ライフサイエンスコーパス: disulfide

1 ter a futile thiol oxidase cycle forming GSH disulfide.

2 nificant catalytic advantage over a cysteine disulfide.

3 ighly effective means to prepare unsymmetric disulfides.

4 chalcogenide (TMD) superconductor 2H-niobium disulfide (2H-NbS(2)) and a commensurate block layer tha

5 ding an extra "H" beta-strand and "clamping" disulfide, absent in known IgV-like structures, that lik

6 We further showed that covalent disulfide adducts of this residue promote autophosphoryl

7 d signaling of TrxR activity compared to the disulfide analogue.

8 to the TrxR active site in comparison to its disulfide analogue.

9 e conformational switch of a highly flexible disulfide-anchored loop to a rigid beta-strand and by tr

10 atile compounds, such as methional, dimethyl disulfide and 1-octen-3-one, which imparted slight sulfu

11 tivation by diorgano diselenide and diorgano disulfide and also their incorporation into the indolizi

12 ods of time dependent on the cleavage of the disulfide and ester linkages.

13 s method to the specific cases of molybdenum disulfide and graphene oxide particles, dispersed in a n

14 nsities of the two Raman bands of molybdenum disulfide and graphene oxide, we demonstrate that an acc

15 bination of solution-processed 2D-molybdenum disulfide and graphene-oxide (GO) that can be deposited

16 uilibrium of GSSH formation from glutathione disulfide and H(2)S.

17 ted as an interface layer between molybdenum disulfide and hafnium dioxide in a bottom-gate configura

18 hemical vapor deposited monolayer molybdenum disulfide and solution-processed semiconducting single-w

19 diorganyl dichalcogenides, such as diorganyl disulfides and diorganyl ditellurides, which did not giv

20 cles with a bimodal size distribution on the disulfides and diselenides, and as atomically thin layer

21 ates, isothiocyanates, carbodiimides, carbon disulfide, and carbon dioxide with carbanions or enamine

22 ne photocatalyst, a trithiocarbonate-derived disulfide, and visible light.

23 ec reaction of phosphorus amides with carbon disulfide; and (2) the one-pot synthesis of thiophosphor

24 e such promising material, with vanadium and disulfide anions [S(2)](2-) forming one-dimensional line

25 ation of sp(2) C-H bonds with aryl and alkyl disulfides as well as diphenyl diselenide.

26 er 3,3'-dithiodipropionic acid (DDPA) with a disulfide bond (SS) extended by short-chain polyethylene

27 vitro data show that the redox state of the disulfide bond affects S. aureus biofilm formation and t

28 reviously unappreciated means to stabilize a disulfide bond and highlight the utility of the n->pai*

29 Our data support a model whereby the disulfide bond and PAS domain of SrrB sense and respond

30 (hereafter referred to as GH-C53S) lacks the disulfide bond between p.Cys-53 and p.Cys-165, which is

31 hiol function site, for forming longitudinal disulfide bond chains.

32 Disulfide bond connectivity characterization is still ch

33 e nanoparticles (GPUs) using a GSH-cleavable disulfide bond containing polyurethane that responds to

34 , side-chain-to-tail cyclization (C2), and a disulfide bond cross-linkage (C3).

35 volve the iRhoms, such as regulation through disulfide bond exchange or through interaction with char

36 al peptidase that requires an intramolecular disulfide bond for in vitro activity.

37 d that S-sulfhydration affected intraprotein disulfide bond formation and was required for the mainte

38 ructure, which is constructed by consecutive disulfide bond formation between a large number of pepti

39 nd to a model ER protein exhibiting improper disulfide bond formation during reductive ER stress but

40 able ligation/desulfurization and subsequent disulfide bond formation in a one-pot process.

