Construction of hevein (Hev b 6.02) with reduced allergenicity for immunotherapy of latex allergy by comutation of six amino acid residues on the conformational IgE epitopes

Recently we have established that IgE Abs bind to conformational epitopes in the N- and C-terminal regions of the major natural rubber latex allergen, hevein (Hev b 6.02). To identify the critical amino acid residues that interact with IgE, the hevein sequence was scanned by using site-specific mutations. Twenty-nine hevein mutants were designed and produced by a baculovirus expression system in insect cells and tested by IgE inhibition-ELISA using sera from 26 latex allergic patients. Six potential IgE-interacting residues of hevein (Arg(5), Lys(10), Glu(29), Tyr(30), His(35), and Gln(38)) were identified and characterized further in detail. Based on these six residues, two triple mutants (Hdelta3A, Hdelta3B) and hevein mutant where all six residues were mutated (Hdelta6), were designed, modeled, and produced. Structural and functional properties of these combinatory mutants were compared experimentally and in silico with those of recombinant hevein. The IgE-binding affinity of the mutants decreased by three to five orders of magnitude as compared with that of recombinant hevein. Skin prick test reactivity of the triple mutant HDelta3A was drastically reduced and that of the six-residue mutant Hdelta6 was completely abolished in all patients examined in this study. The approach presented in this paper offers tools for identification and modification of amino acid residues on conformational epitopes of allergens that interact with IgE. Hevein with a highly reduced ability to bind IgE should provide a valuable candidate molecule for immunotherapy of latex allergy and is anticipated to have a low risk of systemic side effects.     

Characterization of T cell responses to Hev b 3, an allergen associated with latex allergy in spina bifida patients

The prevalence of type I allergy to Hevea brasiliensis latex is particularly high among individuals with frequent exposure such as health care workers and patients with spina bifida (SB). Due to a birth defect of the spinal canal and the resulting neurological and orthopedic defects, these patients require multiple surgeries during childhood. SB patients display a unique pattern of sensitization: IgE-reactivity is preferentially directed against Hev b 3 and Hev b 1, two latex allergens with high sequence similarity. In this study, we analyzed the T cell response to Hev b 3 in latex-allergic SB patients using poly-, oligo-, and monoclonal T lymphocyte cultures. All T cell clones (TCC) were CD3/CD4-positive and expressed the alphabeta TCR. According to their cytokine production pattern (IL-4 vs IFN-gamma), 12 of 21 TCC were classified as Th2-like, 2 of 21 were Th1-like, and 7 of 21 belonged to a Th0-like subset. Using 11 T cell lines and 21 TCC, nine T cell stimulating fragments were determined out of 52 overlapping 12-mer peptides representing the complete amino acid sequence of Hev b 3. Ag presentation of one dominant T cell epitope could be associated with a four-amino acid binding motif (YSTS, position 11-13) in the beta 1 chain of HLA-DR molecules expressed by the respective patients. No reactivity was observed when Hev b 3-reactive T cell lines or TCC were incubated with peptides representing homologous parts of the Hev b 1 molecule, i.e., no cross-reactivity between Hev b 3 and Hev b 1 at the T cell level was evident.     

Role of cysteine residues in structural stability and function of a transmembrane helix bundle

To study the structural and functional roles of the cysteine residues at positions 36, 41, and 46 in the transmembrane domain of phospholamban (PLB), we have used Fmoc (N-(9-fluorenyl)methoxycarbonyl) solid-phase peptide synthesis to prepare alpha-amino-n-butyric acid (Abu)-PLB, the analogue in which all three cysteine residues are replaced by Abu. Whereas previous studies have shown that replacement of the three Cys residues by Ala (producing Ala-PLB) greatly destabilizes the pentameric structure, we hypothesized that replacement of Cys with Abu, which is isosteric to Cys, might preserve the pentameric stability. Therefore, we compared the oligomeric structure (from SDS-polyacrylamide gel electrophoresis) and function (inhibition of the Ca-ATPase in reconstituted membranes) of Abu-PLB with those of synthetic wild-type PLB and Ala-PLB. Molecular modeling provides structural and energetic insight into the different oligomeric stabilities of these molecules. We conclude that 1) the Cys residues of PLB are not necessary for pentamer formation or inhibitory function; 2) the steric properties of cysteine residues in the PLB transmembrane domain contribute substantially to pentameric stability, whereas the polar or chemical properties of the sulfhydryl group play only a minor role; 3) the functional potency of these PLB variants does not correlate with oligomeric stability; and 4) acetylation of the N-terminal methionine has neither a functional nor a structural effect in full-length PLB.     

