Interchain disulfide bonds promote protein cross-linking during protein folding

We provide evidence that in vitro protein cross-linking can be accomplished in three concerted steps: (i) a change in protein conformation; (ii) formation of interchain disulfide bonds; and (iii) formation of interchain isopeptide cross-links. Oxidative refolding and thermal unfolding of ribonuclease A, lysozyme, and protein disulfide isomerase led to the formation of cross-linked dimers/oligomers as revealed by SDS-polyacrylamide gel electrophoresis. Chemical modification of free amino groups in these proteins or unfolding at pH < 7.0 resulted in a loss of interchain isopeptide cross-linking without affecting interchain disulfide bond cross-linking. Furthermore, preformed interchain disulfide bonds were pivotal for promoting subsequent interchain isopeptide cross-links; no dimers/oligomers were detected when the refolding and unfolding solution contained the reducing agent dithiothreitol. Similarly, the Cys326Ser point mutation in protein disulfide isomerase abrogated its ability to cross-link into homodimers. Heterogeneous proteins become cross-linked following the formation of heteromolecular interchain disulfide bonds during thermal unfolding of a mixture of of ribonuclease A and lysozyme. The absence of glutathione and glutathione disulfide during the unfolding process attenuated both the interchain disulfide bond cross-links and interchain isopeptide cross-links. No dimers/oligomers were detected when the thermal unfolding temperature was lower than the midpoint of thermal denaturation temperature.     

Use of a disulfide cross-linking strategy to study muscarinic receptor structure and mechanisms of activation.

To gain insight into the molecular architecture of the cytoplasmic surface of G protein-coupled receptors, we have developed a disulfide cross-linking strategy using the m3 muscarinic receptor as a model system. To facilitate the interpretation of disulfide cross-linking data, we initially generated a mutant m3 muscarinic receptor (referred to as m3'(3C)-Xa) in which most native Cys residues had been deleted or substituted with Ala or Ser (remaining Cys residues Cys-140, Cys-220, and Cys-532) and in which the central portion of the third intracellular loop had been replaced with a factor Xa cleavage site. Radioligand binding and second messenger assays showed that the m3'(3C)-Xa mutant receptor was fully functional. In the next step, pairs of Cys residues were reintroduced into the m3'(3C)-Xa construct, thus generating 10 double Cys mutant receptors. All 10 mutant receptors contained a Cys residue at position 169 at the beginning of the second intracellular loop and a second Cys within the C-terminal portion of the third intracellular loop, at positions 484-493. Radioligand binding studies and phosphatidylinositol assays indicated that all double Cys mutant receptors were properly folded. Membrane lysates prepared from COS-7 cells transfected with the different mutant receptor constructs were incubated with factor Xa protease and the oxidizing agent Cu(II)-(1,10-phenanthroline)3, and the formation of intramolecular disulfide bonds between juxtaposed Cys residues was monitored by using a combined immunoprecipitation/immunoblotting strategy. To our surprise, efficient disulfide cross-linking was observed with 8 of the 10 double Cys mutant receptors studied (Cys-169/Cys-484 to Cys-491), suggesting that the intracellular m3 receptor surface is characterized by pronounced backbone fluctuations. Moreover, [35S]guanosine 5'-3-O-(thio)triphosphate binding assays indicated that the formation of intramolecular disulfide cross-links prevented or strongly inhibited receptor-mediated G protein activation, suggesting that the highly dynamic character of the cytoplasmic receptor surface is a prerequisite for efficient receptor-G protein interactions. This is the first study using a disulfide mapping strategy to examine the three-dimensional structure of a hormone-activated G protein-coupled receptor.     

