Penicillin-binding protein SpoVD disulphide is a target for StoA in Bacillus subtilis forespores

The bacterial endospore is a dormant and heat-resistant form of life. StoA (SpoIVH) in Bacillus subtilis is a membrane-bound thioredoxin-like protein involved in endospore cortex synthesis. It is proposed to reduce disulphide bonds in hitherto unknown proteins in the intermembrane compartment of developing forespores. Starting with a bioinformatic analysis combined with mutant studies we identified the sporulation-specific, high-molecular-weight, class B penicillin-binding protein SpoVD as a putative target for StoA. We then demonstrate that SpoVD is a membrane-bound protein with two exposed redox-active cysteine residues. Structural modelling of SpoVD, based on the well characterized orthologue PBP2x of Streptococcus pneumoniae , confirmed that a disulphide bond can form close to the active site of the penicillin-binding domain restricting access of enzyme substrate or functional association with other cortex biogenic proteins. Finally, by exploiting combinations of mutations in the spoVD , stoA and ccdA genes in B. subtilis cells, we present strong in vivo evidence that supports the conclusion that StoA functions to specifically break the disulphide bond in the SpoVD protein in the forespore envelope. The findings contribute to our understanding of endospore biogenesis and open a new angle to regulation of cell wall synthesis and penicillin-binding protein activity.     

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.     

Characterization of a gene encoding a Pichia pastoris protein disulfide isomerase

Protein disulphide isomerases belong to the thioredoxin superfamily of protein-thiol oxidoreductases that have two double-cysteine redox-active sites and take part in protein folding in the endoplasmic reticulum (ER). We report here the cloning of a Pichia pastoris genomic DNA fragment (2919 bp) that encodes the full length of a protein disulphide isomerase (PpPDI). The deduced amino acid sequence of PDI consists of 517 residues and carries the two characteristic PDI-type redox-active domains -CGHC-, separated by 338 residues, and two potential N-glycosylation sites. The N-terminal end forms a putative signal sequence, and an acidic C-terminal region represents a possible calcium-binding domain. Together with the -HDEL ER retrieval sequence at the C-terminus, these features indicate that the gene encodes a redox-active ER-resident protein disulphide isomerase. The nucleotide sequence, which also contains two other open reading frames, has been submitted to the EMBL Nucleotide Sequence Database, Accession No. AJ302014.     

ERp57 is essential for efficient folding of glycoproteins sharing common structural domains

ERp57 is a member of the protein disulphide isomerase family of oxidoreductases, which are involved in native disulphide bond formation in the endoplasmic reticulum of mammalian cells. This enzyme has been shown to be associated with both calnexin and calreticulin and, therefore, has been proposed to be a glycoprotein-specific oxidoreductase. Here, we identify endogenous substrates for ERp57 by trapping mixed disulphide intermediates between enzyme and substrate. Our results demonstrate that the substrates for this enzyme are mostly heavily glycosylated, disulphide bonded proteins. In addition, we show that the substrate proteins share common structural domains, indicating that substrate specificity may involve specific structural features as well as the presence of an oligosaccharide side chain. We also show that the folding of two of the endogenous substrates for ERp57 is impaired in ERp57 knockout cells and that prevention of an interaction with calnexin or calreticulin perturbs the folding of some, but not all, substrates with multiple disulphide bonds. These results suggest a specific role for ERp57 in the isomerisation of non-native disulphide bonds in specific glycoprotein substrates.     