Mercurial activation of human PMN leucocyte type IV procollagenase (gelatinase).

Autoproteolytic activation and processing of human polymorphonuclear leucocyte (PMNL) type IV procollagenase (gelatinase) was initiated by HgCl2 and was investigated by kinetic analysis and N-terminal sequence determination of the reaction products. In the first instance the propeptide domain was lost by subsequent cleavage of the Asp15-Leu16, Glu40-Met41, Leu52-Leu53 and Ala74-Met75 peptide bonds. The PRCGVPD sequence motif (residues Pro78-Asp84), which is conserved in all metalloproteinases and expected to be relevant for latency, remained uncleaved at the activated enzyme. The generated intermediate was further processed by three C-terminal cleavages. The Glu666-Leu667, Ala506-Glu507 and Ala398-Leu399 bonds were hydrolysed successively. From the fragmentation products we were able to conclude that three released fragment peptides contained unpaired free cysteine with the residues Cys497, Cys653, Cys683. Cleavage of the first C-terminal peptide bond resulted in the loss of one of the conserved Cys residues of the hemopexin-like domain, whereas the Cys residue of the PRCGVPD motif was retained at the fully active enzyme. The possibility of an entirely different activation mechanism for PMNL type IV procollagenase is discussed.     

Site-directed mutagenesis and use of bile acid-MTS conjugates to probe the role of cysteines in the human apical sodium-dependent bile acid transporter (SLC10A2)

The residues involved in substrate interaction of the human apical sodium-dependent bile acid transporter (hASBT, SLC10A2) remain undefined. Biochemical modification of conserved cysteine residues has suggested their direct involvement in hASBT function. In the present study, we developed novel methanethiosulfonyl (MTS)-bile salt derivatives and describe their reactivity toward hASBT and its mutants. Endogenous Cys residues were subjected to Ala/Thr scanning mutagenesis and subsequent exposure to affinity inactivators. We show that C51A/T, C105A/T, C144A, and C255A/T are loss-of-function mutations. Additionally, C74A/T cell surface expression was abolished suggesting a role in protein folding and/or trafficking. C270A remained largely unaffected in the presence of 1.0 mM polar and charged MTS reagents (MTSEA, MTSES, and MTSET) and retained function similar to wt-hASBT control. However, in the presence of synthetic cholyl- and chenodeoxycholyl-MTS analogues, C270A displayed a significant decrease in K(T) and J(max). Our findings demonstrate that Cys270 is a highly accessible extracellular residue susceptible to thiol modification in its native form that remains largely unaffected upon mutation to Ala. Consequently, C270A provides an ideal scaffold for cysteine scanning mutagenesis studies. Furthermore, the substantial decrease in ligand affinity and maximal transport capacity of C270A suggest that C270 may potentially impact, although not critically, a putative substrate binding domain of hASBT. Overall, bile acid-MTS conjugates can serve as novel and powerful tools to probe the role of endogenous as well as engineered Cys residues and, ultimately, aid in defining their role in the bile acid binding region(s) of hASBT.     

Thermodynamic and kinetic destabilization of triosephosphate isomerase resulting from the mutation of conserved and non-conserved cysteines

Several variants of Saccharomyces cerevisiae triosephosphate isomerase (yTIM) were studied to determine how mutations of conserved and non-conserved Cys residues affect the enzyme. Wild-type yTIM has two buried free cysteines: Cys 41 (non-conserved) and the invariant Cys 126. Single-site mutants, containing substitutions of these cysteines with Ala, Val, or Ser (the three most conservative changes for a buried Cys, according to substitution matrices), were examined for stability and enzymatic activity. Neither of the Cys residues was found to be essential for enzyme catalysis. Determination of the global stability of the mutants indicated that, regardless of which Cys was substituted, individual Cys→Ala and Cys→Val mutations, as well as the C41S substitution, all decrease the unfolding free energy of the dimeric protein by less than 23 kJ mol(-1) (at 37 °C, pH 7.4), as compared to the wild-type enzyme. In contrast, a substantially larger destabilization (37 kJ mol(-1)) was found in the C126S mutant. These results suggest that, with the exception of C126S, all of these mutations can be regarded as neutral (i.e., mutations that do not impair the reproductive success of the organism). Accordingly, Cys 126 has remained invariant across evolution because its neutral substitutions by Ala or Val would require a highly unlikely, concerted double mutation at any of the Cys codons. Furthermore, detrimental effects to a cell expressing the C126S TIM mutant more likely arise from the high unfolding rate of this enzyme.     

