiosulfate sulfurtransferase activity with both cyanide and glutathione acceptors. Using native mass spectrometry and in vitro assays, we provide evidence that Ab-RLD can stably carry a persulfide and thiosulfate modification and may employ a ternary catalytic mechanism. Our results will inform future studies aimed at investigating the functional link between Ab-RLD and the desulfurase encapsulin., (© 2024 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published

2024

4. Acidity of persulfides and its modulation by the protein environments in sulfide quinone oxidoreductase and thiosulfate sulfurtransferase.

Author

Benchoam D, Cuevasanta E, Roman JV, Banerjee R, and Alvarez B

Subjects

Humans, Bridged Bicyclo Compounds, Hydrogen Sulfide metabolism, Hydrogen Sulfide chemistry, Hydrogen-Ion Concentration, Oxidation-Reduction, Quinone Reductases metabolism, Quinone Reductases chemistry, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Quinones chemistry, Quinones metabolism, Substrate Specificity, Sulfides chemistry, Sulfides metabolism, Thiosulfate Sulfurtransferase metabolism, Thiosulfate Sulfurtransferase chemistry

Abstract

Persulfides (RSSH/RSS - ) participate in sulfur metabolism and are proposed to transduce hydrogen sulfide (H 2 S) signaling. Their biochemical properties are poorly understood. Herein, we studied the acidity and nucleophilicity of several low molecular weight persulfides using the alkylating agent, monobromobimane. The different persulfides presented similar pK a values (4.6-6.3) and pH-independent rate constants (3.2-9.0 × 10 3  M -1  s -1 ), indicating that the substituents in persulfides affect properties to a lesser extent than in thiols because of the larger distance to the outer sulfur. The persulfides had higher reactivity with monobromobimane than analogous thiols and putative thiols with the same pK a , providing evidence for the alpha effect (enhanced nucleophilicity by the presence of a contiguous atom with high electron density). Additionally, we investigated two enzymes from the human mitochondrial H 2 S oxidation pathway that form catalytic persulfide intermediates, sulfide quinone oxidoreductase and thiosulfate sulfurtransferase (TST, rhodanese). The pH dependence of the activities of both enzymes was measured using sulfite and/or cyanide as sulfur acceptors. The TST half-reactions were also studied by stopped-flow fluorescence spectroscopy. Both persulfidated enzymes relied on protonated groups for reaction with the acceptors. Persulfidated sulfide quinone oxidoreductase appeared to have a pK a of 7.8 ± 0.2. Persulfidated TST presented a pK a of 9.38 ± 0.04, probably due to a critical active site residue rather than the persulfide itself. The TST thiol reacted in the anionic state with thiosulfate, with an apparent pK a  of 6.5 ± 0.1. Overall, our study contributes to a fundamental understanding of persulfide properties and their modulation by protein environments., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

5. Identification and characterization of a small molecule that activates thiosulfate sulfurtransferase and stimulates mitochondrial respiration.

Author

Al-Dahmani ZM, Hadian M, Ruiz-Moreno AJ, Maria SA, Batista FA, Zhang R, Luo Y, Sadremomtaz A, van der Straat R, Spoor M, Dolga AM, Dekker FJ, S S AD, van Goor H, and Groves MR

Subjects

Mice, Humans, Animals, Molecular Docking Simulation, Kinetics, Mitochondria metabolism, Respiration, Obesity metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism, Diabetes Mellitus metabolism

Abstract

The enzyme Thiosulfate sulfurtransferase (TST, EC 2.8.1.1), is a positive genetic predictor of diabetes type 2 and obesity. As increased TST activity protects against the development of diabetic symptoms in mice, an activating compound for TST may provide therapeutic benefits in diabetes and obesity. We identified a small molecule activator of human TST through screening of an inhouse small molecule library. Kinetic studies in vitro suggest that two distinct isomers of the compound are required for full activation as well as an allosteric mode of activation. Additionally, we studied the effect of TST protein and the activator on TST activity through mitochondrial respiration. Molecular docking and molecular dynamics (MD) approaches supports an allosteric site for the binding of the activator, which is supported by the lack of activation in the Escherichia coli. mercaptopyruvate sulfurtransferase. Finally, we show that increasing TST activity in isolated mitochondria increases mitochondrial oxygen consumption., (© 2023 The Authors. Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published

2023

6. A subclass of archaeal U8-tRNA sulfurases requires a [4Fe-4S] cluster for catalysis.

Author

He N, Zhou J, Bimai O, Oltmanns J, Ravanat JL, Velours C, Schünemann V, Fontecave M, and Golinelli-Pimpaneau B

Subjects

Catalysis, Amino Acid Motifs, Mutagenesis, Protein Domains, Bacterial Proteins genetics, Bacterial Proteins metabolism, Archaeal Proteins genetics, Archaeal Proteins metabolism, Archaea enzymology, Archaea genetics, Cysteine metabolism, Iron-Sulfur Proteins metabolism, RNA, Transfer metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism

Abstract

Sulfuration of uridine 8, in bacterial and archaeal tRNAs, is catalyzed by enzymes formerly known as ThiI, but renamed here TtuI. Two different classes of TtuI proteins, which possess a PP-loop-containing pyrophosphatase domain that includes a conserved cysteine important for catalysis, have been identified. The first class, as exemplified by the prototypic Escherichia coli enzyme, possesses an additional C-terminal rhodanese domain harboring a second cysteine, which serves to form a catalytic persulfide. Among the second class of TtuI proteins that do not possess the rhodanese domain, some archaeal proteins display a conserved CXXC + C motif. We report here spectroscopic and enzymatic studies showing that TtuI from Methanococcus maripaludis and Pyrococcus furiosus can assemble a [4Fe-4S] cluster that is essential for tRNA sulfuration activity. Moreover, structural modeling studies, together with previously reported mutagenesis experiments of M. maripaludis TtuI, indicate that the [4Fe-4S] cluster is coordinated by the three cysteines of the CXXC + C motif. Altogether, our results raise a novel mechanism for U8-tRNA sulfuration, in which the cluster is proposed to catalyze the transfer of sulfur atoms to the activated tRNA substrate., (© The Author(s) 2022. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2022

7. Thiosulfate-Cyanide Sulfurtransferase a Mitochondrial Essential Enzyme: From Cell Metabolism to the Biotechnological Applications.

Author

Buonvino S, Arciero I, and Melino S

Subjects

Cyanides metabolism, Mitochondria metabolism, Sulfur metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism, Thiosulfates metabolism

Abstract

Thiosulfate: cyanide sulfurtransferase (TST), also named rhodanese, is an enzyme widely distributed in both prokaryotes and eukaryotes, where it plays a relevant role in mitochondrial function. TST enzyme is involved in several biochemical processes such as: cyanide detoxification, the transport of sulfur and selenium in biologically available forms, the restoration of iron-sulfur clusters, redox system maintenance and the mitochondrial import of 5S rRNA. Recently, the relevance of TST in metabolic diseases, such as diabetes, has been highlighted, opening the way for research on important aspects of sulfur metabolism in diabetes. This review underlines the structural and functional characteristics of TST, describing the physiological role and biomedical and biotechnological applications of this essential enzyme.

Published

2022

8. Urm1: A Non-Canonical UBL.

Author

Termathe M and Leidel SA

Subjects

Gene Expression Regulation, Fungal, Genes, Fungal, Homeostasis, Phenotype, RNA, Transfer metabolism, Stress, Physiological, Sulfurtransferases genetics, Thiosulfate Sulfurtransferase chemistry, Ubiquitin chemistry, Ubiquitin metabolism, Ubiquitins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Small Ubiquitin-Related Modifier Proteins chemistry

Abstract

Urm1 (ubiquitin related modifier 1) is a molecular fossil in the class of ubiquitin-like proteins (UBLs). It encompasses characteristics of classical UBLs, such as ubiquitin or SUMO (small ubiquitin-related modifier), but also of bacterial sulfur-carrier proteins (SCP). Since its main function is to modify tRNA, Urm1 acts in a non-canonical manner. Uba4, the activating enzyme of Urm1, contains two domains: a classical E1-like domain (AD), which activates Urm1, and a rhodanese homology domain (RHD). This sulfurtransferase domain catalyzes the formation of a C-terminal thiocarboxylate on Urm1. Thiocarboxylated Urm1 is the sulfur donor for 5-methoxycarbonylmethyl-2-thiouridine (mcm 5 s 2 U), a chemical nucleotide modification at the wobble position in tRNA. This thio-modification is conserved in all domains of life and optimizes translation. The absence of Urm1 increases stress sensitivity in yeast triggered by defects in protein homeostasis, a hallmark of neurological defects in higher organisms. In contrast, elevated levels of tRNA modifying enzymes promote the appearance of certain types of cancer and the formation of metastasis. Here, we summarize recent findings on the unique features that place Urm1 at the intersection of UBL and SCP and make Urm1 an excellent model for studying the evolution of protein conjugation and sulfur-carrier systems.

Published

2021

9. Biodegradation of cyanide in cassava wastewater using a novel thermodynamically-stable immobilized rhodanese.

Author

Ademakinwa AN, Agunbiade MO, and Fagbohun O

Subjects

Biodegradation, Environmental, Enzyme Stability, Hydrogen-Ion Concentration, Ascomycota enzymology, Cyanides chemistry, Enzymes, Immobilized chemistry, Fungal Proteins chemistry, Manihot chemistry, Thiosulfate Sulfurtransferase chemistry, Wastewater chemistry

Abstract

Extracellular rhodanese obtained from Aureobasidium pullulans was employed in both free and immobilized forms for the biodegradation of cyanide present in cassava processing mill effluent ( CPME ). Crosslinking with glutaraldehyde (at an optimum concentration of 5% v/v) before entrapment in alginate beads resulted in the highest immobilization yield of 94.5% and reduced enzyme leakage of 1.8%. Rhodanese immobilized by cross-linking before entrapment ( cbe) retained about 46% of its initial activity after eight cycles of catalysis compared to the entrapment in alginate alone ( eaa ) which lost more than 79% after the fifth catalytic cycle. A cross-examination of thermodynamic ( Δ G d * , Δ S d * ,   Δ H d * ) kinetic ( k d ,   t 1 / 2 ,   D   and   z - values ) parameters at 30-70 °C showed that cbe displayed a higher resistance to thermal inactivation when compared to the free enzyme ( fe ) and ( eaa ). The efficiency of cyanide biodegradation from the CPME by the fe, eaa and cbe were 55, 62, and 74% respectively after 6 h. Rhodanese immobilized via cbe had a higher resistance to thermal denaturation over other enzyme forms. Hence, this makes cbe adaptable for large-scale detoxification of cyanide from CPME.

