Interaction of Periplasmic Fab Production and Intracellular Redox Balance in Escherichia coli Affects Product Yield.

Antibody fragments such as Fab's require the formation of disulfide bonds to achieve a proper folding state. During their recombinant, periplasmic expression in Escherichia coli, oxidative folding is mediated by the DsbA/DsbB system in concert with ubiquinone. Thereby, overexpression of Fab's is linked to the respiratory chain, which is not only immensely important for the cell's energy household but also known as a major source of reactive oxygen species. However, the effects of an increased oxidative folding demand and the consequently required electron flux via ubiquinone on the host cell have not been characterized so far. Here, we show that Fab expression in E. coli BL21(DE3) interfered with the intracellular redox balance, thereby negatively impacting host cell performance. Production of four different model Fab's in lab-scale fed-batch cultivations led to increased oxygen consumption rates and strong cell lysis. An RNA sequencing analysis revealed transcription activation of the oxidative stress-responsive soxS gene in the Fab-producing strains. We attributed this to the accumulation of intracellular superoxide, which was measured using flow cytometry. An exogenously supplemented ubiquinone analogue improved Fab yields up to 82%, indicating that partitioning of the quinone pool between aerobic respiration and oxidative folding limited ubiquinone availability and hence disulfide bond formation capacity. Combined, our results provide a more in-depth understanding of the profound effects that periplasmic Fab expression and in particular disulfide bond formation has on the host cell. Thereby, we show new possibilities to elaborate cell engineering and process strategies for improved host cell fitness and process outcome.

Human ER Oxidoreductin-1α (Ero1α) Undergoes Dual Regulation through Complementary Redox Interactions with Protein-Disulfide Isomerase.

In the mammalian endoplasmic reticulum, oxidoreductin-1α (Ero1α) generates protein disulfide bonds and transfers them specifically to canonical protein-disulfide isomerase (PDI) to sustain oxidative protein folding. This oxidative process is coupled to the reduction of O2 to H2O2 on the bound flavin adenine dinucleotide cofactor. Because excessive thiol oxidation and H2O2 generation cause cell death, Ero1α activity must be properly regulated. In addition to the four catalytic cysteines (Cys94, Cys99, Cys104, and Cys131) that are located in the flexible active site region, the Cys208-Cys241 pair located at the base of another flexible loop is necessary for Ero1α regulation, although the mechanistic basis is not fully understood. The present study revealed that the Cys208-Cys241 disulfide was reduced by PDI and other PDI family members during PDI oxidation. Differential scanning calorimetry and small angle X-ray scattering showed that mutation of Cys208 and Cys241 did not grossly affect the thermal stability or overall shape of Ero1α, suggesting that redox regulation of this cysteine pair serves a functional role. Moreover, the flexible loop flanked by Cys208 and Cys241 provides a platform for functional interaction with PDI, which in turn enhances the oxidative activity of Ero1α through reduction of the Cys208-Cys241 disulfide. We propose a mechanism of dual Ero1α regulation by dynamic redox interactions between PDI and the two Ero1α flexible loops that harbor the regulatory cysteines.

A substrate-driven allosteric switch that enhances PDI catalytic activity.

Protein disulfide isomerase (PDI) is an oxidoreductase essential for folding proteins in the endoplasmic reticulum. The domain structure of PDI is a-b-b'-x-a', wherein the thioredoxin-like a and a' domains mediate disulfide bond shuffling and b and b' domains are substrate binding. The b' and a' domains are connected via the x-linker, a 19-amino-acid flexible peptide. Here we identify a class of compounds, termed bepristats, that target the substrate-binding pocket of b'. Bepristats reversibly block substrate binding and inhibit platelet aggregation and thrombus formation in vivo. Ligation of the substrate-binding pocket by bepristats paradoxically enhances catalytic activity of a and a' by displacing the x-linker, which acts as an allosteric switch to augment reductase activity in the catalytic domains. This substrate-driven allosteric switch is also activated by peptides and proteins and is present in other thiol isomerases. Our results demonstrate a mechanism whereby binding of a substrate to thiol isomerases enhances catalytic activity of remote domains.

Molecular Characterization of Endoplasmic Reticulum Oxidoreductin 1 from Bombyx mori.

