Reconsideration of an early dogma,saying “there is no evidence for disulfide bonds in proteins from archaea”

Stability and function of a large number of proteins are crucially dependent on the presence of disulfide bonds. Recent genome analysis has pointed out an important role of disulfide bonds for the structural stabilization of intracellular proteins from hyperthermophilic archaea and bacteria. These findings contradict the conventional view that disulfide bonds are rare in those proteins. A specific protein, known as protein disulfide oxidoreductase (PDO) is recognized as a potential key enzyme in intracellular disulfide-shuffling in hyperthermophiles. The structure of this protein consists of two combined thioredoxin-related units which together, in tandem-like manner, form a closed protein domain. Each of these units contains a distinct CXXC active site motif. Both sites seem to have different redox properties. A relation to eukaryotic protein disulfide isomerase is suggested by the observed structural and functional characteristics of the protein. Enzymological studies have revealed that both, the archaeal and bacterial forms of this protein show oxidative and reductive activity and are able to isomerize protein disulfides. The variety of active site disulfides found in PDO’s from hyperthermophiles is puzzling. It is assumed, that PDO enzymes in hyperthermophilic archaea and bacteria may be part of a complex system involved in the maintenance of protein disulfide bonds.     

Disulfide-Bond-Forming Pathways in Gram-Positive Bacteria

Disulfide bonds are important for the stability and function of many secreted proteins. In Gram-negative bacteria, these linkages are catalyzed by thiol-disulfide oxidoreductases (Dsb) in the periplasm. Protein oxidation has been well studied in these organisms, but it has not fully been explored in Gram-positive bacteria, which lack traditional periplasmic compartments. Recent bioinformatics analyses have suggested that the high-GC-content bacteria (i.e., actinobacteria) rely on disulfide-bond-forming pathways. In support of this, Dsb-like proteins have been identified in Mycobacterium tuberculosis, but their functions are not known. Actinomyces oris and Corynebacterium diphtheriae have recently emerged as models to study disulfide bond formation in actinobacteria. In both organisms, disulfide bonds are catalyzed by the membrane-bound oxidoreductase MdbA. Remarkably, unlike known Dsb proteins, MdbA is important for pathogenesis and growth, which makes it a potential target for new antibacterial drugs. This review will discuss disulfide-bond-forming pathways in bacteria, with a special focus on Gram-positive bacteria.     

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.     

Two phases of disulfide bond formation have differing requirements for oxygen

Most proteins destined for the extracellular space require disulfide bonds for folding and stability. Disulfide bonds are introduced co- and post-translationally in endoplasmic reticulum (ER) cargo in a redox relay that requires a terminal electron acceptor. Oxygen can serve as the electron acceptor in vitro, but its role in vivo remains unknown. Hypoxia causes ER stress, suggesting a role for oxygen in protein folding. Here we demonstrate the existence of two phases of disulfide bond formation in living mammalian cells, with differential requirements for oxygen. Disulfide bonds introduced rapidly during protein synthesis can occur without oxygen, whereas those introduced during post-translational folding or isomerization are oxygen dependent. Other protein maturation processes in the secretory pathway, including ER-localized N-linked glycosylation, glycan trimming, Golgi-localized complex glycosylation, and protein transport, occur independently of oxygen availability. These results suggest that an alternative electron acceptor is available transiently during an initial phase of disulfide bond formation and that post-translational oxygen-dependent disulfide bond formation causes hypoxia-induced ER stress.     

Modeling the role of disulfide bonds in protein folding: Entropic barriers and pathways

The role of disulfide bonds in directing protein folding is studied using lattice models. We find that the stability and the specificity of the disulfide bond interactions play quite different roles in the folding process: Under some conditions, the stability decreases the overall rate of folding; the specificity, however, by yielding a simpler connectivity of intermediates, always increases the rate of folding. This conclusion is intimately related to the selection mechanism entailed by entropic driving forces, such as the loop formation probability, and entropic barriers separating the native and the many native-like metastable states. The folding time is found to be a minimum for a certain range of the effective disulfide bond interaction. Examination of a model, which allows for the formation of disulfide bonded intermediates, suggests that folding proceeds via a threestage multiple pathways kinetics. We show that there are pathways to the native state involving only native-like intermediates, as well as those that are mediated by nonnative intermediates. These findings are interpreted in terms of the appropriate energy landscape describing the barriers connecting low energy conformations. The consistency of our conclusions with several experimental studies is also discussed. © 1995 Wiley-Liss, Inc.     

