Pathways for protein disulphide bond formation

The folding of many secretory proteins depends upon the formation of disulphide bonds. Recent advances in genetics and cell biology have outlined a core pathway for disulphide bond formation in the endoplasmic reticulum (ER) of eukaryotic cells. In this pathway, oxidizing equivalents flow from the recently identified ER membrane protein Ero1p to secretory proteins via protein disulphide isomerase (PDI). Contrary to prior expectations, oxidation of glutathione in the ER competes with oxidation of protein thiols. Contributions of PDI homologues to the catalysis of oxidative folding will be discussed, as will similarities between eukaryotic and prokaryotic disulphide-bond-forming systems.     

Building bridges: disulphide bond formation in the cell

Disulphides are often vital for the folding and stability of proteins. Dedicated enzymatic systems have been discovered that catalyse the formation of disulphides in the periplasm of prokaryotes. These discoveries provide compelling evidence for the actual catalysis of protein folding in vivo. Disulphide bond formation in Escherichia coli is catalysed by at least three ‘Dsb’ proteins; DsbA, -B and -C. The DsbA protein has an extremely reactive, oxidizing disulphide which it simply donates directly to other proteins. DsbB is required for the reoxidation of DsbA. DsbC is active in disulphide rearrangements and appears to work synergistically with DsbA. The relative rarity of disulphides in cytoplasmic proteins appears to be dependent upon a disulphide-destruction machine. One pivotal cog in this machine is thioredoxin reductase.     

A homologue of the Escherichia coli DsbA protein involved in disulphide bond formation is required for enterotoxin biogenesis in Vibrio cholerae

A strain of Vibrio cholerae, which had been engineered to express high levels of the non-toxic B subunit (EtxB) of Escherichia coli heat-labile enterotoxin, was subjected to transposon (TnphoA) mutagenesis. Two chromosomal TnphoA insertion mutations of the strain were isolated that showed a severe defect in the amount of EtxB produced. The loci disrupted by TnphoA in the two mutant derivatives were cloned and sequenced, and this revealed that the transposon had inserted at different sites in the same gene. The open reading frame of the gene predicts a 200-amino-acid exported protein, with a Cys-X-X-Cys motif characteristic of thioredoxin, protein disulphide isomerase, and DsbA (a periplasmic protein required for disulphide bond formation in E. coli). The V. cholerae protein exhibited 40% identity with the DsbA protein of E. coli, including 90% identity in the region of the active-site motif. Introduction of a plasmid encoding E. coli DsbA into the V. cholerae TnphoA derivatives was found to restore enterotoxin formation, whilst expression of Etx or EtxB in a dsbA mutant of E. coli confirmed that DsbA is required for enterotoxin formation in E. coli. These results suggest that, since each EtxB subunit contains a single intramolecular disulphide bond, a transient intermolecular interaction with DsbA occurs during toxin subunit folding which catalyses formation of the disulphide in vivo.     

A flavoprotein oxidase defines a new endoplasmic reticulum pathway for biosynthetic disulphide bond formation

Ero1 and Pdi1 are essential elements of the pathway for the formation of disulphide bonds within the endoplasmic reticulum (ER). By screening for alternative oxidation pathways in Saccharomyces cerevisiae, we identified ERV2 as a gene that when overexpressed can restore viability and disulphide bond formation to an ero1-1 mutant strain. ERV2 encodes a luminal ER protein of relative molecular mass 22,000. Purified recombinant Erv2p is a flavoenzyme that can catalyse O2-dependent formation of disulphide bonds. Erv2p transfers oxidizing equivalents to Pdi1p by a dithiol-disulphide exchange reaction, indicating that the Erv2p-dependent pathway for disulphide bond formation closely parallels that of the previously identified Ero1p-dependent pathway.     

Periplasmic disulphide bond formation is essential for cellulase secretion by the plant pathogen Erwinia chrysanthemi

Secretion to the cell exterior of cellulase EGZ and of at least six pectinases enables the Gram-negative Erwinia chrysanthemi to cause severe plant disease. The C-terminal cellulose-binding domain (CBD) of EGZ was found to contain a disulphide bond which forms, in the periplasm, between residues Cys-325 and Cys-382. Dithiothreitol (DTT)-treatment of native EGZ showed that the disulphide bond was dispensable, both for catalysis and cellulose binding. Adding DTT to E. chrysanthemi cultures led to immediate arrest of secretion of EGZ which accumulated in the periplasm where the CBD was eventually proteolysed. Site-directed mutagenesis that affected Cys residues involved in disulphide bond formation resulted in molecules that were catalytically active and able to bind to cellulose but were no longer secreted, Instead they accumulated in the periplasm. Interestingly, the region around EGZ Cys-325 is conserved in two pectinases secreted by the same pathway as EGZ. We conclude that the conserved Cys, and possibly adjacent residues, bear essential information for EGZ to be secreted and that periplasmic disulphide bond formation is an obligatory step which provides a pre-folded functional form of EGZ with secretion competence.     

