Pathway of oxidative folding of alpha-lactalbumin: a model for illustrating the diversity of disulfide folding pathways

The pathway of oxidative folding of alpha-lactalbumin (alpha LA) (four disulfide bonds) has been characterized by structural and kinetic analysis of the acid-trapped folding intermediates. In the absence of calcium, oxidative folding of alpha LA proceeds through highly heterogeneous species of one-, two-, three-, and four-disulfide (scrambled) intermediates to reach the native structure. In the presence of calcium, the folding intermediates of alpha LA comprise two predominant isomers (alpha LA-IIA and alpha LA-IIIA) adopting exclusively native disulfide bonds, including the two disulfide bonds (Cys(61)-Cys(77) and Cys(73)-Cys(91)) located within the beta-sheet calcium binding domain. alpha LA-IIA is a two-disulfide species consisting of Cys(61)-Cys(77) and Cys(73)-Cys(91) disulfide bonds. alpha LA-IIIA contains Cys(61)-Cys(77), Cys(73)-Cys(91), and Cys(28)-Cys(111) disulfide bonds. The underlying mechanism of the contrasting folding pathways of calcium-bound and calcium-depleted alpha LA is congruent with the cause of diversity of disulfide folding pathways observed among many well-characterized three-disulfide proteins, including bovine pancreatic trypsin inhibitor and hirudin. Our study also reveals novel aspects of the folding mechanism of alpha LA that have not been described previously.     

A major kinetic trap for the oxidative folding of human epidermal growth factor

The folding pathway of human epidermal growth factor (EGF) has been characterized by structural and kinetic analysis of the acid-trapped folding intermediates. Oxidative folding of the fully reduced EGF proceeds through 1-disulfide intermediates and accumulates rapidly as a single stable 2-disulfide intermediate (designated as EGF-II), which represents up to more than 85% of the total protein along the folding pathway. Among the five 1-disulfide intermediates that have been structurally characterized, only one is native, and nearly all of them are bridges by neighboring cysteines. Extensive accumulation of EGF-II indicates that it accounts for the major kinetic trap of EGF folding. EGF-II contains two of the three native disulfide bonds of EGF, Cys(14)-Cys(31) and Cys(33)-Cys(42). However, formation of the third native disulfide (Cys(6)-Cys(20)) for EGF-II is slow and does not occur directly. Kinetic analysis reveals that an important route for EGF-II to reach the native structure is via rearrangement pathway through 3-disulfide scrambled isomers. The pathway of EGF-II to attain the native structure differs from that of three major 2-disulfide intermediates of bovine pancreatic trypsin inhibitor (BPTI). The dissimilarities of folding mechanism(s) between EGF, BPTI, and hirudin are discussed in this paper.     

Pathway of Oxidative Folding of a 3-Disulfide α-Lactalbumin May Resemble Either BPTI Model or Hirudin Model

Pathways of oxidative folding of disulfide proteins display a high degree of diversity and vary among two extreme models. The BPTI model is defined by limited species of folding intermediates adopting mainly native disulfide bonds. The hirudin model is characterized by highly heterogeneous folding intermediates containing mostly non-native disulfide bonds. αLA-IIIA is a 3-disulfide variant of α-lactalbumin (αLA) with a 3-D conformation essentially identical to that of intact αLA. αLA-IIIA contains 3 native disulfide bonds of αLA, two of them are located at the calcium binding β-subdomain (Cys⁶¹–Cys⁷⁷ and Cys⁷³–Cys⁹¹) and the third bridge is located within the α-helical domain of the molecule (Cys²⁸–Cys¹¹¹). We investigate here the pathway of oxidative folding of fully reduced αLA-IIIA with and without stabilization of its β-subdomain by calcium binding. In the absence of calcium, the folding pathway of αLA-IIIA was shown to resemble that of hirudin model. Upon stabilization of β-sheet domain by calcium binding, the folding pathway of αLA-IIIA exhibits a striking similarity to that of BPTI model. Three predominant folding intermediates of αLA-IIIA containing exclusively native disulfide bonds were isolated and structurally characterized. Our results further demonstrate that stabilization of subdomains in a protein may dictate its folding pathway and represent a major cause for the existing diversity in the folding pathways of the disulfide-containing proteins.     

