Engineered cysteine mutants of myosin light chain 2. Fluorescent analogues for structural studies

Site-directed mutagenesis has been used to insert cysteine residues at specific locations in the myosin light chain 2 (LC2) sequence. The aim was to modify these cysteines with one or more spectroscopic probes and to reconstitute myosin with labeled light chains for structural studies. Native LC2 has two endogenous cysteine residues at positions 126 and 155; a third sulfhydryl was added by replacing either Pro2, Ser73, or Pro94 with cysteine. By oxidizing the endogenous cysteines to an intramolecular disulfide bond (Katoh, T., and Lowey, S., (1989) J. Cell Biol. 109, 1549), it was expected that the new cysteine could be selectively labeled with a fluorescent probe. This proved more difficult to accomplish than anticipated due to the formation of secondary disulfide bonds between the newly engineered cysteines and the native ones. Nevertheless, the unpaired cysteines were labeled with 5-(iodoacetamido)fluorescein, and singly labeled species were purified by ion-exchange chromatography. Chymotryptic digestion of the light chains, followed by high performance liquid chromatography separation of the peptides, led to the identification of the fluorescein-labeled cysteines. After light chain exchange into myosin, the position of the thiols was mapped by antifluorescyl antibodies in the electron microscope. Rotary-shadowed images showed the antibody bound at the head/rod junction of myosin for all the mutants. These mapping studies, together with the finding that widely separated cysteines can form multiple disulfide bonds, support a model for LC2 as a flexible, globular molecule that resembles other Ca/Mg-binding proteins in tertiary structure.     

Effect of temperature,pH, dissolved oxygen,and hydrolysate on the formation of triple light chain antibodies in cell culture

THIOMABs are recombinant antibodies with reactive cysteine residues used for forming THIOMAB–drug conjugates (TDCs). We recently reported a new impurity associated with THIOMABs: one of the engineered cysteines forms a disulfide bond with an extra light chain (LC) to generate a triple light chain antibody (3LC). In our previous investigations, increased LC expression increased 3LC levels, whereas increased glutathione (GSH) production decreased 3LC levels. In this work, on three stably transfected CHO cell lines, we investigated the effects of temperature, pH, dissolved oxygen (DO), and hydrolysate on 3LC formation during THIOMAB fed‐batch cell culture production. Although pH between 6.8 and 7.0 had no significant impact on 3LC formation, temperature at 35°C instead of 33 or 31°C generated the lowest 3LC values for two cell lines. The decreased 3LC level correlated with increased GSH production. We implemented a 35°C temperature process for large‐scale (2,000 L) production of a THIOMAB. This process reduced 3LC levels by ～50% compared with a 33°C temperature process. By contrast, DO and hydrolysate had modest effect on 3LC levels for the model cell line studied. Overall, we did not find significant changes in LC expression under the conditions tested, whereas changes in GSH production were more evident. By investigating the impact of bioreactor process and medium conditions on 3LC levels, we identified strategies that reduced 3LC levels. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Triple light chain antibodies: Factors that influence its formation in cell culture

THIOMABs are recombinant antibodies engineered with reactive cysteines, which can be covalently conjugated to drugs of interest to generate targeted therapeutics. During the analysis of THIOMABs secreted by stably transfected Chinese Hamster Ovary (CHO) cells, we discovered the existence of a new species—Triple Light Chain Antibody (3LC). This 3LC species is the product of a disulfide bond formed between an extra light chain and one of the engineered cysteines on the THIOMAB. We characterized the 3LC by size exclusion chromatography, mass spectrometry, and microchip electrophoresis. We also investigated the potential causes of 3LC formation during cell culture, focusing on the effects of free light chain (LC) polypeptide concentration, THIOMAB amino acid sequence, and glutathione (GSH) production. In studies covering 12 THIOMABs produced by 66 stable cell lines, increased free LC polypeptide expression—evaluated as the ratio of mRNA encoding for LC to the mRNA encoding for heavy chain (HC)—correlated with increased 3LC levels. The amino acid sequence of the THIOMAB molecule also impacted its susceptibility to 3LC formation: hydrophilic LC polypeptides showed elevated 3LC levels. Finally, increased GSH production—evaluated as the ratio of the cell‐specific production rate of GSH (q_GSH) to the cell‐specific production rate of THIOMAB (q_p)—corresponded to decreased 3LC levels. In time‐lapse studies, changes in extracellular 3LC levels during cell culture corresponded to changes in mRNA LC/HC ratio and q_GSH/q_p ratio. In summary, we found that cell lines with low mRNA LC/HC ratio and high q_GSH/q_p ratio yielded the lowest levels of 3LC. These findings provide us with factors to consider in selecting a cell line to produce THIOMABs with minimal levels of the 3LC impurity. Biotechnol. Bioeng. 2010. 105: 748–760. © 2009 Wiley Periodicals, Inc.     

