New structural insights from Raman spectroscopy of proteins and their assemblies

Protein structure and stability are sensitive to and dependent on the local interactions of amino acid side chains. A diverse and important type of side-chain interaction is the hydrogen bond. Although numerous hydrogen bonds are resolved in protein 3-dimensional structures, those of the cysteine sulfhydryl group (S-H) are elusive to high-resolution X-ray and NMR methods. However, the nature and strength of sulfhydryl hydrogen bonds (S-H* * *X) are amenable to investigation by Raman spectroscopy. The power of the Raman method for characterizing S-H* * *X interactions is illustrated by resolving the Raman S-H stretching band for each of the eight cysteines per 666-residue subunit in the trimeric tailspike of icosahedral bacteriophage P22. The Raman sulfhydryl signatures of the wild-type tailspike and eight single-site cysteine to serine mutants reveal a heretofore unrecognized diversity of S-H hydrogen bonds in a native protein. The use of Raman spectroscopy to identify the non-hydrogen-bonded state of the tyrosine phenoxyl group is also described. This unusual and unexpected state occurs for all tyrosines in the assembled capsids of filamentous viruses Ff and Pf1. The Raman spectral signature of the non-hydrogen-bonded tyrosine phenoxyl, which is characterized by an extraordinary Raman Fermi doublet intensity ratio (I850/I830 = 6.7), extends and refines the existing correlation for hydrogen-bonded tyrosines. Finally, a novel Raman signature for tryptophan in the Pf3 filamentous virus is identified, which is proposed as diagnostic of "cation-pi interaction" involving the guanidinium group of Arg 37 as a cation donor and the indolyl ring of Trp 38 as a pi-electron acceptor. These studies demonstrate the power of Raman spectroscopy for investigating the interactions of key side chains in native protein assemblies.     

Structural roles of subunit cysteines in the folding and assembly of the DNA packaging machine (portal) of bacteriophage P22

The DNA packaging machine (portal assembly) of bacteriophage P22 is constructed from 12 copies of a multidomain 725-residue subunit comprising a complex alpha/beta fold. The portal subunit contains four cysteines (Cys 153, Cys 173, Cys 283, and Cys 516), which produce distinctive Raman markers in the spectral interval 2500-2600 cm(-1) originating from S-H bond-stretching vibrations diagnostic of S-H...X hydrogen-bonding interactions. The Raman spectrum is unique in the capability to characterize cysteine sulfhydryl interactions in proteins and shows that portal cysteine environments are significantly altered by assembly (Rodriguez-Casado et al. (2001) Biochemistry 40, 13583-13591). We have employed site-directed mutagenesis, size-exclusion chromatography, and Raman difference spectroscopy to characterize the roles of portal cysteines in subunit folding and dodecamer assembly. The stability of the portal monomer is severely reduced by a Cys --> Ser point mutation introduced at either residue 173 or 516. In the case of C516S, the destabilized monomer still forms portal rings, as visualized by negative-stain electron microscopy, whereas portal ring formation cannot be detected for C173S, which forms aberrant aggregates. The C283S mutant is a hyperstable monomer that is defective in portal ring formation. Interestingly, Cys 283 is suggested by secondary structure homology with the phi29 portal to be within a domain involved in DNA translocation. Conversely, the phenotype of the C153S mutant is close to that of the wild-type protein, implying that the sulfhydryl moiety of Cys 153 is not essential to formation of the native subunit fold and productive assembly dynamics. The present results demonstrate that cysteines of the P22 portal protein span a wide range of sulfhydryl hydrogen-bonding strengths in the wild-type assembly, that three of the four sulfhydryls play key roles in portal protein stability and assembly kinetics, and that substitution of a mutant seryl interaction (O-H...X) for a wild-type cysteinyl interaction (S-H...X) can either stabilize or destabilize the native fold depending upon sequence context.     

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.     

Structure of bacteriophage P22 portal protein in relation to assembly: investigation by Raman spectroscopy.