Insights into a conformational epitope of Hev b 6.02 (hevein)

Hevein (Hev b 6.02) is a major IgE-binding allergen in natural rubber latex and manufactured products. Both tryptophans (Trp(21) and Trp(23)) of the hevein molecule were chemically modified with BNPS-skatole (2-nitrophenylsulfenyl-3-methyl-3(')-bromoindolenine); derivatized allergen failed to significantly inhibit binding of serum IgE in ELISA assays. Similarly, skin prick tests showed that hevein-positive patients gave no response with the modified allergen. Dot blot experiments carried out with anti-hevein mono- and polyclonal antibodies confirmed the importance of Trp(21) and Trp(23) for antibody-recognition, and demonstrated the specific cross-reactivity of other molecules containing hevein-like domains. We also report the structure of Hev b 6.02 at an extended resolution (1.5A) and compare its surface properties around Trp residues with those of similar regions in other allergens. Overall our results indicate that the central part of the protein, which comprises three aromatic and other acidic and polar residues, constitutes a conformational epitope.     

Second mutations rescue point mutant of the Na(+)/H(+) exchanger NHE1 showing defective surface expression

We studied the effect of point mutation within the putative 11th transmembrane domain (TM11) of the Na(+)/H(+) exchanger NHE1 on the plasma membrane expression. Of the 19 mutants tested, two mutants (Tyr454 or Arg458 replaced by Cys) were retained in the endoplasmic reticulum. Interestingly, Y454C was expressed on the cell surface when one of the endogenous cysteine residues at position 8, 133, 421, or 477 was substituted with alanine. Random mutagenesis at Cys8 and its surrounding residues in the cytosolic N-tail revealed that replacement of Cys8 with Ala was the only identified single residue mutation that rescued Y454C. These results suggest that the abnormal conformation of the region of TM11 containing the Y454C mutation is compensated by the second mutation within other domains such as the N-tail. This approach may provide evidence for the interdomain interaction in NHE1.     

The disulfide bonding pattern in ficolin multimers

Ficolin is a plasma lectin, consisting of a short N-terminal multimerization domain, a middle collagen domain, and a C-terminal fibrinogen-like domain. The collagen domains assemble the subunits into trimers, and the N-terminal domain assembles four trimers into 12-mers. Two cysteine residues in the N-terminal domain are thought to mediate multimerization by disulfide bonding. We have generated three mutants of ficolin alpha in which the N-terminal cysteines were substituted by serines (Cys4, Cys24, and Cys4/Cys24). The N-terminal cysteine mutants were produced in a mammalian cell expression system, purified by affinity chromatography, and analyzed under nondenaturing conditions to resolve the multimer structure of the native protein and under denaturing conditions to resolve the disulfide-linked structure. Glycerol gradient sedimentation and electron microscopy in nondenaturing conditions showed that plasma and recombinant wild-type protein formed 12-mers. The Cys4 mutant also formed 12-mers, but Cys24 and Cys4/Cys24 mutants formed only trimers. This means that protein interfaces containing Cys4 are stable as noncovalent protein-protein interactions and do not require disulfides, whereas those containing Cys24-Cys24 require the disulfides for stability. Proteins were also analyzed by nonreducing SDS-PAGE to show the covalent structure under denaturing conditions. Wild-type ficolin was covalently linked into 12-mers, whereas elimination of either Cys4 or Cys24 gave dimers and monomers. We present a model in which symmetric Cys24-Cys24 disulfide bonds between trimers are the basis for multimerization. The model may also be relevant to collectin multimers.     

Cysteine 981 of the human insulin receptor is required for covalent cross-linking between beta-subunit and a thiol-reactive membrane-associated protein