Studies in serum support rapid formation of disulfide bond between unpaired cysteine residues in the VH domain of an immunoglobulin G1 molecule

Recombinant monoclonal antibodies undergo extensive posttranslational modifications. In this article, we characterize major modifications, separated by cation exchange chromatography, on an immunoglobulin G1 (IgG1) monoclonal antibody (mAb). We found that N-terminal cyclization of glutamine residues to pyroglutamate on the light and heavy chains are the major isoforms resolved during cation exchange chromatography. However, using CEX, we also separated and identified isoforms with unpaired cysteine residues in the V_H domain of the molecule (Cys22-Cys96). Omalizumab, a therapeutic anti-IgE antibody, has unpaired cysteine residues in the V_H domain between Cys22 and Cys96, and the Fab fragment, containing the unpaired cysteine residues, is reported to have reduced potency. Dynamic interchain disulfide rearrangement, with slow kinetics, was recently reported to take place in serum for an IgG2 molecule and resulted in predictable mature isoforms. Analytical evaluation of our mAb, after recovery from serum, revealed that the unpaired intrachain cysteine residues (Cys22-Cys96) reformed their disulfide bond. The significance of this study is that correct pairing occurred rapidly, and we speculate that thiol molecules such as cysteine, homocysteine, and glutathione in serum provide an environment, outside the endoplasmic reticulum, for correct linkage.     

Characterization and analysis of scFv-IgG bispecific antibody size variants

ABSTRACT

Bispecific antibodies are an emergent class of biologics that is of increasing interest for therapeutic applications. In one bispecific antibody format, single-chain variable fragments (scFv) are linked to or inserted in different locations of an intact immunoglobulin G (IgG) molecule to confer dual epitope binding. To improve biochemical stability, cysteine residues are often engineered on the heavy- and light-chain regions of the scFv to form an intrachain disulfide bond. Although this disulfide bond often improves stability, it can also introduce unexpected challenges to manufacturing or development. We report size variants that were observed for an appended scFv-IgG bispecific antibody. Structural characterization studies showed that the size variants resulted from the engineered disulfide bond on the scFv, whereby the engineered disulfide was found to be either open or unable to form an intrachain disulfide bond due to cysteinylation or glutathionylation of the cysteines. Furthermore, the scFv engineered cysteines also formed intermolecular disulfide bonds, leading to the formation of highly stable dimers and aggregates. Because both the monomer variants and dimers showed lower bioactivity, they were considered to be product-related impurities that must be monitored and controlled. To this end, we developed and optimized a robust, precise, and accurate high-resolution size-exclusion chromatographic method, using a statistical design-of-experiments methodology.     

Structural and evolutionary consequences of unpaired cysteines in trypsinogen

Vertebrate trypsins usually contain six disulfide bonds but human trypsin 1 (PRSS1) contains only five and human trypsin 2 (PRSS2) contains only four. To elucidate possible evolutionary pathways leading to the loss of disulfide bonds, we have constructed mutants lacking one or two cysteines of four disulfide bonds (C22-C157, C127-C232, C136-C201, and C191-C220) in rat anionic trypsinogen and followed their expression in the periplasm of Escherichia coli. When both cysteines of any of the above-mentioned disulfide bonds were replaced by alanines we found, as expected, proteolytically active enzymes. In the case of C127-C232 (missing from both human trypsins) and C191-C220 both single mutants gave active enzymes although their yield was significantly reduced. In contrast, only one of the single mutants of disulfide bonds C22-C157 and C136-C201 (missing from human trypsin 2) was expressed in E. coli. In the case of these disulfide bonds, we obtained no expression when the solvent accessible molecular surface of the free cysteine residue was the smaller one, indicating that a buried unpaired cysteine was more deleterious than one on the surface of the molecule.     

