Sequential action of mitochondrial chaperones in protein import into the matrix.

Translocation and folding of proteins imported into mitochondria are mediated by two matrix-localized chaperones, mhsp70 and hsp60. In order to investigate whether these chaperones act sequentially or in parallel, we studied their interaction with newly imported precursor proteins in isolated yeast mitochondria by coimmunoprecipitation. All precursors bound transiently to mhsp70. Release from mhsp70 required hydrolysis of ATP and did not immediately generate a tightly folded protein. For example, after imported mouse dihydrofolate reductase (a soluble monomeric enzyme) had been released from mhsp70, folding to a protease resistant conformation occurred only after a lag and was much slower than the release. Under standard import conditions, no significant association of DHFR with hsp60 could be detected. Similarly, newly imported hsp60 subunit was released from mhsp70 as an incompletely folded, unassembled intermediate which accumulated at low temperature and assembled to hsp60 14-mer at higher temperature in an ATP-dependent manner. Mas2p (the larger subunit of the MAS-encoded processing protease) first bound to mhsp70, then to hsp60, and only then assembled with its partner subunit, Mas1p. We propose that ATP-dependent release from mhsp70 is insufficient to cause folding of imported proteins and that assembly of hsp60 and Mas2p requires sequential, ATP-dependent interactions with mhsp70 and hsp60.     

The role of the N-terminal propeptide of the pro-aminopeptidase processing protease: refolding,processing, and enzyme inhibition

Pro-aminopeptidase processing protease (PA protease) is an extracellular zinc metalloprotease produced by Aeromonas caviae T-64 and it is classified as M04.016 according to the MEROPS database. The precursor of PA protease consists of four regions; a signal peptide, an N-terminal propeptide, a C-terminal propeptide, and the mature PA protease. The in vitro refolding of the intermediate pro-PA protease containing the C-terminal propeptide (MC) was investigated in the presence and absence of the N-terminal propeptide. The results indicate that the noncovalently linked N-terminal propeptide is able to assist in the refolding of MC. In the absence of the N-terminal propeptide, MC is trapped into a folding competent state that is converted into the active form by the addition of the N-terminal propeptide. Moreover, the N-terminal propeptide was found to form a complex with the folded MC and inhibit further processing of MC into the mature PA protease. Inhibitory activity of the purified N-terminal propeptide toward mature PA protease was also observed, and the mode of this inhibition was determined to be a mixed, noncompetitive inhibition with an associated allosteric effect.     

alpha-lytic protease precursor: characterization of a structured folding intermediate

The bacterial alpha-lytic protease (alphaLP) is synthesized as a precursor containing a large N-terminal pro region (Pro) transiently required for correct folding of the protease [Silen, J. L., and Agard, D. A. (1989) Nature 341, 462-464]. Upon folding, the precursor is autocatalyticly cleaved to yield a tight-binding inhibitory complex of the pro region and the fully folded protease (Pro/alphaLP). An in vitro purification and refolding protocol has been developed for production of the disulfide-bonded precursor. A combination of spectroscopic approaches have been used to compare the structure and stability of the precursor with either the Pro/alphaLP complex or isolated Pro. The precursor and complex have significant similarities in secondary structure but some differences in tertiary structure, as well as a dramatic difference in stability. Correlations with isolated Pro suggest that the pro region part of the precursor is fully folded and acts to stabilize and structure the alphaLP region. Precursor folding is shown to be biphasic with the fast phase matching the rate of pro region folding. Further, the rate-limiting step in oxidative folding is formation of the disulfide bonds and autocatalytic processing occurs rapidly thereafter. These studies suggests a model in which the pro region folds first and catalyzes folding of the protease domain, forming the active site and finally causing autocatalytic cleavage of the bond separating pro region and protease. This last processing step is critical as it allows the protease N-terminus to rearrange, providing the majority of net stabilization of the product Pro/alphaLP complex.     