The underlying mechanism for the diversity of disulfide folding pathways

The disulfide folding pathway of bovine pancreatic trypsin inhibitor (BPTI) is characterized by the predominance of folding intermediates with native-like structures. Our laboratory has recently analyzed the folding pathway(s) of four 3-disulfide-containing proteins, including hirudin, potato carboxypeptidase inhibitor, epidermal growth factor, and tick anticoagulant peptide. Their folding mechanism(s) differ from that of BPTI by 1) a higher degree of heterogeneity of 1- and 2-disulfide intermediates and 2) the presence of 3-disulfide scrambled isomers as folding intermediates. To search for the underlying causes of these diversities, we conducted kinetic analyses of the reductive unfolding of these five proteins. The experiment of reductive unfolding was designed to evaluate the relative stability and interdependence of disulfide bonds in the native protein. It is demonstrated here that among these five proteins, there exists a striking correlation between the mechanism(s) of reductive unfolding and that of oxidative folding. Those proteins with their native disulfide bonds reduced in a collective and simultaneous manner exhibit both a high degree of heterogeneity of folding intermediates and the accumulation of scrambled isomers along the folding pathway. A sequential reduction of the native disulfide bonds is associated with the presence of predominant intermediates with native- like structures.     

The structure of denatured bovine pancreatic trypsin inhibitor (BPTI)

In the presence of denaturant and thiol initiator, the native bovine pancreatic trypsin inhibitor (BPTI) denatures by shuffling its native disulfide bonds and converts to a mixture of scrambled isomers. The extent of denaturation is evaluated by the relative yields of the scrambled and native species of BPTI. BPTI is an exceedingly stable molecule and can be effectively denatured only by guanidine thiocyanate (GdmSCN) at concentrations higher than 3-4 M. The denatured BPTI consists of at least eight fractions of scrambled isomers. Their composition varies under increasing concentrations of GdmSCN. In the presence of 6 M GdmSCN, the most predominant fraction of scrambled BPTI accounts for 56% of the total structure of denatured BPTI. Structural analysis reveals that this predominant fraction contains the bead-form isomer of scrambled BPTI, bridged by three pairs of neighboring cysteines, Cys5-Cys14, Cys30-Cys38 and Cys51-Cys55. The extreme conformational stability of BPTI has important implications in its distinctive folding pathway.     

Major kinetic traps for the oxidative folding of leech carboxypeptidase inhibitor

The leech carboxypeptidase inhibitor (LCI) is a 66-amino acid protein, containing four disulfides that stabilize its structure. This polypeptide represents an excellent model for the study and understanding of the diversity of folding pathways in small, cysteine-rich proteins. The pathway of oxidative folding of LCI has been elucidated in this work, using structural and kinetic analysis of the folding intermediates trapped by acid quenching. Reduced and denatured LCI refolds through a rapid, sequential flow of one- and two-disulfide intermediates and reaches a rate-limiting step in which a mixture of three major three-disulfide species and a heterogeneous population of non-native four-disulfide (scrambled) isomers coexist. The three three-disulfide intermediates have been identified as major kinetic traps along the folding pathway of LCI, and their disulfide structures have been elucidated in this work. Two of them contain only native disulfide pairings, and one contains one native and two non-native disulfide bonds. The coexistence of three-disulfide kinetic traps adopting native disulfide bonds together with a significant proportion of fully oxidized scrambled isomers shows that the folding pathway of LCI features properties exhibited by both the bovine pancreatic trypsin inhibitor and hirudin, two diverse models with extreme folding characteristics. The results further demonstrate the large diversity of disulfide folding pathways.     

Study of a major intermediate in the oxidative folding of leech carboxypeptidase inhibitor: contribution of the fourth disulfide bond