Catechol as a nucleophilic catalyst of peptide bond formation.

The aminolysis of a mildly activated aminoacid ester, benzyloxycarbonyl-L-phenylalanine cyanomethyl ester, by glycine esters in the presence of catechol has been studied as a model of catalysis by RNA cis-vicinal-diol systems in protein biosynthesis. Catechol accelerated the aminolysis, especially in the presence of bases, probably by nucleophilic catalysis.     

The requirement for DsbA in pullulanase secretion is independent of disulphide bond formation in the enzyme

Results from previous studies have suggested that an intramolecular disulphide bond in the exoprotein pullulanase is needed for its recognition and transport across the outer membrane. This interpretation of the data is shown here to be incorrect: pullulanase devoid of all potential disulphide bonds is secreted with apparently the same efficiency as the wild-type protein. Furthermore, the periplasmic disulphide bond, oxidoreductase DsbA, previously shown to catalyse the formation of a disulphide bond in pullulanase and to decrease its transit time in the periplasm, is shown here to be required for the rapid secretion of pullulanase devoid of disulphide bonds. Several possible explanations for the role of DsbA in pullulanase secretion are discussed.     

Tantalum pentachloride as a coupling agent for stereohindered amide bond formation

We have previously reported that tantalum carboxylates show high reactivity toward primary amines to give primary amides. We report herein that tantalum pentachloride, in contrast with the behavior of standard coupling reagents, mediates the couplings of secondary amines and the couplings of very hindered carboxylates. Such coupling reactions are particularly difficult to achieve, when using chiral carboxylates (including N-protected amino acids), without a significant degree of accompanying racemization. Racemization levels with the present systems are found to be very low in comparison with those obtained using a standard amide/peptide coupling system (DCC/HOBt).     

Intermolecular disulfide bond formation in the NEMO dimer requires Cys54 and Cys347

NEMO is an essential regulatory component of the IκB kinase (IKK) complex, which controls activation of the NF-κB signaling pathway. Herein, we show that NEMO exists as a disulfide-bonded dimer when isolated from several cell types and analyzed by SDS-polyacrylamide gel electrophoresis under non-reducing conditions. Treatment of cells with hydrogen peroxide (H₂O₂) induces further formation of NEMO dimers. Disulfide bond-mediated formation of NEMO dimers requires Cys54 and Cys347. The ability of these residues to form disulfide bonds is consistent with their location in a NEMO dimer structure that we generated by molecular modeling. We also show that pretreatment with H₂O₂ decreases TNFα-induced IKK activity in NEMO-reconstituted cells, and that TNFα has a diminished ability to activate NF-κB DNA binding in cells reconstituted with NEMO mutant C54/347A. This study implicates NEMO as a target of redox regulation and presents the first structural model for the NEMO protein.     

Identification of Vibrio spp. with the 'string' test

The 'string' test has been described as a test for the initial characterization of Vibrio spp., in particular, to differentiate between Vibrio and Aeromonas spp. Despite early literature questioning the validity of the test, its use has continued to be recommended. In this study, 49 Vibrio spp., 32 Aeromonas spp. and 47 enteric Gram-negative bacilli were tested and it was found that four genera gave a positive 'string' test, including Vibrio, Aeromonas, Pseudomonas and Klebsiella. The sensitivity and specificity of the test for separating Vibrio spp. from other Gram-negative bacilli were 86% and 70%, respectively. Hence the use of the string test in the initial characterization of Vibrio spp. should be supported by appropriate confirmatory tests.     