Salmonella phage P22, which serves as an assembly paradigm for icosahedral double-stranded DNA viruses, packages its viral genome through a capsid channel (portal) comprising 12 copies of a 725-residue subunit. Secondary and tertiary structures of the portal subunit in monomeric and dodecameric states have been investigated by Raman spectroscopy using a His6-tagged recombinant protein that self-assembles in vitro [Moore, S. D., and Prevelige, P. E., Jr. (2001) J. Biol. Chem. 276, 6779-6788]. The portal protein exhibits Raman secondary structure markers typical of a highly alpha-helical subunit fold that is little perturbed by assembly. On the other hand, Raman markers of subunit side chains change dramatically with assembly, an indication of extensive changes in side chain environments. The cysteinyl Raman signature of the portal consists of a complex pattern of sulfhydryl stretching bands, revealing diverse hydrogen-bonding states for the four S-H groups per subunit (Cys 153, Cys 173, Cys 283, and Cys 516). Upon assembly, the population of strongly hydrogen-bonded S-H groups decreases, while the population of weakly hydrogen-bonded S-H groups increases, implying that specific intrasubunit S-H.X hydrogen bonds must be weakened to effect dodecamer assembly and that the molecular mechanism involves reorganization of subunit domains without appreciable changes in domain conformations. Comparison with other viral protein assemblies suggests an assembly process not requiring metastable intermediates. The recently published X-ray structure of the phi29 portal [Simpson, A. A., et al. (2000) Nature 408, 745-750] shows that residues 125-225 lining the channel surface form alpha-helical modules spaced by short beta-strands and turns; a surprisingly close secondary structure homology is predicted for residues 240-350 of the P22 portal, despite no apparent sequence homology. This motif is proposed as an evolutionarily conserved domain involved in DNA translocation.     

The structure of hepadnaviral core antigens. Identification of free thiols and determination of the disulfide bonding pattern.

A set of wild-type and mutant human, woodchuck, and duck hepatitis viral core proteins have been prepared and used to study the free thiol groups and the disulfide bonding pattern present within the core particle. Human (HBcAg) and woodchuck (WHcAg) core proteins contain 4 cysteine residues, whereas duck (DHcAg) core protein contains a single cysteine residue. Each of the cysteines of HBcAg has been eliminated, either singly or in combinations, by a two-step mutagenesis procedure. All of the proteins were shown to have very similar physical and immunochemical properties. All assemble into essentially identical core particle structures. Therefore disulfide bonds are not essential for core particle formation. No intra-chain disulfide bonds occur. Cys107 is a free thiol buried within the particle structure, whereas Cys48 is present partly as a free sulfhydryl which is exposed at the surface of the particle. Cys61 is always and Cys48 is partly involved in interchain disulfide bonds with the identical residues of another monomer, whereas Cys183 is always involved in a disulfide bond with the Cys183 of a different monomer. WHcAg has the same pattern of bonding, whereas DHcAg lacks any disulfide bonds, and the single free sulfhydryl, Cys153 which is equivalent to Cys107 of HBcAg, is buried.     

Role for cysteine residues in the in vivo folding and assembly of the phage P22 tailspike

The predominantly beta-sheet phage P22 tailspike adhesin contains eight reduced cysteines per 666 residue chain, which are buried and unreactive in the native trimer. In the pathway to the native trimer, both in vivo and in vitro transient interchain disulfide bonds are formed and reduced. This occurs in the protrimer, an intermediate in the formation of the interdigitated beta-sheets of the trimeric tailspike. Each of the eight cysteines was replaced with serine by site-specific mutagenesis of the cloned P22 tailspike gene and the mutant genes expressed in Escherichia coli. Although the yields of native-like Cys>Ser proteins varied, sufficient soluble trimeric forms of each of the eight mutants accumulated to permit purification. All eight single Cys>Ser mature proteins maintained the high thermostability of the wild type, as well as the wild-type biological activity in forming infectious virions. Thus, these cysteine thiols are not required for the stability or activity of the native state. When their in vivo folding and assembly kinetics were examined, six of the mutant substitutions--C267S, C287S, C458S, C613S, and C635S--were significantly impaired at higher temperatures. Four--C290S, C496, C613S, and C635--showed significantly impaired kinetics even at lower temperatures. The in vivo folding of the C613S/C635S double mutant was severely defective independent of temperature. Since the trimeric states of the single Cys>Ser substituted chains were as stable and active as wild type, the impairment of tailspike maturation presumably reflects problems in the in vivo folding or assembly pathways. The formation or reduction of the transient interchain disulfide bonds in the protrimer may be the locus of these kinetic functions.     