The cytoplasmic domain of the insulin receptor (IR) beta-subunit contains cysteine (Cys) residues whose reactivity and function remain uncertain. In this study, we examined the ability of the bifunctional cross-linking reagent 1,6-bismaleimidohexane (BMH) to covalently link IR with interacting proteins that possess reactive thiols. Transfected Chinese hamster ovary cells expressing either the wild-type human IR, C-terminally truncated receptors, or mutant receptors with Cys --> Ala substitutions and mouse 3T3-L1 adipocytes were used to compare the BMH effect. The results showed the formation of a large complex between the wild-type human receptor beta-subunit and molecule X, a thiol-reactive membrane-associated protein, in both intact and semipermeabilized cells in response to BMH. Prior cell stimulation with insulin had only a modest effect in this process. Western blot analysis revealed that the receptor alpha-subunit was not present in the beta-X complex. The BMH cross-linking did not inhibit in vitro tyrosine phosphorylation of the receptor complexed with molecule X. Both the human IR Cys981Ala mutant and murine IR, that lacks the equivalent of human Cys(981), failed to react with BMH. Finally, no covalent association between IR beta-subunit and IRS-1, the protein tyrosine phosphatase LAR or SHP-2 was observed in BMH-treated cells expressing the wild-type human IR. These results demonstrate a striking difference in reactivity among the cytoplasmic IR beta-subunit thiols and clearly show that Cys(981) of human IR beta-subunit is in close proximity to a thiol-reactive membrane-associated protein under basal and insulin-stimulated conditions.     

Evidence for intramolecular disulfide bond shuffling in the folding of mutant human lysozyme

Our previous results using the Saccharomyces cerevisiae secretion system suggest that intramolecular exchange of disulfide bonds occurs in the folding pathway of human lysozyme in vivo (Taniyama, Y., Yamamoto, Y., Kuroki, R., and Kikuchi, M. (1990) J. Biol. Chem. 265, 7570-7575). Here we report on the results of introducing an artificial disulfide bond in mutants with 2 cysteine residues substituting for Ala83 and Asp91. The mutant (C83/91) protein was not detected in the culture medium of the yeast, probably because of incorrect folding. Thereupon, 2 cysteine residues Cys77 and Cys95 were replaced with Ala in the mutant C83/91, because a native disulfide bond Cys77-Cys95 was found not necessary for correct folding in vivo (Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M., and Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967). The resultant mutant (AC83/91) was secreted as two proteins (AC83/91-a and AC83/91-b) with different specific activities. Amino acid and peptide mapping analyses showed that two glutathiones appeared to be attached to the thiol groups of the cysteine residues introduced into AC83/91-a and that four disulfide bonds including an artificial disulfide bond existed in the AC83/91-b molecule. The presence of cysteine residues modified with glutathione may indicate that the non-native disulfide bond Cys83-Cys91 is not so easily formed as a native disulfide bond. These results suggest that the introduction of Cys83 and Cys91 may act to suppress the process of native disulfide bond formation through disulfide bond interchange in the folding of human lysozyme.     

Functional structure of the somatomedin B domain of vitronectin

The N-terminal somatomedin B domain (SMB) of vitronectin binds PAI-1 and the urokinase receptor with high affinity and regulates tumor cell adhesion and migration. We have shown previously in the crystal structure of the PAI-1/SMB complex that SMB, a peptide of 51 residues, is folded as a compact cysteine knot of four pairs of crossed disulfide bonds. However, the physiological significance of this structure was questioned by other groups, who disputed the disulfide bonding shown in the crystal structure (Cys5-Cys21, Cys9-Cys39, Cys19-Cys32, Cys25-Cys31), notably claiming that the first disulfide is Cys5-Cys9 rather than the Cys5-Cys21 bonding shown in the structure. To test if the claimed Cys5-Cys9 bond does exist in the SMB domain of plasma vitronectin, we purified mouse and rat plasma vitronectin that have a Met (hence cleavable by cyanogen bromide) at residue 14, and also prepared recombinant human SMB variants from insect cells with residues Asn14 or Leu24 mutated to Met. HPLC and mass spectrometry analysis showed that, after cyanogen bromide digestion, all the fragments of the SMB derived from mouse or rat vitronectin or the recombinant SMB mutants are still linked together by disulfides, and the N-terminal peptide (residue 1-14 or 1-24) can only be released when the disulfide bonds are broken. This clearly demonstrates that Cys5 and Cys9 of SMB do not form a disulfide bond in vivo, and together with other structural evidence confirms that the only functional structure of the SMB domain of plasma vitronectin is that seen in its crystallographic complex with PAI-1.     

