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.     

Two critical cysteine residues implicated in disulfide bond formation and proper folding of Kir2.1

Inwardly rectifying potassium channels are important in cellular repolarization of many excitable tissues. Amino acid sequence alignment of different mammalian inward rectifier K(+) channels revealed two absolutely conserved cysteine residues in the putative extracellular face, suggesting a possible disulfide bond. Replacement of these cysteine residues in the Kir2.1 channel (i.e., C122 and C154) with either alanine or serine abolished current in Xenopus laevis oocytes although Western blotting established that the channels were fully expressed. The digestion pattern of channels treated with V8 protease combined with Western blotting under reducing and nonreducing conditions confirmed intrasubunit cross-linking of C122 and C154. Whole-cell and single channel current recordings of oocytes expressing tandem tetrameric constructs with one or two of the mutant subunits suggested that insertion of one mutant subunit is sufficient to eliminate channel function. Coexpression studies confirmed that the cysteine mutant channels eliminate wild-type Kir2.1 currents in a dominant-negative manner. Despite these results, sulfhydryl reduction did not alter the functional properties of Kir2.1 currents. Molecular modeling of Kir2.1 with the two cysteines cross-linked predicted that the extracellular loop between the first transmembrane domain and the pore helix contains a beta-hairpin structure. Distinct from the KcsA structure, the disulfide bond together with the beta-hairpin structure is expected to constrain and stabilize the P-loop and selectivity filter. Taken together, these results suggest that intramolecular disulfide bond exists between C122 and C154 of Kir2.1 channel and this cross-link might be required for proper channel folding.     

Pro-sequence assisted folding and disulfide bond formation of human nerve growth factor

Nerve growth factor (NGF) is a member of the neurotrophin family. These growth factors support neuronal survival and differentiation. Neurotrophins are synthesized as pre-pro-proteins. Whereas the pre-sequences mediate secretion, the function of the pro-peptides is largely unknown. To test the role of the pro-sequence as a folding enhancer, recombinant human pro-NGF (rh-pro-NGF) was produced in Escherichia coli. The oxidative refolding of rh-pro-NGF and rh-NGF was studied using electrospray mass spectrometry (ESIMS) time-course analysis. This analysis permitted both the identification and quantification of intermediates present during the process. The disulfide bonds formed at different times of the refolding processes were characterized by proteolytic digestion followed by matrix assisted laser desorption ionization mass spectrometry (MALDIMS) analysis. Folding yields and kinetics of rh-pro-NGF were significantly enhanced when compared to the in vitro refolding of mature rh-NGF. These results suggest that the pro-sequence of NGF promotes folding of the mature part.     

Folding of human lysozyme in vivo by the formation of an alternative disulfide bond.

The mutant h-lysozyme, W64CC65A, with Trp64 and Cys65 replaced by Cys and Ala, respectively, was secreted by yeast and purified. Peptide mapping confirmed that W64CC65A contained a nonnative Cys64-Cys81 bond and three native disulfide bonds. The mutant had 2% of the lytic activity of the wild-type lysozyme. The midpoint concentration of the guanidine hydrochloride denaturation curve, the [D]1/2, was 2.7 M for W64CC65A at pH 3.0 and 25 degrees C, whereas the [D]1/2 for the wild-type h-lysozyme was 2.9 M. These results show that the W64CC65A protein is a compactly folded molecule. Our previous results, using the mutant C81A, indicate that Cys81 is not required for correct folding and activity, whereas Cys65 is indispensable (Taniyama, Y., Yamamoto, Y., Kuroki, R., and Kikuchi, M. (1990) J. Biol. Chem. 65, 7570-7575). Cys64 substituted for Cys65 in W64CC65A, even though the distance between the alpha-carbons at positions 64 and 81 in the wild-type h-lysozyme is not favorable for forming a disulfide bond. Unlike C81A, the mutant W64CC65/81A, which has the additional substitution of Ala for Cys81, did not fold. These results suggest that the absence of both the Cys64-Cys81 bond and the amino acid residue Trp64 caused the misfolding or destabilization of W64CC65/81A in vivo. It is proposed that the formation of the alternative bond, Cys64-Cys81 is important for the folding of W64CC65A in vivo.     