Early intermediates in the PDI-assisted folding of ribonuclease A

The oxidative refolding of ribonuclease A has been investigated in several experimental conditions using a variety of redox systems. All these studies agree that the formation of disulfide bonds during the process occurs through a nonrandom mechanism with a preferential coupling of certain cysteine residues. We have previously demonstrated that in the presence of glutathione the refolding process occurs through the reiteration of two sequential reactions: a mixed disulfide with glutathione is produced first which evolves to form an intramolecular S-S bond. In the same experimental conditions, protein disulfide isomerase (PDI) was shown to catalyze formation and reduction of mixed disulfides with glutathione as well as formation of intramolecular S-S bonds. This paper reports the structural characterization of the one-disulfide intermediate population during the oxidative refolding of Ribonuclease A under the presence of PDI and glutathione with the aim of defining the role of the enzyme at the early stages of the reaction. The one-disulfide intermediate population occurring at the early stages of both the uncatalyzed and the PDI-catalyzed refolding was purified and structurally characterized by proteolytic digestion followed by MALDI-MS and LC/ESIMS analyses. In the uncatalyzed refolding, a total of 12 disulfide bonds out of the 28 theoretical possible cysteine couplings was observed, confirming a nonrandom distribution of native and nonnative disulfide bonds. Under the presence of PDI, only two additional nonnative disulfides were detected. Semiquantitative LC/ESIMS analysis of the distribution of the S-S bridged peptides showed that the most abundant species were equally populated in both the uncatalyzed and the catalyzed process. This paper shows the first structural characterization of the one-disulfide intermediate population formed transiently during the refolding of ribonuclease A in quasi-physiological conditions that mimic those present in the ER lumen. At the early stages of the process, three of the four native disulfides are detected, whereas the Cys26-Cys84 pairing is absent. Most of the nonnative disulfide bonds identified are formed by nearest-neighboring cysteines. The presence of PDI does not significantly alter the distribution of S-S bonds, suggesting that the ensemble of single-disulfide species is formed under thermodynamic control.     

Increasing the reactivity of an artificial dithiol-disulfide pair through modification of the electrostatic milieu

The thiol-disulfide exchange reaction plays a central role in the formation of disulfide bonds in newly synthesized proteins and is involved in many aspects of cellular metabolism. Because the thiolate form of the cysteine residue is the key reactive species, its electrostatic milieu is thought to play a key role in determining the rates of thiol disulfide exchange reactions. While modest reactivity effects have previously been seen in peptide model studies, here, we show that introduction of positive charges can have dramatic effects on disulfide bond formation on a structurally restricted surface. We have studied properties of vicinal cysteine residues in proteins using a model system based on redox-sensitive yellow fluorescent protein (rxYFP). In this system, the formation of a disulfide bond between two cysteines Cys149 and Cys202 is accompanied by a 2.2-fold decrease in fluorescence. Introduction of positively charged amino acids in the proximity of the two cysteines resulted in an up to 13-fold increase in reactivity toward glutathione disulfide. Determination of the individual pK(a) values of the cysteines showed that the observed increase in reactivity was caused by a decrease in the pK(a) value of Cys149, as well as favorable electrostatic interactions with the negatively charged reagents. The results presented here show that the electrostatic milieu of cysteine thiols in proteins can have substantial effects on the rates of the thiol-disulfide exchange reactions.     