Evidence for a partially folded intermediate in alpha-synuclein fibril formation

Intracellular proteinaceous aggregates (Lewy bodies and Lewy neurites) of alpha-synuclein are hallmarks of neurodegenerative diseases such as Parkinson's disease, dementia with Lewy bodies, and multiple systemic atrophy. However, the molecular mechanisms underlying alpha-synuclein aggregation into such filamentous inclusions remain unknown. An intriguing aspect of this problem is that alpha-synuclein is a natively unfolded protein, with little or no ordered structure under physiological conditions. This raises the question of how an essentially disordered protein is transformed into highly organized fibrils. In the search for an answer to this question, we have investigated the effects of pH and temperature on the structural properties and fibrillation kinetics of human recombinant alpha-synuclein. Either a decrease in pH or an increase in temperature transformed alpha-synuclein into a partially folded conformation. The presence of this intermediate is strongly correlated with the enhanced formation of alpha-synuclein fibrils. We propose a model for the fibrillation of alpha-synuclein in which the first step is the conformational transformation of the natively unfolded protein into the aggregation-competent partially folded intermediate.     

沙门菌、志贺菌、副溶血性弧菌多重PCR检测方法的研究

建立快速检测沙门菌、志贺菌和副溶血性弧菌的多重PCR方法[1-4].根据沙门菌hilA基因、志贺菌ipaH基因及副溶血性弧菌TDH基因设计特异性PCR引物[5-6],被检样品经4 h振荡培养后金属浴裂解制备DNA模板,使用全自动毛细管电泳核酸检测系统分析PCR扩增产物.在580、423和245 bp处分别出现预期的特异性DNA条带,且无非特异扩增条带出现.敏感性试验显示沙门菌在模拟标本中的检测灵敏度为101-2cfu/mL、志贺菌为101cfu/mL、副溶血性弧菌为102cfu/mL.该方法操作方便、分析时间短、特异性和灵敏度高,可用于公共卫生突发事件食源性病原菌的快速检测.     

C-H-deprotonation mediated by a remote syn-axial acetoxy group--an unprecedented double bond formation upon cyanation of the dimer from L-fucal

Replacement of the anomeric acetate by a cyanide group in the dimer of di-O-acetyl-L-fucal by the action of mild Lewis acid [Hg(CN)(2)-HgBr(2)-Me(3)SiCN], resulted not only in the desired transformation but also in the introduction of an additional double bond between C-2A and C-3A. Due to its configuration, the remote C-4A acetoxy group may facilitate the deprotonation by functioning as an internal base. 1H NMR spectroscopy and X-ray crystallography indicate that the conformations of both rings A and B and their relative orientation in the resulting C-linked disaccharidic glycosyl cyanide, 4-O-acetyl-2-C-(4-O-acetyl-2,3-dideoxy-alpha-L-threo-hex-2-enopyranosyl)-2,3-dideoxy-2-eno-alpha-L-fucopyranosyl cyanide, in solution are virtually identical to the crystal structure.     

Arbitrarily primed PCR to type Vibrio spp. pathogenic for shrimp

A molecular typing study on Vibrio strains implicated in shrimp disease outbreaks in New Caledonia and Japan was conducted by using AP-PCR (arbitrarily primed PCR). It allowed rapid identification of isolates at the genospecies level and studies of infraspecific population structures of epidemiological interest. Clusters identified within the species Vibrio penaeicida were related to their area of origin, allowing discrimination between Japanese and New Caledonian isolates, as well as between those from two different bays in New Caledonia separated by only 50 km. Other subclusters of New Caledonian V. penaeicida isolates could be identified, but it was not possible to link those differences to accurate epidemiological features. This contribution of AP-PCR to the study of vibriosis in penaeid shrimps demonstrates its high discriminating power and the relevance of the epidemiological information provided. This approach would contribute to better knowledge of the ecology of Vibrio spp. and their implication in shrimp disease in aquaculture.     

Interchain disulfide bond formation in types I and II procollagen. Evidence for a protein disulfide isomerase catalyzing bond formation

The assembly of reduced pro-alpha chains of type I and type II procollagen into the native triple-helical molecule was examined in vitro in the presence and absence of pure protein disulfide isomerase. The data clearly indicates that protein disulfide isomerase is able to accelerate the formation of native interchain disulfide bonds in these procollagens. It takes about 6 min after disulfide bonding before triple-helical molecules exist, while the time required to produce triple-helical type I procollagen in the presence of protein disulfide isomerase is 9.4 min and that for type II procollagen 17.2 min. These values agree with those obtained for type I and II procollagen in vivo suggesting that protein disulfide isomerase is also an enzyme catalyzing interchain disulfide bond formation in procollagen in vivo. The formation of native disulfide bonds can proceed without any enzyme catalysis but then requires the presence of reduced and oxidized glutathione. Bonding is rather slow in such a case, however, resulting in a delay in the formation of the triple helix.