Glycosaminoglycans modulate activation, activity, and stability of tripeptidyl-peptidase I in vitro and in vivo

Tripeptidyl-peptidase I (TPP I, CLN2 protein) is a lysosomal exopeptidase that sequentially removes tripeptides from the N termini of polypeptides and shows a minor endoprotease activity. Mutations in TPP I lead to classic late-infantile neuronal ceroid lipofuscinosis, a neurodegenerative lysosomal storage disease. TPP I proenzyme is converted in lysosomes into a mature enzyme with the assistance of another protease and is able to autoactivate in acidic pH in vitro via a unimolecular mechanism. Because autoactivation in vitro at the pH values reported for lysosomes generated inactive enzyme, we intended to determine whether physiologically relevant factors can modify this process to also make it plausible in vivo. Here, we report that high ionic strength and glycosaminoglycans (GAGs) increase yields (ionic strength) or yields and rates (GAGs) of activation, enhance degradation of liberated TPP I prosegment fragments, and switch effective autoactivation of TPP I proenzyme toward less acidic pH values (up to pH 6.0). Although ionic strength and GAGs also inhibited TPP I activity in vitro and in living cells, the degree of inhibition (from 20 to 60%) appears to be of rather limited functional significance. Importantly, binding to GAGs improved thermal stability of TPP I and protected the enzyme against alkaline pH-induced denaturation in vitro (t((1/2)) of mature enzyme at pH 7.4 increased by approximately 8-fold in the presence of heparin) and in vivo ( approximately 2-fold higher loss of TPP I in cells deficient in GAGs than in control cells after bafilomycin A1 treatment). These findings elucidate a potent physiologically relevant mechanism of TPP I regulation by GAGs and suggest that generation of the active enzyme via autoactivation can be accomplished not only in vitro but in vivo as well.     

Biosynthesis,glycosylation, and enzymatic processing in vivo of human tripeptidyl-peptidase I

Human tripeptidyl-peptidase I (TPP I, CLN2 protein) is a lysosomal serine protease that removes tripeptides from the free N termini of small polypeptides and also shows a minor endoprotease activity. Due to various naturally occurring mutations, an inherited deficiency of TPP I activity causes a fatal lysosomal storage disorder, classic late infantile neuronal ceroid lipofuscinosis (CLN2). In the present study, we analyzed biosynthesis, glycosylation, transport, and proteolytic processing of this enzyme in stably transfected Chinese hamster ovary cells as well as maturation of the endocytosed proenzyme in CLN2 lymphoblasts, fibroblasts, and N2a cells. Human TPP I was initially identified as a single precursor polypeptide of approximately 68 kDa, which, within a few hours, was converted to the mature enzyme of approximately 48 kDa. Compounds affecting the pH of intracellular acidic compartments, those interfering with the intracellular vesicular transport as well as inhibition of the fusion between late endosomes and lysosomes by temperature block or 3-methyladenine, hampered the conversion of TPP I proenzyme into the mature form, suggesting that this process takes place in lysosomal compartments. Digestion of immunoprecipitated TPP I proenzyme with both N-glycosidase F and endoglycosidase H as well as treatment of the cells with tunicamycin reduced the molecular mass of TPP I proenzyme by approximately 10 kDa, which indicates that all five potential N-glycosylation sites in TPP I are utilized. Mature TPP I was found to be partially resistant to endo H treatment; thus, some of its N-linked oligosaccharides are of the complex/hybrid type. Analysis of the effect of various classes of protease inhibitors and mutation of the active site Ser(475) on human TPP I maturation in cultured cells demonstrated that although TPP I zymogen is capable of autoactivation in vitro, a serine protease that is sensitive to AEBSF participates in processing of the proenzyme to the mature, active form in vivo.     

Proregion of Bombyx mori cysteine proteinase functions as an intramolecular chaperone to promote proper folding of the mature enzyme.

A cDNA encoding the proform of Bombyx cysteine proteinase (BCP) was expressed at a high level in Escherichia coli using the T7 polymerase expression system. The insoluble recombinant zymogen was solubilized and renatured by modifying a method applied to human pro-cathepsin L. Like the natural BCP precursor, the recombinant proenzyme was spontaneously converted to an active proteinase at pH 3.75. A deletion in the central region of the propeptide resulted in much loss of the activity, suggesting that the propeptide is essential for proper folding during renaturation. In contrast, the renatured mature form of recombinant BCP was not active but regained activity by including the propeptide in the renaturing buffer, suggesting that the propeptide, acting as an intramolecular chaperone, promotes refolding of the associated proteinase domain into an active conformation. The mature form of natural BCP rapidly lost its activity at neutral pH, whereas its proform was stable. The mature enzyme retained some activity in the presence of the propeptide. Arch.     