Subunit interaction sites between the regulatory and catalytic subunits of cAMP-dependent protein kinase. Identification of a specific interchain disulfide bond

The catalytic (C) subunit and the type II regulatory (RII) subunit of cAMP-dependent protein kinase can be cross-linked by interchain disulfide bonding. This disulfide bond can be catalyzed by cupric phenanthroline and also can be generated by a disulfide interchange using either RII-subunit or C-subunit that has been modified with either 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or N-4(azidophenylthio)phthalimide (APTP). When the 2 cysteine residues of the C-subunit are reacted with DTNB prior to incubation with the RII-subunit, interchain disulfide bonding occurs. Similar observations are seen with C-subunit that had been modified with APTP. Interchain disulfide bonds also form when the RII-subunit is modified with DTNB prior to incubation with the C-subunit. The presence of cAMP facilitates this cross-linking while autophosphorylation of the RII-subunit retards the rate at which the interchain disulfide bond forms. Interchain disulfide bonds also form spontaneously when the RII-subunit and the C-subunit are dialyzed at pH 8.0 in the absence of reducing agents. The specific amino acid residues that participate in intersubunit disulfide bonding have been identified as Cys-97 in the RII-subunit and Cys-199 in the C-subunit. Based on the sequence homologies of the RII-subunit with other kinase substrates and on the proximity of Cys-97 to the catalytic site, a model is proposed in which the autophosphorylation site of the RII-subunit occupies the substrate-binding site in the holoenzyme. The model also proposes that this same site may be occupied by the region flanking Cys-199 in the C-subunit when the C-subunit is dissociated.     

大肠杆菌L-酒石酸脱氢酶b亚基体外分子交联

通过PCR技术扩增大肠杆菌L-酒石酸脱氢酶b亚基(L-tartrate dehydratase beta subunit, TtdB)野生型与Cys/Ser突变型目的基因, 构建带6×His标签的诱导型表达载体pTrcHisC-TtdB。重组蛋白以包含体形式存在, 应用TALON固定化金属亲和树脂(Immobilized metal affinity chromatography, IMAC)以变性的方法纯化, 通过分步透析逐步去除变性剂的方法复性, 复性率可达70%。将复性后的两种蛋白通过热诱导去折叠和氧化重折叠方法进行体外蛋白质分子交联实验。SDS-PAGE分析表明: 野生型TtdB在其变性的临界温度反应时, 出现交联二聚体和多聚体; 在氧化重折叠后SDS-PAGE前加入100 mmol/L DTT时, 交联强度明显减弱。这种DTT打不开的交联即为异肽键交联; 若在其氧化重折叠反应液中加入DTT则没有任何交联。突变型TtdB在与野生型TtdB相同的热诱导去折叠条件下, 完全没有二聚体和多聚体的形成。     

Primary structure of human alpha 2-macroglobulin. V. The complete structure

The primary structure of the tetrameric plasma glycoprotein human alpha 2-macroglobulin has been determined. The identical subunits contain 1451 amino acid residues. Glucosamine-based oligosaccharide groups are attached to asparagine residues 32, 47, 224, 373, 387, 846, 968, and 1401. Eleven intrachain disulfide bridges have been placed (Cys25-Cys63, Cys228-Cys276, Cys246-Cys264, Cys255-Cys408, Cys572-Cys748, Cys619-Cys666, Cys798-Cys826, Cys824-Cys860, Cys898-Cys1298, Cys1056-Cys1104, and Cys1329-Cys1444). Cys-447 probably forms an interchain bridge with Cys-447 from another subunit. The beta-SH group of Cys-949 is thiol esterified to the gamma-carbonyl group of Glx-952, thus forming an activatable reactive site which can mediate covalent binding of nucleophiles. A putative transglutaminase cross-linking site is constituted by Gln-670 and Gln-671. The primary sites of proteolytic cleavage in the activation cleavage area (the "bait" region) are located in the sequence: -Arg681-Val-Gly-Phe-Tyr-Glu-. The molecular weight of the unmodified alpha 2-macroglobulin subunit is 160,837 and approximately 179,000, including the carbohydrate groups. The presence of possible internal homologies within the alpha 2-macroglobulin subunit is discussed. A comparison of stretches of sequences from alpha 2-macroglobulin with partial sequence data for complement components C3 and C4 indicates that these proteins are evolutionary related. The properties of alpha 2-macroglobulin are discussed within the context of proteolytically regulated systems with particular reference to the complement components C3 and C4.     

State-dependent disulfide cross-linking in rhodopsin.