Bacterial conjugation: a two-step mechanism for DNA transport

Ten years ago it was thought that disulphide bond formation in prokaryotes occurred spontaneously. Now two pathways involved in disulphide bond formation have been well characterized, the oxidative pathway, which is responsible for the formation of disulphides, and the isomerization pathway, which shuffles incorrectly formed disulphides. Disulphide bonds are donated directly to unfolded polypeptides by the DsbA protein; DsbA is reoxidized by DsbB. DsbB generates disulphides de novo from oxidized quinones. These quinones are reoxidized by the electron transport chain, showing that disulphide bond formation is actually driven by electron transport. Disulphide isomerization requires that incorrect disulphides be attacked using a reduced catalyst, followed by the redonation of the disulphide, allowing alternative disulphide pairing. Two isomerases exist in Escherichia coli, DsbC and DsbG. The membrane protein DsbD maintains these disulphide isomerases in their reduced and thereby active form. DsbD is kept reduced by cytosolic thioredoxin in an NADPH-dependent reaction.     

Kinetics of refolding of reduced ribonuclease

The kinetics of disulphide bond formation in reduced ribonuclease have been determined by following electrophoretically the appearance and disappearance of protein molecules with one, two, three or four intramolecular disulphide bonds. Each successive protein disulphide bond was observed to be formed much less readily than the preceding one, and the resulting species are increasingly unstable to reduction of their disulphide bonds. Most of the species formed directly, even those with four disulphide bonds, do not have the electrophoretic mobility of native protein.Protein molecules apparently refolded correctly are formed by slow intramolecular interconversion of molecules with three disulphide bonds and by thiolcatalyzed interchange of incorrect disulphide bonds in three-or four-disulphide species.These observations are compared with the properties of the folding pathway elucidated for pancreatic trypsin inhibitor under the same conditions and are contrasted with those often envisaged as to how proteins might fold.     

SP-40,40, a protein involved in the control of the complement pathway, possesses a unique array of disulphide bridges.

SP-40,40 is a two-chain serum protein which acts in vitro as a potent inhibitor of the assembly of the membrane attack complex of human complement. It contains 10 cysteine residues, the numbers and locations of which are conserved in several mammalian species. Evidence is presented that all the cysteine residues are involved in interchain (alpha-beta) disulphide bonds. There are no free cysteine residues. The disulphide bond motif established in this study for SP-40,40 is unique and bears no obvious homology to those complement components whose disulphide bonds have been assigned, nor is there any homology apparent between SP-40,40 and other multi-chain proteins containing disulphide bonds.     

The single-disulphide intermediates in the refolding of reduced pancreatic trypsin inhibitor

The intermediate species with one disulphide bond in the renaturation of reduced pancreatic trypsin inhibitor have been trapped, isolated, and the Cys residues involved in the disulphide bonds determined. Approximately half the intermediate species had the disulphide bond between Cys-30 and 51, a disulphide bond also present in the native inhibitor. The next most predominant species, representing one-quarter of the total, had a disulphide bond between Cys-5 and 30, and two more minor species involving Cys-30 and 55 and Cys-5 and 51 were detected; these disulphide bonds are not present in the native inhibitor.The nature of the disulphide bonds present are concluded to reflect primarily the conformational forces acting at this stage of folding, which may be primarily interactions between segments with propensities for secondary structure, either helices or β-sheet. The general importance of such interactions in protein folding is discussed.     

Subunits of Tamm–Horsfall glycoprotein

1. The effect of 6m-guanidine hydrochloride on the urinary glycoprotein described by Tamm & Horsfall (1952) is to produce a homogeneous subunit of molecular weight approx. 100000. 2. Complete reduction of the disulphide bonds of this subunit does not decrease the molecular weight, suggesting that all disulphide bonds are intrachain. 3. Comparison of sedimentation and viscometric behaviour of unreduced and reduced material in 6m-guanidine hydrochloride is consistent with reduction causing an opening-up of intrachain disulphide bonds to give a more asymmetric molecule.     

Large increase in disulphide bonds containing cytosol proteins after chronic cadmium administration, estimated in isolated rat liver cells

Using histochemical staining, followed by cytophotometric quantitation of disulphide bonds and total protein in isolated liver cells of rats treated for a long time with low doses of CdCl2, a large increase in disulphide bonds containing proteins could be demonstrated in cells of one ploidy class. This increase seems to be due to an increase in high molecular weight (HMW) cytosol proteins as estimated biochemically. They probably represent polymers of metallothionein.     