Stability and structure-forming properties of the two disulfide bonds of alpha-conotoxin GI

alpha-Conotoxin GI is a 13 residue snail toxin peptide cross-linked by Cys2-Cys7 and Cys3-Cys13 disulfide bridges. The formation of the two disulfide bonds by thiol/disulfide exchange with oxidized glutathione (GSSG) has been characterized. To characterize formation of the first disulfide bond in each of the two pathways by which the two disulfide bonds can form, two model peptides were synthesized in which Cys3 and Cys13 (Cono-1) or Cys2 and Cys7 (Cono-2) were replaced by alanines. Equilibrium constants were determined for formation of the single disulfide bonds of Cono-1 and Cono-2, and an overall equilibrium constant was measured for formation of the two disulfide bonds of alpha-conotoxin GI in pH 7.00 buffer and in pH 7. 00 buffer plus 8 M urea using concentrations obtained by HPLC analysis of equilibrium thiol/disulfide exchange reaction mixtures. The results indicate a modest amount of cooperativity in the formation of the second disulfide bond in both of the two-step pathways by which alpha-conotoxin GI folds into its native structure at pH 7.00. However, when considered in terms of the reactive thiolate species, the results indicate substantial cooperativity in formation of the second disulfide bond. The solution conformational and structural properties of Cono-1, Cono-2, and alpha-conotoxin GI were studied by 1H NMR to identify structural features which might facilitate formation of the disulfide bonds or are induced by formation of the disulfide bonds. The NMR data indicate that both Cono-1 and Cono-2 have some secondary structure in solution, including some of the same secondary structure as alpha-conotoxin GI, which facilitates formation of the second disulfide bond by thiol/disulfide exchange. However, both Cono-1 and Cono-2 are considerably less structured than alpha-conotoxin GI, which indicates that formation of the second disulfide bond to give the Cys2-Cys7, Cys3-Cys13 pairing induces considerable structure into the backbone of the peptide.     

Oxidative Folding of Conopeptides Modified by <Emphasis Type="Italic">Conus</Emphasis> Protein Disulfide Isomerase

Protein disulfide isomerase is a type of enzyme that catalyses the oxidation, isomerization and reduction of disulfide bonds. Conotoxins that containing disulfide bonds are likely substrates of protein disulfide isomerise. Here, we cloned 12 protein disulfide isomerise genes from 12 different cone snail species that inhabited the sea near Sanya in China. The full-length amino acid sequences of these protein disulfide isomerase genes share a high degree of homology, including the same -CGHC- active site sequence and -RDEL- endoplasmic reticulum retention signal. To obtain enough conus protein disulfide isomerase for functional studies, we constructed the expression vector pET28a-sPDI. Conus protein disulfide isomerase was successfully expressed using Escherichia coli expression system and purified using chromatography method of affinity chromatography. The recombinant conus protein disulfide isomerase showed the ability to catalyse disulfide bond formation and rearrangement in the lysozyme enzyme activity assay. The role of conus protein disulfide isomerase in the in vitro oxidative folding of conotoxins was investigated using synthetic linear conotoxin lt14a, a peptide composed of 13 amino acids. It was confirmed by high performance liquid chromatography and mass spectrometry analysis that conus protein disulfide isomerase can catalyse the disulfide bond formation of linear lt14a. Then, conus protein disulfide isomerase was acted as a fusion partner during the production of engineered peptidyl-prolyl cis–trans isomerase and lt14a derived from cone snails. It was shown that peptidyl-prolyl cis–trans isomerase and conotoxin lt14a are successfully expressed in a highly soluble form by fusion with conus protein disulfide isomerase. Thus, conus protein disulfide isomerase functions not only as an enzyme that catalyses oxidative process but also a fusion partner in recombinant conotoxin expression.     