General function of N-terminal propeptide on assisting protein folding and inhibiting catalytic activity based on observations with a chimeric thermolysin-like protease

Pro-aminopeptidase processing protease (PA protease) is a thermolysin-like metalloprotease produced by Aeromonas caviae T-64. The N-terminal propeptide acts as an intramolecular chaperone to assist the folding of PA protease and shows inhibitory activity toward its cognate mature enzyme. Moreover, the N-terminal propeptide strongly inhibits the autoprocessing of the C-terminal propeptide by forming a complex with the folded intermediate pro-PA protease containing the C-terminal propeptide (MC). In order to investigate the structural determinants within the N-terminal propeptide that play a role in the folding, processing, and enzyme inhibition of PA protease, we constructed a chimeric pro-PA protease by replacing the N-terminal propeptide with that of vibriolysin, a homologue of PA protease. Our results indicated that, although the N-terminal propeptide of vibriolysin shares only 36% identity with that of PA protease, it assists the refolding of MC, inhibits the folded MC to process its C-terminal propeptide, and shows a stronger inhibitory activity toward the mature PA protease than that of PA protease. These results suggest that the N-terminal propeptide domains in these thermolysin-like proteases may have similar functions, in spite of their primary sequence diversity. In addition, the conserved regions in the N-terminal propeptides of PA protease and vibriolysin may be essential for the functions of the N-terminal propeptide.     

The pro-sequence domain of streptopain directs the folding of the mature enzyme

The cysteine endopeptidase streptopain, an extracellular enzyme from pathogenic Streptococcus pyogenes, is synthesized as a precursor containing an NH2-terminal pro-sequence. The pro-sequence of streptopain was expressed in Escherichia coli and subjected to structural and functional investigation. Heat-induced denaturation of the pro-sequence studied using circular dichroism spectroscopy revealed that it forms a compact structure and represents an independently folded domain. The isolated pro-sequence exhibits high affinity towards mature streptopain and associates with its cognate enzyme by forming an equimolar complex. Refolding of denatured streptopain in the presence of pro-sequence in vitro facilitated recovery of active enzyme. Expression of the mature streptopain in E. coli either alone, or in trans with its pro-sequence as an independent polypeptide, led to the formation of insoluble protein aggregates or functionally active enzyme, respectively. These results demonstrate that the pro-sequence domain acts as an intramolecular chaperone that directs the correct folding of the mature streptopain.     

Pro-sequence and Ca2+-binding: implications for folding and maturation of Ntn-hydrolase penicillin amidase from E. coli

Penicillin amidase (PA) is a bacterial periplasmic enzyme synthesized as a pre-pro-PA precursor. The pre-sequence mediates membrane translocation. The intramolecular pro-sequence is expressed along with the A and B chains but is rapidly removed in an autocatalytic manner. In extensive studies we show here that the pro-peptide is required for the correct folding of PA. Pro-PA and PA unfold via a biphasic transition that is more pronounced in the case of PA. According to size-exclusion chromatography and limited proteolysis experiments, the inflection observed in the equilibrium unfolding curves corresponds to an intermediate in which the N-terminal domain (A-chain) still possesses native-like topology, whereas the B-chain is unfolded to a large extent. In a series of in vitro experiments with a slow processing mutant pro-PA, we show that the pro-sequence in cis functions as a folding catalyst and accelerates the folding rate by seven orders of magnitude. In the absence of the pro-domain the PA refolds to a stable inactive molten globule intermediate that has native-like secondary but little tertiary structure. The pro-sequence of the homologous Alcaligenes faecalis PA can facilitate the folding of the hydrolase domain of Escherichia coli PA when added in trans (as a separate polypeptide chain). The isolated pro-sequence has a random structure in solution. However, difference circular dichroism spectra of native PA and native PA with pro-peptide added in trans suggest that the pro-sequence adopts an alpha-helical conformation in the context of the mature PA molecule. Furthermore, our results establish that Ca2+, found in the crystal structure, is not directly involved in the folding process. The cation shifts the equilibrium towards the native state and facilitates the autocatalytic processing of the pro-peptide.     

Mitochondrial import of rat pre-ornithine transcarbamylase: accurate processing of the precursor form is not required for uptake into mitochondria, nor assembly into catalytically active enzyme

Mitochondrial uptake of the cytoplasmically synthesized precursor of the mammalian enzyme ornithine transcarbamylase is mediated by an N-terminal leader sequence of 32 amino acids. In the mitochondrial matrix, the precursor form is processed to the mature subunit by proteolytic removal of this pre-sequence and in the enzyme from rat liver it has been suggested that this occurs in a two-step process which involves an intermediate cleavage at residue 24. We show that deletion of residues 20-26 spanning this intermediate cleavage site prevents correct processing to the mature subunit but it does not prevent mitochondrial targeting and internalization or assembly of the incorrectly processed product into a catalytically active enzyme. The incorrectly processed enzyme, which is larger than the normal mature enzyme, is nevertheless more susceptible to proteolytic degradation in permanently transfected human cells than the correctly processed enzyme.     