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.     

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.     

Conformational stability of P22 tailspike proteins carrying temperature-sensitive folding mutations

The thermostable tailspike endorhamnosidase of Salmonella phage P22 provides a model system for comparing the role of amino acid sequences in determining the intracellular folding pathway with their role in stabilizing the mature structural protein. Complete Raman band assignments are given here for the native form of the tailspike trimer in aqueous solution. Once correctly folded and assembled, the wild-type and two well-characterized mutant proteins, tsfIle258----Leu and tsfGly323----Asp, exhibit the same secondary structure in solution, consisting predominantly of beta-strand (56 +/- 5%) and turns (17 +/- 2%). Raman bands that are sensitive indicators of hydrogen-bonding interactions of tyrosine (phenolic OH) and tryptophan (indole NH) are unchanged between 30 and 80 degrees C in both wild type and tsf mutants. Similarly, Raman bands that are sensitive to changes in the hydrophobic environment of nonpolar side chains exhibit no significant temperature dependence in wild type and tsf mutants. In contrast, these conformational features are greatly altered by chemical denaturation of the tailspike with lithium halide and guanidine hydrochloride. In the chemically denatured tailspike, the beta-strand structure is substantially converted to irregular or "random coil" conformation. These findings confirm conclusions from physiological studies that the three-dimensional structures of the tsf mutants, once stabilized at permissive temperatures, are equivalent to the native structure of the wild type, and this structure is maintained at temperatures far above those that block the folding of the chain into the final native conformation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cysteine conformation and sulfhydryl interactions in proteins and viruses. 3. Quantitative measurement of the Raman S-H band intensity and frequency.

The bond stretching vibration of the cysteine sulfhydryl (SH) group in a typical protein generates a Raman band in the spectral interval 2500-2600 cm-1, a region devoid of interference from any other fundamental mode of vibration of the protein. The relatively high Raman cross section associated with the S-H stretching vibration, the sensitivity of the vibrational frequency to hydrogen bonding interactions and side chain configurations, and the dependence of the Raman intensity on thiol-thiolate equilibria, combine to make the Raman SH band a potentially valuable marker of protein sulfhydryl interactions and a unique indicator of sulfhydryl participation in thiol-disulfide oxidoreductase activity. In order to exploit Raman spectroscopy for these purposes, accurate and precise measurements of Raman SH band profiles are required. We show here that the required precision and accuracy can be achieved by use of the Raman band corresponding to the stretching vibration of in situ nitrogen gas as a quantitative intensity and frequency standard. The Raman Q-branch center of the N2 band occurs at 2330.7 cm-1.     

Profile of the disulfide bonds in acetylcholinesterase

The inter- and intrasubunit disulfide bridges for the 11 S form of acetylcholinesterase isolated from Torpedo californica have been identified. Localized within the basal lamina of the synapse, the dimensionally asymmetric forms of acetylcholinesterase contain either two (13 S) or three (17 S) sets of catalytic subunits linked to collagenous and noncollagenous structural subunits. Limited proteolysis of these molecules yields a tetramer of catalytic subunits that sediments at 11 S. Each catalytic subunit contains 8 cysteine residues which were identified following tryptic digestion of the reduced, 14C-carboxymethylated protein. The tryptic peptides were purified by gel filtration followed by reverse-phase high performance liquid chromatography (HPLC) and then sequenced. The disulfide bonding profile was determined by treating the native, nonreduced 11 S form of acetylcholinesterase with a fluorescent, sulfhydryl-specific reagent, monobromobimane, prior to tryptic digestion. Peptides again were resolved by gel filtration and reverse-phase HPLC. One fluorescent cysteine-containing peptide was identified, indicating that a single sulfhydryl residue, Cys231, was present in its reduced form. Three pairs of disulfide-bonded peptides were identified. These were localized in the polypeptide chain based on the cDNA-deduced sequence of the protein and were identified as Cys67-Cys94, Cys254-Cys265, and Cys402-Cys521. Hence, three loops are found in the secondary structure. Cys572, located in the carboxyl-terminal tryptic peptide, was disulfide-bonded to an identical peptide and most likely forms an intersubunit cross-link. Since the 6 cysteine residues in acetylcholinesterase that are involved in intrachain disulfide bonds are conserved in the sequence of the homologous protein thyroglobulin, it is likely that both proteins share a common folding pattern in their respective tertiary structures. Cys231 and the carboxyl-terminal cysteine residue Cys572 are not conserved in thyroglobulin.     