Analycys: a database for conservation and conformation of disulphide bonds in homologous protein domains

Disulphide bonds in proteins are known to play diverse roles ranging from folding to structure to function. Thorough knowledge of the conservation status and structural state of the disulphide bonds will help in understanding of the differences in homologous proteins. Here we present a database for the analysis of conservation and conformation of disulphide bonds in SCOP structural families. This database has a wide range of applications including mapping of disulphide bond mutation patterns, identification of disulphide bonds important for folding and stabilization, modeling of protein tertiary structures and in protein engineering. The database can be accessed at: http://bioinformatics.univ-reunion.fr/analycys/.     

A comparison of the in vitro and in vivo activities of conjugates of anti-mouse lymphocyte globulin and abrin

Anti-mouse lymphocyte globulin and normal immunoglobulin have been conjugated to abrin using two procedures, one involving linkage through an amide bond and a piperazine ring and the other the introduction of two amide bonds flanking a disulphide bridge. The four conjugates produced were equipotent as inhibitors of protein synthesis in rabbit reticulocyte lysates. Each antibody-containing conjugate was a more effective inhibitor of protein synthesis in cultured cells than the equivalent normal immunoglobulin-containing conjugate. In addition the conjugates with disulphide linkage groups were ten times more potent than their counterparts. The disulphide conjugates were also twice as toxic to mice in an acute toxicity test but when used to suppress their immune responses to sheep red blood cells it was the non-disulphide-linked conjugates that were superior. In all instances antibody-containing conjugates were more powerful immunosuppressants than those containing normal IgG. The results are taken to indicate a relative lack of stability of the disulphide conjugates in the tissues.     

Large increase in disulphide bonds containing cytosol proteins after chronic cadmium administration, estimated in isolated rat liver cells

Summary Using histochemical staining, followed by cytophotometric quantitation of disulphide bonds and total protein in isolated liver cells of rats treated for a long time with low doses of CdCl₂, a large increase in disulphide bonds containing proteins could be demonstrated in cells of one ploidy class. This increase seems to be due to an increase in high molecular weight (HMW) cytosol proteins as estimated biochemically. They probably represent polymers of metallothionein.     

Controlling pore assembly of staphylococcal gamma-haemolysin by low temperature and by disulphide bond formation in double-cysteine LukF mutants

Staphylococcal LukF and Hlg2 are water-soluble monomers of gamma-haemolysin that assemble into oligomeric pores on the erythrocyte membranes. Here, we have created double-cysteine LukF mutants, in which single disulphide bonds connect either the prestem domain and the cap domain (V12C-T136C, Cap-Stem), or two beta-strands within the prestem domain (T117C-T136C, Stem-Stem) to control pore assembly of gamma-haemolysin at intermediate stages. The disulphide-trapped mutants were inactive in erythrocyte lysis, but gained full haemolytic activity if the disulphide bonds were reduced. The disulphide bonds blocked neither the membrane binding ability nor the intermediate prepore oligomerization, but efficiently inhibited the transition from prepores to pores. The prepores of Cap-Stem were dissociated into monomers in 1% SDS. In contrast, the prepores of Stem-Stem were stable in SDS and had ring-shaped structures similar to those of wild-type LukF, as observed by transmission electron microscopy. The transition of both mutants from prepores to pores could even be achieved by reducing disulphide bonds at low temperature (2 degrees C), whereas prepore oligomerization was effectively inhibited by low temperature. Finally, real-time transition of Stem-Stem from prepores to pores on ghost cells, visualized using a Ca2+-sensitive fluorescent indicator (Rhod2), was shown by the sequential appearance of fluorescence spots, indicating pore-opening events. Taken together, these data indicate that the prepores are legitimate intermediates during gamma-haemolysin pore assembly, and that conformational changes around residues 117 and 136 of the prestem domain are essential for pore formation, but not for membrane binding or prepore oligomerization. We propose a mechanism for gamma-haemolysin pore assembly based on the demonstrated intermediates.     

