Roles of the Intramolecular Disulfide Bridge in MotX and MotY, the Specific Proteins for Sodium-Driven Motors in Vibrio spp

ABSTRACT The proteins PomA, PomB, MotX, and MotY are essential for the motor function of Na+-driven flagella in Vibrio spp. Both MotY and MotX have the two cysteine residues (one of which is in a conserved tetrapeptide [CQLV]) that are inferred to form an intramolecular disulfide bond. The cysteine mutants of MotY prevented the formation of an intramolecular disulfide bond, which is presumably important for protein stability. Disruption of the disulfide bridge in MotX by site-directed mutagenesis resulted in increased instability, which did not, however, affect the motility of the cells. These lines of evidence suggest that the intramolecular disulfide bonds are involved in the stability of both proteins, but only MotY requires the intramolecular bridge for proper function.

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Replacement of the interchain disulfide bridge-forming amino acids A7 and B7 by glutamate impairs the structure and activity of insulin

Biological Chemistry ◽

10.1515/bc.2004.151 ◽

2004 ◽

Vol 385 (12) ◽

pp. 1171-1175 ◽

Cited By ~ 7

Author(s):

Zhan-Yun Guo ◽

Xiao-Yuan Jia ◽

You-Min Feng

Keyword(s):

Biological Activity ◽

Disulfide Bonds ◽

Negative Charge ◽

Disulfide Bridge ◽

Site Directed Mutagenesis ◽

Side Chain ◽

Insulin Analogs ◽

High Biological Activity ◽

Chemical Groups ◽

Structure And Activity

Abstract Insulin contains three disulfide bonds, one intrachain bond, A6–A11, and two interchain bonds, A7–B7 and A20–B19. Site-directed mutagenesis results (the two cysteine residues of disulfide A7–B7 were replaced by serine) showed that disulfide A7–B7 is crucial to both the structure and activity of insulin. However, chemical modification results showed that the insulin analogs still retained relatively high biological activity when A7Cys and B7Cys were modified by chemical groups with a negative charge. Did the negative charge of the modification groups restore the loss of activity and/or the disturbance of structure of these insulin analogs caused by deletion of disulfide A7–B7? To answer this question, an insulin analog with both A7Cys and B7Cys replaced by Glu, which has a long side-chain and a negative charge, was prepared by protein engineering, and its structure and activity were analyzed. Both the structure and activity of the present analog are very similar to that of the mutant with disulfide A7–B7 replaced by Ser, but significantly different from that of wild-type insulin. The present results suggest that removal of disulfide A7–B7 will result in serious loss of biological activity and the native conformation of insulin, even if the disulfide is replaced by residues with a negative charge.

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The crystal structure of wild-type human brain neuroglobin reveals flexibility of the disulfide bond that regulates oxygen affinity

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s1399004714000078 ◽

2014 ◽

Vol 70 (4) ◽

pp. 1005-1014 ◽

Cited By ~ 31

Author(s):

Beatriz G. Guimarães ◽

Djemel Hamdane ◽

Christophe Lechauve ◽

Michael C. Marden ◽

Béatrice Golinelli-Pimpaneau

Keyword(s):

Disulfide Bond ◽

Conformational Transition ◽

Bond Formation ◽

Oxygen Affinity ◽

Disulfide Bridge ◽

Wild Type ◽

X Ray ◽

Intramolecular Disulfide Bond ◽

Internal Cavities ◽

High Oxygen Affinity

Neuroglobin plays an important function in the supply of oxygen in nervous tissues. In human neuroglobin, a cysteine at position 46 in the loop connecting the C and D helices of the globin fold is presumed to form an intramolecular disulfide bond with Cys55. Rupture of this disulfide bridge stabilizes bi-histidyl haem hexacoordination, causing an overall decrease in the affinity for oxygen. Here, the first X-ray structure of wild-type human neuroglobin is reported at 1.74 Å resolution. This structure provides a direct observation of two distinct conformations of the CD region containing the intramolecular disulfide link and highlights internal cavities that could be involved in ligand migration and/or are necessary to enable the conformational transition between the low and high oxygen-affinity states following S—S bond formation.