The oxidative folding pathway of leech carboxypeptidase inhibitor (LCI; four disulfide bonds) proceeds through the formation of two major intermediates (III-A and III-B) that contain three native disulfide bonds and act as strong kinetic traps in the folding process. The III-B intermediate lacks the Cys19-Cys43 disulfide bond that links the beta-sheet core with the alpha-helix in wild-type LCI. Here, an analog of this intermediate was constructed by replacing Cys19 and Cys43 with alanine residues. Its oxidative folding follows a rapid sequential flow through one, two, and three disulfide species to reach the native form; the low accumulation of two disulfide intermediates and three disulfide (scrambled) isomers accounts for a highly efficient reaction. The three-dimensional structure of this analog, alone and in complex with carboxypeptidase A (CPA), was determined by X-ray crystallography at 2.2A resolution. Its overall structure is very similar to that of wild-type LCI, although the residues in the region adjacent to the mutation sites show an increased flexibility, which is strongly reduced upon binding to CPA. The structure of the complex also demonstrates that the analog and the wild-type LCI bind to the enzyme in the same manner, as expected by their inhibitory capabilities, which were similar for all enzymes tested. Equilibrium unfolding experiments showed that this mutant is destabilized by approximately 1.5 kcal mol(-1) (40%) relative to the wild-type protein. Together, the data indicate that the fourth disulfide bond provides LCI with both high stability and structural specificity.     

Pathway of oxidative folding of bovine alpha-interferon: predominance of native disulfide-bonded folding intermediates

Bovine alpha-interferon (BoINF-alpha) is a single polypeptide protein containing 166 amino acids, two disulfide bonds (Cys1-Cys99 and Cys29-Cys138), and five stretches of alpha-helical structure. The pathway of oxidative folding of BoINF-alpha has been investigated here. Of the eight possible one- and two-disulfide isomers, only two nativelike one-disulfide isomers, BoINF-alpha (Cys1-Cys99) and BoINF-alpha (Cys29-Cys138), predominate as intermediates along the folding pathway. More strikingly, alpha-helical structures formed almost quantitatively before any detectable formation of a disulfide bond. This is demonstrated by the observation that fully reduced BoINF-alpha (starting material of oxidative folding) and reduced carboxymethylated BoINF-alpha both exhibit alpha-helical structure content indistinguishable form that of native BoINF-alpha. The folding mechanism of BoINF-alpha appears to be compatible with the framework model, in which secondary structures fold first, followed by docking (compaction) of preformed secondary structural elements yielding the native structure.     

Role of kinetic intermediates in the folding of leech carboxypeptidase inhibitor

The oxidative folding and reductive unfolding pathways of leech carboxypeptidase inhibitor (LCI; four disulfides) have been characterized in this work by structural and kinetic analysis of the acid-trapped folding intermediates. The oxidative folding of reduced and denatured LCI proceeds rapidly through a sequential flow of 1-, 2-, 3-, and 4-disulfide (scrambled) species to reach the native form. Folding intermediates of LCI comprise two predominant 3-disulfide species (designated as III-A and III-B) and a heterogeneous population of scrambled isomers that consecutively accumulate along the folding reaction. Our study reveals that forms III-A and III-B exclusively contain native disulfide bonds and correspond to stable and partially structured species that interconvert, reaching an equilibrium prior to the formation of the scrambled isomers. Given that these intermediates act as kinetic traps during the oxidative folding, their accumulation is prevented when they are destabilized, thus leading to a significant acceleration of the folding kinetics. III-A and III-B forms appear to have both native disulfides bonds and free thiols similarly protected from the solvent; major structural rearrangements through the formation of scrambled isomers are required to render native LCI. The reductive unfolding pathway of LCI undergoes an apparent all-or-none mechanism, although low amounts of intermediates III-A and III-B can be detected, suggesting differences in protection against reduction among the disulfide bonds. The characterization of III-A and III-B forms shows that the former intermediate structurally and functionally resembles native LCI, whereas the III-B form bears more resemblance to scrambled isomers.     

The folding pathway of alpha-lactalbumin elucidated by the technique of disulfide scrambling. Isolation of on-pathway and off-pathway intermediates