Denaturant-assisted formation of a stabilizing disulfide bridge from engineered cysteines in nonideal conformations

The engineered disulfide bridge A23C/L203C in human carbonic anhydrase II, inserted from homology modeling of Neisseria gonorrhoeae carbonic anhydrase, significantly stabilizes the native state of the protein. The inserted cysteine residues are placed in the interior of the structure, and because of the conformationally restrained localization, the protein is expressed in the reduced state and the cysteines are not readily oxidized. However, upon exposure to low concentrations of denaturant (0.6 M guanidine hydrochloride), corresponding to the lower part of the denaturation curve for the first unfolding transition, the oxidation rate of correctly formed disulfide bridges was markedly increased. By entropy estimations it appears that the increased flexibility, induced by the denaturant, enables the cysteines to find each other and hence to form the disulfide bridge. The outlined strategy of facilitating formation of disulfide bonds by addition of adjusted concentrations of a denaturant should be applicable to other proteins in which engineered cysteine residues are located in nonideal conformations. Moreover, a S99C/V242C variant was constructed, in which the cysteine residues are located on the surface. In this mutant the disulfide bridge was spontaneously formed and the native state was considerably stabilized (midpoint concentration of unfolding was increased from 1.0 to 1.4 M guanidine hydrochloride).     

Specific cysteines in beta3 are involved in disulfide bond exchange-dependent and -independent activation of alphaIIbbeta3

Disulfide bond exchange among cysteine residues in epidermal growth factor (EGF)-like domains of beta3 was suggested to be involved in activation of alphaIIbbeta3. To investigate the role of specific beta3 cysteines in alphaIIbbeta3 expression and activation, we expressed in baby hamster kidney cells normal alphaIIb with normal beta3 or beta3 with single or double cysteine substitutions of nine disulfide bonds in EGF-3, EGF-4, and beta-tail domains and assessed alphaIIbbeta3 surface expression and activation state by flow cytometry using P2 or PAC-1 antibodies, respectively. Most mutants displayed reduced surface expression of alphaIIbbeta3. Disruptions of disulfide bonds in EGF-3 yielded constitutively active alphaIIbbeta3, implying that these bonds stabilize the inactive alphaIIbbeta3 conformer. Mutants of the Cys-567-Cys-581 bond in EGF-4 were inactive even after exposure to alphaIIbbeta3-activating antibodies, indicating that this bond is necessary for activating alphaIIbbeta3. Disrupting Cys-560-Cys-583 in the EGF-3/EGF-4 or Cys-608-Cys-655 in beta-tail domain resulted in alphaIIbbeta3 activation only when Cys-560 or Cys-655 of each pair was mutated but not when their partners (Cys-583, Cys-608) or both cysteines were mutated, suggesting that free sulfhydryls of Cys-583 and Cys-608 participate in alphaIIbbeta3 activation by a disulfide bond exchange-dependent mechanism. The free sulfhydryl blocker dithiobisnitrobenzoic acid inhibited 70% of anti-LIBS6 antibody-induced activation of wild-type alphaIIbbeta3 and had a smaller effect on mutants, implicating disulfide bond exchange-dependent and -independent mechanisms in alphaIIbbeta3 activation. These data suggest that different disulfide bonds in beta3 EGF and beta-tail domains play variable structural and regulatory roles in alphaIIbbeta3.     

Locations of disulfide bonds and free cysteines in the heavy and light chains of recombinant human factor VIII (antihemophilic factor A).

The locations of disulfide bonds and free cysteines in the heavy and light chains of recombinant human factor VIII were determined by sequence analysis of fragments produced by chemical and enzymatic digestions. The A1 and A2 domains of the heavy chain and the A3 domain of the light chain contain one free cysteine and two disulfide bonds, whereas the C1 and C2 domains of the light chain have one disulfide bond and no free cysteine. The positions of these disulfide bonds are conserved in factor V and ceruloplasmin except that the second disulfide bond in the A3 domain is missing in both factor V and ceruloplasmin. The positions of the three free cysteines of factor VIII are the same as three of the four cysteines present in ceruloplasmin. However, the positions of the free cysteines in factor VIII and ceruloplasmin are not conserved in factor V.     