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The kinetics of in vitro reoxidation and reduction of the inter heavy–light chain disulfide bond in an unusual murine immunoglobulin G myeloma protein lacking inter-heavy chain disulfide bonds

Canadian Journal of Biochemistry ◽

10.1139/o79-035 ◽

1979 ◽

Vol 57 (3) ◽

pp. 279-285 ◽

Cited By ~ 1

Author(s):

Maire E. Percy ◽

Lebe Chang ◽

Catherine Demoliou ◽

Reuben Baumal

Keyword(s):

Disulfide Bond ◽

Disulfide Bonds ◽

Peptide Mapping ◽

Polyacrylamide Gel Electrophoresis ◽

Sodium Dodecyl ◽

Sedimentation Coefficient ◽

Disulfide Bridge ◽

Myeloma Protein ◽

Kinetics Of

After 5 years of subcutaneous transfer in Balb/C mice, our MOPC 173 myeloma tumour line (originally an IgG2a,κ H2L2-producer) exclusively synthesized an unusual IgG2b,κ protein lacking inter-heavy (H) chain disulfide bonds. This protein was designated MOPC 173B. On sodium dodecyl sulfate – polyacrylamide gel electrophoresis, it migrated with an apparent molecular weight of 77 000; following complete reduction and alkylation, the mobilities of its constituent H and light (L) chains were found to differ slightly from those of MOPC 173 H2L2. MOPC 173B was serologically identical to another typical IgG2b,κ myeloma protein, MOPC 195, and peptide mapping studies showed that it possessed only the inter H–L disulfide bond characteristic of typical IgG2b,κ proteins. In a nondissociating solvent, the sedimentation coefficient of the protein was 6.3S even at concentrations as low as 0.2 mg/ml, indicating that noncovalent interactions existed between two half-molecule subunits. Since this unusual IgG myeloma protein contained only a single category of interchain disulfide bridge, the inter H–L bond, it was an ideal model system for characterization of the kinetics of formation and reduction of interchain disulfide bonds. The kinetics of the glutathione-catalyzed reoxidation of the inter H–L disulfide bridge in MOPC 173B followed an apparent second-order rate equation. In contrast, reduction of its inter H–L bridge under anaerobic conditions with dithioerythritol in excess, was strictly a first-order process and not a simple reversal of the reoxidation. These studies provide the basis for the more complex mathematical models that describe the reoxidation and reduction of typical immunoglobulin molecules.

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The Single Disulfide-Directed β-Hairpin Fold: Role of Disulfide Bond in Folding and Effect of an Additional Disulfide Bond on Stability

Australian Journal of Chemistry ◽

10.1071/ch19386 ◽

2020 ◽

Vol 73 (4) ◽

pp. 312

Author(s):

Balasubramanyam Chittoor ◽

Bankala Krishnarjuna ◽

Rodrigo A. V. Morales ◽

Raymond S. Norton

Keyword(s):

Disulfide Bond ◽

Disulfide Bonds ◽

Solution Structure ◽

Conformational Stability ◽

Disulfide Bridge ◽

Solution Nmr ◽

Peptide Epitope ◽

The Core ◽

Native Fold

Disulfide bonds play a key role in the oxidative folding, conformational stability, and functional activity of many peptides. A few disulfide-rich peptides with privileged architecture such as the inhibitor cystine knot motif have garnered attention as templates in drug design. The single disulfide-directed β-hairpin (SDH), a novel fold identified more recently in contryphan-Vc1, has been shown to possess remarkable thermal, conformational, and chemical stability and can accept a short bioactive epitope without compromising the core structure of the peptide. In this study, we demonstrated that the single disulfide bond is critical in maintaining the native fold by replacing both cysteine residues with serine. We also designed an analogue with an additional, non-native disulfide bridge by replacing Gln1 and Tyr9 with Cys. Contryphan-Vc11–22[Q1C, Y9C] was synthesised utilising orthogonal cysteine protection and its solution structure determined using solution NMR spectroscopy. This analogue maintained the overall fold of native contryphan-Vc1. Previous studies had shown that the β-hairpin core of contryphan-Vc1 was resistant to proteolysis by trypsin and α-chymotrypsin but susceptible to cleavage by pepsin. Contryphan-Vc11–22[Q1C, Y9C] proved to be completely resistant to pepsin, thus confirming our design strategy. These results highlight the role of the disulfide bond in maintaining the SDH fold and provide a basis for the design of more stable analogues for peptide epitope grafting.