Effect of an alternative disulfide bond on the structure, stability, and folding of human lysozyme

Human lysozyme has four disulfide bonds, one of which, Cys65-Cys81, is included in a long loop of the beta-domain. A cysteine-scanning mutagenesis in which the position of Cys65 was shifted within a continuous segment from positions 61 to 67, with fixed Cys81, has previously shown that only the mutant W64CC65A, which has a nonnative Cys64-Cys81 disulfide, can be correctly folded and secreted by yeast. Here, using the W64CC65A mutant, we investigated the effects of an alternative disulfide bond on the structure, stability, and folding of human lysozyme using circular dichroism (CD) and fluorescence spectroscopy combined with a stopped-flow technique. Although the mutant is expected to have a different main-chain structure from that of the wild-type protein around the loop region, far- and near-UV CD spectra show that the native state of the mutant has tightly packed side chains and secondary structure similar to that of the wild-type. Guanidine hydrochloride-induced equilibrium unfolding transition of the mutant is reversible, showing high stability and cooperativity of folding. In the kinetic folding reaction, both proteins accumulate a similar burst-phase intermediate having pronounced secondary structure within the dead time of the measurement and fold into the native structure by means of a similar folding mechanism. Both the kinetic refolding and unfolding reactions of the mutant protein are faster than those of the wild-type, but the increase in the unfolding rate is larger than that of the refolding rate. The Gibbs' free-energy diagrams obtained from the kinetic analysis suggest that the structure around the loop region in the beta-domain of human lysozyme is formed after the transition state of folding, and thus, the effect of the alternative disulfide bond on the structure, stability, and folding of human lysozyme appears mainly in the native state.     

A conserved cysteine residue is involved in disulfide bond formation between plant plasma membrane aquaporin monomers

AQPs (aquaporins) are conserved in all kingdoms of life and facilitate the rapid diffusion of water and/or other small solutes across cell membranes. Among the different plant AQPs, PIPs (plasma membrane intrinsic proteins), which fall into two phylogenetic groups, PIP1 and PIP2, play key roles in plant water transport processes. PIPs form tetramers in which each monomer acts as a functional channel. The intermolecular interactions that stabilize PIP oligomer complexes and are responsible for the resistance of PIP dimers to denaturating conditions are not well characterized. In the present study, we identified a highly conserved cysteine residue in loop A of PIP1 and PIP2 proteins and demonstrated by mutagenesis that it is involved in the formation of a disulfide bond between two monomers. Although this cysteine seems not to be involved in regulation of trafficking to the plasma membrane, activity, substrate selectivity or oxidative gating of ZmPIP1s (Zm is Zea mays), ZmPIP2s and hetero-oligomers, it increases oligomer stability under denaturating conditions. In addition, when PIP1 and PIP2 are co-expressed, the loop A cysteine of ZmPIP1;2, but not that of ZmPIP2;5, is involved in the mercury sensitivity of the channels.     

Oxidative folding of Amaranthus alpha-amylase inhibitor: disulfide bond formation and conformational folding

Oxidative folding is the fusion of native disulfide bond formation with conformational folding. This complex process is guided by two types of interactions: first, covalent interactions between cysteine residues, which transform into native disulfide bridges, and second, non-covalent interactions giving rise to secondary and tertiary protein structure. The aim of this work is to understand both types of interactions in the oxidative folding of Amaranthus alpha-amylase inhibitor (AAI) by providing information both at the level of individual disulfide species and at the level of amino acid residue conformation. The cystine-knot disulfides of AAI protein are stabilized in an interdependent manner, and the oxidative folding is characterized by a high heterogeneity of one-, two-, and three-disulfide intermediates. The formation of the most abundant species, the main folding intermediate, is favored over other species even in the absence of non-covalent sequential preferences. Time-resolved NMR and photochemically induced dynamic nuclear polarization spectroscopies were used to follow the oxidative folding at the level of amino acid residue conformation. Because this is the first time that a complete oxidative folding process has been monitored with these two techniques, their results were compared with those obtained at the level of an individual disulfide species. The techniques proved to be valuable for the study of conformational developments and aromatic accessibility changes along oxidative folding pathways. A detailed picture of the oxidative folding of AAI provides a model study that combines different biochemical and biophysical techniques for a fuller understanding of a complex process.     