Published

2021

10. MdRDH1, a HSP67B2-like rhodanese homologue plays a positive role in maintaining redox balance in Musca domestica.

Author

Tang T, Sun H, Li Y, Chen P, and Liu F

Subjects

Amino Acid Sequence, Animals, Doxorubicin pharmacology, Houseflies microbiology, Organ Specificity, Oxidation-Reduction, Oxidative Stress drug effects, Phylogeny, RNA, Messenger genetics, RNA, Messenger metabolism, Sequence Analysis, Protein, Superoxide Dismutase metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Houseflies enzymology, Insect Proteins metabolism, Thiosulfate Sulfurtransferase metabolism

Abstract

Rhodanese homology domains (RHODs) are the structural modules of ubiquitous tertiary that occur in three major evolutionary phyla. Despite the versatile and important physiological functions of RHODs containing proteins, little is known about their invertebrate counterparts. A novel HSP67B2-like single-domain rhodanese homologue, MdRDH1 from Musca domestica, whose expression can be induced by bacterial infection or oxidative stress. Silencing MdRDH1 through RNAi causes important accumulations of reactive oxygen species (ROS) and malondialdehyde (MDA), and increases mortality in the larvae treated with bacterial invasion. The E. coli with MdRDH1 and the mutant MdRDH1 C135A are transformed, with significant rhodanese activity of the recombinant protein of MdRDH1 in vitro found, without no detection of enzyme activity of the mutant MdRDH1 C135A , revealing that catalytic Cys135 in the active-site loop is essential in the sulfurtransferase activity of MdRDH1. When oxidative stress is insulted by phenazine methosulfate (PMS), the MdRDH1 transformed E. coli shows enhanced survival rates compared with those bacteria transformed with MdRDH1 C135A . Our research indicates that MdRDH1 confers oxidative stress tolerance, thus rendering evidence for the idea that rhodanese family genes play a critical role in antioxidant defenses. This paper yields novel insights into the potential antioxidative and immune functions of HSP67B2-like rhodanese homologues in invertebrate., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

11. Molecular identification and characterization of rhodaneses from the insect herbivore Pieris rapae.

Author

Steiner AM, Busching C, Vogel H, and Wittstock U

Subjects

Animals, Butterflies growth & development, Cyanides metabolism, Glucosinolates metabolism, Herbivory, Insect Proteins chemistry, Insect Proteins classification, Insect Proteins genetics, Kinetics, Larva metabolism, Phylogeny, Sequence Analysis, RNA, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase classification, Thiosulfate Sulfurtransferase genetics, Butterflies metabolism, Insect Proteins metabolism, Thiosulfate Sulfurtransferase metabolism

Abstract

The association of cabbage white butterflies (Pieris spec., Lepidoptera: Pieridae) with their glucosinolate-containing host plants represents a well-investigated example of the sequential evolution of plant defenses and insect herbivore counteradaptations. The defensive potential of glucosinolates, a group of amino acid-derived thioglucosides present in plants of the Brassicales order, arises mainly from their rapid breakdown upon tissue disruption resulting in formation of toxic isothiocyanates. Larvae of P. rapae are able to feed exclusively on glucosinolate-containing plants due to expression of a nitrile-specifier protein in their gut which redirects glucosinolate breakdown to the formation of nitriles. The release of equimolar amounts of cyanide upon further metabolism of the benzylglucosinolate-derived nitrile suggests that the larvae are also equipped with efficient means of cyanide detoxification such as β-cyanoalanine synthases or rhodaneses. While insect β-cyanoalanine synthases have recently been identified at the molecular level, no sequence information was available of characterized insect rhodaneses. Here, we identify and characterize two single-domain rhodaneses from P. rapae, PrTST1 and PrTST2. The enzymes differ in their kinetic properties, predicted subcellular localization and expression in P. rapae indicating different physiological roles. Phylogenetic analysis together with putative lepidopteran rhodanese sequences indicates an expansion of the rhodanese family in Pieridae.

Published

2018

12. Thiosulfate sulfurtransferase-like domain-containing 1 protein interacts with thioredoxin.

Author

Libiad M, Motl N, Akey DL, Sakamoto N, Fearon ER, Smith JL, and Banerjee R

Subjects

Amino Acid Substitution, Animals, Biocatalysis, Catalytic Domain, Colon enzymology, Colon metabolism, Colon pathology, Colorectal Neoplasms enzymology, Colorectal Neoplasms metabolism, Colorectal Neoplasms pathology, Crystallography, X-Ray, Databases, Protein, Humans, Intestinal Mucosa enzymology, Intestinal Mucosa metabolism, Intestinal Mucosa pathology, Mutation, Neoplasm Proteins chemistry, Neoplasm Proteins genetics, Protein Conformation, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Substrate Specificity, Thioredoxin-Disulfide Reductase chemistry, Thioredoxins chemistry, Thioredoxins genetics, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Models, Molecular, NADP metabolism, Neoplasm Proteins metabolism, Thioredoxin-Disulfide Reductase metabolism, Thioredoxins metabolism, Thiosulfate Sulfurtransferase metabolism

Abstract

Rhodanese domains are structural modules present in the sulfurtransferase superfamily. These domains can exist as single units, in tandem repeats, or fused to domains with other activities. Despite their prevalence across species, the specific physiological roles of most sulfurtransferases are not known. Mammalian rhodanese and mercaptopyruvate sulfurtransferase are perhaps the best-studied members of this protein superfamily and are involved in hydrogen sulfide metabolism. The relatively unstudied human thiosulfate sulfurtransferase-like domain-containing 1 (TSTD1) protein, a single-domain cytoplasmic sulfurtransferase, was also postulated to play a role in the sulfide oxidation pathway using thiosulfate to form glutathione persulfide, for subsequent processing in the mitochondrial matrix. Prior kinetic analysis of TSTD1 was performed at pH 9.2, raising questions about relevance and the proposed model for TSTD1 function. In this study, we report a 1.04 Å resolution crystal structure of human TSTD1, which displays an exposed active site that is distinct from that of rhodanese and mercaptopyruvate sulfurtransferase. Kinetic studies with a combination of sulfur donors and acceptors reveal that TSTD1 exhibits a low K m for thioredoxin as a sulfane sulfur acceptor and that it utilizes thiosulfate inefficiently as a sulfur donor. The active site exposure and its interaction with thioredoxin suggest that TSTD1 might play a role in sulfide-based signaling. The apical localization of TSTD1 in human colonic crypts, which interfaces with sulfide-releasing microbes, and the overexpression of TSTD1 in colon cancer provide potentially intriguing clues as to its role in sulfide metabolism., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

13. HSP60 possesses a GTPase activity and mediates protein folding with HSP10.

Author

Okamoto T, Yamamoto H, Kudo I, Matsumoto K, Odaka M, Grave E, and Itoh H

Subjects

Adenosine Triphosphate metabolism, Allosteric Regulation, Animals, Binding Sites, Chaperonin 10 chemistry, Chaperonin 10 genetics, Chaperonin 60 genetics, Computer Simulation, GTP Phosphohydrolases metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Guanosine Triphosphate metabolism, Models, Molecular, Molecular Chaperones metabolism, Protein Folding, Protein Multimerization, Sus scrofa, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, Chaperonin 10 metabolism, Chaperonin 60 chemistry, Chaperonin 60 metabolism

Abstract

The mammalian molecular chaperone, HSP60, plays an essential role in protein homeostasis through mediating protein folding and assembly. The structure and ATP-dependent function of HSP60 has been well established in recent studies. After ATP, GTP is the major cellular nucleotide. In this paper, we have investigated the role of GTP in the activity of HSP60. It was found that HSP60 has different properties with respect to allostery, complex formation and protein folding activity depending on the nucleoside triphosphate present. The presence of GTP slightly affected the ATPase activity of HSP60 during protein folding. These results provide clues as to the functional mechanism of the HSP60-HSP10 complex.

Published

2017

14. Structural and biochemical analyses indicate that a bacterial persulfide dioxygenase-rhodanese fusion protein functions in sulfur assimilation.

Author

Motl N, Skiba MA, Kabil O, Smith JL, and Banerjee R

Subjects

Amino Acid Substitution, Apoenzymes chemistry, Apoenzymes genetics, Apoenzymes metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Biocatalysis, Catalytic Domain, Computational Biology, Crystallography, X-Ray, Cysteine chemistry, Disulfides metabolism, Enzyme Stability, Glutathione analogs & derivatives, Glutathione chemistry, Glutathione metabolism, Hydrogen Sulfide metabolism, Mutant Chimeric Proteins chemistry, Mutant Chimeric Proteins genetics, Mutation, Peptide Fragments chemistry, Peptide Fragments genetics, Peptide Fragments metabolism, Protein Conformation, Quinone Reductases chemistry, Quinone Reductases genetics, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Thiosulfates metabolism, Bacterial Proteins metabolism, Burkholderiaceae enzymology, Models, Molecular, Mutant Chimeric Proteins metabolism, Quinone Reductases metabolism, Thiosulfate Sulfurtransferase metabolism

Abstract

Hydrogen sulfide (H 2 S) is a signaling molecule that is toxic at elevated concentrations. In eukaryotes, it is cleared via a mitochondrial sulfide oxidation pathway, which comprises sulfide quinone oxidoreductase, persulfide dioxygenase (PDO), rhodanese, and sulfite oxidase and converts H 2 S to thiosulfate and sulfate. Natural fusions between the non-heme iron containing PDO and rhodanese, a thiol sulfurtransferase, exist in some bacteria. However, little is known about the role of the PDO-rhodanese fusion (PRF) proteins in sulfur metabolism. Herein, we report the kinetic properties and the crystal structure of a PRF from the Gram-negative endophytic bacterium Burkholderia phytofirmans The crystal structures of wild-type PRF and a sulfurtransferase-inactivated C314S mutant with and without glutathione were determined at 1.8, 2.4, and 2.7 Å resolution, respectively. We found that the two active sites are distant and do not show evidence of direct communication. The B. phytofirmans PRF exhibited robust PDO activity and preferentially catalyzed sulfur transfer in the direction of thiosulfate to sulfite and glutathione persulfide; sulfur transfer in the reverse direction was detectable only under limited turnover conditions. Together with the kinetic data, our bioinformatics analysis reveals that B. phytofirmans PRF is poised to metabolize thiosulfate to sulfite in a sulfur assimilation pathway rather than in sulfide stress response as seen, for example, with the Staphylococcus aureus PRF or sulfide oxidation and disposal as observed with the homologous mammalian proteins., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

