The reactions of inter- and intra-chain disulphide bonds in proteins with sulphite

Cecil, R.; Wake, R.G.

doi:10.1042/bj0820401

Cited by 146 publications

(40 citation statements)

References 21 publications

(11 reference statements)

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“…This difference in the susceptibility of the inter-chain and intra-chain disulfide bonds to reduction has been explained by Cecil and Wake [34]. They proposed that intra-chain disulfide bonds commonly form compact ring structures stabilized by hydrogen bonds (or other non-covalent bonds).…”

Section: Discussionmentioning

confidence: 94%

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

Tomasi¹,

Battistini²,

Araco³

et al. 1979

European Journal of Biochemistry

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The chemical reactivity of disulfide bonds towards reducing agents, in the absence of denaturing conditions, in cholera toxin has been studied. Treatment of the toxin with dithiothreitol or other mercaptans gave selective reduction of one of the six disulfide bonds of the protein. This reactive disulfide links two distinct functional regions of the toxin, fragment CI, which activates adenylate cyclase, and fragment y/35, which recognizes the cell surface receptors. Upon reduction, the two fragments remain bound together and the secondary structure of the protein is retained. The two functional regions have been separated and purified only by methods based on charge differences. When mixed together, purified a and purified y/35 fragments spontaneously and rapidly re-form the disulfide bond. However, reduction of the disulfide bond is an absolute requirement for freeing the catalytic site of the CI functional region. Thus, while other non-covalent binding regions are involved in maintaining cholera toxin molecular structure, the reactive disulfide bond may play a role in the mechanism of cell intoxication.Cholera toxin is a protein extremely potent in stimulating the membrane-bound enzyme, adenylate cyclase, in a variety of mammalian cells [1,2]. It has been shown that the toxin molecule is composed of two protomeric species A and B [3-81. Protonier A contains two non-identical polypeptide chains CI and y, linked through a single disulfide bond. The remainder of the molecule consists of five identical polypeptide chains [9], each containing a single intra-chain disulfide bond, forming a stable aggregate, protomer B.Thus, the toxin has a molecular formula ay/35. The A protomer is required for the activation of adenylate cyclase [lo], while protomer B is responsible for the binding of the toxin to the cell [ll,12], interacting specifically with the hydrophilic moiety of ganglioside GMI [13].Protomer A and B are very tightly bound as shown by their slow dissociation in sodium dodecyl sulfate or urea solutions. Dissociation conditions in acid pH, with or without unfolding agents, separate cholera toxin into two fractions, protomer A and the disaggregated /3 polypeptide chains [3,6,7]. Although the lipid environment of the cell membrane might ayl-(N-acetylneuraminyl)-galactosylglucosylceramide.mimic the properties of detergents, no direct evidence of the dissociation in vivo of protomers A and B has been described. It seems more probable, as suggested by Gill [8], that one of the commited steps in the intoxication process is the cleavage of one of the six disulfide bonds of cholera toxin. Exposure of native toxin to dithiothreitol, in the absence of denaturing agents, splits selectively the reactive disulfide bond joining the CI and y polypeptide chains. This partial reduction results in the formation of two fragments, possessing functional properties, the a chain and a complex of the y polypeptide chain and protomer B, y/35 [3 -8,141. The a fragment stimulates adenylate cyclase in cell-free systems in an NAD-dependen...

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Section: Discussionmentioning

confidence: 94%

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

Tomasi¹,

Battistini²,

Araco³

et al. 1979

European Journal of Biochemistry

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“…Another case of facilitated sulfitolysis with physiological significance, produced by 1 mM sulfite, concerns the mixed-disulfide bond present in the non-mercaptalbumin fraction of rabbit plasma proteins [12]. In contrast, insulin undergoes partial sulfitolysis only in 20-3OmM sulfite solution and the internal disulfide bridges in larger proteins such as lysozyme, ribonuclease, or bovine serum albumin are largely resistant to sulfite in the absence of denaturants [6], excluding a role as toxicological targets.…”

Section: Discussionmentioning

confidence: 99%

Facile sulfitolysis of the disulfide bonds in oxidized thioredoxin and glutaredoxin