41 Disulfide bond formation is a common mechanism to stabil

42 Disulfide bond formation is a critical post-translationa

43 n dimer-decamer transitions and intersubunit disulfide bond formation is more complex than previously

44 potentially destabilizing or preventing the disulfide bond formation required for proper protein fun

45 it tunnel provides sufficient space even for disulfide bond formation which can guide protein folding

46 ic ends of the MA-helices, are conducive for disulfide bond formation.

47 cture shows a unique intramolecular cysteine disulfide bond in the ATP-binding domain that significan

48 ctodomain trimer, covalently stabilized by a disulfide bond in the closed conformation.

49 ts highlight the critical structural role of disulfide bond in ToxR and along with VtrA define a doma

50 endocarditis model, we demonstrate that the disulfide bond is a critical regulatory element of SrrB

51 We find that the disulfide bond is stabilized by two n->pai* interactions

52 strate protein unfolding by showing that MFS disulfide bond mutations markedly disrupt normal mechano

53 nd two helical turns stabilized by a complex disulfide bond network that creates an embedded ring aro

54 ence of glycosylation, and containing proper disulfide bond pairings.

55 ell proteins and beta3 integrin intraprotein disulfide bond rearrangement.

56 Reduction of the Cys1-Cys7 disulfide bond resulted in faster fibrillation with invo

57 oxRp crystal structure showed this is due to disulfide bond stabilization.

58 sensitivity of the internal friction to the disulfide bond status suggests that one or both of the c

59 s, the diketopiperazine ring is spanned by a disulfide bond that is constrained in a high-energy ecli

60 teine residues, generating an intermolecular disulfide bond that promotes dimerization and fibrilliza

61 n, the oxidation of two cysteine thiols to a disulfide bond, during the catalytic cycle of the N-term

62 e 213, which is engaged in an intramolecular disulfide bond, leads to butterfly-shaped pattern dystro

63 d combinatorial library of cholesteryl-based disulfide bond-containing biodegradable cationic lipidoi

64 o investigate whether a straight versus bent disulfide bond-containing CDRH3 is specific to particula

65 ed from HCV-infected individuals, revealed a disulfide bond-containing CDRH3 that adopts straight (in

66 for MHC class II-restricted presentation of disulfide bond-containing proteins, including the self-a

67 traditionally relied on lactam, lactone and disulfide bond-forming reactions that aim at introducing

68 rate that RALF peptides fold into bioactive, disulfide bond-stabilized proteins that bind the LRR dom

69 site that substitutes for a loop-stabilizing disulfide bond.

70 physicochemical attributes of this atypical disulfide bond.

71 equence (K(d) = 1.8 nM) containing an i, i+4 disulfide bond.

72 ains two HRMs whose cysteine residues form a disulfide bond; when reduced, these cysteines are availa

73 t studies have reported that upregulation of disulfide-bond A oxidoreductase-like protein (DsbA-L) pr

74 oper posttranslational processing, incorrect disulfide-bond formation, protein aggregation, changes i

75 Mutants targeting the disulfide-bond stabilized LRX dimer interface fail to re

76 accompanied by the generation of large mixed disulfide bonded complexes, including ERp44.

77 for the ToxS periplasmic domain than the non-disulfide bonded conformation.

78 u rubripes, presumably through maintaining a disulfide-bonded conformation.

79 The differentiation of individual disulfide-bonded isomers by traditional high-performance

80 ass spectrometry (TIMS-MS), several 2- and 3-disulfide-bonded isomers of the mu-conotoxin PIIIA were

81 4's codon 373 (C373A) exhibit alterations in disulfide-bonded K14 species and a barrier defect second

82 d by a dimer of the heavily glycosylated and disulfide-bonded OSTM1, which serves to protect CLC-7 fr

83 S that allow the production of thermostable, disulfide-bonded S-protein trimers that are trapped in t

84 teines involved in intra- and intermolecular disulfide bonding and protein folding.

