The role of proteolysis in the processing and assembly of 11S seed globulins.

11S seed storage proteins are synthesized as precursors that are cleaved post-translationally in storage vacuoles by an asparaginyl endopeptidase. To study the specificity of the reaction catalyzed by this asparaginyl endopeptidase, we prepared a series of octapeptides and mutant legumin B and G4 glycinin subunits. These contained amino acid mutations in the region surrounding the cleavage site. The endopeptidase had an absolute specificity for Asn on the N-terminal side of the severed peptide bond but exhibited little specificity for amino acids on the C-terminal side. The ability of unmodified and modified subunits to assemble into hexamers after post-translational modification was evaluated. Cleavage of subunits in trimers is required for hexamer assembly in vitro. Products from a mutant gene encoding a noncleavable prolegumin subunit (LeBDeltaN281) accumulated as trimers in seed of transgenic tobacco, but products from the unmodified prolegumin B gene accumulated as hexamers. Therefore, the asparaginyl endopeptidase is required for hexamer assembly.     

Processing and assembly in vitro of engineered soybean beta-conglycinin subunits with the asparagine-glycine proteolytic cleavage site of 11S globulins

A short interdomain sequence between the N- and C-terminal domains of beta-conglycinin, the major 7S seed storage protein of soybean, was selected as a target for insertion of amino acid residues specifically cleaved by an asparaginyl endopeptidase that processes globulins into acidic and basic chains. Modified beta-conglycinin subunits containing the proteolytic cleavage site self-assembled into trimers in vitro at an efficiency similar to that of the unmodified subunit. In contrast to the absence of cleavage of the unmodified subunits, however, the modified beta-conglycinin trimers were processed by purified soybean asparaginyl endopeptidase into two polypeptides, each the size expected for the beta-conglycinin N- and C-terminal domains, respectively. The cleavage did not alter the assembly of mutant beta-conglycinins and the cleaved mutant trimers remained stable to further proteolytic attack. To examine the possibility of coassembly between the cleaved 11S and 7S subunits, in vitro processed mutant beta-conglycinin subunits were mixed with native dissociated 11S globulin preparations. Reassembly at a high ionic condition did not induce the 7S subunits to interact with 11S subunits to form hexameric complexes. Thus, cleavage of 7S globulin subunits into acidic and basic domains may not be sufficient for hexamer assembly to occur. Biotechnological implications of the engineered proteins are discussed.     

Role of posttranslational cleavage in glycinin assembly.

Glycinin, like other 11S seed storage proteins, undergoes a complex series of posttranslational events between the time proglycinin precursors are synthesized in endoplasmic reticulum and the mature glycinin subunits are deposited in vacuolar protein bodies. According to the current understanding of this process, proglycinin subunits aggregate into trimers in endoplasmic reticulum, and then the trimers move to the vacuolar protein bodies where a protease cleaves them into acidic and basic polypeptide chains. Stable glycinin hexamers, rather than trimers, are isolated from mature seeds. We used a re-assembly assay in this study to demonstrate that proteolytic cleavage of the proglycinin subunits is required for in vitro assembly of glycinin oligomers beyond the trimer stage. The possibility that the cleavage is a regulatory step and that it triggers the deposition of 11S seed storage proteins as insoluble aggregates in vivo is considered.     

Zinc enhances adiponectin oligomerization to octadecamers but decreases the rate of disulfide bond formation

Adiponectin, a hormone secreted from adipocytes, has been shown to protect against development of insulin resistance, ischemia–reperfusion injury, and inflammation. Adiponectin assembles into multiple oligomeric isoforms: trimers, hexamers and several higher molecular weight (HMW) species. Of these, the HMW species are selectively decreased during the onset of type 2 diabetes. Despite the critical role of HMW adiponectin in insulin responsiveness, its assembly process is poorly understood. In this report, we investigated the role of divalent cations in adiponectin assembly. Purified adiponectin 18mers, the largest HMW species, did not collapse to smaller oligomers after treatment with high concentrations of EDTA. However, treatment with EDTA or another chelator DTPA inhibited the oligomerization of 18mers from trimers in vitro. Zn²⁺ specifically increased the formation of 18mers when compared with Cu²⁺, Mg²⁺, and Ca²⁺. Distribution of adiponectin oligomers secreted from zinc chelator TPEN-treated rat adipocytes skewed toward increased proportions of hexamers and trimers. While we observed presence of zinc in adiponectin purified from calf serum, the role of zinc in disulfide bonding between oligomers was examined because the process is critical for 18mer assembly. Surprisingly, Zn²⁺ inhibited disulfide bond formation early in the oligomerization process. We hypothesize that initial decreases in disulfide formation rates could allow adiponectin subunits to associate before becoming locked in fully oxidized conformations incapable of further oligomerization. These data demonstrate that zinc stimulates oligomerization of HMW adiponectin and possibly other disulfide-dependent protein assembly processes.     