The technique of disulfide scrambling permits reversible conversion of the native and denatured (scrambled) proteins via shuffling and reshuffling of disulfide bonds. Under strong denaturing conditions (e.g. 6 m guanidinium chloride) and in the presence of a thiol initiator, alpha-lactalbumin (alphaLA) denatures by shuffling its four native disulfide bonds and converts to an assembly of 45 species of scrambled isomers. Among them, two predominant isomers, designated as X-alphaLA-a and X-alphaLA-d, account for about 50% of the total denatured structure of alphaLA. X-alphaLA-a and X-alphaLA-d, which adopt the disulfide patterns of (1-2,3-4,5-6,7-8) and (1-2,3-6,4-5,7-8), respectively, represent the most unfolded structures among the 104 possible scrambled isomers (Chang, J.-Y., and Li, L. (2001) J. Biol. Chem. 276, 9705-9712). In this study, X-alphaLA-a and X-alphaLA-d were purified and allowed to refold through disulfide scrambling to form the native alphaLA. Folding intermediates were trapped kinetically by acid quenching and analyzed quantitatively by reversed phase high pressure liquid chromatography. The results revealed two major on-pathway productive intermediates, two major off-pathway kinetic traps, and at least 30 additional minor transient intermediates. Of the two major on-pathway intermediates, one takes on a native-like alpha-helical domain, and the other comprises a structured beta-sheet, calcium binding domain. The two major kinetic traps are apparently stabilized by locally formed non-native-like structures. Overall, the folding mechanism of alphaLA is essentially congruent with the model of "folding funnel" furnished with a rather intricate energy landscape.     

Structures of scrambled disulfide forms of the potato carboxypeptidase inhibitor predicted by molecular dynamics simulations with constraints

The structures of two species of potato carboxypeptidase inhibitor with nonnative disulfide bonds were determined by molecular dynamics simulations in explicit solvent using disulfide bond constraints that have been shown to work for the native species. Ten structures were determined; five for scrambled A (disulfide bonds between Cys8-Cys27, Cys12-Cys18, and Cys24-Cys34) and five for the scrambled C (disulfide bonds Cys8-Cys24, Cys12-Cys18, and Cys27-Cys34). The two scrambled species were both more solvent exposed than the native structure; the scrambled C species was more solvent exposed and less compact than the scrambled A species. Analysis of the loop regions indicates that certain loops in scrambled C are more nativelike than in scrambled A. These factors, combined with the fact that scrambled C has one native disulfide bond, may contribute to the observed faster conversion to the native structure from scrambled C than from scrambled A. Results from the PROCHECK program using the standard parameter database and a database specially constructed for small, disulfide-rich proteins indicate that the 10 scrambled structures have correct stereochemistry. Further, the results show that a characteristic feature of small, disulfide-rich proteins is that they score poorly using the standard PROCHECK parameter database. Proteins 2000;40:482-493.     

Two-State Folding of Lysozyme Versus Multiple-State Folding of α-Lactalbumin Illustrated by the Technique of Disulfide Scrambling

The folding of lysozyme and of alpha-lactalbumin exhibits vastly different kinetics and pathways. Existing evidence indicates that folding intermediates of alphaLA form a well-populated equilibrium molten globule state that is absent in the case of hen lysozyme. We demonstrate here such divergent folding mechanisms of lysozyme and alphaLA using the technique of disulfide scrambling. Two extensively unfolded homologous isomers (beads-form) of lysozyme (Cys6-Cys30, Cys64-Cys76, Cys80-Cys94, Cys115-Cys127) and alphaLA (Cys6-Cys28, Cys61-Cys73, Cys77-Cys91, Cys111-Cys120) were allowed to refold in parallel to form the native protein. Folding kinetics was measured by the recovery of the native structure. Folding intermediates, which illustrate the folding pathway, were trapped by quenching disulfide shuffling and were analyzed by reversed-phase high-pressure liquid chromatography. The results revealed that under identical folding conditions, the folding rate of lysozyme is about 30-fold faster than that of alphaLA. Folding intermediates of lysozyme are far less heterogeneous and sparsely populated than those of alphaLA. Numerous predominant on-pathway and off-pathway intermediates observed along the folding pathway of alphaLA are conspicuously absent in the case of lysozyme. The difference is most striking under fast folding conditions performed in the presence of protein disulfide isomerase. Under these conditions, folding of lysozyme undergoes a near two-state mechanism without accumulation of stable folding intermediates.     