In previous studies, we developed a new method for detecting tertiary interactions in rhodopsin using split receptors and disulfide cross-linking. Cysteines are engineered into separate fragments of the split opsin, the disulfide bond can be formed between the juxtaposed residues by treatment with Cu(phen)3(2+), and then disulfide cross-links can be detected on the gel by an electrophoretic mobility shift. In this study, we utilized this method to examine the cross-linking reactions between native cysteines in the ground state and after photoexcitation of rhodopsin. In the dark, Cys140 on transmembrane segment (TM) 3 cross-links to Cys222 on TM5. After photobleaching, Cys140 cross-links to Cys316 and Cys222, and the rate of the cross-linking reaction between Cys140 and Cys222 significantly increases.     

Formation of a polymethylene bis(disulfide) intersubunit cross-link between cysteine-281 residues in rabbit muscle glyceraldehyde-3-phosphate dehydrogenase using octamethylene bis(methane[35S]thiosulfonate)

The synthesis of a radioactive cross-linking agent, S,S'-octamethylene bis(methane[35S]thiosulfonate) (OBMTS), is described. The route of synthesis can be generally used in the synthesis of 35S-labeled thiosulfonates for the selective modification of thiols in proteins. Glyceraldehyde-3-phosphate dehydrogenase (G3PD) reacts asymmetrically with the bifunctional inhibitor. Initially two molecules of OBMTS react rapidly with the active-site thiol, Cys-149, on two of the four subunits to inhibit the enzyme completely without cross-linking. This is followed by the modification of four Cys-281 residues to incorporate two cross-links into the tetramer. Reduction of modified G3PD with 5 mM dithioerythritol under nondenaturing conditions released the inhibitor blocking the active-site thiol and completely restored enzyme activity while leaving the cross-link intact. Sodium dodecyl sulfate (Na-DodSO4) gel electrophoresis of the cross-linked enzyme under nonreducing conditions showed a dimer (Mr 72000) as the major species which was only cleaved by reduction in Na-DodSO4 containing beta-mercaptoethanol. The monomer formed was still radioactive, showing that the first disulfide in the cross-link was reduced at a much faster rate than the second disulfide. The latter was only reduced by using vigorous conditions. The location of the intersubunit cross-linked residues was established by isolation of the cyanogen bromide and tryptic subdigest peptides containing modified Cys-281. There were identified by molecular weight, amino terminal sequence, and amino acid composition.     

An engineered disulfide bond in dihydrofolate reductase

Substitution of cysteine for proline-39 in Escherichia coli dihydrofolate reductase by oligonucleotide-directed mutagenesis positions the new cysteine adjacent to already existing cysteine-85. When the mutant protein is expressed in the E. coli cytosol, the cysteine sulfur atoms are found, by X-ray crystallographic analysis, to be in van der Waals contact but not covalently bonded to one another. In vitro oxidation by dithionitrobenzoate results in formation of a disulfide bond between residues 39 and 85 with a geometry close to that of the commonly observed left-handed spiral. Comparison of 2.0-A-refined crystal structures of the oxidized (cross-linked) and reduced (un-cross-linked) forms of the mutant enzyme shows that the conformation of the enzyme molecule was not appreciably affected by formation of the disulfide bond but that details of the molecule's thermal motion were altered. The disulfide-cross-linked enzyme is at least 1.8 kcal/mol more stable with respect to unfolding, as measured by guanidine hydrochloride denaturation, than either the wild-type or the reduced (un-cross-linked) mutant enzyme. Nevertheless, the cross-linked form is not more resistant to thermal denaturation. Moreover, the appearance of intermediates in the guanidine hydrochloride denaturation profile and urea-gradient polyacrylamide gels indicates that the folding/unfolding pathway of the disulfide-cross-linked enzyme has changed significantly.     

Disulfide structure of the leucine-rich repeat C-terminal cap and C-terminal stalk region of Nogo-66 receptor