Muscarinic acetylcholine receptors. Peptide sequencing identifies residues involved in antagonist binding and disulfide bond formation

Muscarinic acetylcholine receptors (mAChR) were purified from rat brain and labeled either with the site-directed affinity label [3H]propylbenzilylcholine mustard (PrBCM) or with the sulfhydryl-specific label [3H]N-ethylmaleimide (NEM), using a protocol designed to give selective incorporation of the label into disulfide-bonded cysteines. m1 mAChRs were purified from CHO-K1 cells stably expressing the cloned receptor sequence and labeled with [3H]PrBCM. The labeled receptors were cleaved with the lysine-specific protease Lys-C and, after fractionation of the products, subcleaved with cyanogen bromide. Two major CNBr cleavage products were found with a molecular mass of approximately 3.9 and approximately 2.4 kDa, labeled either by [3H]PrBCM or [3H]NEM. The results obtained from CNBr cleavage of purified forebrain receptors were consistent with those obtained from the purified cloned m1 mAChR. Edman degradation was applied to the CNBr peptides. The results were compatible with the attachment of the [3H]PrBCM label to a conserved aspartic acid residue in transmembrane helix 3 of the mAChR (corresponding to Asp-105, m1 sequence) and of [3H]NEM to a conserved cysteine residue (corresponding to Cys-98, m1 sequence). These results support the hypothesis that the cysteine residue participates in a disulfide bond on the extracellular surface of the mAChRs and related G-protein-coupled receptors, while the aspartic acid residue is involved in binding the positively charged headgroup of muscarinic antagonists.     

Generation of two isomers with the same disulfide connectivity during disulfide bond formation of human uroguanylin

Summary In a two-step selective disulfide-bond-forming reaction of human uroguanylin, a 16-residue peptide with two intramolecular disulfide bonds, two compounds (I and II) were formed, which could be detected by RP-HPLC after the second disulfide-bond-forming reaction and were isolated as single entities. Their primary structures, molecular weights, and disulfide connectivities proved to be identical, but their optical rotation values were different, suggesting that they are topological isomers. Only compound I was found to increase the cGMP levels in cultured T84 cells significantly. The ratio of these compounds was affected by the order of the disulfide-bond-forming reactions, but not by the solvent used. The presence of a carboxyl-terminal leucine residue seems to be crucial for stabilizing the conformation of the two isomers.     

Manipulating disulfide bond formation and protein folding in the endoplasmic reticulum.

Addition of the reducing agent dithiothreitol (DTT) to the medium of living cells prevented disulfide bond formation in newly synthesized influenza hemagglutinin (HA0) and induced the reduction of already oxidized HA0 inside the ER. The reduced HA0 did not trimerize or leave the ER. When DTT was washed out, HA0 was rapidly oxidized, correctly folded, trimerized and transported to the Golgi complex. We concluded that protein folding and the redox conditions in the ER can be readily manipulated by addition of DTT without affecting most other cellular functions, that the reduced influenza HA0 remains largely unfolded, and that folding events that normally take place on the nascent HA0 chains can be delayed and induced post-translationally without loss in efficiency.     