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Identification and functional analysis of inter-subunit disulfide bonds of the F protein of Helicoverpa armigera nucleopolyhedrovirus

Journal of General Virology ◽

10.1099/vir.0.068122-0 ◽

2014 ◽

Vol 95 (12) ◽

pp. 2820-2830 ◽

Cited By ~ 2

Author(s):

Feifei Yin ◽

Manli Wang ◽

Ying Tan ◽

Fei Deng ◽

Just M. Vlak ◽

...

Keyword(s):

Disulfide Bond ◽

Viral Entry ◽

Helicoverpa Armigera ◽

Disulfide Bonds ◽

Site Directed Mutagenesis ◽

Disulfonic Acid ◽

Viral Infectivity ◽

F Protein ◽

Free Thiol ◽

Helicoverpa Armígera

The major envelope fusion protein F of the budded virus of baculoviruses consists of two disulfide-linked subunits: an N-terminal F2 subunit and a C-terminal, membrane-anchored F1 subunit. There is one cysteine in F2 and there are 15 cysteines in F1, but their role in disulfide linking is largely unknown. In this study, the inter- and intra-subunit disulfide bonds of the Helicoverpa armigera single nucleocapsid nucleopolyhedrovirus (HearNPV) F protein were analysed by site-directed mutagenesis. Results indicated that in a functional F protein, an inter-subunit disulfide bond exists between amino acids C108 (F2) and C241 (F1). When C241 was mutated, an alternative disulfide bond was formed between C108 and C232, rendering F non-functional. No inter-subunit bridge was observed in a double C232/C241 mutant of F1. C403 was not involved in the formation of inter-subunit disulfide bonding, but mutation of this amino acid decreased viral infectivity significantly, suggesting that it might be involved in intra-subunit disulfide bonds. The influence of reductant [tris(2-carboxyethyl) phosphine (TCEP)] and free-thiol inhibitors [4-acetamido-4′-maleimidylstilbene 2,2′-disulfonic acid (AMS) and 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB)] on the infectivity of HearNPV was tested. The results indicated that TCEP greatly decreased the infection of HzAm1 cells by HearNPV. In contrast, AMS and DTNB had no inhibitory effect on viral infectivity. The data suggested that free thiol/disulfide isomerization was not likely to play a role in viral entry and infectivity.

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The Role of the Disulfide Bridge in the Stability and Structural Integrity of Ovalbumin Evaluated by Site-Directed Mutagenesis

Bioscience Biotechnology and Biochemistry ◽

10.1271/bbb.100772 ◽

2011 ◽

Vol 75 (3) ◽

pp. 544-549 ◽

Cited By ~ 6

Author(s):

Takayuki ISHIMARU ◽

Kazunari ITO ◽

Miho TANAKA ◽

Syunpei TANAKA ◽

Naotoshi MATSUDOMI

Keyword(s):

Structural Integrity ◽

Disulfide Bridge ◽

Site Directed Mutagenesis ◽

Directed Mutagenesis ◽

The Stability

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Two dileucine motifs mediate late endosomal/lysosomal targeting of transmembrane protein 192 (TMEM192) and a C-terminal cysteine residue is responsible for disulfide bond formation in TMEM192 homodimers

Biochemical Journal ◽

10.1042/bj20101396 ◽

2011 ◽

Vol 434 (2) ◽

pp. 219-231 ◽

Cited By ~ 15

Author(s):

Jörg Behnke ◽

Eeva-Liisa Eskelinen ◽

Paul Saftig ◽

Bernd Schröder

Keyword(s):