Nogo-66 receptor (NgR1) is a leucine-rich repeat (LRR) protein that forms part of a signaling complex modulating axon regeneration. Previous studies have shown that the entire LRR region of NgR1, including the C-terminal cap of the LRR, LRRCT, is needed for ligand binding, and that the adjacent C-terminal region (CT stalk) of the NgR1 contributes to interaction with its coreceptors. To provide structure-based information for these interactions, we analyzed the disulfide structure of full-length NgR1. Our analysis revealed a novel disulfide structure in the C-terminal region of the NgR1, wherein the two Cys residues, Cys-335 and Cys-336, in the CT stalk are disulfide-linked to Cys-266 and Cys-309 in the LRRCT region: Cys-266 is linked to Cys-335, and Cys-309 to Cys-336. The other two Cys residues, Cys-264 and Cys-287, in the LRRCT region are disulfide-linked to each other. The analysis also showed that Cys-419 and Cys-429, in the CT stalk region, are linked to each other by a disulfide bond. Although published crystal structures of a recombinant fragment of NgR1 had revealed a disulfide linkage between Cys-266 and Cys-309 in the LRRCT region and we verified its presence in the corresponding fragment, this is artificially caused by the truncation of the protein, since this linkage was not detected in intact NgR1 or a slightly larger fragment containing Cys-335 and Cys-336. A structural model of the LRRCT with extended residues 311-344 from the CT stalk region is proposed, and its function in coreceptor binding is discussed.     

Glutamic acid-88 is close to SH-1 in the tertiary structure of myosin subfragment 1

The thiol-specific photoactivatable reagent benzophenone iodoacetamide (BPIA) can be selectively incorporated into the most reactive thiol, SH-1, of myosin S1, and upon photolysis, an intramolecular cross-link is formed between SH-1 and the N-terminal 25-kDa region of S1. If a Mg2+-nucleotide is present during photolysis, cross-links can be formed either with the 25-kDa region or with the central 50-kDa region [Lu et al. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 6392]. Comparison of the peptide maps of cross-linked and un-cross-linked S1 heavy chains indicates that the segment located about 12-16 kDa from the N-terminus of the heavy chain can be cross-linked to SH-1 via BPIA independently of the presence of a nucleotide whereas the segment located 57-60 kDa from the N-terminus can be cross-linked to SH-1 only in the presence of a Mg2+-nucleotide [Sutoh & Lu (1987) Biochemistry 26, 4511]. In this report, S1 was labeled with radioactive BPIA, photolyzed in the absence of nucleotide, and then degraded with proteolytic enzymes. Peptides containing cross-links were isolated by liquid chromatography and subjected to amino acid sequence analyses. The results show that Glu-88 is the major site and Asp-89 and Met-92 are the minor sites involved in cross-linking with SH-1 (Cys-707) via BPIA. These residues are very near the reactive lysine residue (Lys-83) but relatively remote in the primary structure from the putative nucleotide binding region.     

Acetylcholine receptor binding site contains a disulfide cross-link between adjacent half-cystinyl residues

A conserved feature of all nicotinic receptors is the presence of a readily reducible disulfide bond adjacent to the acetylcholine binding site. Previously we showed that in intact receptor from Torpedo californica electric tissue reduction of this disulfide followed by affinity alkylation with 4-(N-maleimido)benzyltri[3H] methylammonium iodide specifically and uniquely labels the alpha subunit residues Cys-192 and Cys-193. To identify all of the half-cystinyl residues contributing to the binding site disulfide(s), we have now reduced receptor under mild conditions and alkylated with a mixture of 4-(N-maleimido)benzyltri[3H]methylammonium iodide and N-[1-14C]ethylmaleimide and find that Cys-192 and Cys-193 are labeled exclusively. Furthermore, from unreduced receptor we have isolated two cyanogen bromide peptides of alpha, one containing Cys-192 and Cys-193, and the other containing Cys-128 and Cys-142 (which are the other potential contributors to the binding site disulfide(s]. These isolated peptides incorporate iodo[1-14C]acetamide only following reduction by dithiothreitol. Our results demonstrate that: 1) the binding site disulfide is between Cys-192 and Cys-193; 2) Cys-128 is disulfide-cross-linked to Cys-142; and 3) under conditions that reduce Cys-192 and Cys-193 completely, Cys-128 and Cys-142 remain cross-linked. At the acetylcholine binding site, agonists induce a local conformational change that stabilizes the binding site disulfide against reduction. We suggest that a transition between two stable conformations of the vicinal disulfide, both involving a nonplanar cis peptide bond between Cys-192 and Cys-193, is associated with receptor activation by agonists.     

Disulfide structures of highly bridged peptides: a new strategy for analysis.