85 Here, we find that disulfide bonding between a native cysteine pair at the

86 t studies evidenced a role for K14-dependent disulfide bonding in the organization and dynamics of ke

87 all interruptions of D2 loop intramolecular disulfide bonding lead to haploinsufficiency-related RP,

88 the bovine IgG1 hinge region and a predicted disulfide bonding motif linking the upper hinge region,

89 Such conversion is dependent on the unique disulfide bonding properties of the hIgG2 hinge.

90 e of parameters, including primary sequence, disulfide bonding, glycosylation patterns, biotransforma

91 the oxidation of sulfhydryl groups (-SH) to disulfide bonds (-SS-) of extracted proteins at 0.6 mu w

92 x-ERp57 complexes reduce these extracellular disulfide bonds and are essential for ECM degradation.

93 e MEDI3726 protein scaffold lacks interchain disulfide bonds and has an average drug to antibody rati

94 ted by the formation of dimers stabilized by disulfide bonds and then proceeds via primary nucleation

95 re formed, and reduced, in which one or more disulfide bonds are broken.

96 Prior to the signal detection procedure, disulfide bonds are chemically cleaved, and the perfluor

97 bonds remain intact) and fully reduced (all disulfide bonds are cleaved) forms.

98 ted redox states: oxidized, in which all the disulfide bonds are formed, and reduced, in which one or

99 Four pairs of distal, intramonomeric disulfide bonds are found to be coupled to the stability

100 clusters followed by subsequent formation of disulfide bonds between conserved active-site cysteines

101 Disulfide bonds between cysteine residues are commonly i

102 s that can cross-link sigma1 by establishing disulfide bonds between structurally adjacent sites in t

103 of three peptides bearing two intramolecular disulfide bonds but different cysteine connectivity have

104 cific radiation damage at RT was observed at disulfide bonds but not at acidic residues, increasing a

105 evented FeEnt uptake, whereas most inter-N-C disulfide bonds did not prevent FeEnt uptake.

106 omain of neurexins by forming intermolecular disulfide bonds during transport through the secretory p

107 We further demonstrate the disulfide bonds in cbEGF domains uniquely orchestrate pr

108 suggesting that the elimination of multiple disulfide bonds in NOTCH3 accelerates its fragmentation.

109 be reversibly oxidized, forming interprotein disulfide bonds in the holoenzyme complex.

110 in which spontaneously formed intermolecular disulfide bonds initiate amyloid fibril formation by rec

111 We introduced single disulfide bonds into NPC1 and NPC1L1 to explore the impo

112 t and reversible binding, we have introduced disulfide bonds into opposite sides of a flexible loop c

113 Specific damage to disulfide bonds is evident early on at RT and proceeds a

114 first time the ability to efficiently cleave disulfide bonds linking heavy and light chains of mAbs u

115 ts in both the partially reduced (intrachain disulfide bonds remain intact) and fully reduced (all di

116 on, allowing the formation of intermolecular disulfide bonds that result in TFEB oligomerization.

117 tion is characterized by strained interchain disulfide bonds that stabilize the P-loop in an extended

118 Either introducing single disulfide bonds to constrain lumenal/extracellular domai

119 imported into Escherichia coli can transfer disulfide bonds to cytoplasmic proteins.

120 or PNGase F, and (3) reduction of interchain disulfide bonds to generate ~25 kDa ADC subfragments, wh

121 led that the third cysteine, Cys-163, formed disulfide bonds with either of two cysteines in the cano

122 e (Cys) residues, which can oxidize and form disulfide bonds with other Cys residues under oxidizing

123 Disulfide bonds within cysteine-rich peptides are import

124 a highly conserved region stabilized by two disulfide bonds, but it captures RSV G in a conformation

125 is the potential for formation of non-native disulfide bonds, making it necessary for the cell to hav

126 ostability and disruptions to alpha helices, disulfide bonds, or the permeation pore.