15. S-Nitrosylation Induces Structural and Dynamical Changes in a Rhodanese Family Protein.

Author

Eichmann C, Tzitzilonis C, Nakamura T, Kwiatkowski W, Maslennikov I, Choe S, Lipton SA, and Riek R

Subjects

Catalytic Domain, Crystallography, X-Ray, Cysteine metabolism, Magnetic Resonance Spectroscopy, Mass Spectrometry, Models, Molecular, Protein Conformation, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Protein Processing, Post-Translational, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism

Abstract

S-Nitrosylation is well established as an important post-translational regulator in protein function and signaling. However, relatively little is known about its structural and dynamical consequences. We have investigated the effects of S-nitrosylation on the rhodanese domain of the Escherichia coli integral membrane protein YgaP by NMR, X-ray crystallography, and mass spectrometry. The results show that the active cysteine in the rhodanese domain of YgaP is subjected to two competing modifications: S-nitrosylation and S-sulfhydration, which are naturally occurring in vivo. It has been observed that in addition to inhibition of the sulfur transfer activity, S-nitrosylation of the active site residue Cys63 causes an increase in slow motion and a displacement of helix 5 due to a weakening of the interaction between the active site and the helix dipole. These findings provide an example of how nitrosative stress can exert action at the atomic level., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

16. Rhodanese incorporated in Langmuir and Langmuir-Blodgett films of dimyristoylphosphatidic acid: Physical chemical properties and improvement of the enzyme activity.

Author

de Araújo FT and Caseli L

Subjects

Adsorption, Biosensing Techniques methods, Enzyme Assays, Enzymes, Immobilized chemistry, Kinetics, Microscopy, Atomic Force, Spectrometry, Fluorescence, Spectrophotometry, Infrared, Surface Properties, Thermodynamics, Thiosulfate Sulfurtransferase chemistry, Unilamellar Liposomes chemistry, Water chemistry, Enzymes, Immobilized metabolism, Glycerophospholipids chemistry, Thiosulfate Sulfurtransferase metabolism, Unilamellar Liposomes metabolism

Abstract

Preserving the catalytic activity of enzymes immobilized in bioelectronics devices is essential for optimal performance in biosensors. Therefore, ultrathin films in which the architecture can be controlled at the molecular level are of interest. In this work, the enzyme rhodanese was adsorbed onto Langmuir monolayers of the phospholipid dimyristoylphosphatidic acid and characterized by surface pressure-area isotherms, polarization-modulated infrared reflection-absorption spectroscopy (PM-IRRAS), and Brewster angle microscopy (BAM). The incorporation of the enzyme (5% in mol) in the lipid monolayer expanded the film, providing small surface domains, as visualized by BAM. Also, amide bands could be identified in the PM-IRRAS spectra, confirming the presence of the enzyme at the air-water interface. Structuring of the enzyme into α-helices was identified in the mixed monolayer and was preserved when the film was transferred from the liquid interface to solids supports as Langmuir-Blodgett (LB) films. The enzyme-lipid LB films were then characterized by fluorescence spectroscopy, PM-IRRAS, and atomic force microscopy. Measurements of the catalytic activity towards cyanide showed that the enzyme accommodated in the LB films preserved more than 87% of the enzyme activity in relation to the homogeneous medium. After 1 month, the enzyme in the LB film maintained 85% of the activity in contrast to the homogeneous medium, which 24% of the enzyme activity was kept. The method presented in this work not only points to an enhanced catalytic activity toward cyanide, but also may explain why certain film architectures exhibit an improved performance., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

17. Productive folding of a tethered protein in the chaperonin GroEL-GroES cage.

Author

Motojima F and Yoshida M

Subjects

Animals, Cattle, Chaperonin 10 chemistry, Chaperonin 60 chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Models, Molecular, Peptides chemistry, Peptides metabolism, Thiosulfate Sulfurtransferase chemistry, Chaperonin 10 metabolism, Chaperonin 60 metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Protein Folding, Thiosulfate Sulfurtransferase metabolism

Abstract

Many proteins in bacterial cells fold in the chaperonin cage made of the central cavity of GroEL capped by GroES. Recent studies indicate that the polypeptide in the cage spends the most time as a state tethered dynamically to the GroEL/GroES interface region, in which folding occurs in the polypeptide segments away from the tethered site (F. Motojima & M. Yoshida, EMBO J. (2010) 29, 4008-4019). In support of this, we show here that a polypeptide in the cage tethered covalently to an appropriate site in the GroEL/GroES interface region can fold to a near-native structure., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

18. Staphylococcus aureus CstB Is a Novel Multidomain Persulfide Dioxygenase-Sulfurtransferase Involved in Hydrogen Sulfide Detoxification.

Author

Shen J, Keithly ME, Armstrong RN, Higgins KA, Edmonds KA, and Giedroc DP

Subjects

Bacterial Proteins physiology, Hydrogen Sulfide pharmacology, Kinetics, Thiosulfate Sulfurtransferase physiology, Thiosulfates chemistry, Thiosulfates metabolism, Bacterial Proteins chemistry, Hydrogen Sulfide metabolism, Staphylococcus aureus enzymology, Thiosulfate Sulfurtransferase chemistry

Abstract

Hydrogen sulfide (H2S) is both a lethal gas and an emerging gasotransmitter in humans, suggesting that the cellular H2S level must be tightly regulated. CstB is encoded by the cst operon of the major human pathogen Staphylococcus aureus and is under the transcriptional control of the persulfide sensor CstR and H2S. Here, we show that CstB is a multifunctional Fe(II)-containing persulfide dioxygenase (PDO), analogous to the vertebrate protein ETHE1 (ethylmalonic encephalopathy protein 1). Chromosomal deletion of ethe1 is fatal in vertebrates. In the presence of molecular oxygen (O2), hETHE1 oxidizes glutathione persulfide (GSSH) to generate sulfite and reduced glutathione. In contrast, CstB oxidizes major cellular low molecular weight (LMW) persulfide substrates from S. aureus, coenzyme A persulfide (CoASSH) and bacillithiol persulfide (BSSH), directly to generate thiosulfate (TS) and reduced thiols, thereby avoiding the cellular toxicity of sulfite. Both Cys201 in the N-terminal PDO domain (CstB(PDO)) and Cys408 in the C-terminal rhodanese domain (CstB(Rhod)) strongly enhance the TS generating activity of CstB. CstB also possesses persulfide transferase (PT; reverse rhodanese) activity, which generates TS when provided with LMW persulfides and sulfite, as well as conventional thiosulfate transferase (TST; rhodanese) activity; both of these activities require Cys408. CstB protects S. aureus against H2S toxicity, with the C201S and C408S cstB genes being unable to rescue a NaHS-induced ΔcstB growth phenotype. Induction of the cst operon by NaHS reveals that functional CstB impacts cellular TS concentrations. These data collectively suggest that CstB may have evolved to facilitate the clearance of LMW persulfides that occur upon elevation of the level of cellular H2S and hence may have an impact on bacterial viability under H2S misregulation, in concert with the other enzymes encoded by the cst operon.

Published

2015

19. Crystallization and preliminary X-ray analysis of Rv1674c from Mycobacterium tuberculosis.

Author

Li J, Wang X, Gong W, Niu C, and Zhang M

Subjects

Bacterial Proteins isolation & purification, Catalytic Domain, Chromatography, Affinity, Crystallization, Crystallography, X-Ray, Thiosulfate Sulfurtransferase isolation & purification, Bacterial Proteins chemistry, Mycobacterium tuberculosis enzymology, Thiosulfate Sulfurtransferase chemistry

Abstract

Adaptations to hypoxia play an important role in Mycobacterium tuberculosis pathogenesis. Rv0324, which contains an HTH DNA-binding domain and a rhodanese domain, is one of the key transcription regulators in response to hypoxia. M. tuberculosis Rv1674c is a homologue of Rv0324. To understand the interdomain interaction and regulation of the HTH domain and the rhodanese domain, recombinant Rv1674c protein was purified and crystallized by the vapour-diffusion method. The crystals diffracted to 2.25 Å resolution. Preliminary diffraction analysis suggests that the crystals belonged to space group P3121 or P3221, with unit-cell parameters a = b = 67.8, c = 174.5 Å, α = β = 90, γ = 120°. The Matthews coefficient was calculated to be 2.44 Å(3) Da(-1), assuming that the crystallographic asymmetric unit contains two protein molecules.

Published

2015

20. Assay methods for H2S biogenesis and catabolism enzymes.

Author

Banerjee R, Chiku T, Kabil O, Libiad M, Motl N, and Yadav PK

Subjects

Animals, Dioxygenases chemistry, Enzyme Assays, Humans, Kinetics, Oxidation-Reduction, Sulfurtransferases chemistry, Thiosulfate Sulfurtransferase chemistry, Cystathionine beta-Synthase chemistry, Cystathionine gamma-Lyase chemistry, Hydrogen Sulfide chemistry

Abstract

H2S is produced from sulfur-containing amino acids, cysteine and homocysteine, or a catabolite, 3-mercaptopyruvate, by three known enzymes: cystathionine β-synthase, γ-cystathionase, and 3-mercaptopyruvate sulfurtransferase. Of these, the first two enzymes reside in the cytoplasm and comprise the transsulfuration pathway, while the third enzyme is found both in the cytoplasm and in the mitochondrion. The following mitochondrial enzymes oxidize H2S: sulfide quinone oxidoreductase, sulfur dioxygenase, rhodanese, and sulfite oxidase. The products of the sulfide oxidation pathway are thiosulfate and sulfate. Assays for enzymes involved in the production and oxidative clearance of sulfide to thiosulfate are described in this chapter., (© 2015 Elsevier Inc. All rights reserved.)