Würfel

Häberlein

Follmann

1993

European Journal of Biochemistry

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Thioredoxins and glutaredoxins, in their oxidized form, possess a single disulfide bridge located on an edge of the small compact molecules. In contrast to most other disulfide-containing proteins, this S-S bridge is cleaved by millimolar concentrations of sulfite in the absence of protein denaturing agents at pH 7-8 and ambient temperature; however, the reaction is not quantitative. Sulfitolysis of Escherichia coli thioredoxin was found to be associated .with an increase in fluorescence at 345 nm. A comparative study of sulfitolysis in 12 different thioredoxins and glutaredoxins of bacterial and plant origin has been made. Although they are all thought to be highly conserved in threedimensional structure, their reactivities towards sulfite and the effects of 6 M guanidinium chloride (not affecting, or enhancing sulfitolysis) vary strongly in the series, with E. coli thioredoxin being less reactive and plant thioredoxins and E. coli glutaredoxin being more susceptible molecules. Contrary to expectation, reaction with sulfite is not generally correlated with the presence of negatively or positively charged amino acid residues near the disulfide loop but is determined by individ-

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“…RuDP carboxylase (Ziegler, 1972). Finally, the ability of bisulphite to cleave disulphide bonds in proteins is a potential mode of attack (Mahler and Cordes, 1966, p. 74;Roy and Trudinger, 1970 p. 16;Bailey and Cole, 1959;Cecil and Wake, 1962). This cleavage causes changes in the tertiary structure of proteins leading to deactivation in the case of enzymes.…”

Section: Discussionmentioning

confidence: 99%

PHOTOSYNTHETIC ¹⁴C FIXATION BY THE LICHEN UMBILICARIA MUHLENBERGH (ACH) TUCK. FOLLOWING SHORT EXPOSURES TO AQUEOUS SULPHUR DIOXIDE

et al. 1974

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SUMMARY Photosynthetic 14C fixation by the lichen Umbilicaria muhlenbergii was reduced within 15 min of exposure to aqueous sulphur dioxide (75 ppm, pH 3.0), but no changes were observed in the spectra of extracted chlorophyll pigments. Exposed lichen samples maintained under moist, sulphur‐dioxide‐free conditions in the light for 24 h were able to fix 14C at pre‐exposure levels. Partial recovery was observed when samples were kept under moist dark conditions but little when the lichens were maintained dry in the light or dark. When samples were exposed repeatedly to sulphur dioxide, but with a recovery period between each exposure, they gradually lost the ability to regain their photosynthetic activity. After the third cycle of exposure and recovery, little 14C fixation was observed while changes in the spectra of extracted pigments was evident. Increased potassium levels were found in the medium during exposure. These levels reverted to control values after a suitable recovery period. In vitro studies showed that 10‐20 ppm sulphur dioxide was found to deactivate both staphylococcal nuclease and lysozyme. Possible explanations as to the mode of SO2 toxicity on lichen metabolism and suggestions as to recovery mechanisms are fully discussed.

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The reactions of inter- and intra-chain disulphide bonds in proteins with sulphite

Cited by 146 publications

References 21 publications

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

Facile sulfitolysis of the disulfide bonds in oxidized thioredoxin and glutaredoxin

PHOTOSYNTHETIC ¹⁴C FIXATION BY THE LICHEN UMBILICARIA MUHLENBERGH (ACH) TUCK. FOLLOWING SHORT EXPOSURES TO AQUEOUS SULPHUR DIOXIDE

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The reactions of inter- and intra-chain disulphide bonds in proteins with sulphite

Cited by 146 publications

References 21 publications

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

The Role of the Reactive Disulfide Bond in the Interaction of Cholera‐Toxin Functional Regions

Facile sulfitolysis of the disulfide bonds in oxidized thioredoxin and glutaredoxin

PHOTOSYNTHETIC 14C FIXATION BY THE LICHEN UMBILICARIA MUHLENBERGH (ACH) TUCK. FOLLOWING SHORT EXPOSURES TO AQUEOUS SULPHUR DIOXIDE

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PHOTOSYNTHETIC ¹⁴C FIXATION BY THE LICHEN UMBILICARIA MUHLENBERGH (ACH) TUCK. FOLLOWING SHORT EXPOSURES TO AQUEOUS SULPHUR DIOXIDE