Intramolecular disulphide bond arrangements in nonhomologous proteins

The presence and location of intramolecular disulphide bonds are a key determinant of the structure and function of proteins. Intramolecular disulphide bonds in proteins have previously been analyzed under the assumption that there is no clear relationship between disulphide arrangement and disulphide concentration. To investigate this, a set of sequence nonhomologous protein chains containing one or more intramolecular disulphide bonds was extracted from the Protein Data Bank, and the arrangements of the bonds, Protein Data Bank header, and Structural Characterization of Proteins fold were analyzed as a function of intramolecular disulphide bond concentration. Two populations of intramolecular disulphide bond-containing proteins were identified, with a naturally occurring partition at 25 residues per bond. These populations were named intramolecular disulphide bond-rich and -poor. Benefits of partitioning were illustrated by three results: (1) rich chains most frequently contained three disulphides, explaining the plateaux in extant disulphide frequency distributions; (2) a positive relationship between median chain length and the number of disulphides, only seen when the data were partitioned; and (3) the most common bonding pattern for chains with three disulphide bonds was based on the most common for two, only when the data were partitioned. The two populations had different headers, folds, bond arrangements, and chain lengths. Associations between IDSB concentration, IDSB bonding pattern, loop sizes, SCOP fold, and PDB header were also found. From this, we found that intramolecular disulphide bond-rich and -poor proteins follow different bonding rules, and must be considered separately to generate meaningful models of bond formation.     

A quantitative histochemical study of sulphydryl and disulphide content during normal epidermal keratinization

Summary A quantitative histochemical study was carried out on the distribution of protein thiol and disulphide groups in normal human plantar epidermal tissue. Histochemical demonstration of reactive groups was achieved by addition ofN-(4-aminophenyl) maleimide, subsequent diazotization and final coupling with a Nitro Red or chromotropic acid label as first described by Sippel. The quantitative reliability of the method was tested by absorption cytophotometry, and evaluated on the basis of the internal consistency of the results reported.Our histological observations and histophotometric data support accepted views on epidermal keratinization. A limited, though reproducible, amount of disulphide bonds was observed near the basement membrane. The free thiol concentration in basal and prickle cells was low and almost constant, but was higher in the granular cells, where deposition of sulphur-containing proteins on cell membranes is initiated. In Malpighian layers, disulphide cross-links only occurred just beneath the transition zone in thickened cell membranes. The staining pattern of the inner stratum corneum resembled a mosaic and was characterized by a sharp rise of the disulphide content, which exceeded the decrease in free thiol groups. The free thiol concentration decreased further throughout the cornified layers whilst the disulphide content remained fairly constant. Staining of thiol and disulphide groups together corresponded, within the limits of the standard error, to the sum of the thiol and disulphide concentrations when they were assayed separately in living and horny cells. These results confirm that living cells are the main site of free thiol groups, while horny cells are the most prominent site of disulphide cross-links.     

Conformational restrictions on the pathway of folding and unfolding of the pancreatic trypsin inhibitor

The kinetic roles of the partially folded, intermediate protein species with two disulphide bonds in folding and unfolding of the pancreatic trypsin inhibitor have been investigated further. Formation of a second disulphide bond between Cys5 and Cys55 during refolding of the reduced inhibitor, which would yield the species with the 30–51 and 5–55 disulphide bonds and, possibly, the native-like conformation of the protein, is not significant. Instead, three other second disulphide bonds (5–14, 5–38 and 14–38) are formed approximately 10⁵ times more readily, but each of these two-disulphide species then rearranges intramolecularly to the native-like, two-disulphide intermediate. Therefore, the reduced protein does not simply form sequentially the three disulphide bonds of the native state. Unfolding of the native state takes place by the reverse of this process.The kinetic importance for folding and unfolding of this transition between two-disulphide intermediates under the conditions used here was illustrated experimentally by a modified form of the inhibitor in which the thiols of Cys14 and Cys38 were blocked irreversibly. In the folded conformation, this modified protein is more stable to unfolding than normal, but after unfolding cannot readily regain the native-like conformation, because Cys14 or Cys38 are required to be involved in disulphide bonds during the interconversion of the two-disulphide intermediates.Some conception of the conformational transitions that take place at each stage of the folding transition may be inferred from the relative propensities of the six cysteine residues to make or rearrange disulphide bonds. It is concluded that the inhibitor probably does not refold by sequential adoption of the native conformation by the unfolded polypeptide chain. Instead, it appears that essentially all elements of the native conformation are attained simultaneously in the final stage of folding, within an unstable and flexible, yet relatively compact, form of the entire polypeptide chain produced by weak interactions between groups distant in the primary structure.     