We isolated a complementary DNA (cDNA) clone encoding endoplasmic reticulum oxidoreductin 1 (bERO1, a specific oxidant of protein disulfide isomerase (PDI)) from Bombyx mori. This protein has a putative open reading frame (ORF) of 489 amino acids and a predicted size of 57.4 kDa. Although bERO1 protein shares less than 57% amino acid sequence homology with other reported ERO1s, it contains two conserved redox active motifs, a Cys-X-X-X-X-Cys motif of N-terminal and Cys-X-X-Cys-X-X-Cys motif of C-terminal. Both motifs are typically present in ERO1 protein family members. The bEro1 mRNA expression was highest in posterior silk gland on the sixth day of the 5th instar larvae. Expression of bEro1 mRNA also markedly increased during endoplasmic reticulum (ER) stress induced by stimulation with antimycin, calcium ionophore A23187, dithiothreitol, H2O2, monencin, and tunicamycin. In addition, expression levels of bEro1 exactly coincided with that of bPdi. This is the first result suggesting that bERO1 plays an essential role in ER quality control through the combined activities of bERO1 and bPDI as a catalyst of protein folding in the ER and sustaining cellular redox homeostasis.

Small molecule inhibitors of disulfide bond formation by the bacterial DsbA-DsbB dual enzyme system.

The DsbA:DsbB redox machinery catalyzes disulfide bond formation in secreted proteins and is required for bacterial virulence factor assembly. Both enzymes have been identified as targets for antivirulence drugs. Here, we report synthetic analogues of ubiquinone (dimedone derivatives) that inhibit disulfide bond formation (IC50∼1 µM) catalyzed by E. coli DsbA:DsbB. The mechanism involves covalent modification of a single free cysteine leaving other cysteines unmodified. A vinylogous anhydride in each inhibitor is cleaved by the thiol, which becomes covalently modified to a thioester by a propionyl substituent. Cysteines and lysines on DsbA and DsbB and a nonredox enzyme were modified in a manner that implies some specificity. Moreover, human thioredoxin was not inhibited under the same conditions that inhibited EcDsbA. This proof of concept work uses small molecules that target specific cysteines to validate the DsbA and DsbB dual enzyme system as a viable and potentially druggable antivirulence target.

The potato sucrose transporter StSUT1 interacts with a DRM-associated protein disulfide isomerase.

Organization of proteins into complexes is crucial for many cellular functions. Recently, the SUT1 protein was shown to form homodimeric complexes, to be associated with lipid raft-like microdomains in yeast as well as in plants and to undergo endocytosis in response to brefeldin A. We therefore aimed to identify SUT1-interacting proteins that might be involved in dimerization, endocytosis, or targeting of SUT1 to raft-like microdomains. Therefore, we identified potato membrane proteins, which are associated with the detergent-resistant membrane (DRM) fraction. Among the proteins identified, we clearly confirmed StSUT1 as part of DRM in potato source leaves. We used the yeast two-hybrid split ubiquitin system (SUS) to systematically screen for interaction between the sucrose transporter StSUT1 and other membrane-associated or soluble proteins in vivo. The SUS screen was followed by immunoprecipitation using affinity-purified StSUT1-specific peptide antibodies and mass spectrometric analysis of co-precipitated proteins. A large overlap was observed between the StSUT1-interacting proteins identified in the co-immunoprecipitation and the detergent-resistant membrane fraction. One of the SUT1-interacting proteins, a protein disulfide isomerase (PDI), interacts also with other sucrose transporter proteins. A potential role of the PDI as escort protein is discussed.

The potential of protein disulfide isomerase as a therapeutic drug target.

Protein disulfide isomerase (PDI) is a multifunctional protein of the thioredoxin superfamily. PDI mediates proper protein folding by oxidation or isomerization and disrupts disulfide bonds by reduction; it also has chaperone and antichaperone activities. Although PDI localizes primarily to the endoplasmic reticulum (ER), it is secreted and expressed on the cell surface. In the ER, PDI is primarily involved in protein folding, whereas on the cell surface, it reduces disulfide bonds. The functions of PDI depend on its localization and the redox state of its active site cysteines. The ER-based functions of PDI are linked to cancer invasion and migration. Surface-associated PDI facilitates the entry of viruses, such as HIV-1, and toxins, such as diphtheria and cholera. Thus, based on its involvement in pathological events, PDI is considered a potential drug target. However, a significant challenge in the therapeutic targeting of PDI is discovering function-specific inhibitors for it. To this end, a wide range of therapeutic agents, such as antibiotics, thiol blockers, estrogenic compounds, and arsenical compounds, have been used, although few are bona fide specific inhibitors. In this review, we will describe the potential of PDI as a therapeutic drug target.