127 BisAbs contain engineered disulfide bonds, which have been demonstrated to form pr

128 methods consistently showed that the intra-N disulfide bonds, which restrict conformational motion wi

129 nfected cells, forming incorrect cross-chain disulfide bonds, which results in impaired GPC processin

130 While ETD retains modifications and cleaves disulfide bonds-making it attractive for mAb characteriz

131 al CSalphabeta motif stabilized by conserved disulfide bonds.

132 ue antiparallel beta-sheet stabilized by two disulfide bonds.

133 ism for the isomerization of such non-native disulfide bonds.

134 ToPI1, with 33 amino acid residues and three disulfide bonds.

135 llular milieu as a result of the cleavage of disulfide bonds.

136 DsbC reduces mis-formed disulfide bonds.

137 into a compact four-helix bundle with three disulfide bonds.

138 to characterize the cysteine connectivity of disulfide bonds.

139 rtiary structure, with the potential to form disulfide bonds.

140 and is stabilized by three highly conserved disulfide bonds.

141 tion and S-nitrosylation and form non-native disulfide bonds.

142 mposed of proteinogenic amino acids and lack disulfide bonds; they are also known in several genera o

143 onstrate reversible Ni(II) -thiolate/Ni(II) -disulfide (both bound and unbound disulfide-S to Ni(II)

144 Most importantly, AI-ETD reveals disulfide-bound regions that have been intractable, thus

145 Further, the disulfide bridge appears to prevent an inhibitory confor

146 avage site (R508S/R511S) or by introducing a disulfide bridge between gp120 and gp41 designated "SOS"

147 es that form a disulfide bridge in FGF23-WT; disulfide bridge formation in FGF23-WT is dispensable fo

148 R2 is flanked by two cysteines that form a disulfide bridge in FGF23-WT; disulfide bridge formation

149 The engineered disulfide bridge in m01s eliminated the self-association

150 mutagenesis, in which the gap is locked by a disulfide bridge.

151 he role played by previously uncharacterized disulfide-bridge and domain-swapped interfaces from crys

152 eract with serotonin signaling pathways: the disulfide-bridged 2,5-diketopiperazine gliotoxin.

153 lar polymer system is prepared by complexing disulfide-bridged biguanidyl adamantine (Ad-SS-GD) with

154 We find that disulfide bridges are abundant in connective and liver E

155 as a globular protein that dimerizes through disulfide bridges generated by cysteine oxidation.

156 Engineered disulfide bridges that locked the cassettes in two diffe

157 nking under reducing conditions that disrupt disulfide bridges, but soluble fibronectin did not.

158 ith oligomerization in tetramers mediated by disulfide bridges.

159 in backbone and aromatic residues as well as disulfide bridges.

160 ess 2 motifs related to beta-defensins and 6 disulfide bridges.

161 isting of two alpha1beta units, connected by disulfide bridges.

162 Degradation of dimethyl disulfide by direct photolysis caused a small but signif

163 tes: In this protocol, intermediately formed disulfides can be chemoselectively substituted with viny

164 These disulfides can be converted to covalent metal-thiolate b

165 at the overall structural changes during the disulfide cascade expose the Cys-122-Cys-66 disulfide to

166 by ultrasound-induced selective scission of disulfide-centered polymers in solution.

167 Tungsten diselenide and molybdenum disulfide channels were used selectively to potentiate a

168 tion of sulfide into the trisulfide versus a disulfide cofactor.

169 hiosulfonate group to form the corresponding disulfide conjugate with an EPR spectrum characteristic

170 accepts substrates with a noncanonical EGFD disulfide connectivity (i.e. the Cys 1-2, 3-4, 5-6 disul

171 In this respect, the correct disulfide connectivity plays a decisive role.

172 summary, we have identified a unique single-disulfide conopeptide with a noncompetitive, potentially

173 In mouse LV cardiomyocytes, disulfide-containing PKARIalpha was not found to impact

174 ctase (MCR) involves Ni-mediated thiolate-to-disulfide conversion that sustains its catalytic cycle o

175 Disulfide cross-linking validates the physiological rele

176 Engineered disulfide cross-links show that loop movement is require

177 One of the disulfide crosslinked NaAtm1 variants characterized in t

178 formational states, stabilized by individual disulfide crosslinks and nucleotides.

