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.     

In vitro stepwise autoprocessing of the proform of pro-aminopeptidase processing protease from Aeromonas caviae T-64

PA protease (pro-aminopeptidase processing protease) is an extracellular zinc metalloprotease produced by the Gram-negative bacterium Aeromonas caviae T-64. The 590-amino-acid precursor of PA protease is composed of a putative 19-amino-acid signal sequence, a 165-amino-acid N-terminal propeptide, a 33 kDa mature protease domain and an 11 kDa C-terminal propeptide. The proform of PA protease, which was produced as inclusion bodies in Escherichia coli, was subjected to in vitro refolding. It was revealed that the processing of the proform involved a stepwise autoprocessing mechanism. Firstly, the N-terminal propeptide was autocatalytically removed on completion of refolding and secondly, the C-terminal propeptide was autoprocessed after the degradation of the N-terminal propeptide. Both the N- and C-terminal propeptides existed as intact peptides after their successive removal, and they were subsequently degraded gradually. The degradation of the N-terminal propeptide appears to be the rate-limiting step in the maturation of the proform of PA protease.     

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.     

A thermostable cysteine protease precursor from a tropical plant contains an unusual C-terminal propeptide: cDNA cloning, sequence comparison and molecular modeling studies

We report here the cloning and characterization of the entire cDNA of a papain-like cysteine protease from a tropical flowering plant. The 1098-bp ORF of the cDNA codify a protease precursor having a signal peptide of 19 amino acids, a cathepsin-L like N-terminal proregion of 114 amino acids, a mature enzyme part of 208 amino acids and a C-terminal proregion of 24 amino acids. The derived amino acid sequence of the mature part tallies with the thermostable cysteine protease Ervatamin-C--as was aimed at. The C-terminal proregion of the protease has altogether a different sequence pattern not observed in other members of the family and it contains a negatively charged helical zone. The three-dimensional model of the precursor, based on the homology modeling and X-ray structure, shows that the extended peptide stretch region of the N-terminal propeptide, covering the interdomain cleft, contains protruding side chains of positively charged residues. This study also indicates that the negatively charged zone of C-terminal propeptide may interact with the positively charged zone of the N-terminal propeptide in a cooperative manner in the maturation process of this enzyme.     

Involvement of propeptides in formation of catalytically active metalloproteinase from Thermoactinomyces sp

The metalloproteinase from Thermoactinomyces sp. 27a (Mpr) represents secretory thermolysin-like metalloproteinases of the M4 family. The Thermoactinomyces enzyme is synthesized as a precursor consisting of a signal peptide, N-terminal propeptide, mature region, and C-terminal propeptide. The functional molecule lacks the signal peptide, N-terminal propeptide, and C-terminal propeptide, which indicates the processing of these regions. Until now, it remained unclear if the N-terminal propeptide is involved in the formation and functioning of Mpr, and the role of the C-terminal propeptide was also unclear. In this work, a Bacillus subtilis AJ73 strain expressing Mpr without the C-terminal propeptide- encoding region being involved has been obtained. The absence of the Mpr C-terminal propeptide had no significant effect on the formation of the functional molecule and did not interfere with the protease secretion in B. subtilis AJ73 cells. Strains producing the N-terminal propeptide, mature region, and mature region covalently bound to the N-terminal propeptide were generated from Escherichia coli BL-21(DE3) cells. Functionally active Mpr forms could be produced only in the presence of the N-terminal propeptide, either covalently bound to the mature region (in cis) or as a separate molecule (in trans). Thus, the Mpr three-dimensional structure is formed according to the propeptide-assisted mechanism with no requirement of a covalent bond between the N-terminal propeptide and mature region. Moreover, Mpr variants generated in cis and in trans differed in their specificity for certain synthetic substrates.     