Stress-induced expression of protein disulfide isomerase associated 3 (PDIA3) in Atlantic salmon (Salmo salar L.).

In mammals, disulfide isomerase associated 3, PDIA3, is a member of the endoplasmic reticulum (ER) stress proteins, which can be induced by oxidative stress; however, its role in relation to stress regulation is still unknown in fish. Here, we report the cloning of a coding region of PDIA3 from the Atlantic salmon. PDIA3 mRNA expression was evaluated in the liver of Atlantic salmon exposed to environmental hyperoxia stress and toxic perfluorooctane sulfonate (PFOS) exposure stress. The PDIA3 sequence contained two PDI-typical thioredoxin active sites of WCGHC and shared approximately 70% identity with mammalian PDIA3, and its mRNA was primarily expressed in the liver. PDIA3 was significantly increased in the liver of Atlantic salmon exposed to hyperoxic water during smoltification. Also Mn superoxide dismutase (Mn-SOD) and CCAAT/enhancer binding protein (C/EBP), other markers of oxidative stress, were upregulated by hyperoxia. Furthermore, PFOS exposure of hepatocytes resulted in elevated mRNA expression of PDIA3, Mn-SOD and C/EBPdelta as well as peroxisome proliferator-activated receptor gamma (PPARgamma). These results indicate a signaling connection between oxidative stress and ER stress. PDIA3 and C/EBPdelta may be valuable markers in fish for exposure and effect to environmental stress.

Catalysis of thiol/disulfide exchange. Glutaredoxin 1 and protein-disulfide isomerase use different mechanisms to enhance oxidase and reductase activities.

Glutaredoxin (Grx) and protein-disulfide isomerase (PDI) are members of the thioredoxin superfamily of thiol/disulfide exchange catalysts. Thermodynamically, rat PDI is a 600-fold better oxidizing agent than Grx1 from Escherichia coli. Despite that, Grx1 is a surprisingly good protein oxidase. It catalyzes protein disulfide formation in a redox buffer with an initial velocity that is 30-fold faster than PDI. Catalysis of protein and peptide oxidation by the individual catalytic domains of PDI and by a Grx1-PDI chimera show that differences in active site chemistry are fundamental to their oxidase activity. Mutations in the active site cysteines reveal that Grx1 needs only one cysteine to catalyze rapid substrate oxidation, whereas PDI requires both cysteines. Grx1 is a good oxidase because of the high reactivity of a Grx1-glutathione mixed disulfide, and PDI is a good oxidase because of the high reactivity of the disulfide between the two active site cysteines. As a protein disulfide reductase, Grx1 is also superior to PDI. It catalyzes the reduction of nonnative disulfides in scrambled ribonuclease and protein-glutathione mixed disulfides 30-180 times faster than PDI. A multidomain structure is necessary for PDI to catalyze effective protein reduction; however, placing Grx1 into the PDI multidomain structure does not enhance its already high reductase activity. Grx1 and PDI have both found mechanisms to enhance active site reactivity toward proteins, particularly in the kinetically difficult direction: Grx1 by providing a reactive glutathione mixed disulfide to supplement its oxidase activity and PDI by utilizing its multidomain structure to supplement its reductase activity.

A novel eukaryotic selenoprotein in the haptophyte alga Emiliania huxleyi.

The diversity of selenoproteins raises the question of why many life forms require selenium. Especially in photosynthetic organisms, the biochemical basis for the requirement for selenium is unclear because there is little information on selenoproteins. We found six selenium-containing proteins in a haptophyte alga, Emiliania huxleyi, which requires selenium for growth. The 27-kDa protein EhSEP2 was isolated, and its cDNA was cloned. The deduced amino acid sequence revealed that EhSEP2 is homologous to protein disulfide isomerase (PDI) and contains a highly conserved thioredoxin domain. The nucleotide sequence contains an in-frame TGA codon encoding selenocysteine at the position corresponding to the cysteine residue in the reaction center of known PDIs. However, no typical selenocysteine insertion sequence was found in the EhSEP2 cDNA. The EhSEP2 mRNA level was related to the abundance of selenium. E. huxleyi possesses a novel PDI-like selenoprotein and may have a novel type of selenocysteine insertion machinery.