Interchain disulfide bond formation in types I and II procollagen. Evidence for a protein disulfide isomerase catalyzing bond formation

The assembly of reduced pro-alpha chains of type I and type II procollagen into the native triple-helical molecule was examined in vitro in the presence and absence of pure protein disulfide isomerase. The data clearly indicates that protein disulfide isomerase is able to accelerate the formation of native interchain disulfide bonds in these procollagens. It takes about 6 min after disulfide bonding before triple-helical molecules exist, while the time required to produce triple-helical type I procollagen in the presence of protein disulfide isomerase is 9.4 min and that for type II procollagen 17.2 min. These values agree with those obtained for type I and II procollagen in vivo suggesting that protein disulfide isomerase is also an enzyme catalyzing interchain disulfide bond formation in procollagen in vivo. The formation of native disulfide bonds can proceed without any enzyme catalysis but then requires the presence of reduced and oxidized glutathione. Bonding is rather slow in such a case, however, resulting in a delay in the formation of the triple helix.     

The biosynthesis of rat transferrin. Evidence for rapid glycosylation, disulfide bond formation, and tertiary folding

The transit time of newly synthesized transferrin in the liver is markedly longer than that of albumin. We sought to learn the basis of this difference by the use of labeled leucine and mannose in vivo and by isolation of newly formed transferrin from rough microsomes of rat liver. Albumin and alpha 1-antitrypsin, a second glycoprotein, were also studied for comparison. Minimal hepatic transit times were 17, 23, and 31 min for albumin, alpha 1-antitrypsin, and transferrin, respectively. The delay in the case of transferrin was found to occur chiefly in the rough endoplasmic reticulum and to be paralleled by an increase in the amount of transferrin relative to albumin in that organelle. Initial glycosylation of transferrin was as rapid as that of alpha 1-antitrypsin, and essentially all of the transferrin in the rough endoplasmic reticulum contained glycans which bound to concanavalin A and were removed by endoglycosidase H. Only 3% of the transferrin isolated from the rough microsomes came from the plasma by endocytosis or adsorption. Rapidity of disulfide bond formation in rough microsomes was evident from the presence of only 1.3 cysteine thiols/molecule of rough microsomal transferrin (total of 19 cystines) and the absence of mixed disulfides. Peptide patterns upon mild proteolysis were consistent with a native configuration of disulfide bond pairing. The ability of rough microsomal transferrin to bind and deliver iron through interaction with transferrin receptors on reticulocytes suggests that considerable tertiary structure is present. Thus, initial glycosylation, disulfide bridging, and tertiary folding are all rapid processes. The cause for the slow release of transferrin from the rough endoplasmic reticulum may lie with a rate-limiting transfer mechanism.     

Native disulfide bonds greatly accelerate secondary structure formation in the folding of lysozyme.

To assess the respective roles of local and long-range interactions during protein folding, the influence of the native disulfide bonds on the early formation of secondary structure was investigated using continuous-flow circular dichroism. Within the first 4 ms of folding, lysozyme with intact disulfide bonds already had a far-UV CD spectrum reflecting large amounts of secondary structure. Conversely, reduced lysozyme remained essentially unfolded at this early folding time. Thus, native disulfide bonds not only stabilize the cfinal conformation of lysozyme but also provide, in early folding intermediates, the necessary stabilization that favors the formation of secondary structure.     

Two conserved cysteine triads in human Ero1alpha cooperate for efficient disulfide bond formation in the endoplasmic reticulum

Human Ero1alpha is an endoplasmic reticulum (ER)-resident protein responsible for protein disulfide isomerase (PDI) oxidation. To clarify the molecular mechanisms underlying its function, we generated a panel of cysteine replacement mutants and analyzed their capability of: 1) complementing a temperature-sensitive yeast Ero1 mutant, 2) favoring oxidative folding in mammalian cells, 3) forming mixed disulfides with PDI and ERp44, and 4) adopting characteristic redox-dependent conformations. Our results reveal that two essential cysteine triads (Cys85-Cys94-Cys99 and Cys391-Cys394-Cys397) cooperate in electron transfer, with Cys94 likely forming mixed disulfides with PDI. Dominant negative phenotypes arise when critical residues within the triads are mutated (Cys394, Cys397, and to a lesser extent Cys99). Replacing the first cysteine in either triad (Cys85 or Cys391) generates mutants with weaker activity. In addition, mutating either Cys85 or Cys391, but not Cys397, reverts the dominant negative phenotype of the C394A mutant. These findings suggest that interactions between the two triads, dependent on Cys85 and Cys391, are important for Ero1alpha function, possibly stabilizing a platform for efficient PDI oxidation.     