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.     

Structural tolerance of bacterial autotransporters for folded passenger protein domains

In this report we investigate the capacity of bacterial autotransporters (AT) to translocate folded protein domains across the outer membrane (OM). Polypeptides belonging to the AT family contain a C-terminal domain that supports the secretion of the N-domain (the passenger) across the OM of Gram-negative bacteria. Despite some controversial data, it has been widely accepted that N-passenger domains of AT must be unfolded and devoid of disulphide bonds for efficient translocation. To address whether or not AT are able to translocate folded protein domains across the OM, we employed several types of recombinant antibodies as heterologous N-passengers of the transporter C-domain of IgA protease (C-IgAP) of Neisseria gonorroheae. The N-domains used were single chain Fv fragments (scFv) and variable mono-domains derived from camel antibodies (V(HH)) selected on the basis of their distinct and defined folding properties (i.e. enhanced solubility, stability and presence or not of disulphide bonds). Expression of these hybrids in Escherichia coli shows that stable scFv and V(HH) domains are efficiently (>99%) translocated towards the bacterial surface regardless of the presence or not of disulphide bonds on their structure. Antigen-binding assays demonstrate that surface-exposed scFv and V(HH) domains are correctly folded and thus able to bind their cognate antigens. Expression of scFv- or V(HH)-C-IgAP hybrids in E. coli dsbA or fkpA mutant cells reveals that these periplasmic protein chaperones fold these N-domains before their translocation across the OM. Furthermore, large N-passengers composed of strings of V(HH) domains were secreted in a folded state by AT with no loss of efficacy (>99%) despite having multiple disulphide bonds. Thus AT can efficiently translocate toward the cell surface folded N-passengers composed of one, two or three immunoglobulin (Ig) domains, each with a folded diameter between approximately 2 nm and having disulphide bonds. This tolerance for folded protein domains of approximately 2 nm fits with the diameter of the central hydrophilic channel proposed for the ring-like oligomeric complex assembled by C-IgAP in the OM.     

Differential reduction of interchain disulphide bonds of mouse immunoglobulin G

The relative lability of the interchain disulphide bonds of mouse G_2a-myeloma protein 5563 was studied as a function of 2-mercaptoethanol concentration. Analysis of partial-reduction mixtures by polyacrylamide-gel electrophoresis and microdensitometry showed that the disulphide bonds between light and heavy chains are much more susceptible to reduction than the bonds between heavy chains. At a low concentration of 2-mercaptoethanol (10mm) the major dissociable products of mouse immunoglobulin G are heavy-chain dimers and free light chains. These findings contrast with the reported behaviour of rabbit immunoglobulin G, for which the lability of inter-heavy-chain bonds was found to exceed that of the bonds linking light and heavy chains (Hong & Nisonoff, 1965); the relative stability of rabbit immunoglobulin G interchain bonds was confirmed in the present study. Examination of human immunoglobulin G and an immunoglobulin G (γ2) of guinea pig showed that at least in the majority of molecules, as with mouse immunoglobulin G, the disulphide bonds between light and heavy chains are more susceptible to reduction than the inter-heavy-chain bonds.