Cartilage matrix protein forms a type II collagen-independent filamentous network: analysis in primary cell cultures with a retrovirus expression system.

Cartilage matrix protein (CMP) is expressed specifically in mature cartilage and consists of two von Willebrand factor A domains (CMP-A1 and CMP-A2) that are separated by an epidermal growth factor-like domain, and a coiled-coil tail domain at the carboxyl terminal end. We have shown previously that CMP interacts with type II collagen-containing fibrils in cartilage. In this study, we describe a type II collagen-independent CMP filament and we analyze the structural requirement for the formation of this type of filament. Recombinant wild-type CMP and two mutant forms were expressed in chick primary cell cultures using a retrovirus expression system. In chondrocytes, the wild-type virally encoded CMP is able to form disulfide bonded trimers and to assemble into filaments. Filaments also form with CMP whose Cys455 and Cys457 in the tail domain were mutagenized to prevent interchain disulfide bond formation. Therefore, intermolecular disulfide bonds are not necessary for the assembly of CMP into filaments. Both the wild-type and the double cysteine mutant also form filaments in fibroblasts, indicating that chondrocyte-specific factors are not required for filament formation. A truncated form of CMP that consists only of the CMP-A2 domain and the tail domain can form trimers but fails to form filaments, indicating that the deleted CMP-A1 domain and/or the epidermal growth factor domain are necessary for filament assembly but not for trimer formation. Furthermore, the expression of the virally encoded truncated CMP in chondrocyte culture disrupts endogenous CMP filament formation. Together these data suggest a role for CMP in cartilage matrix assembly by forming filamentous networks that require participation and coordination of individual domains of CMP.     

Disulfide bonding among micro 1 trimers in mammalian reovirus outer capsid: a late and reversible step in virion morphogenesis

We examined how a particular type of intermolecular disulfide (ds) bond is formed in the capsid of a cytoplasmically replicating nonenveloped animal virus despite the normally reducing environment inside cells. The micro 1 protein, a major component of the mammalian reovirus outer capsid, has been implicated in penetration of the cellular membrane barrier during cell entry. A recent crystal structure determination supports past evidence that the basal oligomer of micro 1 is a trimer and that 200 of these trimers surround the core in the fenestrated T=13 outer capsid of virions. We found in this study that the predominant forms of micro 1 seen in gels after the nonreducing disruption of virions are ds-linked dimers. Cys679, near the carboxyl terminus of micro 1, was shown to form this ds bond with the Cys679 residue from another micro 1 subunit. The crystal structure in combination with a cryomicroscopy-derived electron density map of virions indicates that the two subunits that contribute a Cys679 residue to each ds bond must be from adjacent micro 1 trimers in the outer capsid, explaining the trimer-dimer paradox. Successful in vitro assembly of the outer capsid by a nonbonding mutant of micro 1 (Cys679 substituted by serine) confirmed the role of Cys679 and suggested that the ds bonds are not required for assembly. A correlation between micro 1-associated ds bond formation and cell death in experiments in which virions were purified from cells at different times postinfection indicated that the ds bonds form late in infection, after virions are exposed to more oxidizing conditions than those in healthy cells. The infectivity measurements of the virions with differing levels of ds-bonded micro 1 showed that these bonds are not required for infection in culture. The ds bonds in purified virions were susceptible to reduction and reformation in situ, consistent with their initial formation late in morphogenesis and suggesting that they may undergo reduction during the entry of reovirus particles into new cells.     

Assembly-defective OmpC mutants of Escherichia coli K-12.