Disulfide Bonds Play a Critical Role in the Structure and Function of the Receptor-binding Domain of the SARS-CoV-2 Spike Antigen

The current coronavirus pandemic is exerting a tremendously detrimental impact on global health. The Spike proteins of coronaviruses, responsible for cell receptor binding and viral internalization, possess multiple and frequently conserved disulfide bonds raising the question about their role in these proteins. Here, we present a detailed structural and functional investigation of the disulfide bonds of the SARS-CoV-2 Spike receptor-binding domain (RBD). Molecular dynamics simulations of the RBD predict increased flexibility of the surface loops when the four disulfide bonds of the domain are reduced. This flexibility is particularly prominent for the disulfide bond-containing surface loop (residues 456–490) that participates in the formation of the interaction surface with the Spike cell receptor ACE2. In vitro, disulfide bond reducing agents affect the RBD secondary structure, lower its melting temperature from 52 °C to 36–39 °C and decrease its binding affinity to ACE2 by two orders of magnitude at 37 °C. Consistent with these in vitro findings, the reducing agents tris(2-carboxyethyl)phosphine (TCEP) and dithiothreitol (DTT) were able to inhibit viral replication at low millimolar levels in cell-based assays. Our research demonstrates the mechanism by which the disulfide bonds contribute to the molecular structure of the RBD of the Spike protein, allowing the RBD to execute its viral function.     

Characterization of a multifunctional protein disulfide oxidoreductase from Sulfolobus solfataricus

A potential role in disulfide bond formation in the intracellular proteins of thermophilic organisms has recently been ascribed to a new family of protein disulfide oxidoreductases (PDOs). We report on the characterization of SsPDO, isolated from the hyperthermophilic archaeon Sulfolobus solfataricus. SsPDO was cloned and expressed in Escherichia coli. We revealed that SsPDO is the substrate of a thioredoxin reductase in S. solfataricus (K(M) 0.3 microm) and not thioredoxins (TrxA1 and TrxA2). SsPDO/S. solfataricus thioredoxin reductase constitute a new thioredoxin system in aerobic thermophilic archaea. While redox (reductase, oxidative and isomerase) activities of SsPDO point to its central role in the biochemistry of cytoplasmic disulfide bonds, chaperone activities also on an endogenous substrate suggest a potential role in the stabilization of intracellular proteins. Northern and western analysis have been performed in order to analyze the response to the oxidative stress.     

Functional Analysis of Paralogous Thiol-disulfide Oxidoreductases in Streptococcus gordonii

Disulfide bonds are important for the stability of many extracellular proteins, including bacterial virulence factors. Formation of these bonds is catalyzed by thiol-disulfide oxidoreductases (TDORs). Little is known about their formation in Gram-positive bacteria, particularly among facultative anaerobic Firmicutes, such as streptococci. To investigate disulfide bond formation in Streptococcus gordonii, we identified five putative TDORs from the sequenced genome. Each of the putative TDOR genes was insertionally inactivated with an erythromycin resistance cassette, and the mutants were analyzed for autolysis, extracellular DNA release, biofilm formation, bacteriocin production, and genetic competence. This analysis revealed a single TDOR, SdbA, which exhibited a pleiotropic mutant phenotype. Using an in silico analysis approach, we identified the major autolysin AtlS as a natural substrate of SdbA and showed that SdbA is critical to the formation of a disulfide bond that is required for autolytic activity. Analysis by BLAST search revealed homologs to SdbA in other Gram-positive species. This study provides the first in vivo evidence of an oxidoreductase, SdbA, that affects multiple phenotypes in a Gram-positive bacterium. SdbA shows low sequence homology to previously identified oxidoreductases, suggesting that it may belong to a different class of enzymes. Our results demonstrate that SdbA is required for disulfide bond formation in S. gordonii and indicate that this enzyme may represent a novel type of oxidoreductase in Gram-positive bacteria.     

Disruption of reducing pathways is not essential for efficient disulfide bond formation in the cytoplasm of <Emphasis Type="Italic">E. coli</Emphasis>

Background  

The formation of native disulfide bonds is a complex and essential post-translational modification for many proteins. The large scale production of these proteins can be difficult and depends on targeting the protein to a compartment in which disulfide bond formation naturally occurs, usually the endoplasmic reticulum of eukaryotes or the periplasm of prokaryotes. It is currently thought to be impossible to produce large amounts of disulfide bond containing protein in the cytoplasm of wild-type bacteria such as E. coli due to the presence of multiple pathways for their reduction.     