Conformational analysis of intermediates involved in the in vitro folding pathways of recombinant human macrophage colony stimulating factor beta by sulfhydryl group trapping and hydrogen/deuterium pulsed labeling

In vitro oxidative folding of reduced recombinant human macrophage colony stimulating factor beta (rhm-CSFbeta) involves two major events: disulfide isomerization in the monomeric intermediates and disulfide-mediated dimerization. Kinetic analysis of rhm-CSFbeta folding indicated that monomer isomerization is slower than dimerization and is, in fact, the rate-determining step. A time-dependent determination of the number of free cysteines remaining was made after refolding commence. The folding intermediates revealed that rhm-CSFbeta folds systematically, forming disulfide bonds via multiple pathways. Mass spectrometric evidence indicates that native as well as non-native intrasubunit disulfide bonds form in monomeric intermediates. Initial dimerization is assumed to involve formation of disulfide bonds, Cys 157/159-Cys' 157/159. Among six intrasubunit disulfide bonds, Cys 48-Cys 139 and Cys' 48-Cys' 139 are assumed to be the last to form, while Cys 31-Cys' 31 is the last intersubunit disulfide bond that forms. Conformational properties of the folding intermediates were probed by H/D exchange pulsed labeling, which showed the coexistence of noncompact dimeric and monomeric species at early stages of folding. As renaturation progresses, the noncompact dimer undergoes significant structural rearrangement, forming a native-like dimer while the monomer maintains a noncompact conformation.     

Structure and heterogeneity of the one- and two-disulfide folding intermediates of tick anticoagulant peptide

Tick anticoagulant peptide (TAP) is a factor Xa-specific inhibitor and is structurally homologous to bovine pancreatic trypsin inhibitor (BPTI). The fully reduced TAP refolds spontaneously to form the native structure under a wide variation of redox buffers. The folding intermediates of TAP consist of at least 22 fractions of one-disulfide, two-disulfide, and three-disulfide scrambled isomers. Three species of well-populated one- and two-disulfide intermediates were isolated and structurally characterized. The predominant one-disulfide species contains TAP-(Cys33—Cys55). Two major two-disulfide isomers were TAP-(Cys33—Cys55, Cys15—Cys39) and TAP-(Cys33—Cys55, Cys5—Cys39). Both Cys33—Cys55 and Cys15—Cys39 are native disulfides of TAP. These three species are structural counterparts of BPTI-(Cys30—Cys51), BPTI-(Cys30—Cys51, Cys14—Cys38), and BPTI-(Cys30—Cys51,Cys5—Cys38), which have been shown to be the major intermediates of BPTI folding. In addition, time-course-trapped folding intermediates of TAP, consisting of about 47% one-disulfide species and 30% two-disulfide species, were collectively digested with thermolysin, and fragmented peptides were analyzed by Edman sequencing and mass spectrometry in order to characterize the disulfide-containing peptides. Among the 15 possible single-disulfide pairings of TAP, 10 (2 native and 8 nonnative) were found as structural components of its one- and two-disulfide folding intermediates. The results demonstrate that the major folding intermediates of TAP bear structural homology to those of BPTI. However, the folding pathway of TAP differs from that of BPTI by (a) a higher degree of heterogeneity of one- and two-disulfide intermediates and (b) the presence of three-disulfide scrambled isomers as folding intermediates. Mechanism(s) that may account for these diversities are proposed and discussed.     

A 3-disulfide mutant of mouse prion protein expression, oxidative folding, reductive unfolding, conformational stability, aggregation and isomerization

The structure of wild-type mouse prion protein mPrP(23-231) consists of two distinctive segments with approximately equal size, a disordered and flexible N-terminal domain encompassing residues 23-124 and a largely structured C-terminal domain containing about 40% of helical structure and stabilized by one disulfide bond (Cys(178)-Cys(213)). We have expressed a mPrP mutant with 4 Ala/Ser-->Cys replacements, two each at the N-(Cys(36), Cys(112)) and C-(Cys(134), Cys(169)) domains. Our specific aims are to study the interaction between N- and C-domains of mPrP during the oxidative folding and to produce stabilized isomers of mPrP for further analysis. Oxidative folding of fully reduced mutant, mPrP(6C), generates one predominant 3-disulfide isomer, designated as N-mPrP(3SS), which comprises the native disulfide (Cys(178)-Cys(213)) and two non-native disulfide bonds (Cys(36)-Cys(134) and Cys(112)-Cys(169)) that covalently connect the N- and C-domains. In comparison to wild-type mPrP(23-231), N-mPrP(3SS) exhibits an indistinguishable CD spectra, a similar conformational stability in the absence of thiol and a reduced ability to aggregate. In the presence of thiol catalyst and denaturant, N-mPrP(3SS) unfolds and generates diverse isomers that are amenable to further isolation, structural and functional analysis.     