Novel ompC(Dex) alleles were utilized to isolate mutants defective in OmpC biogenesis. These ompC(Dex) alleles also conferred sensitivity to sodium dodecyl sulfate (SDS), which permitted the isolation of SDS-resistant and OmpC-specific phage-resistant mutants that remained Dex+. Many mutants acquired resistance against these lethal agents by lowering the OmpC level present in the outer membrane. In the majority of these mutants, a defect in the assembly (metastable to stable trimer formation) was responsible for lowering OmpC levels. The assembly defects in various mutant OmpC proteins were caused by single-amino-acid substitutions involving the G-39, G-42, G-223, G-224, Q-240, G-251, and G-282 residues of the mature protein. This assembly defect was correctable by an assembly suppressor allele, asmA3. In addition, we investigated one novel OmpC mutant in which an assembly defect was caused by a disulfide bond formation between two nonnative cysteine residues. The assembly defect was fully corrected in a genetic background in which the cell's ability to form disulfide bonds was compromised. The assembly defect of the two-cysteine OmpC protein was also mended by asmA3, whose suppressive effect was not achieved by preventing disulfide bond formation in the mutant OmpC protein.     

Crystal structure of allophycocyanin from red algae Porphyra yezoensis at 2.2-A resolution.

The crystal structure of allophycocyanin from red algae Porphyra yezoensis (APC-PY) at 2.2-A resolution has been determined by the molecular replacement method. The crystal belongs to space group R32 with cell parameters a = b = 105.3 A, c = 189.4 A, alpha = beta = 90 degrees, gamma = 120 degrees. After several cycles of refinement using program X-PLOR and model building based on the electron density map, the crystallographic R-factor converged to 19.3% (R-free factor is 26.9%) in the range of 10.0 to 2.2 A. The r.m.s. deviations of bond length and angles are 0.015 A and 2.9 degrees, respectively. In the crystal, two APC-PY trimers associate face to face into a hexamer. The assembly of two trimers within the hexamer is similar to that of C-phycocyanin (C-PC) and R-phycoerythrin (R-PE) hexamers, but the assembly tightness of the two trimers to the hexamer is not so high as that in C-PC and R-PE hexamers. The chromophore-protein interactions and possible pathway of energy transfer were discussed. Phycocyanobilin 1alpha84 of APC-PY forms 5 hydrogen bonds with 3 residues in subunit 2beta of another monomer. In R-PE and C-PC, chromophore 1alpha84 only forms 1 hydrogen bond with 2beta77 residue in subunit 2beta. This result may support and explain great spectrum difference exists between APC trimer and monomer.     

Elimination of disulfide bonds affects assembly and secretion of the human chorionic gonadotropin beta subunit

Human chorionic gonadotropin (hCG) consists of two noncovalently joined alpha and beta subunits similar to the other glycoprotein hormones. To study the function of the individual disulfide bonds in subunit assembly and secretion, site-directed mutagenesis was used to convert the 12 cysteine (Cys) residues in the beta subunit of hCG to either alanine or serine. Both cysteines of proposed disulfide pairs were also mutated. These mutant hCG beta genes were transfected alone or together with the wild-type alpha gene into Chinese hamster ovary cells. Only 3-10% assembly could be achieved with derivatives containing single Cys mutations at positions 26, 110, 72, and 90, whereas no assembly was detected with the other 8 mutants. However, double mutations of pairs 26-110 or 23-72 showed increased dimer formation (11 and 36%, respectively). The secretion rate of individual mutants varied significantly. Whereas the Cys-23 and 72 mutants were secreted normally (t1/2 = 140-190 min), the Cys-26 mutant was secreted faster (t1/2 = 70 min), and the other 9 mutants were secreted slower (t1/2 = 280-440 min); mutations of both Cys at 26 and 110 caused much faster secretion (t1/2 = 34 min). Although the secretion rate of these mutants differed, they were quantitatively recovered in the medium except for mutant Cys-88, Cys-23-72, and Cys-34-88 (40, 55, and 10% secreted, respectively). Thus, interruption of any disulfide bond in the hCG beta subunit alters the structure sufficiently to block dimer formation and in some cases slow secretion, although the stability for most of the mutant hCG beta subunits is not greatly affected. The data indicate that interruption of any hCG beta disulfide bond generates different structural forms that are unable to assemble with the alpha subunit, and that the structural requirements for stability and assembly are different.     

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.     

The legumin precursor from white lupin seed. Identity of the subunits, assembly and proteolysis.