Effect of an engineered disulfide bond on the folding of T4 lysozyme at low temperatures

Equilibrium and kinetic effects on the folding of T4 lysozyme were investigated by fluorescence emission spectroscopy in cryosolvent. To study the role of disulfide cross-links in stability and folding, a comparison was made with a mutant containing an engineered disulfide bond between Cys-3 (Ile-3 in the wild type) and Cys-97, which links the C-terminal domain to the N terminus of the protein [Perry & Wetzel (1984) Science 226, 555]. In our experimental system, stability toward thermal and denaturant unfolding was increased slightly as a result of the cross-link. The corresponding reduced protein was significantly less stable than the wild type. Unfolding and refolding kinetics were carried out in 35% methanol, pH 6.8 at -15 degrees C, with guanidine hydrochloride as the denaturant. Unfolding/refolding of the wild-type and reduced enzyme showed biphasic kinetics both within and outside the denaturant-induced transition region and were consistent with the presence of a populated intermediate in folding. Double-jump refolding experiments eliminated proline isomerization as a possible cause for the biphasicity. The disulfide mutant protein, however, showed monophasic kinetics in all guanidine concentrations studied.     

Accelerated secretion of human lysozyme with a disulfide bond mutation.

The mutant human lysozyme, [Ala77, Ala95]lysozyme, in which the disulfide bond Cys77-Cys95 is eliminated, is known to exhibit increased secretion in yeast, compared to wild-type human lysozyme [Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M. & Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967]. To investigate this phenomenon, mammalian cells were used to analyze the secretion kinetics of [Ala77, Ala95]lysozyme and wild-type human lysozyme. The secretion rate of [Ala77, Ala95]lysozyme during the 150-min chase period was significantly accelerated [half-life (t1/2) = 29 min] compared to that of wild-type human lysozyme (t1/2 = 83 min), when expressed at the same levels within the cells. In contrast, after the 150-min chase, the rates of disappearance of both wild-type and mutant human lysozymes within the cells were similar, and considerably slower (t1/2 = 220 min), respectively. The remaining intracellular wild-type human lysozyme was localized mainly in the endoplasmic reticulum, whereas accelerated transport of the [Ala77, Ala95]lysozyme mutant protein from the endoplasmic reticulum to the Golgi apparatus was observed. Also in yeast cells, similar secretion kinetics and the differences in t1/2 for wild-type and mutant human lysozymes during the early chase period were observed. The two-phase kinetics of disappearance of intracellular human lysozymes suggest that only a proportion of the proteins becomes secretion competent soon after synthesis and is completely secreted during the early chase period, whereas others enter the distinct, slow pathways of intracellular transport and/or degradation. Increased secretion of [Ala77, Ala95]lysozyme is possibly due to enhanced competence for secretion acquired in the endoplasmic reticulum at the early stage of transport events, which is closely connected with the removal of a disulfide bond.     