179 es with narrow Doppler lines, such as carbon disulfide (CS(2)) and its three isotopologues.

180 riggered by a single chemical cue - dimethyl disulfide (DMDS) - emitted from carcasses consumed by bl

181 Regulation of enzyme activity based on thiol-disulfide exchange is a regulatory mechanism in which th

182 The thiol-disulfide exchange reaction is of specific interest as i

183 monstrate detection of single-molecule thiol-disulfide exchange using a label-free optoplasmonic sens

184 iratory chain, glycolysis also enables thiol/disulfide exchange-mediated folding of bacterial cell en

185 Crystal structures reveal how each disulfide exerts opposing effects on structure and funct

186 Iron disulfide (FeS(2)) was the main S species of SNZVI made

187 rearrangement that primes the Cys-122-Cys-66 disulfide for thioredoxin reduction and a reversible pro

188 in Cd-MsrB through intra- and intermolecular disulfide formation and S-mycothiolation.

189 ause I/R impairs oxygen-dependent ER protein disulfide formation and such impairment can be caused by

190 Additionally, intermolecular disulfide formation between PKA type I regulatory subuni

191 sham surgery were used to assess PKARIalpha disulfide formation by immunoblot.

192 The facile control of disulfide formation in M88 will enable the development o

193 ted compounds equally induced intermolecular disulfide formation in PKA-RI, only 1-nitrosocyclohexaly

194 phosphatases are sensitive to intramolecular disulfide formation in their catalytic subunits that inh

195 results on covalent homodimerization through disulfide formation of the full-length mini-protein and

196 bsequent MS analysis indicated corresponding disulfide formation of the substrates, suggesting that t

197 However, the effect of PKARIalpha disulfide formation on downstream signaling in the heart

198 To determine the effect of disulfide formation on PKARIalpha catalytic activity and

199 both humans and mice, myocardial PKARIalpha disulfide formation was found to be significantly increa

200 cross-linking (e.g., Schiff base formation, disulfide formation, reversible Diels-Alder reactions),

201 established human cell lines with a designer disulfide FRET probe.

202 solution studies confirmed that the strained disulfides function as redox "switches" to reversibly re

203 ect transistor biosensor based on molybdenum disulfide/graphene (MoS(2)/graphene) hybrid nanostructur

204 psis PLANT ELICITOR PEPTIDE, and glutathione disulfide (GSSG) treatments induced rapid spatiotemporal

205 The oxidation of alkyl thiols to disulfides has been achieved under mild conditions using

206 Disulfide HMGB1 levels increased concomitantly with IRI

207 RI(+) blood stimulated further production of disulfide-HMGB1 and increased proinflammatory molecule a

208 nts with histopathological IRI had increased disulfide-HMGB1 and induced Toll-like receptor 4-depende

209 These data identify disulfide-HMGB1 as a mechanistic biomarker of, and thera

210 Purified disulfide-HMGB1 or IRI(+) blood stimulated further produ

211 macrophages with hyperacetylated, lysosomal disulfide-HMGB1 that increased postreperfusion at sites

212 Whereas the disulfide in M112 disrupts the closed conformation to in

213 closed conformation to increase k(off), the disulfide in M88 stabilizes the closed conformation, dec

214 envelope homeostasis by forming stabilizing disulfides in crucial bacterial assembly factors (LptD,

215 cyl tetrasulfides to yield the corresponding disulfides in good to excellent yields.

216 addition of NaOH provides the corresponding disulfides in the case of amino azoles, and pyrimidine-f

217 The simple and efficient reduction of this disulfide increases k(off) 19,000-fold, thus creating a

218 The reaction proceeds via disulfide intermediate disulfanediylbis(3-(alkylthio)-1-

219 is study, we describe a new class of protein disulfide isomerase (PDI) inhibitors that significantly

220 plasmic reticulum and is mediated by protein disulfide isomerase (PDIA1).