The precursors of the legumin-like storage protein from developing white lupin seeds (35 days after flowering) are trimers composed of protomers of M(r) 72,000 or 67,000. Some subunits of these oligomers contain processed precursor polypeptides, namely alpha polypeptides of either 52,000 or 44,000 linked through disulphide bonds to a beta polypeptide of 21,000, typical of the mature legumin. The prolegumin is glycosylated. Legumin oligomers purified from the same seeds are both trimers and hexamers; some of their subunits are still made of precursor polypeptides. The hexamer contains less precursor polypeptide than the trimer. A low level or absence of precursor appears to be a condition of hexamer assembly. The heterogenous prolegumin and legumin oligomers represent intermediates in the processing of the prolegumin to mature legumin. Hydrophobic-interaction chromatography on TSK-phenyl-5PW and titration with the hydrophobic probe 8-anilino-1-naphthalenesulphonate indicate that the legumin is less hydrophobic than the prolegumin. This is attributed to structural rearrangements at processing of the propolypeptide, made evident by the behaviour in CD and by the second-derivative ultraviolet spectra of the two proteins. The total protein extract of developing cotyledons at 40 days after flowering contains endopeptidases, similar to those existing in the resting seeds, which cause a limited cascade degradation of the prolegumin and legumin.     

Assembly of mutant subunits of the nicotinic acetylcholine receptor lacking the conserved disulfide loop structure.

Each subunit of the nicotinic acetylcholine receptor (AChR) contains two conserved cysteine residues, which are known to form a disulfide bond, in the N-terminal extracellular domain. The role of this retained structural feature in the biogenesis of the AChR was studied by expressing site-directed mutant alpha and beta subunits together with other normal subunits from Torpedo californica AChR in Xenopus oocytes. Mutation of the cysteines at position 128 or 142 in the alpha subunit, or in the beta subunit, did not prevent subunit assembly. All Cys128 and Cys142 mutants of the alpha and beta subunits were able to associate with coexpressed other normal subunits, although associational efficiency of the mutant alpha subunits with the delta subunit was reduced. Functional studies of the mutant AChR complexes showed that the mutations in the alpha subunit abolished detectable 125I-alpha-bungarotoxin (alpha-BuTX) binding in whole oocytes, whereas the mutations in the beta subunit resulted in decreased total binding of 125I-alpha-BuTX and no detectable surface 125I-alpha-BuTX binding. Additionally, all mutant subunits, when co-expressed with the other normal subunits in oocytes, produced small acetylcholine-activated membrane currents, suggesting incorporation of only small numbers of functional mutant AChRs into the plasma membrane. The functional acetylcholine-gated ion channel formed with mutant alpha subunits, but not mutant beta subunits, could not be blocked by alpha-BuTX. Thus, a disulfide bond between Cys128 and Cys142 of the AChR alpha or beta subunits is not needed for acetylcholine-binding. However, this disulfide bond on the alpha subunit is necessary for formation of the alpha-BuTX-binding site. These results also suggest that the most significant effect caused by disrupting the conserved disulfide loop structure is intracellular retention of most of the assembled AChR complexes.     

Quaternary structure of oligomeric immunoglobulin A forms from human blood serum]

A character of forces stabilyzing quaternary structure of dimer and more high molecular human immunoglobulin A oligomers is found to be different. Quaternary structure of IgA dimer is formed when joining subunits with disulfide bonds and is stabilized by non-covalent interactions between them. Disulfide bonds play a main part in the formation of trimers and tetramers. Dimer IgA reconstructs by 40% from subunits with intact interchain S--S bonds. The addition of exogenous J-chain does not significantly affect the process of dimer self-assembling from subunits with recovered and intact interchain disulfide bonds.     

Gamma-interferon-inducible lysosomal thiol reductase (GILT). Maturation, activity, and mechanism of action

We recently identified a gamma-interferon-inducible lysosomal thiol reductase (GILT), constitutively expressed in antigen-presenting cells, that catalyzes disulfide bond reduction both in vitro and in vivo and is optimally active at acidic pH. GILT is synthesized as a 35-kDa precursor, and following delivery to major histocompatibility complex (MHC) class II-containing compartments (MIICs), is processed to the mature 30-kDa form via cleavage of N- and C-terminal propeptides. The generation of MHC class II epitopes requires both protein denaturation and reduction of intra- and inter-chain disulfide bonds prior to proteolysis. GILT may be important in disulfide bond reduction of proteins delivered to MIICs and consequently in antigen processing. In this report we show that, like its mature form, precursor GILT reduces disulfide bonds with an acidic pH optimum, suggesting that it may also be involved in disulfide bond reduction in the endocytic pathway. We also show that processing of precursor GILT can be mediated by multiple lysosomal proteases and provide evidence that the mechanism of action of GILT resembles that of other thiol oxidoreductases.     