ATP is required for correct folding and disulfide bond formation of rotavirus VP7

Rotavirus is one of very few viruses that utilize the endoplasmic reticulum (ER) for assembly, and therefore it has been used as an attractive model to study ER-associated protein folding. In this study, we have examined the requirements for metabolic energy (ATP) for correct folding of the luminal and ER-associated VP7 of rotavirus. We found that VP7 rapidly misfolds in an energy-depleted milieu and is not degraded within 60 min. We also found that VP7 attained a stable minimum-energy state soon after translation in the ER. Most surprisingly, energy-misfolded VP7 could be recovered and establish correct disulfide bonds and antigenicity following a shift to an ATP-rich milieu. Using a Semliki Forest virus expression system, we observed that VP7 requires ATP and cellular, but not viral, factors for correct disulfide bond formation. Our results show for the first time that the disulfide bond formation of rotavirus VP7 is an ATP-dependent process. It has previously been shown that chaperones hydrolyze ATP during interaction with newly synthesized polypeptides and prevent nonproductive intra- and intermolecular interactions. The most reasonable explanation for the energy requirement of VP7 is thus a close interaction during folding with an ATP-dependent chaperone, such as BiP (Grp78), and possibly with protein disulfide isomerase. Taken together, our observations provide new information about folding of ER-associated proteins in general and rotavirus VP7 in particular.     

Assembly of functional rhodopsin requires a disulfide bond between cysteine residues 110 and 187

Cysteine residues 110 and 187 are essential for the formation of the correct bovine rhodopsin structure (Karnik, S. S., Sakmar, T. P., Chen, H.-B., and Khorana, H. G. (1988) Proc. Natl. Acad. Sci. U. S. A. 85, 8459-8463). We now show that the sulfhydryl groups of these 2 cysteine residues interact to form a disulfide bond. Rhodopsin mutants containing cysteine----serine substitutions were prepared as follows. In one mutant, CysVII, all the 10 cysteine residues of rhodopsin were replaced by serines. A second mutant, CysVIII, contained only C110 and C185; a third mutant, CysIX, contained only C185 and C187 while the fourth mutant, CysX, contained only C110 and C187. Only mutant CysX formed functional rhodopsin. Mutants CysVIII and CysIX reacted with [3H]iodoacetic acid showing the presence of free sulfhydryl groups while mutant CysX was inert to this reagent. CysX reacted with cyanide ion to form a thiocyanate derivative showing the presence of a disulfide bond. The C110-C187 disulfide bond is buried in rhodopsin because reactions with disulfide reducing agents and cyanide ion require prior treatment with denaturants.     

Role of disulfide bonds in folding and secretion of human lysozyme in Saccharomyces cerevisiae

We examined folding and secretion of human lysozyme using four mutants each lacking two cysteines expressed in a yeast secretion system. Our results have revealed that the formation of the disulfide bond Cys6/Cys128 in human lysozyme is a prerequisite for correct folding in vivo in yeast. Substitution of Ala for Cys77 and Cys95 gave eight-fold greater secretion of a molecule with almost the same specific activity as that of the native enzyme. Substitutions of the other cysteines gave molecules that were secreted at a lower rate and had lower specific activities than the native enzyme. These are the first findings that the individual disulfide bonds of human lysozyme have different functions in folding and secretion in vivo.     

Crystal structure of a mutant human lysozyme with a substituted disulfide bond

The three-dimensional structure of a mutant human lysozyme, W64CC65A, in which a non-native disulfide bond Cys64--Cys81 is substituted for the Cys65--Cys81 of the wild type protein by replacing Trp64 and Cys65 with Cys and Ala, respectively, was determined by X-ray crystallography and refined to an R-value of 0.181, using 33,187 reflections at 1.87-A resolution. The refined model of the W64CC65A protein consisted of four molecules, which were related by two noncrystallographic twofold axes and a translation vector. Although no specific structural differences could be observed among these four molecules, the overall B-factors of each molecule were quite different. The overall structure of W64CC65A, especially in the alpha-helical domain, was found to be quite similar to that of the wild type protein. Moreover, the side-chain conformation of the newly formed Cys64--Cys81 bond was quite similar to that of the Cys65--Cys81 bond of the wild-type protein. However, in the beta-sheet domain, the main-chain atoms of the loop region from positions 66-75 could not be determined, and significant structural changes due to the formation of the non-native disulfide bond could be observed. From these results, it is clear that the loop region of the mutant protein does not fold with the specific folding as observed in the wild-type protein.