蛋白质的氧化重折叠

经过近几十年来广泛而深入的研究,蛋白质氧化重折叠的机制已得到相当详细的阐明。1在已研究过的蛋白质中,大多数蛋白质都是沿着多途径而非单一、特定的途径进行氧化重折叠,这与折叠能量景观学说是一致的。2正是氨基酸残基间的天然相互作用而不是非天然的相互作用控制蛋白质的折叠过程。这一结论与含非天然二硫键的折叠中间体在牛胰蛋白酶抑制剂（BPTI）折叠中所起的重要作用并非相互排斥,因为后者仅仅是进行链内二硫键重排的化学反应所必需,与控制肽链折叠无直接关系。3根据对BPTI的研究,二硫键曾被认为仅仅具有稳定蛋白质天然结构的作用,既不决定折叠途径也不决定其三维构象。这一观点不适用于其它蛋白质。对凝乳酶原的研究表明,天然二硫键的形成是恢复天然构象的前提。天然二硫键的形成与肽键的正确折叠相辅相成,更具有普遍意义。4在氧化重折叠的早期,二硫键的形成基本上是一个随机过程,随着肽链的折叠二硫键的形成越来越受折叠中间体构象的限制。提高重组蛋白质的复性产率是生物技术领域中的一个巨大的挑战。除了分子聚集外,在折叠过程中所形成的二硫键错配分子是导致低复性率的另一个主要原因。氧化重折叠机制的阐明为解决此问题提供了有益的启示。如上所述,在折叠的后期,二硫键的形成决定于折叠中间体的构象,类天然、有柔性的结构有利于天然二硫键形成和正确折叠,具有这类结构的分子为有效的折叠中间体,最终都能转变为天然产物;而无效折叠中间体往往具有稳定的结构,使巯基、二硫键内埋妨碍二硫键重排,并因能垒的障碍不利于进一步折叠。因此,降低无效折叠中间体的稳定性使之转变为有效折叠中间体是提高含二硫键蛋白质复性率的一条基本原则,实验证明,碱性pH、低温、降低蛋白质稳定性的试剂、蛋白质二硫键异构酶、改变蛋白质一级结构是实现这一原则的有效手段。此外,这里还就氧化重折叠的基础和应用研究的前景进行了讨论。     

Folding and oxidation of recombinant human granulocyte colony stimulating factor produced in Escherichia coli. Characterization of the disulfide-reduced intermediates and cysteine----serine analogs.

The folding and oxidation of recombinant human granulocyte colony-stimulating factor solubilized from Escherichia coli inclusion bodies was investigated. During the folding process, two intermediates, I1 and I2, were detected by kinetic studies using high performance liquid chromatography. I1 exists transiently and disappears quickly with the concomitant formation of I2. In contrast, I2 requires a longer time to fold into the final oxidized form, N. CuSO4 catalysis increases the folding rate of I2 from I1, while CuSO4 and elevated temperature (37 degrees C) have a dramatic effect on the folding rate of N from I2. These observations suggest the following sequential oxidative folding pathway. [sequence: see text] Peptide map analysis of the iodoacetate-labeled intermediates revealed that I1 represents the fully reduced granulocyte colony-stimulating factor containing 5 free cysteines; I2 is the partially oxidized species containing a single Cys36-Cys42 disulfide bond; and N, the final folded form, has two disulfide bonds. The physicochemical properties and biological activities of I1, I2, N, and several Cys----Ser analogs made by site-directed mutagenesis were further investigated. In guanidine hydrochloride-induced denaturation studies, the disulfide-reduced intermediates and the analogs missing either of the disulfide bonds are conformationally less stable than those of the wild type molecule or the analog with the free Cys at position 17 changed to Ser. Recombinant human granulocyte colony stimulating factor lacking either disulfide bond or both has overall secondary and tertiary structures different from those of the wild type molecule and exhibits lower biological activity. These studies show that disulfide bond formation is crucial for maintaining the molecule in a properly folded and biologically active form.     