Determination of the disulfide bond pairings in human tissue factor pathway inhibitor purified fromEscherichia coli

The disulfide bond assignments of human alanyl tissue factor pathway inhibitor purified fromEscherichia coli have been determined. This inhibitor of the extrinsic blood coagulation pathway possesses three Kunitz-type inhibitor domains, each containing three disulfide bonds. The disulfide bond pairings in domains 1 and 3 were determined by amino acid sequencing and mass spectrometry of peptides derived from a thermolysin digest. However, thermolysin digestion did not cleave any peptide bonds within domain 2. The disulfide bond pairings in domain 2 were determined by isolating it from the thermolysin treatment and subsequently cleaving it with pepsin and trypsin into peptides which yielded the three disulfide bond pairings in this domain. These results demonstrate that the disulfide pairings in each of the three domains of human tissue factor pathway inhibitor purified fromEscherichia coli are homologous to each other and also to those in bovine pancreatic trypsin inhibitor.     

Oligomerization of H-pyrophosphatase and its structural and functional consequences

The H⁺-pyrophosphatase (H⁺-PPase) consists of a single polypeptide, containing 16 or 17 transmembrane domains. To determine the higher order oligomeric state of Streptomyces coelicolor H⁺-PPase, we constructed a series of cysteine substitution mutants and expressed them in Escherichia coli. Firstly, we analyzed the formation of disulfide bonds, promoted by copper, in mutants with single cysteine substitutions. 28 of 39 mutants formed disulfide bonds, including S545C, a substitution at the periplasmic side. The formation of intermolecular disulfide bonds suppressed the enzyme activity of several, where the substituted residues were located in the cytosol. Creating disulfide links in the cytosol may interfere with the enzyme's catalytic function. Secondly, we prepared double mutants by introducing second cysteine substitutions into the S545C mutant. These double-cysteine mutants produced cross-linked complexes, estimated to be at least tetramers and possibly hexamers. Thirdly, we co-expressed epitope-tagged, wild type, and inactive mutant H⁺-PPases in E. coli and confirmed the formation of oligomers by co-purifying one subunit using the epitope tag used to label the other. The enzyme activity of these oligomers was markedly suppressed. We propose that H⁺-PPase is present as an oligomer made up of at least two or three sets of dimers.     

Positive genetic interactors of HMG2 identify a new set of genetic perturbations for improving sesquiterpene production in Saccharomyces cerevisiae

Background

Production of correctly disulfide bonded proteins to high yields remains a challenge. Recombinant protein expression in Escherichia coli is the popular choice, especially within the research community. While there is an ever growing demand for new expression strains, few strains are dedicated to post-translational modifications, such as disulfide bond formation. Thus, new protein expression strains must be engineered and the parameters involved in producing disulfide bonded proteins must be understood.

Results

We have engineered a new E. coli protein expression strain named SHuffle, dedicated to producing correctly disulfide bonded active proteins to high yields within its cytoplasm. This strain is based on the trxB gor suppressor strain SMG96 where its cytoplasmic reductive pathways have been diminished, allowing for the formation of disulfide bonds in the cytoplasm. We have further engineered a major improvement by integrating into its chromosome a signal sequenceless disulfide bond isomerase, DsbC. We probed the redox state of DsbC in the oxidizing cytoplasm and evaluated its role in assisting the formation of correctly folded multi-disulfide bonded proteins. We optimized protein expression conditions, varying temperature, induction conditions, strain background and the co-expression of various helper proteins. We found that temperature has the biggest impact on improving yields and that the E. coli B strain background of this strain was superior to the K12 version. We also discovered that auto-expression of substrate target proteins using this strain resulted in higher yields of active pure protein. Finally, we found that co-expression of mutant thioredoxins and PDI homologs improved yields of various substrate proteins.

Conclusions

This work is the first extensive characterization of the trxB gor suppressor strain. The results presented should help researchers design the appropriate protein expression conditions using SHuffle strains.     

Disulfide bond formation in the Escherichia coli cytoplasm: an in vivo role reversal for the thioredoxins.