Dissociation of intermolecular disulfide bonds in P22 tailspike protein intermediates in the presence of SDS

Each chain of the native trimeric P22 tailspike protein has eight cysteines that are reduced and buried in its hydrophobic core. However, disulfide bonds have been observed in the folding pathway and they are believed to play a critical role in the registration of the three chains. Interestingly, in the presence of sodium dodecyl sulfate (SDS) only monomeric chains, rather than disulfide-linked oligomers, have been observed from a mixture of folding intermediates. Here we show that when the oligomeric folding intermediates were separated from the monomer by native gel electrophoresis, the reduction of intermolecular disulfide bonds did not occur in the subsequent second-dimension SDS-gel electrophoresis. This result suggests that when tailspike monomer is present in free solution with SDS, the partially unfolded tailspike monomer can facilitate the reduction of disulfide bonds in the tailspike oligomers.     

Conformation, stability, and active-site cysteine titrations of Escherichia coli D26A thioredoxin probed by Raman spectroscopy.

The active-site cysteines (Cys 32 and Cys 35) of Escherichia coli thioredoxin are oxidized to a disulfide bridge when the protein mediates substrate reduction. In reduced thioredoxin, Cys 32 and Cys 35 are characterized by abnormally low pKa values. A conserved side chain, Asp 26, which is sterically accessible to the active site, is also essential to oxidoreductase activity. pKa values governing cysteine thiol-thiolate equilibria in the mutant thioredoxin, D26A, have been determined by direct Raman spectrophotometric measurement of sulfhydryl ionizations. The results indicate that, in D26A thioredoxin, both sulfhydryls titrate with apparent pKa values of 7.5+/-0.2, close to values measured previously for wild-type thioredoxin. Sulfhydryl Raman markers of D26A and wild-type thioredoxin also exhibit similar band shapes, consistent with minimal differences in respective cysteine side-chain conformations and sulfhydryl interactions. The results imply that neither the Cys 32 nor Cys 35 SH donor is hydrogen bonded directly to Asp 26 in the wild-type protein. Additionally, the thioredoxin main-chain conformation is largely conserved with D26A mutation. Conversely, the mutation perturbs Raman bands diagnostic of tryptophan (Trp 28 and Trp 31) orientations and leads to differences in their pH dependencies, implying local conformational differences near the active site. We conclude that, although the carboxyl side chain of Asp 26 neither interacts directly with active-site cysteines nor is responsible for their abnormally low pKa values, the aspartate side chain may play a role in determining the conformation of the enzyme active site.     

Structure of the Transmembrane Cysteine Residues in Phospholamban

Phospholamban, a 52-residue membrane protein, associates to form a pentameric complex of five long α-helices traversing the sarcoplasmic reticulum membrane of cardiac muscle cells. The transmembrane domain of the protein is largely hydrophobic, with only three cysteine residues having polar side chains, yet it functions as a Ca²⁺-selective ion channel. In this report, infrared spectroscopy is used to probe the conformation of the three cysteine side chains and to establish whether the free S-H groups form intrahelical hydrogen bonds in the pentameric complex. Vibrational spectra of a transmembrane peptide were obtained which corresponded to the transmembrane domain of wild-type phospholamban and three peptides each containing a cysteine ⇒ alanine substitution. The observed S-H frequencies argue that each of the sulfhydryl groups is hydrogen-bonded to an i-4 backbone carbonyl oxygen. Electrostatic calculations on a model of phospholamban based on molecular dynamics and mutagenesis studies, show that the sulfhydryl groups may significantly contribute to the electrostatic potential field of the protein. Received: 22 July 1996/Revised: 10 October 1996     