Identification of internal autoproteolytic cleavage sites within the prosegments of recombinant procathepsin B and procathepsin S. Contribution of a plausible unimolecular autoproteolytic event for the processing of zymogens belonging to the papain family

The steps involved in the maturation of proenzymes belonging to the papain family of cysteine proteases have been difficult to characterize. Intermolecular processing at or near the pro/mature junction, due either to the catalytic activity of active enzyme or to exogeneous proteases, has been well documented for this family of proenzymes. In addition, kinetic studies are suggestive of a slow unimolecular mechanism of autoactivation which is independent of proenzyme concentration. However, inspection of the recently determined x-ray crystal structures does not support this evidence. This is due primarily to the extensive distances between the catalytic thiolate-imidazolium ion pair and the putative site of proteolysis near the pro/mature junction required to form mature protein. Furthermore, the prosegments for this family of precursors have been shown to bind through the substrate binding clefts in a direction opposite to that expected for natural substrates. We report, using cystatin C- and N-terminal sequencing, the identification of autoproteolytic intermediates of processing in vitro for purified recombinant procathepsin B and procathepsin S. Inspection of the x-ray crystal structures reported to date indicates that these reactions occur within a segment of the proregion which binds through the substrate binding clefts of the enzymes, thus suggesting that these reactions are occurring as unimolecular processes.     

Uncoupling the enzymatic and autoprocessing activities of Helicobacter pylori gamma-glutamyltranspeptidase

Gamma-glutamyltranspeptidase (gammaGT), a member of the N-terminal nucleophile hydrolase superfamily, initiates extracellular glutathione reclamation by cleaving the gamma-glutamyl amide bond of the tripeptide. This protein is translated as an inactive proenzyme that undergoes autoprocessing to become an active enzyme. The resultant N terminus of the cleaved proenzyme serves as a nucleophile in amide bond hydrolysis. Helicobacter pylori gamma-glutamyltranspeptidase (HpGT) was selected as a model system to study the mechanistic details of autoprocessing and amide bond hydrolysis. In contrast to previously reported gammaGT, large quantities of HpGT were expressed solubly in the inactive precursor form. The 60-kDa proenzyme was kinetically competent to form the mature 40- and 20-kDa subunits and exhibited maximal autoprocessing activity at neutral pH. The activated enzyme hydrolyzed the gamma-glutamyl amide bond of several substrates with comparable rates, but exhibited limited transpeptidase activity relative to mammalian gammaGT. As with autoprocessing, maximal enzymatic activity was observed at neutral pH, with hydrolysis of the acyl-enzyme intermediate as the rate-limiting step. Coexpression of the 20- and 40-kDa subunits of HpGT uncoupled autoprocessing from enzymatic activity and resulted in a fully active heterotetramer with kinetic constants similar to those of the wild-type enzyme. The specific contributions of a conserved threonine residue (Thr380) to autoprocessing and hydrolase activities were examined by mutagenesis using both the standard and coexpression systems. The results of these studies indicate that the gamma-methyl group of Thr380 orients the hydroxyl group of this conserved residue, which is required for both the processing and hydrolase reactions.     

Isolation and characterization of a stable activation intermediate of the lysosomal aspartyl protease cathepsin D.

Procathepsin D is the intracellular aspartyl protease precursor of cathepsin D, a major lysosomal enzyme. Procathepsin D is rapidly processed inside the cell, and, thus, examination of its proteolyic activation and structure has been difficult. To study this proenzyme, a nonglycosylated form of the human fibroblast procathepsin D was expressed in Escherichia coli, refold in vitro, and purified by affinity chromatography on pepstatinyl agarose. Sequence analysis of the refolded, autoactivated enzyme allowed determination of the autoproteolytic cleavage site. The sequence surrounding this cleavage site between residues LeuP26 and IleP27 (in the "pro" region) resembled the first cleavage site found during activation of other aspartyl proteases. Thus, the autoactivated procathepsin D is analogous to the pepsin activation intermediate, which has been termed pseudopepsin. The enzymatic activity, thermal and pH stability, and fluorescence spectra of pseudocathepsin D were compared to mature, predominantly two-chain, cathepsin D isolated from human placenta. The results indicated that pseudocathepsin D and mature enzyme have a similar Km toward a peptide substrate and cleave a protein substrate at identical sites. Temperature stability of the recombinant enzyme was similar to that of the tissue-derived enzyme. However, the recombinant enzyme had increased stability at low pH when compared to the glycosylated tissue-derived two-chain cathepsin D. Fluorescence spectra of the recombinant and tissue-derived enzymes were identical. Thus, the absence of asparagine-linked oligosaccharides and the presence of the remaining segment of propeptide did not significantly alter the structural and enzymatic properties of the enzyme.     