Sequencing and characterization of asclepain f: the first cysteine peptidase cDNA cloned and expressed from <Emphasis Type="Italic">Asclepias fruticosa</Emphasis> latex

Asclepain f is a papain-like protease previously isolated and characterized from latex of Asclepias fruticosa. This enzyme is a member of the C1 family of cysteine proteases that are synthesized as preproenzymes. The enzyme belongs to the alpha + beta class of proteins, with two disulfide bridges (Cys22-Cys63 and Cys56-Cys95) in the alpha domain, and another one (Cys150-Cys201) in the beta domain, as was determined by molecular modeling. A full-length 1,152 bp cDNA was cloned by RT-RACE-PCR from latex mRNA. The sequence was predicted as an open reading frame of 340 amino acid residues, of which 16 residues belong to the signal peptide, 113 to the propeptide and 211 to the mature enzyme. The full-length cDNA was ligated to pPICZα vector and expressed in Pichia pastoris. Recombinant asclepain f showed endopeptidase activity on pGlu-Phe-Leu-p-nitroanilide and was identified by PMF-MALDI-TOF MS. Asclepain f is the first peptidase cloned and expressed from mRNA isolated from plant latex, confirming the presence of the preprocysteine peptidase in the latex.     

In HspA from Helicobacter pylori vicinal disulfide bridges are a key determinant of domain B structure

Helicobacter pylori produces a heat shock protein A (HspA) that is unique to this bacteria. While the first 91 residues (domain A) of the protein are similar to GroES, the last 26 (domain B) are unique to HspA. Domain B contains eight histidines and four cysteines and was suggested to bind nickel. We have produced HspA and two mutants: Cys94Ala and Cys94Ala/Cys111Ala and identified the disulfide bridge pattern of the protein. We found that the cysteines are engaged in three disulfide bonds: Cys51/Cys53, Cys94/Cys111 and Cys95/Cys112 that result in a unique closed loop structure for the domain B.     

Multiple cysteine residues are implicated in Janus kinase 2-mediated catalysis

The redox regulation of Janus kinase 2 (JAK2) is poorly understood, and there are contradictory reports as to whether the enzyme's activity is inhibited or stimulated by oxidizing conditions in the cell. Here we demonstrate that multiple cysteine residues within the JAK2 catalytic domain may be crucial for enzymatic activity. The enzyme is catalytically inactive when oxidized; activity can be restored via reduction to the thiol state. A series of recombinant variants of JAK2 were overproduced using the baculoviral expression vector system. A truncated variant of JAK2, GST/(NDelta661)rJAK2, provided evidence that the amino-terminal autoinhibitory domain was not essential for direct redox regulation and that only nine cysteine residues were potentially involved. The effect of individually and combinatorially altering these nine cysteines was examined via cysteine-to-serine mutagenesis. This identified four cysteine residues in the catalytic domain (Cys866, Cys917, Cys1094, and Cys1105) that cooperatively maintain JAK2's catalytic competency. Our data are consistent with a direct mechanism for redox regulation of JAK2 via oxidation and reduction of critical cysteine residues.     

Mutational analysis of the ligand-binding domain of the prolactin receptor

The recent isolation and sequencing of the rat liver prolactin (PRL) receptor cDNA (clone F3) revealed that the receptor is a small molecular weight protein (nonglycosylated form, Mr 33,000; glycosylated form, Mr 42,000) comprised of 291 amino acids. A second form of the PRL receptor exists (591 amino acids) that contains a much longer cytoplasmic domain. In the present study, site-directed point mutations of the 5 conserved cysteine (Cys) residues and of the three potential N-linked glycosylation sites in the extracellular domain of the rat PRL receptor were constructed to assess their involvement in hormone binding. In addition, a truncation mutant (T delta 237) lacking 55 of 57 intracellular amino acids was constructed to determine the influence of the cytoplasmic domain on ligand-receptor interactions. Binding studies of transiently transfected COS-7 cells demonstrated that serine substitution of the first 4 Cys residues (Cys12, Cys22, Cys51, and Cys62) completely eliminated binding of 125I-ovine PRL and 125I-U5 and -U6, two monoclonal antibodies that bind the receptor molecule outside the PRL-binding domain. RNA blot analysis of the transfected cells showed that both the wild-type and mutant clones had similar levels of expression of receptor mRNA. Immunoblot analysis demonstrated that lack of PRL binding in these mutants was not due to incomplete processing of the protein, since the fully glycosylated Mr 42,000 form of the receptor was seen. Mutation of Cys184 had no effect on affinity or dimerization capacity of the receptor, suggesting the 5th cysteine is not directly involved in the binding domain. Carbohydrate groups of some receptors have been shown to be involved in ligand-receptor interactions as well as intracellular trafficking. This does not appear to be the case for the PRL receptor, since there was no corresponding decrease in affinity for PRL or cell surface receptor expression, following mutation of each of the 3 asparagine residues to aspartate. Interestingly, T delta 237 showed a 4-5-fold increase in affinity for PRL as well as a marked increase in the number of receptor sites. Whole cell binding assays also demonstrated that loss of the cytoplasmic domain lead to inefficient recycling of the receptor. These studies suggest that the first 4 conserved Cys residues are crucial for ligand binding.(ABSTRACT TRUNCATED AT 400 WORDS)     