Structural determinants of substrate access to the disulfide oxidase Erv2p

Erv2p is a small, dimeric FAD-dependent sulfhydryl oxidase that generates disulfide bonds in the lumen of the endoplasmic reticulum. Mutagenic and structural studies suggest that Erv2p uses an internal thiol-transfer relay between the FAD-proximal active site cysteine pair (Cys121-Cys124) and a second cysteine pair (Cys176-Cys178) located in a flexible, substrate-accessible C-terminal tail of the adjacent dimer subunit. Here, we demonstrate that Cys176 and Cys178 are the only amino acids in the tail region required for disulfide transfer and that their relative positioning within the tail peptide is important for activity. However, intragenic suppressor mutations could be isolated that bypass the requirement for Cys176 and Cys178. These mutants were found to disrupt Erv2p dimerization and to increase the activity of Erv2p for thiol substrates such as glutathione. We propose that the two Erv2p subunits act together to direct the disulfide transfer to specific substrates. One subunit provides the catalytic domain composed of the active site cysteine residues and the FAD cofactor, while the second subunit appears to have two functions: it facilitates disulfide transfer to substrates via the tail cysteine residues, while simultaneously shielding the active site cysteine residues from non-specific reactions.     

Ligand-linked changes at the subunit interfaces in Scapharca hemoglobins probed through the sulfhydryl infrared absorption.

FTIR spectra of native Scapharca homodimeric hemoglobin (HbI) and of the Phe97-->Ile mutant have been measured in the region 2400-2700 cm(-1) where the absorption of the sulfhydryl groups can be observed. In native HbI, the two Cys92 residues give rise to a relatively intense band centered at 2559 cm(-1) that is shifted to 2568 cm(-1) and strongly quenched upon ligand binding. In the Phe97-->Leu mutant, such ligand-linked changes are not observed and the strong peak at around 2560 cm(-1) persists in the liganded derivatives. In native HbI, the observed changes have been attributed to the decrease in polarity of the interface due to the ligand-induced extrusion of the Phe97 phenyl ring from the heme pocket to the interface and the subsequent release of several water molecules that are clustered in the vicinity of Cys92. In contrast, in the Phe97-->Leu mutant, the Leu residue does not leave the heme pocket upon ligand binding and the interface is unaltered. The Cys92/S-H infrared band, therefore, represents a sensitive probe of the structural rearrangements that take place in the intersubunit interface upon ligand binding to HbI. The heterotetrameric Scapharca hemoglobin HbII contains, in addition to the Cys92 residues in the interfaces, two extra sulfhydryl groups per tetramer (Cys9 in the B chain) that are exposed to solvent in the A helix. The frequency of the Cys9/S-H stretching vibration occurs at 2582 cm(-1) in the unliganded and at 2586 cm(-1) in the liganded derivative, pointing to the involvement of the A helix in the ligand-linked polymerization characteristic of HbII.     

Analysis of the disulfide bonding pattern between domain sequences of recombinant prochymosin solubilized from inclusion bodies

Prochymosin contains three disulfide bonds linking Cys45 to Cys50, Cys206 to Cys210, and Cys250 to Cys283. To analyze the disulfide bonding pattern between domain sequences in the recombinant prochymosin molecule solubilized from inclusion bodies by 8 M urea (designated as solubilized prochymosin), a simple peptide mapping method was established. This process consists of thiol alkylation, cleavage with cyanogen bromide, diagonal electrophoresis on polyacrylamide gel, and N-terminal sequencing. By using this procedure it was found that Cys45 and Cys50 located in the N-terminal domain are not mispaired with the cysteine residues, located in the C-terminal domain, in the solubilized wild-type prochymosin and its mutants. This result implies that Cys45 and Cys50, the partners of a native disulfide, are restricted in some ordered structures existing in inclusion bodies and remaining after solubilization. These native structural elements act as folding nuclei to initiate and facilitate correct refolding. The strategy of preserving the native-like structures including native disulfide in the solubilized inclusion bodies to enhance renaturation efficiency may be applicable to other recombinant proteins.Both authors contributed equally to this work     