221 secreted tick protein, I. scapularis protein disulfide isomerase A3 (IsPDIA3), enhances B. burgdorfer

222 in Pdia6, an essential gene encoding protein disulfide isomerase A6 (PDIA6), an oxidoreductase that f

223 Here we show that an ER protein disulfide isomerase, thioredoxin domain containing 5 (TX

224 ed by ER oxidoreductin 1 (Ero1), and protein disulfide-isomerase can be inactivated by a feedback inh

225 For this purpose, disulfide isomers of three peptides bearing two intramol

226 onor thiol and its analogous N(4) S(2) donor disulfide ligands.

227 jugated to the N-terminus of ubiquitin via a disulfide linkage to deliver the probe into live cells.

228 Mapping highly complicated disulfide linkages and free thiols via liquid chromatogr

229 lfhydryl group and leads to the formation of disulfide linkages and thus improves the bread propertie

230 o complexes in cell extracts suggesting that disulfide linkages in the cysteine-rich region perform a

231 analogues at three different positions using disulfide linkages.

232 Disulfide-linked ADCs captured from plasma were chemical

233 veloped acDrug PK assays for next-generation disulfide-linked ADCs involving immunoaffinity capture,

234 2S albumins are diverse, they have a common disulfide-linked core with similar physicochemical prope

235 eviously showed that a cell culture-derived, disulfide-linked high-molecular-weight (HMW) form of the

236 a disulfide-minimized version (D123A7), into disulfide-linked HMW-like species (Delta123r and Delta12

237 h subunit of the trimeric HA consists of two disulfide-linked polypeptides, HA1 and HA2.

238 ease in affinity when tethered to Ube2N in a disulfide-linked substrate that mimics the charged E2~Ub

239 of P/rds purified from OS membranes revealed disulfide-linked tetramer chains up to 100 nm long, sugg

240 R(561)-V(562) peptide bond, resulting in the disulfide-linked two-chain protease, human plasmin (hPm)

241 poly(N(3)-alpha-epsilon-caprolactone) with a disulfide linker pendant from the caprolactone regions i

242 gent containing a perfluoroalkyl chain and a disulfide linker.

243 [R273C]p53 aggregation is disulfide mediated, leading to cross-beta, thioflavin-T-

244 P/rds activity was promoted by disulfide-mediated tetramer polymerization, which transf

245 gh-yielding monomeric E2 species, D123 and a disulfide-minimized version (D123A7), into disulfide-lin

246 d versatile reaction enables introduction of disulfide moieties from a variety of radical precursors

247 nal fillings of tungsten diselenide/tungsten disulfide moire superlattices.

248 als in the ground state, SH(X), and hydrogen disulfide molecules, H(2)S, are both detected in the int

249 -S to Ni(II) ) transformations via thiyl and disulfide monoradical anions that resemble a primary ste

250 semiconductors such as monolayer molybdenum disulfide (MoS(2) ) are promising material candidates fo

251 Molybdenum disulfide (MoS(2) ) is a multifunctional material that c

252 Forming pits on molybdenum disulfide (MoS(2) ) monolayers is desirable for (opto)el

253 Molybdenum disulfide (MoS(2) ) nanosheet is a two-dimensional (2D)

254 hexagonal boron nitride (BN) and molybdenum disulfide (MoS(2)) crystals on single-walled carbon nano

255 Molybdenum disulfide (MoS(2)) laminar membranes have recently demon

256 Two-dimensional (2D) molybdenum disulfide (MoS(2)) nanomaterials are an emerging class o

257 Few-layered molybdenum disulfide (MoS(2)) nanosheets are poised to be at the co

258 AR3X utilizes both its ultralong CDRH2 and a disulfide motif-containing straight CDRH3 to recognize t

259 are tethered to one another by an extensive disulfide network that differs in architecture from prev

260 exposes the C-terminal sequence, but not its disulfide-oxidized counterpart that protects it, experie

261 entially react with redox proteins including disulfide oxidoreductase enzymes, accounting for their s

262 ide connectivity (i.e. the Cys 1-2, 3-4, 5-6 disulfide pattern).