Disulfide Bond ◽

Disulfide Bonds ◽

Transmembrane Protein ◽

Bond Formation ◽

Immunogold Labelling ◽

Disulfide Bridge ◽

Cysteine Residue ◽

Disulfide Bond Formation ◽

Transmembrane Segments ◽

Late Endosomes

TMEM192 (transmembrane protein 192) is a novel constituent of late endosomal/lysosomal membranes with four potential transmembrane segments and an unknown function that was initially discovered by organellar proteomics. Subsequently, localization in late endosomes/lysosomes has been confirmed for overexpressed and endogenous TMEM192, and homodimers of TMEM192 linked by disulfide bonds have been reported. In the present study the molecular determinants of TMEM192 mediating its transport to late endosomes/lysosomes were analysed by using CD4 chimaeric constructs and mutagenesis of potential targeting motifs in TMEM192. Two directly adjacent N-terminally located dileucine motifs of the DXXLL-type were found to be critical for transport of TMEM192 to late endosomes/lysosomes. Whereas disruption of both dileucine motifs resulted in mistargeting of TMEM192 to the plasma membrane, each of the two motifs was sufficient to ensure correct targeting of TMEM192. In order to study disulfide bond formation, mutagenesis of cysteine residues was performed. Mutation of Cys266 abolished disulfide bridge formation between TMEM192 molecules, indicating that TMEM192 dimers are linked by a disulfide bridge between their C-terminal tails. According to the predicted topology, Cys266 would be localized in the reductive milieu of the cytosol where disulfide bridges are generally uncommon. Using immunogold labelling and proteinase protection assays, the localization of the N- and C-termini of TMEM192 on the cytosolic side of the late endosomal/lysosomal membrane was experimentally confirmed. These findings may imply close proximity of the C-termini in TMEM192 dimers and a possible involvement of this part of the protein in dimer assembly.

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Structure and Genome Release Mechanism of the Human Cardiovirus Saffold Virus 3

Journal of Virology ◽

10.1128/jvi.00746-16 ◽

2016 ◽

Vol 90 (17) ◽

pp. 7628-7639 ◽

Cited By ~ 8

Author(s):

Edukondalu Mullapudi ◽

Jiří Nováček ◽

Lenka Pálková ◽

Pavel Kulich ◽

A. Michael Lindberg ◽

...

Keyword(s):

Disulfide Bond ◽

Disulfide Bonds ◽

Current Knowledge ◽

Virus Genome ◽

Gastrointestinal Disorders ◽

Release Mechanism ◽

Content Type ◽

X Ray Crystallography ◽

A Cell ◽

The Stability

ABSTRACTIn order to initiate an infection, viruses need to deliver their genomes into cells. This involves uncoating the genome and transporting it to the cytoplasm. The process of genome delivery is not well understood for nonenveloped viruses. We address this gap in our current knowledge by studying the uncoating of the nonenveloped human cardiovirus Saffold virus 3 (SAFV-3) of the familyPicornaviridae. SAFVs cause diseases ranging from gastrointestinal disorders to meningitis. We present a structure of a native SAFV-3 virion determined to 2.5 Å by X-ray crystallography and an 11-Å-resolution cryo-electron microscopy reconstruction of an “altered” particle that is primed for genome release. The altered particles are expanded relative to the native virus and contain pores in the capsid that might serve as channels for the release of VP4 subunits, N termini of VP1, and the RNA genome. Unlike in the related enteroviruses, pores in SAFV-3 are located roughly between the icosahedral 3- and 5-fold axes at an interface formed by two VP1 and one VP3 subunit. Furthermore, in native conditions many cardioviruses contain a disulfide bond formed by cysteines that are separated by just one residue. The disulfide bond is located in a surface loop of VP3. We determined the structure of the SAFV-3 virion in which the disulfide bonds are reduced. Disruption of the bond had minimal effect on the structure of the loop, but it increased the stability and decreased the infectivity of the virus. Therefore, compounds specifically disrupting or binding to the disulfide bond might limit SAFV infection.IMPORTANCEA capsid assembled from viral proteins protects the virus genome during transmission from one cell to another. However, when a virus enters a cell the virus genome has to be released from the capsid in order to initiate infection. This process is not well understood for nonenveloped viruses. We address this gap in our current knowledge by studying the genome release ofHuman Saffold virus 3. Saffold viruses cause diseases ranging from gastrointestinal disorders to meningitis. We show that before the genome is released, the Saffold virus 3 particle expands, and holes form in the previously compact capsid. These holes serve as channels for the release of the genome and small capsid proteins VP4 that in related enteroviruses facilitate subsequent transport of the virus genome into the cell cytoplasm.

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Role of Intermolecular Disulfide Bonds of the Organic Solvent-Stable PST-01 Protease in Its Organic Solvent Stability

Applied and Environmental Microbiology ◽

10.1128/aem.67.2.942-947.2001 ◽

2001 ◽

Vol 67 (2) ◽

pp. 942-947 ◽

Cited By ~ 56

Author(s):

Hiroyasu Ogino ◽

Takeshi Uchiho ◽

Jyunko Yokoo ◽

Reina Kobayashi ◽

Rikiya Ichise ◽

...