Characterization of two protein disulfide isomerases from the endocytic pathway of bloodstream forms of Trypanosoma brucei.

Proteins from the endocytic pathway in bloodstream forms of Trypanosome brucei are modified by the addition of linear poly-N-acetyllactosamine side chains, which permits their isolation by tomato lectin affinity chromatography. Antibodies against this tomato lectin binding fraction were employed to screen a cDNA expression library from bloodstream forms of T. brucei. Two cDNAs were prominent among those selected. These cDNAs coded for two putative protein disulfide isomerases (PDIs) that respectively contained one and two double-cysteine redox-active sites and corresponded to a single domain PDI and a class 1 PDI. Assays of the purified recombinant proteins demonstrated that both proteins possess isomerase activity, but only the single domain PDI had a reducing activity. These PDIs possess a number of unusual features that distinguish them from previously characterized PDIs. The expression of both is developmentally regulated, they both co-localize with markers of the endocytic pathway, and both are modified by N-glycosylation. The larger PDI possesses N-glycans containing poly-N-acetyllactosamine, a modification that is indicative of processing in the Golgi and suggests the presence of a novel trafficking pathway for PDIs in trypanosomes. Although generally PDIs are considered essential, neither activity appeared to be essential for the growth of trypanosomes, at least in vitro.

ERp28, a human endoplasmic-reticulum-lumenal protein, is a member of the protein disulfide isomerase family but lacks a CXXC thioredoxin-box motif.

We report on the isolation, sequence and a putative role of a human endoplasmic-reticulum-lumenal protein, ERp28. The protein has the C-terminal retention signal KEEL and localizes to the endoplasmic reticulum (ER) as seen by subcellular fractionation and immunofluorescence studies. The protein has significant sequence similarity to members of the protein disulfide isomerase (PDI) family, although it lacks the thioredoxin box (CGHC) motif. We propose, on the basis of sequence analysis, a model of the domain structure of PDI, representing a significant extension of previously proposed models. Our results are in partial agreement with recently published NMR data [Kemmink, J., Darby, J., Dijkstra, K., Nilges, M. & Creighton, T. E. (1997) Curr. Biol. 7, 239-245] and indicate that PDI contains, in addition to the two thioredoxin folds described in previous models, two thioredoxin folds within the domains previously defined as b and b'. The thioredoxin domain of ERp28 shares a higher degree of similarity with the corresponding active and inactive domains of PDI than with other members of the PDI family, indicating that ERp28 developed from an ancient form of PDI or a PDI precursor. In contrast to Ig-heavy-chain-binding protein, human ERp28 is not induced by metabolic stress (tunicamycin). In in vitro experiments, ERp28 and calnexin precipitate with overexpressed, wild-type hepatitis B small surface antigen and with a mutated ER-retained form. This indicates that ERp28, as calnexin, may be involved in the processing of secretory proteins within the ER.

Contributions of substrate binding to the catalytic activity of DsbC.

DsbA and DsbC are involved in protein disulfide bond formation in the periplasm of Gram-negative bacteria. The two proteins are thought to fulfill different functions in vivo, DsbA as a catalyst of disulfide bond formation and DsbC as a catalyst of disulfide bond rearrangement. To explore the basis of this catalytic complementarity, the reaction mechanism of DsbC has been examined using unstructured model peptides that contain only one or two cysteine residues as substrates. The reactions between the various forms of the peptide and DsbC occur at rates up to 10(6)-fold faster than those that involve glutathione and DsbC, and they were constrained to occur at only one sulfur atom of disulfide bonds involving the peptide. Mixed disulfide complexes of DsbC and the peptide were 10(4)-fold more stable than the corresponding mixed disulfides with glutathione. These observations suggest that noncovalent binding interactions occur between the peptide and DsbC, which contribute to the very rapid kinetics of substrate utilization. The interactions between DsbC and the peptide appear to be more substantial than those between DsbA and the same peptide. The differences in the reaction of the peptide at the active sites of DsbA and DsbC provide insight into why DsbC is the better catalyst of disulfide bond rearrangement and how the active site chemistry of these structurally related proteins has been adapted to fulfill complementary functions.