Published

2015

21. Aha1 can act as an autonomous chaperone to prevent aggregation of stressed proteins.

Author

Tripathi V, Darnauer S, Hartwig NR, and Obermann WM

Subjects

Animals, HEK293 Cells, HSP90 Heat-Shock Proteins metabolism, Humans, Luciferases, Firefly chemistry, Macaca mulatta, Mice, Molecular Chaperones chemistry, Protein Binding, Protein Refolding, Proteolysis, Thiosulfate Sulfurtransferase chemistry, Ubiquitination, Molecular Chaperones physiology, Protein Aggregation, Pathological metabolism

Abstract

Aha1 (activator of Hsp90 ATPase) stimulates the ATPase activity of the molecular chaperone Hsp90 to accelerate the conformational cycle during which client proteins attain their final shape. Thereby, Aha1 promotes effective folding of Hsp90-dependent clients such as steroid receptors and many kinases involved in cellular signaling. In our current study, we find that Aha1 plays a novel, additional role beyond regulating the Hsp90 ATP hydrolysis rate. We propose a new concept suggesting that Aha1 acts as an autonomous chaperone and associates with stress-denatured proteins to prevent them from aggregation similar to the chaperonin GroEL. Our study reveals that an N-terminal sequence of 22 amino acids, present in human but absent from yeast Aha1, is critical for this capability. However, in lieu of fostering their refolding, Aha1 allows ubiquitination of bound clients by the E3 ubiquitin ligase CHIP. Accordingly, Aha1 may promote disposal of folding defective proteins by the cellular protein quality control., (© 2014 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2014

22. Organization of the human mitochondrial hydrogen sulfide oxidation pathway.

Author

Libiad M, Yadav PK, Vitvitsky V, Martinov M, and Banerjee R

Subjects

Catalysis, Cysteine chemistry, Cytochromes c chemistry, Escherichia coli enzymology, Glutathione chemistry, Homeostasis, Humans, Hydrogen-Ion Concentration, Kinetics, Oxidation-Reduction, Oxygen chemistry, Spectrophotometry, Ultraviolet, Sulfides chemistry, Thiosulfate Sulfurtransferase chemistry, Hydrogen Sulfide chemistry, Mitochondria metabolism, Quinone Reductases chemistry

Abstract

Sulfide oxidation is expected to play an important role in cellular switching between low steady-state intracellular hydrogen sulfide levels and the higher concentrations where the physiological effects are elicited. Yet despite its significance, fundamental questions regarding how the sulfide oxidation pathway is wired remain unanswered, and competing proposals exist that diverge at the very first step catalyzed by sulfide quinone oxidoreductase (SQR). We demonstrate that, in addition to sulfite, glutathione functions as a persulfide acceptor for human SQR and that rhodanese preferentially synthesizes rather than utilizes thiosulfate. The kinetic behavior of these enzymes provides compelling evidence for the flow of sulfide via SQR to glutathione persulfide, which is then partitioned to thiosulfate or sulfite. Kinetic simulations at physiologically relevant metabolite concentrations provide additional support for the organizational logic of the sulfide oxidation pathway in which glutathione persulfide is the first intermediate formed., (© 2014 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2014

23. Fast conformational exchange between the sulfur-free and persulfide-bound rhodanese domain of E. coli YgaP.

Author

Wang W, Zhou P, He Y, Yu L, Xiong Y, Tian C, and Wu F

Subjects

Cysteine chemistry, Cysteine metabolism, Escherichia coli enzymology, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Gene Expression, Kinetics, Models, Molecular, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Structural Homology, Protein, Substrate Specificity, Sulfides metabolism, Sulfur metabolism, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism, Thiosulfates chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Sulfides chemistry, Sulfur chemistry, Thiosulfate Sulfurtransferase chemistry

Abstract

Rhodanese domains are abundant structural modules that catalyze the transfer of a sulfur atom from thiolsulfates to cyanide via formation of a covalent persulfide intermediate that is bound to an essential conserved cysteine residue. In this study, the three-dimensional structure of the rhodanese domain of YgaP from Escherichia coli was determined using solution NMR. A typical rhodanese domain fold was observed, as expected from the high homology with the catalytic domain of other sulfur transferases. The initial sulfur-transfer step and formation of the rhodanese persulfide intermediate were monitored by addition of sodium thiosulfate using two-dimensional (1)H-(15)N correlation spectroscopy. Discrete sharp signals were observed upon substrate addition, indicting fast exchange between sulfur-free and persulfide-intermediate forms. Residues exhibiting pronounced chemical shift changes were mapped to the structure, and included both substrate binding and surrounding residues., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

24. Solution NMR structure and functional analysis of the integral membrane protein YgaP from Escherichia coli.

Author

Eichmann C, Tzitzilonis C, Bordignon E, Maslennikov I, Choe S, and Riek R

Subjects

Models, Molecular, Protein Conformation, Structure-Activity Relationship, Thiosulfate Sulfurtransferase chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Escherichia coli Proteins physiology, Membrane Proteins chemistry, Membrane Proteins physiology, Nuclear Magnetic Resonance, Biomolecular methods

Abstract

The solution NMR structure of the α-helical integral membrane protein YgaP from Escherichia coli in mixed 1,2-diheptanoyl-sn-glycerol-3-phosphocholine/1-myristoyl-2-hydroxy-sn-glycero-3-phospho-(1'-rac-glycerol) micelles is presented. In these micelles, YgaP forms a homodimer with the two transmembrane helices being the dimer interface, whereas the N-terminal cytoplasmic domain includes a rhodanese-fold in accordance to its sequence homology to the rhodanese family of sulfurtransferases. The enzymatic sulfur transfer activity of full-length YgaP as well as of the N-terminal rhodanese domain only was investigated performing a series of titrations with sodium thiosulfate and potassium cyanide monitored by NMR and EPR. The data indicate the thiosulfate concentration-dependent addition of several sulfur atoms to the catalytic Cys-63, which process can be reversed by the addition of potassium cyanide. The catalytic reaction induces thereby conformational changes within the rhodanese domain, as well as on the transmembrane α-helices of YgaP. These results provide insights into a potential mechanism of YgaP during the catalytic thiosulfate activity in vivo., (© 2014 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2014

25. Natural variation in arsenate tolerance identifies an arsenate reductase in Arabidopsis thaliana.

Author

Sánchez-Bermejo E, Castrillo G, del Llano B, Navarro C, Zarco-Fernández S, Martinez-Herrera DJ, Leo-del Puerto Y, Muñoz R, Cámara C, Paz-Ares J, Alonso-Blanco C, and Leyva A

Subjects

Alleles, Amino Acid Sequence, Arabidopsis drug effects, Arsenites chemistry, Chromosome Mapping, Escherichia coli metabolism, Genetic Complementation Test, Models, Molecular, Molecular Conformation, Molecular Sequence Data, Mutation, Oxygen chemistry, Phenotype, Polymorphism, Genetic, Quantitative Trait Loci, Sequence Homology, Amino Acid, Thiosulfate Sulfurtransferase chemistry, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Arsenate Reductases metabolism, Arsenic chemistry, Gene Expression Regulation, Plant

Abstract

The enormous amount of environmental arsenic was a major factor in determining the biochemistry of incipient life forms early in the Earth's history. The most abundant chemical form in the reducing atmosphere was arsenite, which forced organisms to evolve strategies to manage this chemical species. Following the great oxygenation event, arsenite oxidized to arsenate and the action of arsenate reductases became a central survival requirement. The identity of a biologically relevant arsenate reductase in plants nonetheless continues to be debated. Here we identify a quantitative trait locus that encodes a novel arsenate reductase critical for arsenic tolerance in plants. Functional analyses indicate that several non-additive polymorphisms affect protein structure and account for the natural variation in arsenate reductase activity in Arabidopsis thaliana accessions. This study shows that arsenate reductases are an essential component for natural plant variation in As(V) tolerance.

Published

2014

26. Nuclear magnetic resonance approaches for characterizing interactions between the bacterial chaperonin GroEL and unstructured proteins.

Author

Nishida N, Yagi-Utsumi M, Motojima F, Yoshida M, Shimada I, and Kato K

Subjects

Amino Acid Sequence, Animals, Binding Sites, Cattle, Chaperonin 60 chemistry, Intrinsically Disordered Proteins metabolism, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, alpha-Synuclein chemistry, alpha-Synuclein metabolism, Chaperonin 60 metabolism, Intrinsically Disordered Proteins chemistry

Abstract

GroEL-protein interactions were characterized by stable isotope-assisted nuclear magnetic resonance (NMR) spectroscopy using chemically denatured bovine rhodanese and an intrinsically disordered protein, α-synuclein, as model ligands. NMR data indicated that proteins tethered to GroEL remain largely unfolded and highly mobile, enabling identification of the interaction hot spots displayed on intrinsically disordered proteins., (Copyright © 2013 The Society for Biotechnology, Japan. Published by Elsevier B.V. All rights reserved.)

Published

2013

27. Biophysical characterization of two different stable misfolded monomeric polypeptides that are chaperone-amenable substrates.