Beta subunit of (Na+ + K+)-ATPase contains three disulfide bonds

Previous studies of titratable (Na+ + K+)-ATPase sulfhydryl groups have indicated the presence of one disulfide bond per mole of holoenzyme. This single disulfide cross-link was assigned to the beta subunit on the basis of the difference between the number of titrated "free" sulfhydryl groups and the total number of titrated sulfhydryl groups for each subunit [Esmann, M. (1982) Biochim. Biophys. Acta 688, 251; Kawamura, M., & Nagano, K. (1984) Biochim. Biophys. Acta 694, 27]. In the present study, beta-subunit tryptic peptides containing disulfide cross-links were identified and purified by HPLC. Two new peptides were generated from each disulfide-bonded peptide by reduction with dithiothreitol, and the amino acid compositions of these reduced peptides were determined. The data demonstrate that there are three disulfide bonds in the native beta subunit: 125Cys-148Cys, 158Cys-174Cys, and 212Cys-275Cys. The number of disulfide bonds in the beta subunit was also estimated by titration of sulfhydryl groups with [14C]iodoacetamide. Six sulfhydryl groups were identified: two sulfhydryl groups were titrated without prior reduction, and four were identified only after reduction of the protein with dithiothreitol. These data, suggesting that the beta subunit contains two disulfide bonds, are inconsistent with the peptide isolation experiments, which directly identified three disulfide bonds in the beta subunit. This inconsistency was resolved by demonstrating that approximately 20% of each disulfide bond in the beta subunit was reduced prior to the start of the experiment, resulting in an underestimation of the number of disulfide-bonded sulfhydryl groups in the beta subunit from the titration experiments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Breaking and re-forming the disulfide bond at the high-potential,respiratory-type Rieske [2Fe-2S] center of thermus thermophilus: characterization of the sulfhydryl state by protein-film voltammetry

A disulfide bond, adjacent to the [2Fe-2S] cluster, is conserved in all high-potential Rieske proteins from the respiratory and photosynthetic cytochrome bc(1) and b(6)f complexes but is absent from the low-potential, bacterial dioxygenase Rieske proteins. The role of the disulfide is unclear, since cysteine mutants have resulted in only apoprotein. The high stability of the soluble Thermus thermophilus Rieske protein permits chemical reduction of the disulfide bond and characterization of the sulfhydryl (dithiol) form by protein-film voltammetry. The effect of disulfide reduction on the cluster potential is small (DeltaE(0)' 相似文献   

Sulfhydryl group content of chicken progesterone receptor: effect of oxidation on DNA binding activity

DNA binding activity of chicken progesterone receptor B form (PRB) and A form (PRA) has been examined. This activity is strongly dependent upon the presence of thiols in the buffer. Stability studies showed that PRB was more sensitive to oxidation than was PRA. Receptor preparations were fractionated by DNA-cellulose chromatography to DNA-positive and DNA-negative subpopulations, and sulfhydryl groups were quantified on immunopurified receptor by labeling with [3H]-N-ethylmaleimide. Labeling of DNA-negative receptors with [3H]-N-ethylmaleimide showed 21-23 sulfhydryl groups on either PRA or PRB form when the proteins were reduced and denatured. A similar number was seen without reduction if denatured DNA-positive receptor species were tested. In contrast, the DNA-negative PRB had only 10-12 sulfhydryl groups detectable without reduction. A similar number (12-13 sulfhydryl groups) was found for PRA species that lost DNA binding activity after exposure to a nonreducing environment in vitro. We concluded that the naturally occurring receptor forms unable to bind to DNA, as well as receptor forms that have lost DNA binding activity due to exposure to a nonreducing environment in vitro, contain 10-12 oxidized cysteine residues, likely present as disulfide bonds. Since we were unable to reduce the disulfide bonds when the native DNA-negative receptor proteins were treated with dithiothreitol (DTT), we speculate that irreversible loss of DNA binding activity of receptor in vitro is due to oxidation of cysteine residues that are not accessible to DTT in the native state.