Contribution of the Disulfide Bond of the A Subunit to the Action of Escherichia coli Heat-Labile Enterotoxin

Escherichia coli heat-labile enterotoxin (LT) consists of an A subunit and five B subunits. These subunits oligomerize into an assembled holotoxin within the periplasm. Structural analysis of LT has revealed that the A subunit interacts with the B subunit through its carboxy terminus. This indicates that the carboxy-terminal portion of the protein is required for assembly of holotoxin in the periplasm. However, it is not known whether other regions of the A subunit contribute to the assembly. The A subunit constituting the holotoxin contains a disulfide bond between Cys-187 and Cys-199. It has been observed in many proteins that the intramolecular disulfide bond is deeply involved in the function and tertiary structure of the protein. We speculated that the disulfide bond of the A subunit contributes to the assembly in the periplasm, although the bond is not a structural element of the carboxy-terminal portion of the A subunit. We replaced these cysteine residues of the A subunit by oligonucleotide-directed site-specific mutagenesis and analyzed the LTs produced by cells containing the mutant LT genes. The amount of the mutant holotoxin produced was small compared with that of the wild-type strain, indicating that the disulfide bond of the A subunit contributes to the structure which functions as the site of nucleation in the assembly. A reconstitution experiment in vitro supported the notion. Subsequently, we found that the mutant A subunit constituting holotoxin is easily degraded by trypsin and that in cells incubated with mutant LTs, the lag until the intracellular cyclic AMP begins to accumulate is longer than in cells incubated with native LTs. These results might be useful for the analysis of the interaction of LT with target cells at the molecular level.     

Crystal structure of soybean proglycinin A1aB1b homotrimer

Soybean glycinin is a member of the 11 S globulin family. The crystal structure of proglycinin was determined by X-ray crystallography at 2.8 A resolution with an R-factor of 0.199 and a free R-factor of 0.250. A trimer molecule was found in an asymmetric unit of crystals. The trimer model contains three A1aB1b subunits and comprises 1128 amino acid residues and 34 water molecules. The constituent protomers of the homo-trimeric protein are arranged around a 3-fold symmetry axis with dimensions of 95 Ax95 Ax40 A. The protomer model is composed of five fragments which correspond roughly to conserved regions based on the sequence alignment of various 11 S globulins. The core of the protomer consists of two jelly-roll beta-barrels and two extended helix domains. This structure of proglycinin is similar to those of canavalin and phaseolin belonging to the 7 S globulin family, strongly supporting the hypothesis that both 7 S and 11 S globulins are derived from a common ancestor. The inter and intra-chain disulfide bonds conserved in the 11 S globulin family are clearly observed. It is found that the face with the inter-chain disulfide bond (IE face) contains more hydrophobic residues than that with the intra-chain disulfide bond. This suggests that a mature hexamer is formed by the interaction between the IE faces after processing.     

Accumulation of β-conglycinin in soybean cotyledon through the formation of disulfide bonds between α'- and α-subunits

β-Conglycinin, one of the major soybean (Glycine max) seed storage proteins, is folded and assembled into trimers in the endoplasmic reticulum and accumulated into protein storage vacuoles. Prior experiments have used soybean β-conglycinin extracted using a reducing buffer containing a sulfhydryl reductant such as 2-mercaptoethanol, which reduces both intermolecular and intramolecular disulfide bonds within the proteins. In this study, soybean proteins were extracted from the cotyledons of immature seeds or dry beans under nonreducing conditions to prevent the oxidation of thiol groups and the reduction or exchange of disulfide bonds. We found that approximately half of the α'- and α-subunits of β-conglycinin were disulfide linked, together or with P34, prior to amino-terminal propeptide processing. Sedimentation velocity experiments, size-exclusion chromatography, and two-dimensional polyacrylamide gel electrophoresis (PAGE) analysis, with blue native PAGE followed by sodium dodecyl sulfate-PAGE, indicated that the β-conglycinin complexes containing the disulfide-linked α'/α-subunits were complexes of more than 720 kD. The α'- and α-subunits, when disulfide linked with P34, were mostly present in approximately 480-kD complexes (hexamers) at low ionic strength. Our results suggest that disulfide bonds are formed between α'/α-subunits residing in different β-conglycinin hexamers, but the binding of P34 to α'- and α-subunits reduces the linkage between β-conglycinin hexamers. Finally, a subset of glycinin was shown to exist as noncovalently associated complexes larger than hexamers when β-conglycinin was expressed under nonreducing conditions.     