Author

Natalello A, Mattoo RU, Priya S, Sharma SK, Goloubinoff P, and Doglia SM

Subjects

Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Biophysical Phenomena, Circular Dichroism, Electrophoresis, Polyacrylamide Gel, HSP70 Heat-Shock Proteins chemistry, HSP70 Heat-Shock Proteins metabolism, Kinetics, Luciferases chemistry, Luciferases metabolism, Models, Molecular, Molecular Chaperones metabolism, Peptides metabolism, Protein Multimerization, Protein Refolding, Protein Stability, Protein Structure, Secondary, Protein Unfolding, Spectroscopy, Fourier Transform Infrared, Substrate Specificity, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, Molecular Chaperones chemistry, Peptides chemistry, Protein Conformation, Protein Folding

Abstract

Misfolded polypeptide monomers may be regarded as the initial species of many protein aggregation pathways, which could accordingly serve as primary targets for molecular chaperones. It is therefore of paramount importance to study the cellular mechanisms that can prevent misfolded monomers from entering the toxic aggregation pathway and moreover rehabilitate them into active proteins. Here, we produced two stable misfolded monomers of luciferase and rhodanese, which we found to be differently processed by the Hsp70 chaperone machinery and whose conformational properties were investigated by biophysical approaches. In spite of their monomeric nature, they displayed enhanced thioflavin T fluorescence, non-native β-sheets, and tertiary structures with surface-accessible hydrophobic patches, but differed in their conformational stability and aggregation propensity. Interestingly, minor structural differences between the two misfolded species could account for their markedly different behavior in chaperone-mediated unfolding/refolding assays. Indeed, only a single DnaK molecule was sufficient to unfold by direct clamping a misfolded luciferase monomer, while, by contrast, several DnaK molecules were necessary to unfold the more resistant misfolded rhodanese monomer by a combination of direct clamping and cooperative entropic pulling., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

28. Effects of interactions with the GroEL cavity on protein folding rates.

Author

Sirur A and Best RB

Subjects

Amino Acid Sequence, Chaperonin 60 metabolism, Kinetics, Molecular Docking Simulation, Molecular Dynamics Simulation, Molecular Sequence Data, Protein Binding, Protein Interaction Domains and Motifs, Protein Structure, Tertiary, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, Chaperonin 60 chemistry, Protein Folding

Abstract

Encapsulation of proteins in chaperonins is an important mechanism by which the cell prevents the accumulation of misfolded species in the cytosol. However, results from theory and simulation for repulsive cavities appear to be inconsistent with recent experimental results showing, if anything, a slowdown in folding rate for encapsulated Rhodanese. We study the folding of Rhodanese in GroEL, using coarse-grained molecular simulations of the complete system including chaperonin and substrate protein. We find that, by approximating the substrate:GroEL interactions as repulsive, we obtain a strong acceleration in rate of between one and two orders of magnitude; a similar result is obtained by representing the chaperonin as a simple spherical cavity. Remarkably, however, we find that using a carefully parameterized, sequence-based potential to capture specific residue-residue interactions between Rhodanese and the GroEL cavity walls induces a very strong reduction of the folding rates. The effect of the interactions is large enough to completely offset the effects of confinement, such that folding in some cases can be even slower than that of the unconfined protein. The origin of the slowdown appears to be stabilization--relative to repulsive confinement--of the unfolded state through binding to the cavity walls, rather than a reduction of the diffusion coefficient along the folding coordinate., (Copyright © 2013 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2013

29. Structural insight into the mode of interactions of SoxL from Allochromatium vinosum in the global sulfur oxidation cycle.

Author

Bagchi A

Subjects

Bacterial Proteins genetics, Catalytic Domain, Chromatiaceae genetics, Hydrogen Bonding, Multigene Family, Oxidation-Reduction, Oxidoreductases Acting on Sulfur Group Donors chemistry, Oxidoreductases Acting on Sulfur Group Donors genetics, Protein Binding, Protein Interaction Domains and Motifs, Protein Structure, Secondary, Structural Homology, Protein, Thiosulfate Sulfurtransferase genetics, Bacterial Proteins chemistry, Chromatiaceae enzymology, Molecular Docking Simulation, Sulfur chemistry, Thiosulfate Sulfurtransferase chemistry

Abstract

Microbial redox reactions of inorganic sulfur compounds are one of the important reactions for the recycling of sulfur to maintain the environmental sulfur balance. These reactions are carried out by phylogenetically diverse microorganisms. The sulfur oxidizing gene cluster (sox) of α-proteobacteria, Allochromatium vinosum comprises two divergently transcribed units. The central players of this process are SoxY, SoxZ and SoxL. SoxY is sulfur compound binder which binds to sulfur anions with the help of SoxZ. SoxL is a rhodanese like protein, which then cleaves off the sulfur substrate from the SoxYZ complex to recycle the SoxY and SoxZ. In the present work, homology modeling has been employed to build the three dimensional structures of SoxY, SoxZ and SoxL. With the help of docking simulations the amino acid residues of these proteins involved in the interactions have been identified. The interactions between the SoxY, SoxZ and SoxL proteins are mediated mainly through hydrogen bonding. Strong positive fields created by the SoxZ and SoxL proteins are found to be responsible for the binding and removal of the sulfur anion. The probable biochemical mechanism of sulfur anion oxidation process has been identified.

Published

2012

30. Crystal structure of the Tum1 protein from the yeast Saccharomyces cerevisiae.

Author

Qiu R, Wang F, Liu M, Lou T, and Ji C

Subjects

Amino Acid Sequence, Binding Sites, Carrier Proteins metabolism, Crystallization, Crystallography, X-Ray, Cysteine chemistry, Molecular Sequence Data, Molecular Structure, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism, Sequence Alignment, Static Electricity, Substrate Specificity, Thiosulfate Sulfurtransferase chemistry, X-Ray Diffraction, Carrier Proteins chemistry, Saccharomyces cerevisiae Proteins chemistry

Abstract

Yeast tRNA-thiouridine modification protein 1 (Tum1) plays essential role in the sulfur transfer process of Urm1 system, which in turn is involved in many important cellular processes. In the rhodanese-like domain (RLD), conserved cysteine residue is proved to be the centre of active site of sulfurtransferases and crucial for the substrate recognition. In this report, we describe the crystal structure of Tum1 protein at 1.90 A resolution which, despite consisting of two RLDs, has only one conserved cysteine residue in the C-terminal RLD. An unaccounted electron density is found near the active site, which might point to the new cofactor in the sulfur transfer mechanism.

Published

2012

31. An unusual tandem-domain rhodanese harbouring two active sites identified in Desulfitobacterium hafniense.

Author

Prat L, Maillard J, Rohrbach-Brandt E, and Holliger C

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Bacterial Proteins metabolism, Catalytic Domain genetics, Desulfitobacterium genetics, Genes, Bacterial, Molecular Sequence Data, Multigene Family, Operon, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Sulfur metabolism, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism, Bacterial Proteins chemistry, Desulfitobacterium enzymology, Thiosulfate Sulfurtransferase chemistry

Abstract

The rhodanese protein domain is common throughout all kingdoms of life and is characterized by an active site cysteine residue that is able to bind sulfane sulfur and catalyse sulfur transfer. No unique function has been attributed to rhodanese-domain-containing proteins, most probably because of their diversity at both the level of sequence and protein domain architecture. In this study, we investigated the biochemical properties of an unusual rhodanese protein, PhsE, from Desulfitobacterium hafniense strain TCE1 which we have previously shown to be massively expressed under anaerobic respiration with tetrachloroethene. The peculiarity of the PhsE protein is its domain architecture which is constituted of two rhodanese domains each with an active site cysteine. The N-terminal rhodanese domain is preceded by a lipoprotein signal peptide anchoring PhsE on the outside of the cytoplasmic membrane. In vitro sulfur-transferase activity of recombinant PhsE variants was measured for both domains contrasting with other tandem-domain rhodaneses in which usually only the C-terminal domain has been found to be active. The genetic context of phsE shows that it is part of a six-gene operon displaying homology with gene clusters encoding respiratory molybdoenzymes of the PhsA/PsrA family, possibly involved in the reduction of sulfur compounds. Our data suggest, however, that the presence of sulfide in the medium is responsible for the high expression of PhsE in Desulfitobacterium, where it could play a role in the sulfur homeostasis of the cell., (© 2012 The Authors Journal compilation © 2012 FEBS.)

Published

2012

32. Chromatographic refolding of rhodanese and lysozyme assisted by the GroEL apical domain, DsbA and DsbC immobilized on cellulose.

Author

Antonio-Pérez A, Ramón-Luing LA, and Ortega-López J

Subjects

Animals, Cattle, Cellulose chemistry, Chaperonin 60 chemistry, Immobilized Proteins chemistry, Oxidoreductases chemistry, Protein Structure, Tertiary, Chromatography methods, Muramidase chemistry, Protein Refolding, Thiosulfate Sulfurtransferase chemistry

Abstract

The Escherichia coli expression system remains the first choice for the production of recombinant proteins when biological activity is not compromised by posttranslational modification. Many strains of E. coli, vectors and culture conditions are available to express recombinant proteins in a soluble and correctly folded conformation. Often these strategies fail, and misfolded recombinant proteins aggregate into inclusion bodies. To recover its biological activity, a recombinant protein must be refolded, a step that has become the major limitation of the E. coli expression system. Chromatographic refolding, assisted by immobilized chaperones and foldases, is an in vitro refolding protocol that significantly improves refolding yields, yet its application at the bioprocess scale has been limited. Therefore, new cost-efficient alternatives to utilize chromatographic refolding assisted by chaperones and foldases might improve the production of biologically active proteins in E. coli. In this work, the GroEL apical domain (AD) and the oxidoreductases DsbA and DsbC fused to a carbohydrate-binding module (CBM) were purified and immobilized on microcrystalline cellulose particles. A column packed with a 60:40 (v/v) mixture of gel filtration media and cellulose particles with immobilized AD significantly improved the chromatographic refolding of rhodanese. A similar column with equimolar amounts of AD, DsbA and DsbC immobilized on cellulose particles significantly improved the oxidative chromatographic refolding of lysozyme. The assisted refolding yields were up to 80% for rhodanese and 100% for lysozyme, compared with 33% and 23%, respectively, obtained in the experiments without immobilized chaperones. In addition, AD, DsbA and DsbC immobilized on cellulose exhibited significant operational stability under the extreme denaturing conditions used in the chromatographic refolding batches. These results suggest that chromatographic refolding assisted by AD, DsbA, and DsbC immobilized on cellulose is suitable for the oxidative refolding of proteins expressed in E. coli as inclusion bodies., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

33. A novel rhodanese is required to maintain chloroplast translation in Chlamydomonas.

Author

Luo L and Herrin DL

Subjects

Amino Acid Sequence, Chlamydomonas reinhardtii growth & development, Chloroplast Proteins antagonists & inhibitors, Chloroplast Proteins chemistry, Chloroplasts genetics, Chloroplasts metabolism, Genes, Plant, Molecular Sequence Data, Plant Proteins antagonists & inhibitors, Plant Proteins chemistry, Protein Biosynthesis, Protein Structure, Tertiary, RNA Interference, RNA, Chloroplast genetics, RNA, Messenger genetics, RNA, Plant genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Thiosulfate Sulfurtransferase antagonists & inhibitors, Thiosulfate Sulfurtransferase chemistry, Chlamydomonas reinhardtii genetics, Chlamydomonas reinhardtii metabolism, Chloroplast Proteins genetics, Chloroplast Proteins metabolism, Plant Proteins genetics, Plant Proteins metabolism, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism

Abstract

Rhodanese-domain proteins (RDPs) are widespread in plants and other organisms, but their biological roles are mostly unknown. Here we report on a novel RDP from Chlamydomonas that has a single rhodanese domain, and a predicted chloroplast transit peptide. The protein was produced in Escherichia coli with a His-tag, but lacking most of the N-terminal transit peptide, and after purification was found to have rhodanese activity in vitro. It was also used to elicit antibodies for western blot analysis, which showed that the native Chlamydomonas protein migrated slower on SDS gels (apparent M(r) =34 kDa) than its predicted size (27 kDa), and co-fractionated with chloroplasts. To assess function in vivo, the tandem-RNAi approach was used to generate Chlamydomonas strains that had reductions of 30-70% for the mRNA and ~20-40% for the 34-kDa protein. These strains showed reduced growth under all trophic conditions, and were sensitive to even moderate light; properties reminiscent of chloroplast translation mutants. Pulse-labeling in the presence of cycloheximide indicated that chloroplast protein synthesis was broadly reduced in the RNAi strains, and transcript analysis (by RT-PCR and northern blotting) indicated the effect was mainly translational. These results identify a novel rhodanese-like protein that we have named CRLT, because it is required to maintain chloroplast translation.