Energetics of structural domains in alpha-lactalbumin.

alpha-Lactalbumin is a small, globular protein that is stabilized by four disulfide bonds and contains two structural domains. One of these domains is rich in alpha-helix (the alpha-domain) and has Cys 6-Cys 120 and Cys 28-Cys 111 disulfide bonds. The other domain is rich in beta-sheet (the beta-domain), has Cys 61-Cys 77 and Cys 73-Cys 91 disulfide bonds, and includes one calcium binding site. To investigate the interaction between domains, we studied derivatives of bovine alpha-lactalbumin differing in the number of disulfide bonds, using calorimetry and CD at different temperatures and solvent conditions. The three-disulfide form, having a reduced Cys 6-Cys 120 disulfide bond with carboxymethylated cysteines, is similar to intact alpha-lactalbumin in secondary and tertiary structure as judged by its ellipticity in the near and far UV. the two-disulfide form of alpha-lactalbumin, having reduced Cys 6-Cys 120 and Cys 28-Cys 111 disulfide bonds with carboxymethylated cysteines, retains about half the secondary and tertiary structure of the intact alpha-lactalbumin. The remaining structure is able to bind calcium and unfolds cooperatively upon heating, although at lower temperature and with significantly lower enthalpy and entropy. We conclude that, in the two disulfide form, alpha-lactalbumin retains its calcium-binding beta-domain, whereas the alpha-domain is unfolded. It appears that the beta-domain does not require alpha-domain to fold, but its structure is stabilized significantly by the presence of the adjacent folded alpha-domain.     

AUT凝胶电泳在牛胰核糖核酸酶折叠研究中的应用

目的:牛胰核糖核酸酶是一种用于蛋白折叠研究的经典模式蛋白,在折叠研究过程中主要使用高效液相色谱用于分离检测不同阶段的蛋白折叠中间体。高效液相色谱具有自动化、分离效果好、样品可回收等优点,同时也存在检测通量较低、仪器设备较为昂贵等不足。AUT凝胶电泳简便、快捷、检测通量较高,本文尝试将其应用于牛胰核糖核酸酶的折叠研究。方法:使用AUT凝胶电泳、酶活性检测、质谱对牛胰核糖核酸酶还原变性过程及产生的折叠中间体进行检测;通过高效液相色谱和质谱对折叠中间单体进行分离检测,并分别进行AUT凝胶电泳检测以解析各折叠中间单体在电泳中的条带位置;通过AUT凝胶电泳和酶切后质谱鉴定各折叠中间单体的二硫键配对方式。结果:AUT凝胶电泳可以有效区分不同条件下的牛胰核糖核酸酶还原变性过程,检测结果与酶活性、质谱结果相符,并可以很好地区分牛胰核糖核酸酶还原变性过程折叠中间体。高效液相色谱将牛胰核糖核酸酶还原变性过程折叠中间体分离为13个色谱峰,并与AUT凝胶电泳中的11个条带位置进行匹配。确认牛胰核糖核酸酶还原变性过程折叠中间单体的二硫键配对方式,并与AUT凝胶电泳条带进行匹配,Cys58-Cys110和Cys26-Cys84构象熵减作用强于Cys40-Cys95和Cys65-Cys72。结论:AUT凝胶电泳适用于检测牛胰核糖核酸酶折叠中间体,可以与高效液相色谱、质谱等检测技术相互补充,共同应用于牛胰核糖核酸酶的折叠研究。     

Evidence for difference in the roles of two cysteine residues involved in disulfide bond formation in the folding of human lysozyme

Human lysozyme is made up of 130 amino acid residues and has four disulfide bonds at Cys6-Cys128, Cys30-Cys116, Cys65-Cys81, and Cys77-Cys95. Our previous results using the Saccharomyces cerevisiae secretion system indicate that the individual disulfide bonds of human lysozyme have different functions in the correct in vivo folding and enzymatic activity of the protein (Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M., and Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967). In this paper, we report the results of experiments that were focused on the roles of Cys65 and Cys81 in the folding of human lysozyme protein in yeast. A mutant protein (C81A), in which Cys81 was replaced with Ala, had almost the same enzymatic activity and conformation as those of the native enzyme. On the other hand, another mutant (C65A), in which Cys65 was replaced with Ala, was not found to fold correctly. These results indicate that Cys81 is not a requisite for both correct folding and activity, whereas Cys65 is indispensable. The mutant protein C81A is seen to contain a new, non-native disulfide bond at Cys65-Cys77. The possible occurrence of disulfide bond interchange during our mapping experiments cannot be ruled out by the experimental techniques presently available, but characterization of other mutant proteins and computer analysis suggest that the intramolecular exchange of disulfide bonds is present in the folding pathway of human lysozyme in vivo.