The Escherichia coli heat shock proteins GroEL and GroES modulate the folding of the beta-lactamase precursor.

One of the fundamental problems in biochemistry is the role of accessory proteins in the process of protein folding. The Escherichia coli heat shock protein complex GroEL/ES has been suggested to be a 'chaperonin' and be involved in both oligomer assembly as well as protein transport through the membrane. We show here that the folding of the purified precursor of beta-lactamase is inhibited by purified GroEL or the GroEL/ES complex with a stoichiometry of one particle per molecule of pre-beta-lactamase. Purified GroES alone has no effect on folding. After Mg2+ ATP addition folding resumes and the yield of active enzyme is higher than in the absence of GroEL or GroEL/ES. Unexpectedly, GroEL or GroEL/ES, when added to folded pre-beta-lactamase, lead to an apparent net 'unfolding', probably to a collapsed state of the protein, which can be reversed by the addition of Mg2+ ATP. The reversible and Mg2+ ATP-dependent association of GroEL/ES with non-native proteins might explain its postulated role in both protein transport and oligomer assembly.     

Aggregation and assembly of phage P22 temperature-sensitive coat protein mutants in vitro mimic the in vivo phenotype

Aggregation is a common side reaction in the folding of proteins which is likely due to inappropriate interactions of folding intermediates. In the in vivo folding of phage P22 coat protein, amino acid substitutions that cause a temperature-sensitive-folding (tsf) phenotype lead to the localization of the mutant coat proteins to inclusion bodies. Investigated here is the aggregation of wild-type (WT) coat protein and 3 tsf mutants of coat protein. The tsf coat proteins aggregated when refolded in vitro at high temperature. If the tsf coat proteins were refolded at 4 degrees C, they were able attain an assembly active state. WT coat protein, on the other hand, did not aggregate significantly even when folded at high temperature. The refolded tsf mutants exhibited altered secondary and tertiary structures and had an increased surface hydrophobicity, which may explain the increased propensity of their folding intermediates to aggregate.     

RNA-dependent folding and stabilization of C5 protein during assembly of the E. coli RNase P holoenzyme

The pre-tRNA processing enzyme ribonuclease P is a ribonucleoprotein. In Escherichia coli assembly of the holoenzyme involves binding of the small (119 amino acid residue) C5 protein to the much larger (377 nucleotide) P RNA subunit. The RNA subunit makes the majority of contacts to the pre-tRNA substrate and contains the active site; however, binding of C5 stabilizes P RNA folding and contributes to high affinity substrate binding. Here, we show that RNase P ribonucleoprotein assembly also influences the folding of C5 protein. Thermal melting studies demonstrate that the free protein population is a mixture of folded and unfolded conformations under conditions where it assembles quantitatively with the RNA subunit. Changes in the intrinsic fluorescence of a unique tryptophan residue located in the folded core of C5 provide further evidence for an RNA-dependent conformational change during RNase P assembly. Comparisons of the CD spectra of the free RNA and protein subunits with that of the holoenzyme provide evidence for changes in P RNA structure in the presence of C5 as indicated by previous studies. Importantly, monitoring the temperature dependence of the CD signal in regions of the holoenzyme spectra that are dominated by protein or RNA structure permitted analysis of the thermal melting of the individual subunits within the ribonucleoprotein. These analyses reveal a significantly higher Tm for C5 when bound to P RNA and show that unfolding of the protein and RNA are coupled. These data provide evidence for a general mechanism in which the favorable free energy for formation of the RNA-protein complex offsets the unfavorable free energy of structural rearrangements in the RNA and protein subunits.     

Folding and assembly of the Escherichia coli succinyl-CoA synthetase heterotetramer without participation of molecular chaperones.