Published

2012

34. Interaction of oxidized chaperonin GroEL with an unfolded protein at low temperatures.

Author

Melkani GC, Sielaff R, Zardeneta G, and Mendoza JA

Subjects

Animals, Cattle, Cold Temperature, Kinetics, Liver enzymology, Oxidation-Reduction, Protein Binding, Protein Denaturation, Urea chemistry, Chaperonin 60 chemistry, Protein Refolding, Thiosulfate Sulfurtransferase chemistry

Abstract

The chaperonin GroEL binds to non-native substrate proteins via hydrophobic interactions, preventing their aggregation, which is minimized at low temperatures. In the present study, we investigated the refolding of urea-denatured rhodanese at low temperatures, in the presence of ox-GroEL (oxidized GroEL), which contains increased exposed hydrophobic surfaces and retains its ability to hydrolyse ATP. We found that ox-GroEL could efficiently bind the urea-unfolded rhodanese at 4°C, without requiring excess amount of chaperonin relative to normal GroEL (i.e. non-oxidized). The release/reactivation of rhodanese from GroEL was minimal at 4°C, but was found to be optimal between 22 and 37°C. It was found that the loss of the ATPase activity of ox-GroEL at 4°C prevented the release of rhodanese from the GroEL-rhodanese complex. Thus ox-GroEL has the potential to efficiently trap recombinant or non-native proteins at 4°C and release them at higher temperatures under appropriate conditions.

Published

2012

35. Selenomodification of tRNA in archaea requires a bipartite rhodanese enzyme.

Author

Su D, Ojo TT, Söll D, and Hohn MJ

Subjects

Amino Acid Sequence, Animals, Archaeal Proteins chemistry, Archaeal Proteins classification, Archaeal Proteins genetics, Ligases chemistry, Ligases classification, Ligases genetics, Ligases metabolism, Methanococcus metabolism, Models, Molecular, Molecular Sequence Data, Organoselenium Compounds chemistry, Phylogeny, Protein Structure, Tertiary, RNA, Transfer classification, RNA, Transfer genetics, Sequence Alignment, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Uridine chemistry, Uridine genetics, Uridine metabolism, Archaeal Proteins metabolism, Methanococcus genetics, Organoselenium Compounds metabolism, RNA, Transfer metabolism, Selenium metabolism, Thiosulfate Sulfurtransferase metabolism, Uridine analogs & derivatives

Abstract

5-Methylaminomethyl-2-selenouridine (mnm(5)Se(2)U) is found in the first position of the anticodon in certain tRNAs from bacteria, archaea and eukaryotes. This selenonucleoside is formed in Escherichia coli from the corresponding thionucleoside mnm(5)S(2)U by the monomeric enzyme YbbB. This nucleoside is present in the tRNA of Methanococcales, yet the corresponding 2-selenouridine synthase is unknown in archaea and eukaryotes. Here we report that a bipartite ybbB ortholog is present in all members of the Methanococcales. Gene deletions in Methanococcus maripaludis and in vitro activity assays confirm that the two proteins act in trans to form in tRNA a selenonucleoside, presumably mnm(5)Se(2)U. Phylogenetic data suggest a primal origin of seleno-modified tRNAs., (Copyright © 2012 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2012

36. Partial purification and characterization of rhodanese from rainbow trout (Oncorhynchus mykiss) liver.

Author

Tayefi-Nasrabadi H and Rahmani R

Subjects

Animals, Enzyme Activation, Enzyme Stability, Oncorhynchus mykiss metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase isolation & purification

Abstract

Cyanide is one of the most toxic substances present in a wide variety of food materials that are consumed by animals. Rhodanese, a ubiquitous enzyme, can catalyse the detoxification of cyanide by sulphuration reaction. In this study, rhodanese was partially purified and characterized from the liver tissue homogenate of the rainbow trout. The enzyme was active in a broad range of pH, from 5 to 12. The optimal activity was found at a high pH (pH 10.5), and the temperature optimum was 25 °C. The enzyme was heat labile, losing > 50% of relative activity after only 5 min of incubation at 40 °C. The K(m) values for KCN and Na(2)S(2)O(3) as substrates were 36.81 mM and 19.84 mM, respectively. Studies on the enzyme with a number of cations showed that the activity of the enzyme was not affected by Sn(2+), but Hg(2+), Ba(2+), Pb(2+), and Ca(2+) inhibited and Cu(2+) activated the enzyme with a concentration-dependent manner.

Published

2012

37. Involvement of the Azotobacter vinelandii rhodanese-like protein RhdA in the glutathione regeneration pathway.

Author

Remelli W, Guerrieri N, Klodmann J, Papenbrock J, Pagani S, and Forlani F

Subjects

Azotobacter vinelandii genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Catalytic Domain, Cysteine chemistry, Cysteine metabolism, Escherichia coli genetics, Free Radicals metabolism, Gene Expression, Kinetics, Lipid Peroxides metabolism, Molecular Docking Simulation, Mutation, Oxidation-Reduction, Oxidative Stress, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase deficiency, Azotobacter vinelandii enzymology, Bacterial Proteins metabolism, Glutathione metabolism, Thiosulfate Sulfurtransferase genetics

Abstract

The phenotypic features of the Azotobacter vinelandii RhdA mutant MV474 (in which the rhdA gene was deleted) indicated that defects in antioxidant systems in this organism were related to the expression of the tandem-domain rhodanese RhdA. In this work, further insights on the effects of the oxidative imbalance generated by the absence of RhdA (e.g. increased levels of lipid hydroperoxides) are provided. Starting from the evidence that glutathione was depleted in MV474, and using both in silico and in vitro approaches, here we studied the interaction of wild-type RhdA and Cys(230)Ala site-directed RhdA mutant with glutathione species. We found that RhdA was able to bind in vitro reduced glutathione (GSH) and that RhdA-Cys(230) residue was mandatory for the complex formation. RhdA catalyzed glutathione-disulfide formation in the presence of a system generating the glutathione thiyl radical (GS, an oxidized form of GSH), thereby facilitating GSH regeneration. This reaction was negligible when the Cys(230)Ala RhdA mutant was used. The efficiency of RhdA as catalyst in GS-scavenging activity is discussed on the basis of the measured parameters of both interaction with glutathione species and kinetic studies.

Published

2012

38. Nuclear magnetic resonance spectroscopy with the stringent substrate rhodanese bound to the single-ring variant SR1 of the E. coli chaperonin GroEL.

Author

Koculi E, Horst R, Horwich AL, and Wüthrich K

Subjects

Amino Acid Sequence, Bacterial Proteins metabolism, Chaperonin 60 metabolism, Escherichia coli metabolism, Humans, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Protein Binding, Protein Folding, Thiosulfate Sulfurtransferase metabolism, Bacterial Proteins chemistry, Chaperonin 60 chemistry, Escherichia coli chemistry, Thiosulfate Sulfurtransferase chemistry

Abstract

Nuclear magnetic resonance (NMR) observation of the uniformly (2) H,(15) N-labeled stringent 33-kDa substrate protein rhodanese in a productive complex with the uniformly (14) N-labeled 400 kDa single-ring version of the E. coli chaperonin GroEL, SR1, was achieved with the use of transverse relaxation-optimized spectroscopy, cross-correlated relaxation-induced polarization transfer, and cross-correlated relaxation-enhanced polarization transfer. To characterize the NMR-observable parts of the bound rhodanese, coherence buildup rates by different magnetization transfer mechanisms were measured, and effects of covalent crosslinking of the rhodanese to the apical binding surface of SR1 were investigated. The results indicate that the NMR-observable parts of the SR1-bound rhodanese are involved in intracomplex rate processes, which are not related to binding and release of the substrate protein from the SR1 binding surface. Rather, they correspond to mobility of the stably bound substrate, which thus appears to include flexibly disordered polypeptide segments devoid of long-lived secondary structures or tertiary folds, as was previously observed also with the smaller substrate human dihydrofolate reductase., (Copyright © 2011 The Protein Society.)

Published

2011

39. The virulence factor PEB4 (Cj0596) and the periplasmic protein Cj1289 are two structurally related SurA-like chaperones in the human pathogen Campylobacter jejuni.