A 38 kDa precursor protein of aqualysin I (a thermophilic subtilisin-type protease) with a C-terminal extended sequence: its purification and in vitro processing

The precursor of aqualysin I, an extracellular subtilisin-type protease produced by Thermus aquaticus, consists of four domains: an N-terminal signal peptide, an N-terminal pro-sequence, a protease domain, and a C-terminal extended sequence. In an Escherichia coli expression system for the aqualysin I gene, a 38 kDa precursor protein consisting of the protease domain and the C-terminal extended sequence is accumulated in the membrane fraction and processed to a 28 kDa mature enzyme upon heat treatment at 65°C. The 38 kDa precursor protein is separated as a soluble form from denatured E. coli proteins after heat treatment. Accordingly, purification of the 38 kDa proaqualysin I was performed using chromatography. The purified precursor protein gave a single band on SDS-polyacrylamide gels. The precursor protein exhibited proteolytic activity comparable to that of the mature enzyme. The purified precursor protein was processed to the mature enzyme upon heat treatment. The processing was inhibited by diisopropyl fluorophosphate. The processing rate increased upon either the addition of mature aqualysin I or upon an increase in the concentration of the precursor, suggesting that the cleavage of the C-terminal extended sequence occurs through an intermolecular self-processing mechanism.     

Purification and molecular characterization of glycylglycine endopeptidase produced by Staphylococcus capitis EPK1.

A novel staphylolytic enzyme, ALE-1, acting on Staphylococcus aureus, was purified from a Staphylococcus capitis EPK1 culture supernatant. The optimal pH range for staphylolytic activity was 7 to 9. ALE-1 contains one Zn2+ atom per molecule. Analysis of peptidoglycan fragments released by ALE-1 indicated that the enzyme is a glycylglycine endopeptidase. The effects of various modulators were determined, and we found that o-phenanthroline, iodoacetic acid, diethylpyrocarbonate, and Cu2+ reduced the staphylolytic activity of ALE-1. beta-Casein, elastin, and pentaglycine were poor substrates for ALE-1. Molecular cloning data revealed that ALE-1 is composed of 362 amino acid residues and is synthesized as a precursor protein which is cleaved after Ala at position 35, thus producing a mature ALE-1 of 35.6 kDa. The primary structure of mature ALE-1 is very similar to the proenzyme form of lysostaphin. It has the modular design of an N-terminal domain of tandem repeats of a 13-amino-acid sequence fused to the active site containing C-terminal domain. Unlike lysostaphin, ALE-1 does not undergo processing of the N-terminal repeat domain in broth culture. ale-1 is encoded on the plasmid. Protein homology search suggested that ALE-1 and lysostaphin are members of the novel Zn2+ protease family with a homologous 38-amino-acid-long motif, Tyr-X-His-X(11)-Val-X(12/20)-Gly-X(5-6)-His.     

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.     

In vitro processing of the human alkyl-dihydroxyacetonephosphate synthase precursor.

Alkyl-dihydroxyacetonephosphate synthase, a peroxisomal enzyme involved in the biosynthesis of ether phospholipids, is synthesized with a cleavable N-terminal presequence containing the peroxisomal targeting signal type 2. The human alkyl-dihydroxyacetonephosphate synthase precursor produced in vitro or expressed in Escherichia coli could be processed to a lower molecular weight protein by incubation at 37 degrees C with a guinea pig liver fraction, enriched in mitochondria, lysosomes, and peroxisomes. This lower molecular weight protein was identified as the mature human alkyl-dihydroxyacetonephosphate synthase by radiosequencing, indicating that the processing protease is present in this organellar fraction. Characterization of the processing protease indicated that it is a cysteine protease with a pH optimum of 6.5. Furthermore, it was demonstrated that exogenously added pre-alkyl-dihydroxyacetonephosphate synthase was imported and processed in purified peroxisomes in vitro. Processing of alkyl-dihydroxyacetonephosphate synthase did not increase the activity of the enzyme. This indicates that the presence of the presequence does not affect the activity of the enzyme.     