263 at AspH substrates have a non-canonical EGFD disulfide pattern.

264 Here, we identified the single-disulfide peptides Czon1107 and Cca1669 from the venoms

265 d NAD-to-NADH and glutathione-to-glutathione disulfide ratios, increased NOX4 expression, apoptosis a

266 urements, enabling the observation of single disulfide reaction kinetics and pathways on a plasmonic

267 lysis of the folding reactions, we found the disulfide-reduced form of the protein that exposes the C

268 isms giving rise to the internal friction of disulfide-reduced mSOD1 might play a role in the amyotro

269 a regulatory mechanism in which the protein disulfide reductase activity of thioredoxins (TRXs) play

270 The n->pai* interactions in ETPs make disulfide reduction much more difficult, endowing stabil

271 orted into mitochondria by the mitochondrial disulfide relay.

272 ned, which enhances the oxidative folding of disulfide-rich cyclic proteins such in the case of Kalat

273 irst of a unique structural class of knotted disulfide-rich peptides and defines a previously unseen

274 and MS analysis of conformational isomers of disulfide-rich peptides and proteins.

275 Twenty-six of the 33 superfamilies are disulfide-rich peptides, and we show that 15 of these ar

276 te/Ni(II) -disulfide (both bound and unbound disulfide-S to Ni(II) ) transformations via thiyl and di

277 favored globular conformation and suppressed disulfide scrambling.

278 e noncanonical EGFD AspH substrates to avoid disulfide shuffling.

279 identification and assignment of physisorbed disulfides solve a long-standing mystery and reveal new,

280 s that were partially reduced and form mixed-disulfide species on nonreducing gels.

281 Structures of the disulfide-stabilized and non-disulfide-stabilized protei

282 ructures of the disulfide-stabilized and non-disulfide-stabilized proteins reveal distinct closed and

283 Here, we characterize a disulfide-stabilized version of the human class I molecu

284 A disulfide-stabilized, trimeric Env ectodomain-the "SOSIP

285 e mutations did not appear to directly alter disulfide status of FAD4.

286 so reveals one natural source of cytoplasmic disulfide stress and sheds light on a role for broad-spe

287 reptavidin muteins (M88 and M112) with novel disulfide-switchable binding properties.

288 ysical characteristics of such dimers, using disulfide-templated (PPG)(10) dimers as a model.

289 The tetraethylthiuram disulfide (TETD) molecule shows high solubility in vario

290 is platform identifies heterogeneous protein disulfide/thiol patterns in a de-novo fashion with artif

291 workflow was applied to characterize unknown disulfide/thiol patterns of the recombinant cyclophilin

292 from chalcones and then condense with carbon disulfide to afford 8-azachromones containing a methylth

293 disulfide cascade expose the Cys-122-Cys-66 disulfide to recycling through thioredoxin.

294 lustrate Ni-ion mediated reversible thiolate/disulfide transformation are unknown.

295 Reducing the C55-C175 disulfide triggers alpha9 release, which promotes mitoch

296 Symmetric reduction of the intramonomeric disulfides triggers marked dynamical heterogeneity, inte

297 formed reversible intra- and intermolecular disulfides without losing its Cys-coordinated Zn(2+), an

298 by growing supertwisted spirals of tungsten disulfide (WS(2)) and tungsten diselenide (WSe(2)) drape

299 Tungsten disulfide (WS(2)) with an average particle size of 2 mum

300 urfactant stabilized/functionalized tungsten disulfide (WS(2)-B) quantum dots (QDs) and its applicati