Author

Kale A, Phansopa C, Suwannachart C, Craven CJ, Rafferty JB, and Kelly DJ

Subjects

Bacterial Proteins genetics, Bacterial Proteins physiology, Chaperonins chemistry, Crystallography, X-Ray methods, Genome, Bacterial, Humans, Hydrophobic and Hydrophilic Interactions, Magnetic Resonance Spectroscopy methods, Molecular Chaperones genetics, Plasmids metabolism, Protein Conformation, Protein Folding, Surface Properties, Thiosulfate Sulfurtransferase chemistry, Virulence Factors genetics, Virulence Factors physiology, Bacterial Proteins metabolism, Campylobacter jejuni metabolism, Carrier Proteins chemistry, Escherichia coli Proteins chemistry, Molecular Chaperones physiology, Peptidylprolyl Isomerase chemistry, Virulence Factors metabolism

Abstract

The PEB4 protein is an antigenic virulence factor implicated in host cell adhesion, invasion, and colonization in the food-borne pathogen Campylobacter jejuni. peb4 mutants have defects in outer membrane protein assembly and PEB4 is thought to act as a periplasmic chaperone. The crystallographic structure of PEB4 at 2.2-Å resolution reveals a dimer with distinct SurA-like chaperone and peptidyl-prolyl cis/trans isomerase (PPIase) domains encasing a large central cavity. Unlike SurA, the chaperone domain is formed by interlocking helices from each monomer, creating a domain-swapped architecture. PEB4 stimulated the rate of proline isomerization limited refolding of denatured RNase T(1) in a juglone-sensitive manner, consistent with parvulin-like PPIase domains. Refolding and aggregation of denatured rhodanese was significantly retarded in the presence of PEB4 or of an engineered variant specifically lacking the PPIase domain, suggesting the chaperone domain possesses a holdase activity. Using bioinformatics approaches, we identified two other SurA-like proteins (Cj1289 and Cj0694) in C. jejuni. The 2.3-Å structure of Cj1289 does not have the domain-swapped architecture of PEB4 and thus more resembles SurA. Purified Cj1289 also enhanced RNase T(1) refolding, although poorly compared with PEB4, but did not retard the refolding of denatured rhodanese. Structurally, Cj1289 is the most similar protein to SurA in C. jejuni, whereas PEB4 has most structural similarity to the Par27 protein of Bordetella pertussis. Our analysis predicts that Cj0694 is equivalent to the membrane-anchored chaperone PpiD. These results provide the first structural insights into the periplasmic assembly of outer membrane proteins in C. jejuni.

Published

2011

40. Amphiphilic polysaccharide nanogels as artificial chaperones in cell-free protein synthesis.

Author

Sasaki Y, Asayama W, Niwa T, Sawada S, Ueda T, Taguchi H, and Akiyoshi K

Subjects

Biomimetic Materials metabolism, Cell-Free System, Cyclodextrins metabolism, Endopeptidase K metabolism, Escherichia coli K12 chemistry, Escherichia coli K12 metabolism, Escherichia coli Proteins metabolism, Gels chemistry, Glucans chemistry, Kinetics, Molecular Chaperones metabolism, Nanostructures chemistry, Protein Folding, Solubility, Thiosulfate Sulfurtransferase chemistry, Water, Biomimetic Materials chemical synthesis, Escherichia coli Proteins chemistry, Gels metabolism, Molecular Chaperones chemical synthesis, Protein Biosynthesis, Thiosulfate Sulfurtransferase metabolism

Abstract

Cell-free protein synthesis is a promising technique for the rapid production of proteins. However, the application of the cell-free systems requires the development of an artificial chaperone that prevents aggregation of the protein and supports its correct folding. Here, nanogel-based artificial chaperones are introduced that improve the folding efficiency of rhodanese produced in cell-free systems. Although rhodanese suffers from rapid aggregation, rhodanese was successfully expressed in the presence of the nanogel and folded to the enzymatically active form after addition of cyclodextrin. To validate the general applicability, the cell-free synthesis of ten water-soluble proteins was examined. It is concluded that the nanogel enables efficient expression of proteins with strong aggregation tendency., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

41. 1H, 13C and 15N resonance assignments of rhodanese GlpE from Escherichia coli.

Author

Li H, Xia B, and Jin C

Subjects

Amino Acid Sequence, Carbon Isotopes, Hydrogen, Molecular Sequence Data, Nitrogen Isotopes, DNA-Binding Proteins chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Nuclear Magnetic Resonance, Biomolecular, Thiosulfate Sulfurtransferase chemistry

Abstract

Rhodanese catalyzes the sulfur-transfer reaction in which a sulfur atom is transferred from thiosulfate to cyanide by a double-displacement mechanism. During the reaction, a persulfide-intermediate form of rhodanese is generated by the reaction of a conserved active cysteine residue with thiosulfate. Escherichia coli GlpE is a prototype for the single-domain rhodanese superfamily. Though there are some studies on rhodaneses, the molecular mechanism of the catalytic activity of rhodaneses is still unclear. Herein, we report the resonance assignments of (1)H, (13)C and (15)N atoms of E. coli GlpE, which provides the basis for further structural, dynamic and functional studies of rhodaneses using NMR technique.

Published

2011

42. 1H, 13C and 15N resonance assignments of the rhodanese domain of YgaP from Escherichia coli.

Author

Li H, Bi Y, Xia B, and Jin C

Subjects

Amino Acid Sequence, Carbon Isotopes, Hydrogen, Molecular Sequence Data, Nitrogen Isotopes, Protein Structure, Tertiary, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Nuclear Magnetic Resonance, Biomolecular, Thiosulfate Sulfurtransferase chemistry

Abstract

Rhodanese domain is a ubiquitous structural module commonly found in bacterial, archaeal and eukaryotic cells. Growing evidence indicates that rhodanese domains act as the carrier of reactive sulfur atoms by forming persulfide intermediates in distinct metabolic pathways. YgaP, a membrane protein consisting of a rhodanese domain and a C-terminal transmembrane segment, is the only membrane-associated rhodanese in Escherichia coli. Herein, we report the resonance assignments of (1)H, (13)C and (15)N atoms of rhodanese domain of YgaP. Totally, chemical shifts of more than 95% of the atoms were assigned.

Published

2011

43. Characterization of an NADH-dependent persulfide reductase from Shewanella loihica PV-4: implications for the mechanism of sulfur respiration via FAD-dependent enzymes.

Author

Warner MD, Lukose V, Lee KH, Lopez K, H Sazinsky M, and Crane EJ 3rd

Subjects

Amino Acid Sequence, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Dithionite metabolism, Flavin-Adenine Dinucleotide metabolism, Models, Molecular, Molecular Sequence Data, Mutation, NADP metabolism, Oxidoreductases chemistry, Oxidoreductases genetics, Protein Structure, Tertiary, Sequence Alignment, Shewanella chemistry, Shewanella genetics, Substrate Specificity, Thiosulfate Sulfurtransferase chemistry, Titanium metabolism, NAD metabolism, Oxidoreductases metabolism, Shewanella enzymology, Sulfides metabolism, Sulfur metabolism

Abstract

The NADH-dependent persulfide reductase (Npsr), a recently discovered member of the PNDOR family of flavoproteins that contains both the canonical flavoprotein reductase domain and a rhodanese domain, is proposed to be involved in the dissimilatory reduction of S(0) for Shewanella loihica PV-4. We have previously shown that polysulfide is a substrate for this enzyme, and a recently determined structure of a closely related enzyme (CoADR-Rhod from Bacillus anthracis) suggested the importance of a bound coenzyme A in the mechanism. The work described here shows that the in vivo oxidizing substrates of Npsr are the persulfides of small thiols such as CoA and glutathione. C43S, C531S, and C43,531S mutants were created to determine the role of the flavoprotein domain cysteine (C43) and the rhodanese domain cysteine (C531) in the mechanism. The absolute requirement for C43 in persulfide or DTNB reductase activity shows that this residue is involved in S-S bond breakage. C531 contributes to, but is not required for, catalysis of DTNB reduction, while it is absolutely required for reduction of any persulfide substrates. Titrations of the enzyme with NADH, dithionite, titanium(III), or TCEP demonstrate the presence of a mixed-disulfide between C43 and a tightly bound CoA, and structures of the C43 and C43,531S mutants confirm that this coenzyme A remains tightly bound to the enzyme in the absence of a C43-CoA S-S bond. The structure of Npsr suggests a likely site for binding and reaction with the persulfide substrate on the rhodanese domain. On the basis of kinetic, titration, and structural data, a mechanism for the reduction of persulfides by Npsr is proposed.

Published

2011

44. Physicochemical and kinetic characteristics of rhodanese from the liver of African catfish Clarias gariepinus Burchell in Asejire lake.

Author

Akinsiku OT, Agboola FK, Kuku A, and Afolayan A

Subjects

Animals, Chromatography, Ion Exchange, Dextrans, Electrophoresis, Polyacrylamide Gel, Hydrogen-Ion Concentration, Kinetics, Nigeria, Spectrophotometry, Atomic, Spectrophotometry, Ultraviolet, Temperature, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase isolation & purification, Catfishes metabolism, Liver chemistry, Thiosulfate Sulfurtransferase analysis

Abstract

Two forms of rhodanese were purified from the liver of Clarias gariepinus Burchell, designated catfish rhodanese I (cRHD I) and rhodanese II (cRHD II), by ion-exchange chromatography on a CM-Sepharose CL-6B column and gel filtration through a Sephadex G-75 column. The apparent molecular weight obtained for cRHD I and cRHD II was 34,500 +/- 707 and 36,800 +/- 283 Da, respectively. The subunit molecular weight determined by sodium dodecyl sulphate-polyacrylamide gel electrophoresis was 33,200 +/- 283 and 35,100 +/- 141 Da for cRHD I and cRHD II, respectively. Atomic absorption spectrophotometric analysis revealed that cRHD II contained a high level of iron (Fe), which presumably was responsible for the brownish colour of the preparation. In contrast, no Fe was identified in cRHD I, and its preparation was colourless. Further characterization of cRHD II gave true Michaelis-Menten constant (K(m)) values of 25.40 +/- 1.70 and 18.60 +/- 1.68 mM for KCN and Na(2)S(2)O(3), respectively, an optimum pH of 6.5 and an optimum temperature of 40 degrees C. The Arrhenius plot of the effects of temperature on the reaction rate consisted of two linear segments with a break occurring at 40 degrees C. The apparent activation energy values from these slopes were 7.3 and 72.9 kcal/mol. Inhibition studies on the cRHD II enzyme showed that the activity of the enzyme was not affected by Mn(2+), Co(2+), Sn(2+), Ni(2+) and NH(4) (+), but Zn(2+) inhibited the enzyme considerably.