Cytoplasmic proteins do not generally contain structural disulfide bonds, although certain cytoplasmic enzymes form such bonds as part of their catalytic cycles. The disulfide bonds in these latter enzymes are reduced in Escherichia coli by two systems; the thioredoxin pathway and the glutathione/glutaredoxin pathway. However, structural disulfide bonds can form in proteins in the cytoplasm when the gene (trxB) for the enzyme thioredoxin reductase is inactivated by mutation. This disulfide bond formation can be detected by assessing the state of the normally periplasmic enzyme alkaline phosphatase (AP) when it is localized to the cytoplasm. Here we show that the formation of disulfide bonds in cytoplasmic AP in the trxB mutant is dependent on the presence of two thioredoxins in the cell, thioredoxins 1 and 2, the products of the genes trxA and trxC, respectively. Our evidence supports a model in which the oxidized forms of these thioredoxins directly catalyze disulfide bond formation in cytoplasmic AP, a reversal of their normal role. In addition, we show that the recently discovered thioredoxin 2 can perform many of the roles of thioredoxin 1 in vivo, and thus is able to reduce certain essential cytoplasmic enzymes. Our results suggest that the three most effective cytoplasmic disulfide-reducing proteins are thioredoxin 1, thioredoxin 2 and glutaredoxin 1; expression of any one of these is sufficient to support aerobic growth. Our results help to explain how the reducing environment in the cytoplasm is maintained so that disulfide bonds do not normally occur.     

Formation of native structure by intermolecular thiol-disulfide exchange reactions without oxidants in the folding of bovine pancreatic ribonuclease A

It has been shown previously that the oxidative folding of bovine pancreatic ribonuclease A proceeds through parallel pathways with two major native-like three-disulfide (3S) intermediates. We show here that, under some conditions, the native disulfide bonds can also be regenerated through disproportionation reactions; in other words, the protein can serve as its own redox reagent. The results also show that disulfide species of the unstructured 3S ensemble have a strong propensity to participate in intermolecular interactions. These interactions are favored at high protein concentration, temperature and pH, and lead to formation of the native structure during disulfide reshuffling in the rate-determining step.     

Role of the amino- and carboxy-terminal regions in the folding and oligomerization of wheat high molecular weight glutenin subunits

The high molecular weight glutenin subunits are considered one of the most important components of wheat (Triticum aestivum) gluten, but their structure and interactions with other gluten proteins are still unknown. Understanding the role of these proteins in gluten formation may be aided by analyses of the conformation and interactions of individual wild-type and modified subunits expressed in heterologous systems. In the present report, the bacterium Escherichia coli was used to synthesize four naturally occurring X- and Y-type wheat high molecular weight glutenin subunits of the Glu-1D locus, as well as four bipartite chimeras of these proteins. Naturally occurring subunits synthesized in the bacteria exhibited sodium dodecyl sulfate-polyacrylamide gel electrophoresis migration properties identical to those of high molecular weight glutenin subunits extracted from wheat grains. Wild-type and chimeric subunits migrated in sodium dodecyl sulfate gels differently than expected based on their molecular weights due to conformational properties of their N- and C-terminal regions. Results from cycles of reductive cleavage and oxidative reformation were consistent with the formation of both inter- and intramolecular disulfide bonds in patterns and proportions that differed among specific high molecular weight glutenin species. Comparison of the chimeric and wild-type proteins indicated that the two C-terminal cysteines of the Y-type subunits are linked by intramolecular disulfide bonds, suggesting that the role of these cysteines in glutenin polymerization may be limited.     

Disulfide bonds in ER protein folding and homeostasis

Proteins that are expressed outside the cell must be synthesized, folded, and assembled in a way that ensures they can function in their designate location. Accordingly, these proteins are primarily synthesized in the endoplasmic reticulum (ER), which has developed a chemical environment more similar to that outside the cell. This organelle is equipped with a variety of molecular chaperones and folding enzymes that both assist the folding process, while at the same time exerting tight quality control measures that are largely absent outside the cell. A major post-translational modification of ER-synthesized proteins is disulfide bridge formation, which is catalyzed by the family of protein disulfide isomerases. As this covalent modification provides unique structural advantages to extracellular proteins, multiple pathways to disulfide bond formation have evolved. However, the advantages that disulfide bonds impart to these proteins come at a high cost to the cell. Very recent reports have shed light on how the cell can deal with or even exploit the side reactions of disulfide bond formation to maintain homeostasis of the ER and its folding machinery.