Nonnative interactions between cysteines direct productive assembly of P22 tailspike protein

Nonnative disulfide bond formation can play a critical role in the assembly of disulfide bonded proteins. During the folding and assembly of the P22 tailspike protein, nonnative disulfide bonds form both in vivo and in vitro. However, the mechanism and identity of cysteine disulfide pairs remains elusive, particularly for P22 tailspike, which contains no disulfide bonds in its native, functional form. Understanding the interactions between cysteine residues is important for developing a mechanistic model for the role of nonnative cysteines in P22 tailspike assembly. Prior in vivo studies have suggested that cysteines 496, 613, and 635 are the most likely site for sulfhydryl reactivity. Here we demonstrate that these three cysteines are critical for efficient assembly of tailspike trimers, and that interactions between cysteine pairs lead to productive assembly of native tailspike.     

Disulfide bond structure determination and biochemical analysis of glycoprotein C from herpes simplex virus.

A biochemical analysis of glycoprotein C (gC of herpes simplex virus was undertaken to further characterize the structure of the glycoprotein and to determine its disulfide bond arrangement. We used three recombinant forms of gC, gC1(457t), gC1(delta33-123t), and gC2(426t), each truncated prior to the transmembrane region. The proteins were expressed and secreted by using a baculovirus expression system and have been shown to bind to monoclonal antibodies which recognize discontinuous epitopes and to complement component C3b in a dose-dependent manner. We confirmed the N-terminal residues of each mature protein by Edman degradation and confirmed the internal deletion in gC1(delta33-123t). The molecular weight and extent of glycosylation of gC1 (457t), gC1(delta33-123t), and gC2(426t) were determined by treating each protein with endoglycosidases and then subjecting it to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and mass spectrometric analysis. The data indicate that eight to nine of the predicted N-linked oligosaccharide sites on gC1(457t) are occupied by glycans of approximately 1,000 Da. In addition, O-linked oligosaccharides are present on gC1(457t), primarily localized to the N-terminal region (amino acids [aa] 33 to 123) of the protein. gC2(426t) contains N-linked oligosaccharides, but no O-linked oligosaccharides were detected. To determine the disulfide bond arrangement of the eight cysteines of gC1(457t),the protein was cleaved with cyanogen bromide. SDS-PAGE analysis followed by Edman degradation identified three cysteine-containing fragments which are not connected by disulfide linkages. Chemical modification of cysteines combined with matrix-assisted laser desorption ionization mass spectrometry identified disulfide bonds between cysteine 1 (aa 127) and cysteine 2 (aa 144) and between cysteine 3 (aa 286) and cysteine 4 (aa 347). Further proteolysis of the cyanogen bromide-generated fragment containing cysteine 5 through cysteine 8, combined with mass spectrometry and Edman degradation, showed that disulfide bonds link cysteine 5 (aa 386) to cysteine 8 (aa 442) and cysteine 6 (aa 390) to cysteine 7 (aa 419). A similar disulfide bond arrangement is postulated to exist in gC homologs from other herpesviruses.     

Engineering disulfide bonds within an antibody

Antibodies have evolved to function in oxidative, extracellular environments. A pair of cysteines in close proximity will oxidatively react to form a disulfide bond that fixes and stabilizes the tertiary structure of a protein. Immunoglobulin G (IgG) includes several disulfide bonds, and the patterns of inter-chain disulfide bonds characterize different IgG sub-classes. Moreover, the Ig-fold domains are characterized by a buried intra-domain disulfide bond, which is important for its structural stability. However, the intra-domain disulfide bond can be replaced without crucial effects on the structure and function, if the domain structure is intrinsically stable or has been stabilized by protein engineering. In previous studies, disulfide bonds were removed by amino-acid substitution indicating that Val and/or Ala (i.e. Ala–Ala, Ala–Val, Val–Ala, and Val–Ala) pairs were preferred for cysteine replacement in the Ig-fold domain. As such, these mutations may be useful for the intracellular use of antibodies. Recently, additional intra-domain disulfide bonds have been shown to stabilize Ig-fold domains and whole IgGs. In heavy chain variable or light chain variable domains, the introduction of additional disulfide bonds into the framework region did not reduce antigen-binding affinity, suggesting that generating disulfide bonds may be a method for stabilizing IgG and antibody fragments, such as the antigen-binding fragment, and single-chain and single-domain antibodies. This article is part of a Special Issue entitled: Recent advances in molecular engineering of antibody.     