Published

2010

45. The rhodanese RhdA helps Azotobacter vinelandii in maintaining cellular redox balance.

Author

Remelli W, Cereda A, Papenbrock J, Forlani F, and Pagani S

Subjects

Azotobacter vinelandii genetics, Azotobacter vinelandii metabolism, Catalytic Domain, Cysteine analogs & derivatives, Cysteine chemistry, Cysteine metabolism, Oxidation-Reduction, Oxidative Stress, Protein Conformation, Reactive Oxygen Species metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Thiosulfate Sulfurtransferase chemistry, Azotobacter vinelandii enzymology, Thiosulfate Sulfurtransferase metabolism

Abstract

The tandem domain rhodanese-homology protein RhdA of Azotobacter vinelandii shows an active-site loop structure that confers structural peculiarity in the environment of its catalytic cysteine residue. The in vivo effects of the lack of RhdA were investigated using an A. vinelandii mutant strain (MV474) in which the rhdA gene was disrupted by deletion. Here, by combining analytical measurements and transcript profiles, we show that deletion of the rhdA gene generates an oxidative stress condition to which A. vinelandii responds by activating defensive mechanisms. In conditions of growth in the presence of the superoxide generator phenazine methosulfate, a stressor-dependent induction of rhdA gene expression was observed, thus highlighting that RhdA is important for A. vinelandii to sustain oxidative stress. The potential of RhdA to buffer general levels of oxidants in A. vinelandii cells via redox reactions involving its cysteine thiol is discussed.

Published

2010

46. Single-molecule spectroscopy of protein folding in a chaperonin cage.

Author

Hofmann H, Hillger F, Pfeil SH, Hoffmann A, Streich D, Haenni D, Nettels D, Lipman EA, and Schuler B

Subjects

Biophysical Phenomena, Chaperonin 10 chemistry, Chaperonin 60 chemistry, Escherichia coli Proteins chemistry, Fluorescence Resonance Energy Transfer, Fluorescent Dyes, Kinetics, Microfluidics, Models, Molecular, Mutagenesis, Site-Directed, Protein Folding, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Thermodynamics, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase genetics, Thiosulfate Sulfurtransferase metabolism, Chaperonins chemistry

Abstract

Molecular chaperones are known to be essential for avoiding protein aggregation in vivo, but it is still unclear how they affect protein folding mechanisms. We use single-molecule Förster resonance energy transfer to follow the folding of a protein inside the GroEL/GroES chaperonin cavity over a time range from milliseconds to hours. Our results show that confinement in the chaperonin decelerates the folding of the C-terminal domain in the substrate protein rhodanese, but leaves the folding rate of the N-terminal domain unaffected. Microfluidic mixing experiments indicate that strong interactions of the substrate with the cavity walls impede the folding process, but the folding hierarchy is preserved. Our results imply that no universal chaperonin mechanism exists. Rather, a competition between intra- and intermolecular interactions determines the folding rates and mechanisms of a substrate inside the GroEL/GroES cage.

Published

2010

47. Understanding the functional interplay between mammalian mitochondrial Hsp70 chaperone machine components.

Author

Goswami AV, Chittoor B, and D'Silva P

Subjects

Adenosine Triphosphate chemistry, Alternative Splicing, Animals, Anisotropy, Cattle, HeLa Cells, Humans, Microscopy, Fluorescence methods, Models, Biological, Molecular Chaperones chemistry, Peptides chemistry, Protein Isoforms, Thiosulfate Sulfurtransferase chemistry, HSP70 Heat-Shock Proteins metabolism, Mitochondria metabolism

Abstract

Mitochondria biogenesis requires the import of several precursor proteins that are synthesized in the cytosol. The mitochondrial heat shock protein 70 (mtHsp70) machinery components are highly conserved among eukaryotes, including humans. However, the functional properties of human mtHsp70 machinery components have not been characterized among all eukaryotic families. To study the functional interactions, we have reconstituted the components of the mtHsp70 chaperone machine (Hsp70/J-protein/GrpE/Hep) and systematically analyzed in vitro conditions for biochemical functions. We observed that the sequence-specific interaction of human mtHsp70 toward mitochondrial client proteins differs significantly from its yeast counterpart Ssc1. Interestingly, the helical lid of human mtHsp70 was found dispensable to the binding of P5 peptide as compared with the other Hsp70s. We observed that the two human mitochondrial matrix J-protein splice variants differentially regulate the mtHsp70 chaperone cycle. Strikingly, our results demonstrated that human Hsp70 escort protein (Hep) possesses a unique ability to stimulate the ATPase activity of mtHsp70 as well as to prevent the aggregation of unfolded client proteins similar to J-proteins. We observed that Hep binds with the C terminus of mtHsp70 in a full-length context and this interaction is distinctly different from unfolded client-specific or J-protein binding. In addition, we found that the interaction of Hep at the C terminus of mtHsp70 is regulated by the helical lid region. However, the interaction of Hep at the ATPase domain of the human mtHsp70 is mutually exclusive with J-proteins, thus promoting a similar conformational change that leads to ATPase stimulation. Additionally, we highlight the biochemical defects of the mtHsp70 mutant (G489E) associated with a myelodysplastic syndrome.

Published

2010

48. Bacitracin is not a specific inhibitor of protein disulfide isomerase.

Author

Karala AR and Ruddock LW

Subjects

Binding, Competitive, Catalytic Domain, Disulfides metabolism, Endoplasmic Reticulum enzymology, Enzyme Inhibitors pharmacology, Isomerism, Kinetics, Macromolecular Substances chemistry, Macromolecular Substances metabolism, Oxidation-Reduction, Peptides chemistry, Peptides metabolism, Protein Denaturation, Protein Disulfide-Isomerases chemistry, Protein Disulfide-Isomerases metabolism, Protein Folding, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase metabolism, Bacitracin pharmacology, Protein Disulfide-Isomerases antagonists & inhibitors

Abstract

To successfully dissect molecular pathways in vivo, there is often a need to use specific inhibitors. Bacitracin is very widely used as an inhibitor of protein disulfide isomerase (PDI) in vivo. However, the specificity of action of an inhibitor for a protein-folding catalyst cannot be determined in vivo. Furthermore, in vitro evidence for the specificity of bacitracin for PDI is scarce, and the mechanism of inhibition is unknown. Here, we present in vitro data showing that 1 mM bacitracin has no significant effect on the ability of PDI to introduce or isomerize disulfide bonds in a folding protein or on its ability to act as a chaperone. Where bacitracin has an effect on PDI activity, the effect is relatively minor and appears to be via competition of substrate binding. Whereas 1 mM bacitracin has minimal effects on PDI, it has significant effects on both noncatalyzed protein folding and on other molecular chaperones. These results suggest that the use of bacitracin as a specific inhibitor of PDI in cellular systems requires urgent re-evaluation.

Published

2010

49. Nano-intercalated rhodanese in cyanide antagonism.

Author

Petrikovics I, Baskin SI, Beigel KM, Schapiro BJ, Rockwood GA, Manage AB, Budai M, and Szilasi M

Subjects

Allyl Compounds administration & dosage, Allyl Compounds chemistry, Allyl Compounds therapeutic use, Animals, Antidotes administration & dosage, Antidotes chemistry, Disulfides administration & dosage, Disulfides chemistry, Disulfides therapeutic use, Drug Synergism, Male, Mice, Mice, Inbred BALB C, Oxazoles chemistry, Poisoning prevention & control, Polyamines, Polymers chemistry, Potassium Cyanide antagonists & inhibitors, Potassium Cyanide chemistry, Thiosulfate Sulfurtransferase administration & dosage, Thiosulfate Sulfurtransferase chemistry, Thiosulfates administration & dosage, Thiosulfates chemistry, Thiosulfates therapeutic use, Antidotes therapeutic use, Dendrimers chemistry, Drug Carriers chemistry, Potassium Cyanide poisoning, Thiosulfate Sulfurtransferase therapeutic use

Abstract

Present studies have focused on nano-intercalated rhodanese in combination with sulfur donors to prevent cyanide lethality in a prophylactic mice model for future development of an effective cyanide antidotal system. Our approach is based on the idea of converting cyanide to the less toxic thiocyanate before it reaches the target organs by utilizing sulfurtransferases (e.g., rhodanese) and sulfur donors in a close proximity by injecting them directly into the blood stream. The inorganic thiosulfate (TS) and the garlic component diallydisulfide (DADS) were compared as sulfur donors with the nano-intercalated rhodanese in vitro and in vivo. The in vivo and in vitro experiments showed that DADS is not a more efficient sulfur donor than TS. However, the utilization of external rhodanese significantly enhanced the in vivo efficacy of both sulfur donor-nitrite combinations, indicating the potential usefulness of enzyme nano-delivery systems in developing antidotal therapeutic agents.

Published

2010

50. Characterization of a new periplasmic single-domain rhodanese encoded by a sulfur-regulated gene in a hyperthermophilic bacterium Aquifex aeolicus.

Author

Giuliani MC, Jourlin-Castelli C, Leroy G, Hachani A, and Giudici-Orticoni MT

Subjects

Amino Acid Sequence, Bacteria enzymology, Bacterial Adhesion, Disulfides chemistry, Genes, Bacterial, Kinetics, Molecular Sequence Data, Periplasm enzymology, Protein Structure, Tertiary, Sequence Alignment, Substrate Specificity, Thiosulfate Sulfurtransferase chemistry, Thiosulfate Sulfurtransferase isolation & purification, Sulfur metabolism, Thiosulfate Sulfurtransferase genetics

Abstract

Rhodaneses (thiosulfate cyanide sulfurtransferases) are enzymes involved in the production of the sulfur in sulfane form, which has been suggested to be the relevant biologically active sulfur species. Rhodanese domains occur in the three major domains of life. We have characterized a new periplasmic single-domain rhodanese from a hyperthermophile bacterium, Aquifex aeolicus, with thiosulfate:cyanide transferase activity, Aq-1599. The oligomeric organization of the enzyme is stabilized by a disulfide bridge. To date this is the first characterization from a hyperthermophilic bacterium of a periplasmic sulfurtransferase with a disulfide bridge. The aq-1599 gene belongs to an operon that also contains a gene for a prepilin peptidase and that is up-regulated when sulfur is used as electron acceptor. Finally, we have observed a sulfur-dependent bacterial adherence linked to an absence of flagellin suggesting a possible role for sulfur detection by A. aeolicus., (Copyright (c) 2009 Elsevier Masson SAS. All rights reserved.)

Published

2010