Activation of Arabidopsis vacuolar processing enzyme by self-catalytic removal of an auto-inhibitory domain of the C-terminal propeptide

Vacuolar processing enzyme (VPE) is a cysteine proteinase responsible for the maturation of various vacuolar proteins in higher plants. To clarify the mechanism of maturation and activation of VPE, we expressed the precursors of Arabidopsis gamma VPE in insect cells. The cells accumulated a glycosylated proprotein precursor (pVPE) and an unglycosylated preproprotein precursor (ppVPE) which might be unfolded. The N-terminal sequence of pVPE revealed that ppVPE had a 22-amino-acid signal peptide to be removed co-translationally. Under acidic conditions, the 56-kDa pVPE was self-catalytically converted to a 43-kDa intermediate form (iVPE) and then to the 40-kDa mature form (mVPE). N-terminal sequencing of iVPE and mVPE showed that sequential removal of the C-terminal propeptide and N-terminal propeptide produced mVPE. Both iVPE and mVPE exhibited the activity, while pVPE exhibited no activity. These results imply that the removal of the C-terminal propeptide is essential for activating the enzyme. Further removal of the N-terminal propeptide from iVPE is not required to activate the enzyme. To demonstrate that the C-terminal propeptide functions as an inhibitor of VPE, we expressed the C-terminal propeptide and produced specific antibodies against it. We found that the C-terminal propeptide reduced the activity of VPE and that this inhibitory activity was suppressed by specific antibodies against it. Our findings suggest that the C-terminal propeptide functions as an auto-inhibitory domain that masks the catalytic site. Thus, the removal of the C-terminal propeptide of pVPE might expose the catalytic site of the enzyme.     

The N-terminal propeptide of Vibrio vulnificus extracellular metalloprotease is both an inhibitor of and a substrate for the enzyme

Vibrio vulnificus, a marine bacterium capable of causing wound infection and septicemia, secretes a 45-kDa metalloprotease (vEP) with many biological activities. The precursor of vEP consists of four regions: a signal peptide, an N-terminal propeptide (nPP), a C-terminal propeptide, and the mature protease. Two forms of vEP-vEP-45, which contains the mature protease plus the C-terminal propeptide, and vEP-34, which contains only the mature protease-were expressed in Escherichia coli and purified. vEP-45 and vEP-34 had similar activities with azocasein as a substrate, but vEP-34 had reduced activity toward insoluble proteins. The nPP of vEP was expressed as a His tag fusion protein, and its effect on vEP activity was investigated. nPP inhibited the activities of both vEP-45 and vEP-34 but not that of thermolysin, a different but related zinc-dependent protease. The inhibition of vEP by nPP was further examined using vEP-34 as a representative enzyme. The inhibition could be completely reversed under conditions of low enzyme and propeptide concentrations and with prolonged incubation, which resulted from the degradation of nPP by vEP. However, even at high nPP and vEP concentrations, inhibition of vEP by nPP at high temperatures was not effective, resulting in the degradation of both nPP and vEP. These results demonstrate that the nPP of vEP could bind to vEP and inhibit its activity, resulting in the degradation of the propeptide.     

Maturation of Fibrinolytic Bacillopeptidase F Involves both Hetero- and Autocatalytic Processes

Bacillopeptidase F (Bpr) is a fibrinolytic serine protease produced by Bacillus subtilis. Its precursor is composed of a signal peptide, an N-terminal propeptide, a catalytic domain, and a long C-terminal extension (CTE). Several active forms of Bpr have been previously reported, but little is known about the maturation of this enzyme. Here, a gene encoding a Bpr (BprL) was cloned from B. subtilis LZW and expressed in B. subtilis WB700, and three fibrinolytic mature forms with apparent molecular masses of 45, 75, and 85 kDa were identified in the culture supernatant. After treatment with urea, the 75-kDa mature form had the same molecular mass as the 85-kDa mature form, from which we infer that they adopt different conformations. Mutational analysis revealed that while the 85-kDa mature form is generated via heterocatalytic processing of a BprL proform by an unidentified protease of B. subtilis, the production of the 75- and 45-kDa mature forms involves both hetero- and autocatalytic events. From in vitro analysis of BprL and its sequential C-terminal truncation variants, it appears that partial removal of the CTE is required for the initiation of autoprocessing of the N-terminal propeptide, which is composed of a core domain (N*) and a 15-residue linker peptide, thereby yielding the 45-kDa mature form. These data suggest that the differential processing of BprL, either heterocatalytically or autocatalytically, leads to the formation of multiple mature forms with different molecular masses or conformations.     

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.     