Mapping single cysteine mutants of light chain 2 in chicken skeletal myosin.

The NH2- and COOH-terminal regions of the regulatory light chain (LC2) have been mapped to the head/rod junction by immunoelectron microscopy, using monoclonal and anti-fluorescyl antibodies as probes. In order to map the entire length of the light chain, we have engineered and purified mutants that contain a single cysteine residue at positions 2, 73, 94, 126, or 155. The single cysteine residues were labeled with either 5-iodoacetamido fluorescein or N-ethylmaleimide-biotin. We observed that the reactivity of Cys126 is far greater than that of Cys155, confirming that cysteine 126 is the fast-reacting thiol in wild-type light chain. The labeled light chains were exchanged into myosin stripped of its native LC2 by immunoaffinity chromatography, and the reconstituted myosin was reacted with anti-fluorescein antibody or avidin prior to rotary shadowing for electron microscopy. The position of the antibody or avidin was found to be near the head/rod junction for all mutants. These mapping studies, together with our finding that cysteines widely separated in the primary sequence can form multiple disulfide bonds (Saraswat, L.D., and Lowey, S. (1991) J. Biol. Chem. 226, 19777-19785), support a model for LC2 as a flexible, globular molecule localized mainly in the vicinity of the head/rod junction of myosin.     

Probing the dark state tertiary structure in the cytoplasmic domain of rhodopsin: proximities between amino acids deduced from spontaneous disulfide bond formation between Cys316 and engineered cysteines in cytoplasmic loop 1

A dark state tertiary structure in the cytoplasmic domain of rhodopsin is presumed to be the key to the restriction of binding of transducin and rhodopsin kinase to rhodopsin. Upon light-activation, this tertiary structure undergoes a conformational change to form a new structure, which is recognized by the above proteins and signal transduction is initiated. In this and the following paper in this issue [Cai, K., Klein-Seetharaman, J., Altenbach, C., Hubbell, W. L., and Khorana, H. G. (2001) Biochemistry 40, 12479-12485], we probe the dark state cytoplasmic domain structure in rhodopsin by investigating proximity between amino acids in different regions of the cytoplasmic face. The approach uses engineered pairs of cysteines at predetermined positions, which are tested for spontaneous formation of disulfide bonds between them, indicative of proximity between the original amino acids. Focusing here on proximity between the native cysteine at position 316 and engineered cysteines at amino acid positions 55-75 in the cytoplasmic sequence connecting helices I-II, disulfide bond formation was studied under strictly defined conditions and plotted as a function of the position of the variable cysteines. An absolute maximum was observed for position 65 with two additional relative maxima for cysteines at positions 61 and 68. The observed disulfide bond formation rates correlate well with proximity of these residues found in the crystal structure of rhodopsin in the dark. Modeling of the engineered cysteines in the crystal structure indicates that small but significant motions are required for productive disulfide bond formation. During these motions, secondary structure elements are retained as indicated by the lack of disulfide bond formation in cysteines that do not face toward Cys316 in the crystal structure model. Such motions may be important in light-induced conformational changes.     

Identification and function of disulfide bridges in the extracellular domains of the angiotensin II type 2 receptor.

The angiotensin II (AngII) receptor family is comprised of two subtypes, type 1 (AT(1)) and type 2 (AT(2)). Although sharing low homology (only 34%), mutagenesis has identified some key residues that are conserved between both subtypes, including four extracellular cysteines. Previous AT(1) mutagenesis demonstrated that the cysteines form two disulfide bonds, one linking the first and second extracellular loops and another connecting the amino terminus to the third extracellular loop. The importance of these AT(1) disulfides in ligand binding is supported by the effect of dithiothreitol (DTT). DTT breaks disulfide bonds, thereby strongly inhibiting ligand binding in AT(1) receptors. Despite retaining the same cysteines, AT(2) receptor ligand binding is paradoxically enhanced by DTT. Thus, we constructed a series of AT(2) cysteine mutations, either individually or paired, to establish the role of the cysteines and the source of DTT's effects. The AT(2) cysteine mutants surprisingly confirmed that the cysteines form disulfide bonds in the same manner as in the AT(1) subtype. However, breaking the AT(2) disulfide bridges yielded two responses. As in AT(1) receptors, mutations disrupting the disulfide bond between the first and second extracellular loops reduced AT(2) binding by 4-fold. In contrast, mutations breaking the disulfide bridge between the amino terminus and the third extracellular loop increased AT(2) binding, mimicking DTT's effect on this subtype. Further analysis of AT(1)/AT(2) chimeric exchange mutants of these domains suggested that the AT(2) amino terminus and third extracellular loop may possess latent binding epitopes that are only uncovered after DTT exposure.     