Succinyl-CoA synthetase of Escherichia coli (alpha 2B2 subunit structure) has been shown to fold and assemble without participation by molecular chaperones. Renaturation experiments showed that purified bacterial chaperone GroEL has no effect on the folding and assembly of the active tetrameric enzyme. When isolated 35S-labeled alpha or beta subunits were incubated with GroEL in the absence of ATP, there was no complex formation between the subunits and GroEL. These in vitro results were confirmed by in vivo analysis of the folding and assembly of newly synthesized succinyl-CoA synthetase subunits. When expression of the subunits was induced in E. coli strains that bear GroEL or GroES temperature-sensitive mutations, the assembly of active succinyl-CoA synthetase was not affected as the temperature was raised to 43 degrees C. These and other observations are discussed that indicate that folding and assembly of succinyl-CoA synthetase may be independent of assistance by any chaperone.     

In vitro folding/unfolding of insulin/single-chain insulin

Insulin is a double-chain (designated A and B chain respectively) protein hormone containing three disulfides, while insulin is synthesized in vivo as a single-chain precursor and folded well before being released from B-cells. Although the structure and function of insulin have been well characterized, the progress in oxidative folding pathway studies of insulin has been very slow, mainly due to the difficulties brought about by its disulfide-linked double-chain structure. To overcome these difficulties, we recently studied the in vitro oxidative folding process of two single-chain insulins: porcine insulin precursor (PIP) and human proinsulin (HPI). Based on the analysis of the intermediates captured during folding process, the folding pathways have been proposed for PIP and HPI separately. Similarities between the two folding pathways disclose some common principles that govern the insulin folding process. The following unfolding studies of PIP and HPI further indicate that C-peptide might also function during the folding of proinsulin. Here, we gave a brief review on in vitro folding/unfolding process of insulin and single-chain insulin. The implication of these studies on protein folding has also been discussed.     

Identification of a new active site for autocatalytic processing of penicillin acylase precursor in Escherichia coli ATCC11105

Penicillin acylase (PA) from Escherichia coli ATCC11105 is a periplasmic heterodimer consisting of a 24 kDa small subunit and a 65 kDa large subunit. It is synthesized as a single 96 kDa precursor and then matures to functional PA via a posttranslational processing pathway. The GST-PA fusion protein expression system was established for monitoring the precursor PA processing in vitro. The purified PA precursor was processed into mature PA the same way as in vivo, but pH dependently. From the primary sequence analysis, we identified a putative conserved lysine residue (K299) responsible for the pH dependent processing. The substitution of K299 residue by site-directed mutagenesis affected both the enzyme activity and the precursor PA processing in vivo. Furthermore, it was shown that the processing rates of wild-type and mutant precursor PAs depended on the pKa values of their side chain R group. These results demonstrated that the lysine residue (K299) was involved in the precursor processing of PA together with N-terminal serine residue (S290) of the large subunit.     

Alpha-glucosidase inhibitors reduce dengue virus production by affecting the initial steps of virion morphogenesis in the endoplasmic reticulum

We report that endoplasmic reticulum alpha-glucosidase inhibitors have antiviral effects on dengue (DEN) virus. We found that glucosidase inhibition strongly affects productive folding pathways of the envelope glycoproteins prM (the intracellular glycosylated precursor of M [membrane protein]) and E (envelope protein): the proper folding of prM bearing unprocessed N-linked oligosaccharide is inefficient, and this causes delayed formation of prME heterodimer. The complexes formed between incompletely folded prM and E appear to be unstable, leading to a nonproductive pathway. Inhibition of alpha-glucosidase-mediated N-linked oligosaccharide trimming may thus prevent the assembly of DEN virus by affecting the early stages of envelope glycoprotein processing.     

Autocatalytic processing of gamma-glutamyltranspeptidase

gamma-Glutamyltranspeptidase is the key enzyme in glutathione metabolism, and we previously presented evidence suggesting that it belongs to the N-terminal nucleophile hydrolase superfamily. Enzymatically active gamma-glutamyltranspeptidase, which consists of one large subunit and one small subunit, is generated from an inactive common precursor through post-translational proteolytic processing. The processing mechanism for gamma-glutamyltranspeptidase of Escherichia coli K-12 has been analyzed by means of in vitro studies using purified precursors. Here we show that the processing of a precursor of gamma-glutamyltranspeptidase is an intramolecular autocatalytic event and that the catalytic nucleophile for the processing reaction is the oxygen atom of the side chain of Thr-391 (N-terminal residue of the small (beta) subunit), which is also the nucleophile for the enzymatic reaction.     