A new approach is described for analyzing disulfide linkage patterns in peptides containing tightly clustered cystines. Such peptides are very difficult to analyze with traditional strategies, which require that the peptide chain be split between close or adjacent Cys residues. The water-soluble tris-(2-carboxyethyl)-phosphine (TCEP) reduced disulfides at pH 3, and partially reduced peptides were purified by high performance liquid chromatography with minimal thiol-disulfide exchange. Alkylation of free thiols, followed by sequencer analysis, provided explicit assignment of disulfides that had been reduced. Thiol-disulfide exchange occurred during alkylation of some peptides, but correct deductions were still possible. Alkylation competed best with exchange when peptide solution was added with rapid mixing to 2.2 M iodoacetamide. Variants were developed in which up to three alkylating agents were used to label different pairs of thiols, allowing a full assignment in one sequencer analysis. Model peptides used included insulin (three bridges, intra- and interchain disulfides; -Cys.Cys- pair), endothelin and apamin (two disulfides; -Cys.x.Cys- pair), conotoxin GI and isomers (two disulfides; -Cys.Cys- pair), and bacterial enterotoxin (three bridges within 13 residues; two -Cys.Cys- pairs). With insulin, all intermediates in the reduction pathway were identified; with conotoxin GI, analysis was carried out successfully for all three disulfide isomers. In addition to these known structures, the method has been applied successfully to the analysis of several previously unsolved structures of similar complexity. Rates of reduction of disulfide bonds varied widely, but most peptides did not show a strongly preferred route for reduction.     

Recombinant rat liver guanidinoacetate methyltransferase: reactivity and function of sulfhydryl groups

Rat liver guanidinoacetate methyltransferase, produced in Escherichia coli by recombinant DNA technique, possesses five cysteine residues per molecule. No disulfide bond is present. Analysis of the chymotryptic peptides derived from the iodo[14C]acetate-modified enzyme shows that Cys-90, Cys-15, Cys-219, and Cys-207 are alkylated by the reagent in order of decreasing reactivity. Incubation of the enzyme with excess 5,5'-dithiobis(2-nitrobenzoate) (DTNB) in the absence and presence of cystamine [2,2'-dithiobis(ethylamine)] causes the appearance of 4 and 5 mol of 2-nitro-5-mercaptobenzoate/mol of enzyme, respectively. Reaction of the methyltransferase with an equimolar amount of DTNB results in an almost quantitative disulfide cross-linking of Cys-15 and Cys-90 with loss of a large portion of the activity. The methyltransferase is completely inactivated by iodoacetate following nonlinear kinetics. Comparison of the extent of inactivation with that of modification of cysteine residues and the experiment with the enzyme whose Cys-15 and Cys-90 are cross-linked suggest that alkylation of Cys-15 and Cys-90 results in a partially active enzyme and that carboxymethylation of Cys-219 completely eliminates enzyme activity. The inactivation of guanidinoacetate methyltransferase by iodoacetate or DTNB is not protected by substrates. Furthermore, disulfide cross-linking of Cys-15 and Cys-90 or carboxymethylation of Cys-219 does not impair the enzyme's capacity to bind S-adenosylmethionine. Thus, these cysteine residues appear to occur outside the active-site region, but their integrity is crucial for the expression of enzyme activity.     

The positions of the disulfide bonds and the glycosylation site in a lectin of the acorn barnacle Megabalanus rosa

The positions of the interchain and intrachain disulfide bonds and the glycosylation site in a lectin of the acorn barnacle Megabalanus rosa were determined. The lectin (Mr 140,000) is composed of the same subunit (Mr 22,000) which is cross-linked by disulfide bonds to form a dimer. Intact lectin yielded two fragments, CB1 and CB2, by cleavage with cyanogen bromide. One intrachain and two interchain disulfide bonds were identified as Cys-53-Cys-61, Cys-14-Cys-50' and Cys-50-Cys-14', respectively, by enzymatic digestion and Edman degradation of CB1. Two intrachain disulfide bonds were determined as Cys-78-Cys-168 and Cys-144-Cys-160 by enzymatic digestion of CB2. The two intrachain disulfide bonds are well conserved through all invertebrate lectins and calcium-dependent animal lectins. S-Carboxamidomethylated lectin was digested with Staphylococcus aureus V8 proteinase and separated by reversed-phase HPLC. Glycopeptides were detected by the 4-N,N-dimethylamino-4'-azobenzene sulfonyl hyrazide method. Sequence analyses of the glycopeptides showed that a carbohydrate chain attached to Asn-39.     