A single amino acid substitution on the surface of a natural hevein isoform (Hev b 6.0202), confers different IgE recognition

Decreased immune reactivity of isoforms of major allergens has been reported. However, such claims have always been based on experiments with recombinant proteins. This work describes the molecular and physicochemical characterization of a hevein (Hev b 6.0201) natural isoform (Hev b 6.0202), which is present in rubber latex from Hevea brasiliensis. The isoallergen has a single substitution Asn14Asp, which gives rise to local differences in the surface potential, as observed from the crystal structure presented here. Besides, ELISA inhibition using serum pools of adult and pediatric patients showed reduced IgE-binding capacity ( approximately 27%) with the isoallergen. Overall, these results are relevant to delineate crucial residues involved in this dominant discontinuous epitope.     

Variants of ribonuclease inhibitor that resist oxidation

Human ribonuclease inhibitor (hRI) is a cytosolic protein that protects cells from the adventitious invasion of pancreatic-type ribonucleases. hRI has 32 cysteine residues. The oxidation of these cysteine residues to form disulfide bonds is a rapid, cooperative process that inactivates hRI. The most proximal cysteine residues in native hRI are two pairs that are adjacent in sequence: Cys94 and Cys95, and Cys328 and Cys329. A cystine formed from such adjacent cysteine residues would likely contain a perturbing cis peptide bond within its eight-membered ring, which would disrupt the structure of hRI and could facilitate further oxidation. We find that replacing Cys328 and Cys329 with alanine residues has little effect on the affinity of hRI for bovine pancreatic ribonuclease A (RNase A), but increases its resistance to oxidation by 10- to 15-fold. Similar effects are observed for the single variants, C328A hRI and C329A hRI, suggesting that oxidation resistance arises from the inability to form a Cys328-Cys329 disulfide bond. Replacing Cys94 and Cys95 with alanine residues increases oxidation resistance to a lesser extent, and decreases the affinity of hRI for RNase A. The C328A, C329A, and C328A/C329A variants are likely to be more useful than wild-type hRI for inhibiting pancreatic-type ribonucleases in vitro and in vivo. We conclude that replacing adjacent cysteine residues can confer oxidation resistance in a protein.     

Cysteine reactivity and thiol-disulfide interchange pathways in AhpF and AhpC of the bacterial alkyl hydroperoxide reductase system

AhpC and AhpF from Salmonella typhimurium undergo a series of electron transfers to catalyze the pyridine nucleotide-dependent reduction of hydroperoxide substrates. AhpC, the peroxide-reducing (peroxiredoxin) component of this alkyl hydroperoxidase system, is an important scavenger of endogenous hydrogen peroxide in bacteria and acts through a reactive, peroxidatic cysteine, Cys46, and a second cysteine, Cys165, that forms an active site disulfide bond. AhpF, a separate disulfide reductase protein, regenerates AhpC every catalytic cycle via electrons from NADH which are transferred to AhpC through a tightly bound flavin and two disulfide centers, Cys345-Cys348 and Cys129-Cys132, through putative large domain movements. In order to assess cysteine reactivity and interdomain interactions in both proteins, a comprehensive set of single and double cysteine mutants (replacing cysteine with serine) of both proteins were prepared. Based on 5,5-dithiobis(2-nitrobenzoic acid) (DTNB) and AhpC reactivity with multiple mutants of AhpF, the thiolate of Cys129 in the N-terminal domain of AhpF initiates attack on Cys165 of the intersubunit disulfide bond within AhpC for electron transfer between proteins. Cys348 of AhpF has also been identified as the nucleophile attacking the Cys129 sulfur of the N-terminal disulfide bond to initiate electron transfer between these two redox centers. These findings support the modular architecture of AhpF and its need for domain rotations for function, and emphasize the importance of Cys165 in the reductive reactivation of AhpC. In addition, two new constructs have been generated, an AhpF-AhpC complex and a "twisted" form of AhpF, in which redox centers are locked together by stable disulfide bonds which mimic catalytic intermediates.