Assembled F1-(alpha beta ) and Hybrid F1-alpha 3beta 3gamma -ATPases from Rhodospirillum rubrum alpha, wild type or mutant beta, and chloroplast gamma subunits. Demonstration of Mg2+versus Ca2+-induced differences in catalytic site structure and function

Refolding together the expressed alpha and beta subunits of the Rhodospirillum rubrum F(1)(RF(1))-ATPase led to assembly of only alpha(1)beta(1) dimers, showing a stable low MgATPase activity. When incubated in the presence of AlCl(3), NaF and either MgAD(T)P or CaAD(T)P, all dimers associated into closed alpha(3)beta(3) hexamers, which also gained a low CaATPase activity. Both hexamer ATPase activities exhibited identical rates and properties to the open dimer MgATPase. These results indicate that: a) the hexamer, as the dimer, has no catalytic cooperativity; b) aluminium fluoride does not inhibit their MgATPase activity; and c) it does enable the assembly of RrF(1)-alpha(3)beta(3) hexamers by stabilizing their noncatalytic alpha/beta interfaces. Refolding of the RrF(1)-alpha and beta subunits together with the spinach chloroplast F(1) (CF(1))-gamma enabled a simple one-step assembly of two different hybrid RrF(1)-alpha(3)beta(3)/CF(1)gamma complexes, containing either wild type RrF(1)-beta or the catalytic site mutant RrF(1)beta-T159S. They exhibited over 100-fold higher CaATPase and MgATPase activities than the stabilized hexamers and showed very different catalytic properties. The hybrid wild type MgATPase activity was, as that of RrF(1) and CF(1) and unlike its higher CaATPase activity, regulated by excess free Mg(2+) ions, stimulated by sulfite, and inhibited by azide. The hybrid mutant had on the other hand a low CaATPase but an exceptionally high MgATPase activity, which was much less sensitive to the specific MgATPase effectors. All these very different ATPase activities were regulated by thiol modulation of the hybrid unique CF(1)-gamma disulfide bond. These hybrid complexes can provide information on the as yet unknown factors that couple ATP binding and hydrolysis to both thiol modulation and rotational motion of their CF(1)-gamma subunit.     

Effect of structural modifications on the assembly of a glycinin subunit.

A Gy4 glycinin cDNA was modified and used to produce structurally altered 11S storage protein subunits. We evaluated these modified subunits for their ability to assemble into oligomers. Alterations made in the acidic polypeptide changed the subunit solubility characteristics but did not eliminate assembly. Modifications in the basic polypeptide usually eliminated assembly of subunits into trimers. A region exhibiting high natural variability located at the COOH terminus of the acidic polypeptide that we have designated the hypervariable region was also studied. Extensive deletions and insertions were tolerated in the hypervariable region without perturbing subunit assembly. Some of the insertions significantly increased the methionine content in the Gy4 glycinin subunit. Together, our results indicated that the structure of the basic polypeptide was more critical for assembly of trimers than that of the acidic polypeptide, an observation that implies that the basic polypeptides direct trimer formation. The assembly assays described here will be useful in efforts to improve seed quality. Using them, the effects of modifications to the storage protein subunits can be rapidly evaluated before introducing the mutated genes into plants.     

Multiple equilibria of the Escherichia coli chaperonin GroES revealed by mass spectrometry

Nanospray time-of-flight mass spectrometry has been used to study the assembly of the heptamer of the Escherichia coli cochaperonin protein GroES, a system previously described as a monomer-heptamer equilibrium. In addition to the monomers and heptamers, we have found measurable amounts of dimers and hexamers, the presence of which suggests the following mechanism for heptamer assembly: 2 Monomers <--> Dimer; 3 Dimers <--> Hexamer; Hexamer + Monomer <--> Heptamer. Equilibrium constants for each of these steps, and an overall constant for the Monomer <--> Heptamer equilibrium, have been estimated from the data. These constants imply a standard free-energy change, DeltaG(0), of about 9 kcal/mol for each contact surface formed between GroES subunits, except for the addition of the last subunit, where DeltaG(0) = 6 kcal/mol. This lower value probably reflects the loss of entropy when the heptamer ring is formed. These experiments illustrate the advantages of electrospray mass spectrometry as a method of measuring all components of a multiple equilibrium system.