Initial steps in assembly of microfibrils. Formation of disulfide-cross-linked multimers containing fibrillin-1

Fibrillins are the major constituents of extracellular microfibrils. How fibrillin molecules assemble into microfibrils is not known. Sequential extractions and pulse-chase labeling of organ cultures of embryonic chick aortae revealed rapid formation of disulfide-cross-linked aggregates containing fibrillin-1. These results demonstrated that intermolecular disulfide bond formation is an initial step in the assembly process. To identify free cysteine residues available for intermolecular cross-linking, small recombinant peptides of fibrillin-1 harboring candidate cysteine residues were analyzed. Results revealed that the first four cysteine residues in the unique N terminus form intramolecular disulfide bonds. One cysteine residue (Cys(204)) in the first hybrid domain of fibrillin-1 was found to occur as a free thiol and is therefore a good candidate for intermolecular disulfide bonding in initial steps of the assembly process. Furthermore, evidence indicated that the comparable cysteine residue in fibrillin-2 (Cys(233)) also occurs as a free thiol. These free cysteine residues in fibrillins are readily available for intermolecular disulfide bond formation, as determined by reaction with Ellman's reagent. In addition to these major results, the cleavage site of the fibrillin-1 signal peptide and the N-terminal sequence of monomeric authentic fibrillin-1 from conditioned fibroblast medium were determined.     

Three-dimensional structure of the mini-M conotoxin mr3a

Conotoxin mr3a from the venom of Conus marmoreus, a novel peptide that induces rolling seizures in mice, has the peptide sequence GCCGSFACRFGCVOCCV, where O is trans-4-hydroxyproline, and the chain is cross-linked with disulfide bonds between Cys-2 and Cys-16, Cys-3 and Cys-12, and Cys-8 and Cys-15. The tertiary structure of mr3a was determined by 2D 1H NMR in combination with a standard distance-geometry algorithm. The final set of 22 structures for the peptide had a mean global backbone RMS deviation of 0.53 +/- 0.22 A based on 51 NOE, 6 hydrogen bond, 6 phi dihedral angle, and 3 disulfide bond constraints. Conotoxin mr3a is the first example of the new mini-M branch of conopeptides in the M superfamily. Members of the maxi-M branch, whose structures are known, include the mu- and psi-conotoxins, both of which share a common disulfide bond connectivity. Although mr3a has the same arrangement of Cys residues as the mu- and psi-conotoxins, its disulfide connectivity is different. This gives mr3a a distinctive "triple-turn" backbone.     

Introduction of reactive cysteine residues in the epsilon subunit of Escherichia coli F1 ATPase, modification of these sites with tetrafluorophenyl azide-maleimides, and examination of changes in the binding of the epsilon subunit when different nucleotides are in catalytic sites.

Cysteine residues have been exchanged for serine residues at positions 10 and 108 in the epsilon subunit of the Escherichia coli F1 ATPase by site-directed mutagenesis to create two mutants, epsilon-S10C and epsilon-S108C. These two mutants and wild-type enzyme were reacted with [14C]N-ethylmaleimide (NEM) to examine the solvent accessibility of Cys residues and with novel photoactivated cross-linkers, tetrafluorophenyl azide-maleimides (TFPAM's), to examine near-neighbor relationships of subunits. In native wild-type F1 ATPase, NEM reacted with alpha subunits at a maximal level of 1 mol/mol of enzyme (1 mol/3 alpha subunits) and with the delta subunit at 1 mol/mol of enzyme; other subunits were not labeled by the reagent. In the mutants epsilon-S10C and epsilon-S108C, Cys10 and Cys108, respectively, were also labeled by NEM, indicating that these are surface residues. Reaction of wild-type enzyme with TFPAM's gave cross-linking of the delta subunit to both alpha and beta subunits. Reaction of the mutants with TFPAM's also cross-linked delta to alpha and beta and in addition formed covalent links between Cys10 of the epsilon subunit and the gamma subunit and between Cys108 of the epsilon subunit and the alpha subunit. The yield of cross-linking between sites on epsilon and other subunits depended on the nucleotide conditions used; this was not the case for delta-alpha or delta-beta cross-linked products. In the presence of ATP+EDTA the yield of cross-linking between epsilon-Cys10 and gamma was high (close to 50%) while the yield of epsilon-Cys108 and alpha was low (around 10%).(ABSTRACT TRUNCATED AT 250 WORDS)     