Characterization of the alpha-peptide released upon protease activation of pyruvate oxidase

The pyruvate oxidase of Escherichia coli is a homo-tetrameric enzyme which can be activated greater than 500-fold (kcat/Km) by limited proteolytic digestion with alpha-chymotrypsin in the presence of pyruvate and thiamine pyrophosphate. The cleavage produces an Mr 2000 peptide (the alpha-peptide) from each subunit and mimics the physiologically important activation of the enzyme by phospholipids. Moreover, the proteolytic cleavage results in the loss of the high affinity lipid-binding site of the enzyme. We now report the isolation and characterization of the alpha-peptide fragment which is cleaved from the carboxyl terminus of each subunit by protease activation. Both the site of cleavage and the sequence of the alpha-peptide have been determined by a combination of Edman degradation of the purified peptide and DNA sequence analysis of the gene encoding the oxidase. The cleavage site lies within a sequence of hydrophobic amino acids predicted to form a beta-sheet. Another segment of the alpha-peptide is predicted to form an amphipathic alpha-helix. Quantitative assessment of the amphipathic nature of this alpha-helix (Eisenberg, D. (1984) Annu. Rev. Biochem. 53, 595-623) gives a value very similar to the values for several helical peptides which spontaneously bind to the surface of phospholipid vesicles. From these analyses, we propose that the alpha-peptide may play a role in binding pyruvate oxidase to cell membrane phospholipids in vivo.     

The glycoprotein precursor of concanavalin A is converted to an active lectin by deglycosylation.

We have previously shown that concanavalin A is synthesized as a glycoprotein precursor that is unable to bind to sugars and is processed through six intermediate forms before assembly of the mature active lectin. Since processing involves removal of the N-glycan, four proteolytic steps and a religation, the precise event that leads to carbohydrate binding activity was not known. We have now purified the glycoprotein precursor from microsomal membranes and show that deglycosylation in vitro is sufficient alone to convert the precursor to an active carbohydrate binding protein. This is the first demonstration of a novel role for N-glycans and N-glycanases in the regulation of protein activity.     

Isolation of point mutations that affect the folding of the H chain of human ferritin in E.coli.

We have approached the problem of folding and assembly of the heavy (H) chain of human ferritin by isolating point mutations that affect this process. Apoferritin is an ideal model system to approach the problem of protein folding and assembly into multimeric structures. We have developed a recombinant hybrid molecule that allows us to select for ferritin mutants in which the folding-assembly process is altered or completely impaired. The selection procedure is based on a recombinant protein which consists of a fusion between the H chain of human ferritin and the alpha-peptide of beta-galactosidase. In the wild type situation, the alpha-peptide domain is segregated inside the apoferritin shell upon assembly and is unable to interact with the substrate and perform its enzymic function. We show that by selecting for mutations that restore beta-galactosidase activity we are able to identify ferritin mutations that affect the folding-assembly process. The selective procedure was applied to the analysis of the amino acid side chains that are important for the attainment of the correct conformation of the carboxy-terminal E helix in the 4-fold axis.     

Binding of pyruvate oxidase alpha-peptide to phospholipid vesicles

The alpha-peptide of pyruvate oxidase is a 23 residue peptide which is cleaved from the carboxy terminus of the enzyme during proteolytic activation by chymotrypsin (M. Recny et al. (1985) J. Biol. Chem. 260, 14287-14291). Cleavage of alpha-peptide results in the loss of the high affinity lipid-binding site in the enzyme. The beta-peptide of pyruvate oxidase is a 101 residue peptide which also is cleaved from the carboxy terminus of pyruvate oxidase. Cleavage of the beta-peptide from pyruvate oxidase results in the inactivation of the enzyme. The beta-peptide includes the alpha-peptide amino acid sequences at its carboxyl terminus. We now report on the binding of the alpha- and beta-peptides to phospholipid vesicles. Both peptides bind with equal and high affinity to phosphatidylcholine vesicles. We conclude from these results that the alpha-peptide furnishes the membrane-binding site which plays the physiologically important role in the activation of this peripheral membrane enzyme.