Keyword(s):

Organic Solvent ◽

Organic Solvents ◽

Disulfide Bond ◽

Disulfide Bonds ◽

Site Directed Mutagenesis ◽

Solvent Stability ◽

Organic Solvent Tolerant ◽

Intermolecular Disulfide Bonds ◽

Solvent Tolerant ◽

Solvent Stable

ABSTRACT The PST-01 protease is secreted by the organic solvent-tolerant microorganism Pseudomonas aeruginosa PST-01 and is stable in the presence of various organic solvents. Therefore, the PST-01 strain and the PST-01 protease are very useful for fermentation and reactions in the presence of organic solvents, respectively. The organic solvent-stable PST-01 protease has two disulfide bonds (between Cys-30 and Cys-58 and between Cys-270 and Cys-297) in its molecule. Mutant PST-01 proteases in which one or both of the disulfide bonds were deleted were constructed by site-directed mutagenesis, and the effect of the disulfide bonds on the activity and the various stabilities was investigated. The disulfide bond between Cys-270 and Cys-297 in the PST-01 protease was found to be essential for its activity. The disulfide bond between Cys-30 and Cys-58 played an important role in the organic solvent stability of the PST-01 protease.

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Formation of an Intramolecular Periplasmic Disulfide Bond in TcpP Protects TcpP and TcpH from Degradation in Vibrio cholerae

Journal of Bacteriology ◽

10.1128/jb.00338-15 ◽

2015 ◽

Vol 198 (3) ◽

pp. 498-509 ◽

Cited By ~ 14

Author(s):

Sarah J. Morgan ◽

Emily L. French ◽

Joshua J. Thomson ◽

Craig P. Seaborn ◽

Christian A. Shively ◽

...

Keyword(s):

Gene Expression ◽

Transcription Factor ◽

Vibrio Cholerae ◽

Disulfide Bond ◽

Virulence Gene ◽

Content Type ◽

Virulence Gene Expression ◽

Intramolecular Disulfide Bond ◽

Periplasmic Domain ◽

The Stability

ABSTRACTTcpP and ToxR coordinately regulate transcription oftoxT, the master regulator of numerous virulence factors inVibrio cholerae. TcpP and ToxR are membrane-localized transcription factors, each with a periplasmic domain containing two cysteines. In ToxR, these cysteines form an intramolecular disulfide bond and a cysteine-to-serine substitution affects activity. We determined that the two periplasmic cysteines of TcpP also form an intramolecular disulfide bond. Disruption of this intramolecular disulfide bond by mutation of either cysteine resulted in formation of intermolecular disulfide bonds. Furthermore, disruption of the intramolecular disulfide bond in TcpP decreased the stability of TcpP. While the decreased stability of TcpP-C207S resulted in a nearly complete loss oftoxTactivation and cholera toxin (CT) production, the second cysteine mutant, TcpP-C218S, was partially resistant to proteolytic degradation and maintained ∼50%toxTactivation capacity. TcpP-C218S was also TcpH independent, since deletion oftcpHdid not affect the stability of TcpP-C218S, whereas wild-type TcpP was degraded in the absence of TcpH. Finally, TcpH was also unstable when intramolecular disulfides could not be formed in TcpP, suggesting that the single periplasmic cysteine in TcpH may assist with disulfide bond formation in TcpP by interacting with the periplasmic cysteines of TcpP. Consistent with this finding, a TcpH-C114S mutant was unable to stabilize TcpP and was itself unstable. Our findings demonstrate a periplasmic disulfide bond in TcpP is critical for TcpP stability and virulence gene expression.IMPORTANCETheVibrio choleraetranscription factor TcpP, in conjunction with ToxR, regulates transcription oftoxT, the master regulator of numerous virulence factors inVibrio cholerae. TcpP is a membrane-localized transcription factor with a periplasmic domain containing two cysteines. We determined that the two periplasmic cysteines of TcpP form an intramolecular disulfide bond and disruption of the intramolecular disulfide bond in TcpP decreased the stability of TcpP and reduced virulence gene expression. Normally TcpH, another membrane-localized periplasmic protein, protects TcpP from degradation. However, we found that TcpH was also unstable when intramolecular disulfides could not be formed in TcpP, indicating that the periplasmic cysteines of TcpP are required for functional interaction with TcpH and that this interaction is required for both TcpP and TcpH stability.

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