Predicting disulfide bond connectivity in proteins by correlated mutations analysis

MOTIVATION: Prediction of disulfide bond connectivity facilitates structural and functional annotation of proteins. Previous studies suggest that cysteines of a disulfide bond mutate in a correlated manner. RESULTS: We developed a method that analyzes correlated mutation patterns in multiple sequence alignments in order to predict disulfide bond connectivity. Proteins with known experimental structures and varying numbers of disulfide bonds, and that spanned various evolutionary distances, were aligned. We observed frequent variation of disulfide bond connectivity within members of the same protein families, and it was also observed that in 99% of the cases, cysteine pairs forming non-conserved disulfide bonds mutated in concert. Our data support the notion that substitution of a cysteine in a disulfide bond prompts the substitution of its cysteine partner and that oxidized cysteines appear in pairs. The method we developed predicts disulfide bond connectivity patterns with accuracies of 73, 69 and 61% for proteins with two, three and four disulfide bonds, respectively.     

Disulfide bond formation during the folding of influenza virus hemagglutinin

To study the importance of individual sulfhydryl residues during the folding and assembly in vivo of influenza virus hemagglutinin (HA), we have constructed and expressed a series of mutant HA proteins in which cysteines involved in three disulfide bonds have been substituted by serine residues. Investigations of the structure and intracellular transport of the mutant proteins indicate that (a) cysteine residues in the ectodomain are essential both for efficient folding of HA and for stabilization of the folded molecule; (b) cysteine residues in the globular portion of the ectodomain are likely to form native disulfide bonds rapidly and directly, without involvement of intermediate, nonnative linkages; and (c) cysteine residues in the stalk portion of the ectodomain also appear not to form intermediate disulfide bonds, even though they have the opportunity to do so, being separated from their correct partners by hundreds of amino acids including two or more other sulfhydryl residues. We propose a role for the cellular protein BiP in shielding the cysteine residues of the stalk domain during the folding process, thus preventing them from forming intermediate, nonnative disulfide bonds.     

Disulfide bonds in rat cutaneous fatty acid-binding protein

Unlike other fatty acid-binding proteins, cutaneous (epidermal) fatty acid-binding proteins contain a large number of cysteine residues. The status of the five cysteine residues in rat cutaneous fatty acid-binding protein was examined by chemical and mass-spectrometric analyses. Two disulfide bonds were identified, between Cys-67 and Cys-87, and between Cys-120 and Cys-127, though extent of formation of the first disulfide bond was rather low in another preparation. Cys-43 was free cysteine. Homology modeling study of the protein indicated the close proximity of the sulfur atoms of these cysteine pairs, supporting the presence of the disulfide bonds. These disulfide bonds appear not to be directly involved in fatty acid-binding activity, because a recombinant rat protein expressed in Escherichia coli in which all five cysteines are fully reduced showed fatty acid-binding activity as examined by displacement of a fluorescent fatty acid analog by long-chain fatty acids. However, the fact that the evolutionarily distant shark liver fatty acid-binding protein also has a disulfide bond corresponding to the one between Cys-120 and Cys-127, and that fatty acid-binding proteins play multiple roles suggests that some functions of cutaneous fatty acid-binding protein might be regulated by the cellular redox state through formation and reduction of disulfide bonds. Although we cannot completely exclude the possibility of oxidation during preparation and analysis, it is remarkable that a protein in cytosol under normally reducing conditions appears to contain disulfide bonds.