Autoprocessing of Helicobacter pylori gamma-glutamyltranspeptidase leads to the formation of a threonine-threonine catalytic dyad

Helicobacter pylorigamma-glutamyltranspeptidase (HpGT) is a glutathione-degrading enzyme that has been shown to be a virulence factor in infection. It is expressed as a 60-kDa inactive precursor that must undergo autocatalytic processing to generate a 40-kDa/20-kDa heterodimer with full gamma-glutamyl amide bond hydrolase activity. The new N terminus of the processed enzyme, Thr-380, is the catalytic nucleophile in both the autoprocessing and enzymatic reactions, indicating that HpGT is a member of the N-terminal nucleophile hydrolase superfamily. To further investigate activation as a result of autoprocessing, the structure of HpGT has been determined to a resolution of 1.9 A. The refined model contains two 40-kDa/20-kDa heterodimers in the asymmetric unit and has structural features comparable with other N-terminal nucleophile hydrolases. Autoprocessing of HpGT leads to a large conformational change, with the loop preceding the catalytic Thr-380 moving >35 A, thus relieving steric constraints that likely limit substrate binding. In addition, cleavage of the proenzyme results in the formation of a threonine-threonine dyad comprised of Thr-380 and a second conserved threonine residue, Thr-398. The hydroxyl group of Thr-398 is located equidistant from the alpha-amino group and hydroxyl side chain of Thr-380. Mutation of Thr-398 to an alanine results in an enzyme that is fully capable of autoprocessing but is devoid of enzymatic activity. Substrate docking studies in combination with homology modeling studies of the human homologue reveal additional mechanistic details of enzyme maturation and activation, substrate recognition, and catalysis.     

Purification, refolding and autoactivation of the recombinant cysteine proteinase EhCP112 from Entamoeba histolytica

The cysteine proteinase EhCP112 and the adhesin EhADH112 assemble to form the EhCPADH complex involved in Entamoeba histolytica virulence. To further characterize this cysteine proteinase, the recombinant full-length EhCP112 enzyme was expressed and purified under denaturing conditions. After a refolding step under reductive conditions, the inactive precursor (ppEhCP112) was processed to a 35.5 kDa mature and active enzyme (EhCP112). The thiol specific inhibitor E-64, but not serine or aspartic proteinase inhibitors arrested this activation process. The activation step of the proenzyme followed by the mature enzyme suggests an autocatalytic process during EhCP112 maturation. The experimentally determined processing sites observed during EhCP112 activation lie close to processing sites of other cysteine proteinases from parasites. The kinetic parameters of the mature EhCP112 were determined using hemoglobin and azocasein as substrates. The proteinase activity of EhCP112 was completely inhibited by thiol inhibitors, E-64, TLCK, and chymostatin, but not by general proteinase inhibitors. Since EhCP112 is a proteinase involved in the virulence of E. histolytica, a reliable source of active EhCP112 is a key step for its biochemical characterization and to carry out future protein structure-function studies.     

Active prorenin: Evidence for the formation of a conformational variant of recombinant human prorenin

Using highly purified recombinant human prorenin, we report the first evidence for the formation of a stable, partially active, conformational variant of the recombinant proenzyme. The enzymatically active prorenin exhibits the following characteristics: (1) the proenzyme N-terminal sequence and molecular weight are maintained; (2) the active proenzyme is capable of cleaving a novel fluorogenic peptide substrate based on the sequence of human angiotensinogen and exhibits about 30% of mature renin specific activity for the fluorogenic substrate; (3) the active proenzyme conformation binds to, and can be eluted from, a pepstatin affinity column; and (4) the activity of the active proenzyme can be inhibited by a novel peptidomimetic renin inhibitor.     