Proximity of cytoplasmic and periplasmic loops in NhaA Na+/H+ antiporter of Escherichia coli as determined by site-directed thiol cross-linking

The unique trypsin cleavable site of NhaA, the Na(+)/H(+) antiporter of Escherichia coli, was exploited to detect a change in mobility of cross-linked products of NhaA by polyacrylamide gel electrophoresis. Double-Cys replacements were introduced into loops, one on each side of the trypsin cleavage site (Lys 249). The proximity of paired Cys residues was assessed by disulfide cross-linking of the two tryptic fragments, using three homobifunctional cross-linking agents: 1,6-bis(maleimido)hexane (BMH), N,N'-o-phenylenedimaleimide (o-PDM), and N,N'-p-phenylenedimaleimide (p-PDM). The interloop cross-linking was found to be very specific, indicating that the loops are not merely random coils that interact randomly. In the periplasmic side of NhaA, two patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently between the double-Cys replacements A118C/S286C, N177C/S352C, and H225C/S352C; (b) only BMH cross-links the double-Cys replacements A118C/S352C, N177C/S286C, and H225C/S286C. In the cytoplasmic side of NhaA, three patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently the pairs of Cys replacements L4C/E252C, S146C/L316C, S146C/R383C, and E241C/E252C; (b) BMH and p-PDM cross-link efficiently the pairs of Cys replacements S87C/E252C, S87C/L316C, and S146C/E252C; (c) none of the reagents cross-links the double-Cys replacements L4C/L316C, L4C/R383C, S87C/R383C, A202C/E252C, A202C/L316C, A202C/R383C, E241C/L316C, and E241C/R383C. The data reveal that the N-terminus and loop VIII-IX that have previously been shown to change conformation with pH are in close proximity within the NhaA protein. The data also suggest close proximity between N-terminal and C-terminal helices at both the cytoplasmic and the periplasmic face of NhaA.     

Cross-linking of residue 57 in the regulatory domain of a mutant rabbit skeletal muscle troponin C to the inhibitory region of troponin I

Interactions between troponin C (TnC) and troponin I (TnI) play an important role in the Ca(2+)-dependent regulation of vertebrate striated muscle contraction. In the present study, we investigated the sites of interaction between the N-terminal regulatory domain of TnC and the inhibitory region (residues 96-116) of TnI, using a mutant rabbit skeletal TnC (designated as TnC57) that contains a single Cys at residue 57 in the C-helix. TnC57 was modified with the photoreactive cross-linker 4-maleimidobenzophenone (BP-Mal), and, after formation of a binary complex with TnI, cross-linking between the proteins was induced by photolysis. The resulting product was cleaved with CNBr and several proteases, and peptides containing cross-links were purified and subjected to amino acid sequencing. The results show that Cys-57 of TnC57 is cross-linked to the segment of TnI spanning residues 113-121. Previously, we showed that Cys-98 of TnC can be cross-linked via BP-Mal to TnI residues 103-110 (Leszyk, J., Collins, J.H., Leavis, P.C., and Tao, T. (1987) Biochemistry 26, 7042-7047). Taken together, these results demonstrate that both the C- and the N-terminal domains of TnC interact with the inhibitory region of TnI and are consistent with the hypothesis that, in a complex with TnI, TnC adopts a more compact conformation than in the crystal structure.     

Human surfactant polypeptide SP-B. Disulfide bridges, C-terminal end, and peptide analysis of the airway form.

Human hydrophobic surfactant polypeptide, SP-B, purified from lung tissue by exclusion chromatography in organic solvents, has been characterized. The polypeptide is 79 residues long, has a C-terminal methionine, and contains seven Cys residues. Native human SP-B lacks free thiol groups. Three intrachain disulfide bridges were defined, linking Cys8 to Cys77, Cys11 to Cys71 and Cys35 to Cys46. The remaining Cys48 is concluded to link the protein chains into homodimers via an interchain disulfide to its counterpart in a second SP-B polypeptide. These SS bridges are identical to those in the porcine form and confirm a consestant and unique disulfide pattern for SP-B polypeptides in general.