N-glycosylation is crucial for folding, trafficking, and stability of human tripeptidyl-peptidase I

Tripeptidyl-peptidase I (TPP I) is a lysosomal serine-carboxyl peptidase that sequentially removes tripeptides from polypeptides. Naturally occurring mutations in TPP I are associated with the classic late infantile neuronal ceroid lipofuscinosis. Human TPP I has five potential N-glycosylation sites at Asn residues 210, 222, 286, 313, and 443. To analyze the role of N-glycosylation in the function of the enzyme, we obliterated each N- glycosylation consensus sequence by substituting Gln for Asn, either individually or in combinations, and expressed mutated cDNAs in Chinese hamster ovary and human embryonic kidney 293 cells. Here, we demonstrate that human TPP I in vivo utilizes all five N-glycosylation sites. Elimination of one of these sites, at Asn-286, dramatically affected the folding of the enzyme. However, in contrast to other misfolded proteins that are retained in the endoplasmic reticulum, only a fraction of misfolded TPP I mutant expressed in Chinese hamster ovary cells, but not in human embryonic kidney 293 cells, was arrested in the ER, whereas its major portion was secreted. Secreted proenzyme formed non-native, interchain disulfide bridges and displayed only residual TPP I activity upon acidification. A small portion of TPP I missing Asn-286-linked glycan reached the lysosome and was processed to an active species; however, it showed low thermal and pH stability. N-Glycans at Asn-210, Asn-222, Asn-313, and Asn-443 contributed slightly to the specific activity of the enzyme and its resistance to alkaline pH-induced inactivation. Phospholabeling experiments revealed that N-glycans at Asn-210 and Asn-286 of TPP I preferentially accept a phosphomannose marker. Thus, a dual role of oligosaccharide at Asn-286 in folding and lysosomal targeting could contribute to the unusual, but cell type-dependent, fate of misfolded TPP I conformer and represent the molecular basis of the disease process in subjects with naturally occurring missense mutation at Asn-286.     

Efficient purification of TIMP-2 from culture medium conditioned by human hepatoma cell line, and its inhibitory effects on metalloproteinases and in vitro tumor invasion.

Metalloproteinase inhibitors were surveyed with the culture media of 19 kinds of human tumor cell lines, using transin (rat stromelysin) as the target enzyme. This survey showed that most of the cell lines more or less secreted inhibitor activity, and that a human hepatoma cell line, HLE, secreted an extremely high inhibitor activity into the culture medium. Two kinds of metalloproteinase inhibitors were purified from the serum-free conditioned medium of HLE cells. The major inhibitor, which showed a single protein band with a molecular weight (Mr) of 21,000 (21k) (nonreduced) or 24k (reduced) on SDS-polyacrylamide gel electrophoresis, was identified as TIMP-2 (tissue inhibitor of metalloproteinases-2) by the analysis of its N-terminal amino acid sequence. The other was immunologically identified as TIMP. Purified TIMP-2 inhibited the activities of transin, matrin (pump-1), Mr 72k gelatinase, and interstitial collagenase with 1:1 stoichiometry. When the latent precursor form (Mr 57k) of transin was incubated with p-aminophenylmercuric acetate as an activating reagent, TIMP-2 inhibited the conversion of the intermediate form (Mr 45k) into the mature enzyme (Mr 42k). This indicated that TIMP-2 regulates not only the activity of the mature enzyme but also the autolytic processing of the proenzyme. TIMP-2 also inhibited in vitro tumor invasion through reconstituted basement membrane (matrigel) in chemotaxis chambers, showing that the metalloproteinase inhibitors as well as the extracellular matrix metalloproteinases are involved in tumor invasion through basement membrane and other extracellular matrices.     

Asparaginyl endopeptidase (VmPE-1) and autocatalytic processing synergistically activate the vacuolar cysteine proteinase (SH-EP).

A vacuolar cysteine proteinase, designated SH-EP, is synthesized in cotyledons of germinated Vigna mungo seeds and is responsible for degradation of the seed proteins accumulated in protein bodies (protein storage vacuoles). SH-EP belongs to the papain proteinase family and has a large N-terminal prosegment consisting of 104 amino acid residues and a C-terminal prosegment of 10 amino acid residues. It has been suggested that an asparaginyl endopeptidase, V. mungo processing enzyme 1 (VmPE-1), is involved in the N-terminal post-translational processing of SH-EP. The recombinant proform of SH-EP (rSH-EP) was produced in Escherichia coli cells, purified to homogeneity and refolded by stepwise dialysis. 31P-NMR analysis of intact germinated cotyledons revealed that the vacuolar pH of cotyledonary cells changes from 6.04 to 5.47 during seed germination and early seedling growth. rSH-EP was converted in vitro to the mature form through autocatalytic processing at a pH mimicking the vacuolar pH at the mid and late stages of seed germination, but not at the pH of the early stage. VmPE-1 accelerated the rate of processing of rSH-EP in vitro at the pH equivalent to the vacuolar pH at the early and mid stages of germination. In addition, the cleavage sites of the in vitro processed intermediates and the mature form of SH-EP were identical to those of SH-EP purified from germinated cotyledons of V. mungo. We propose that the asparaginyl endopeptidase (VmPE-1)-mediated processing mainly functions in the activation of proSH-EP at the early stage of seed germination, and both VmPE-1-mediated and autocatalytic processings function synergistically in the activation of proSH-EP in cotyledons at the mid and late stages.     

Cloning of the authentic bovine gene encoding pepsinogen a and its expression in microbial cells

Bovine pepsin is the second major proteolytic activity of rennet obtained from young calves and is the main protease when it is extracted from adult animals, and it is well recognized that the proteolytic specificity of this enzyme improves the sensory properties of cheese during maturation. Pepsin is synthesized as an inactive precursor, pepsinogen, which is autocatalytically activated at the pH of calf abomasum. A cDNA coding for bovine pepsin was assembled by fusing the cDNA fragments from two different bovine expressed sequence tag libraries to synthetic DNA sequences based on the previously described N-terminal sequence of pepsinogen. The sequence of this cDNA clearly differs from the previously described partial bovine pepsinogen sequences, which actually are rabbit pepsinogen sequences. By cloning this cDNA in different vectors we produced functional bovine pepsinogen in Escherichia coli and Saccharomyces cerevisiae. The recombinant pepsinogen is activated by low pH, and the resulting mature pepsin has milk-clotting activity. Moreover, the mature enzyme generates digestion profiles with alpha-, beta-, or kappa-casein indistinguishable from those obtained with a natural pepsin preparation. The potential applications of this recombinant enzyme include cheese making and bioactive peptide production. One remarkable advantage of the recombinant enzyme for food applications is that there is no risk of transmission of bovine spongiform encephalopathy.     

Proteolytic activity of novel human immunodeficiency virus type 1 proteinase proteins from a precursor with a blocking mutation at the N terminus of the PR domain.

The mature human immunodeficiency virus type 1 proteinase (PR; 11 kDa) can cleave all interdomain junctions in the Gag and Gag-Pol polyprotein precursors. To determine the activity of the enzyme in its precursor form, we blocked release of mature PR from a truncated Gag-Pol polyprotein by introducing mutations into the N-terminal Phe-Pro cleavage site of the PR domain. The mutant precursor autoprocessed efficiently upon expression in Escherichia coli. No detectable mature PR was released; however, several PR-related products ranging in size from approximately 14 to 18 kDa accumulated. Products of the same size were generated when mutant precursors were digested with wild-type PR. Thus, PR can utilize cleavage sites in the region upstream of the PR domain, resulting in the formation of extended PR species. On the basis of active-site titration, the PR species generated from mutated precursor exhibited wild-type activity on peptide substrates. However, the proteolytic activity of these extended enzymes on polyprotein substrates provided exogenously was low when equimolar amounts of extended and wild-type PR proteins were compared. Mammalian cells expressing the mutated precursor produced predominantly precursor and considerably reduced amounts of mature products. Released particles consisted mostly of uncleaved or partially cleaved polyproteins. Our results suggest that precursor forms of PR can autoprocess but are less efficient in processing of the Gag precursor for formation of mature virus particles.     

Multistep autoactivation of asparaginyl endopeptidase in vitro and in vivo

Mammalian asparaginyl endopeptidase (AEP) or legumain is a recently discovered lysosomal cysteine protease that specifically cleaves after asparagine residues. How this unusually specific lysosomal protease is itself activated is not fully understood. Using purified recombinant pro-enzyme, we show that activation is autocatalytic, requires sequential removal of C- and N-terminal pro-peptides at different pH thresholds, and is bimolecular. Removal of the N-terminal propeptide requires cleavage after aspartic acid rather than asparagine. Cellular processing, either of exogenously added AEP precursor or of pulse-labeled endogenous precursor, introduces at least one further cleavage to yield the final mature lysosomal enzyme. We also provide evidence that in living cells, there is clear compartmental heterogeneity in terms of AEP activation status. Moreover, we show that human monocyte-derived dendritic cells harbor inactive proforms of AEP that become activated upon maturation of dendritic cells with lipopolysaccharide.