Vacuolar processing enzyme is self-catalytically activated by sequential removal of the C-terminal and N-terminal propeptides

A vacuolar processing enzyme (VPE) responsible for maturation of various vacuolar proteins is synthesized as an inactive precursor. To clarify how to convert the VPE precursor into the active enzyme, we expressed point mutated VPE precursors of castor bean in the pep4 strain of Saccharomyces cerevisiae. A VPE with a substitution of the active site Cys with Gly showed no ability to convert itself into the mature form, although a wild VPE had the ability. The mutated VPE was converted by the action of the VPE that had been purified from castor bean. Substitution of the conserved Asp-Asp at the putative cleavage site of the C-terminal propeptide with Gly-Gly abolished both the conversion into the mature form and the activation of the mutated VPE. In vitro assay with synthetic peptides demonstrated that a VPE exhibited activity towards Asp residues and that a VPE cleaved an Asp-Gln bond to remove the N-terminal propeptide. Taken together, the results indicate that the VPE is self-catalytically maturated to be converted into the active enzyme by removal of the C-terminal propeptide and subsequent removal of the N-terminal one.     

Identification of interaction site of propeptide toward mature carboxypeptidase Y (mCPY) based on the similarity between propeptide and CPY inhibitor (IC)

Both the propeptide in the precursor carboxypeptidase Y (proCPY) and the mature CPY (mCPY)-specific endogenous inhibitor (I(C)) inhibit CPY activity. The N-terminal inhibitory reactive site of I(C) (the N-terminal seven amino acids of I(C)) binds to the substrate-binding site of mCPY and is essential for mCPY inhibition, but the mechanism of mCPY inhibition by the propeptide is poorly understood. In this study, sequence alignment between I(C) and proCPY indicated that a sequence similar to the N-terminal region of I(C) was present in proCPY. In particular, a region including the C-terminus of the propeptide was similar to the N-terminal seven amino acids of I(C). In the presence of peptides identical to the N-terminus of I(C) and the C-terminus of the propeptide, CPY activity was competitively inhibited. The C-terminal region of the propeptide might bind to the substrate-binding site of mCPY.     

Maturation pathway of metalloprotease produced by Aeromonas sobria

Previously, we cloned the metalloprotease gene of Aeromonas sobria (amp) and determined its nucleotide sequence (GenBank accession number DQ784565). The protease is composed of 591 amino acid residues. In this study, we purified the mature metalloprotease from the culture supernatant of A. sobria and determined the amino terminal sequence and molecular size of AMP. In addition, we examined the production of AMP diachronically and found that AMP emerges outside of the cell as an intermediate composed of mature and propeptide regions. Subsequently, we determined that the N-terminal amino acid sequence of the intermediate and found that the sequence is identical to that of the mature metalloprotease. This means that the intermediate is composed of a mature AMP region and a C-terminal propeptide. The cross culture experiment of mutants of metalloprotease and serine protease of A. sobria on skim milk agar medium indicates that the intermediate released outside of the cell is inactive and that serine protease produced by A. sobria accelerates the conversion of the intermediate from the inactive to the active form.     

Cloning and analysis of WF146 protease, a novel thermophilic subtilisin-like protease with four inserted surface loops

Cloning and sequencing of the gene encoding WF146 protease, an extracellular subtilisin-like protease from the thermophile Bacillus sp. WF146, revealed that the WF146 protease was translated as a 416-amino acid precursor consisting of a putative 18-amino acid signal peptide, a 10-kDa N-terminal propeptide and a 32-kDa mature protease region. The mature WF146 protease shares a high degree of amino acid sequence identity with two psychrophilic subtilisins, S41 (68.2%) and S39 (65.4%), and a mesophilic subtilisin, SSII (67.1%). Significantly, these closely related proteases adapted to different temperatures all had four inserted surface loops not found in other subtilisins. However, unlike those of S41, S39 and SSII, the inserted loops of the WF146 protease possessed stabilizing features, such as the introduction of Pro residues into the loop regions. Interestingly, the WF146 protease contained five of the seven mutations previously found in a hyperstable variant of subtilisin S41 obtained by directed evolution. The proform of WF146 protease (pro-WF146 protease) was overexpressed in Escherichia coli in an inactive soluble form. After heat treatment, the 42-kDa pro-WF146 protease converted to a 32-kDa active mature form by processing the N-terminal propeptide. The purified mature WF146 protease hydrolyzed casein with an optimum temperature of 85 degrees C, and lost activity with a half-life of 30 min at 80 degrees C in the presence of 10 mM CaCl2.     

Cloning, nucleotide sequence, and expression of Achromobacter protease I gene

Achromobacter protease I (API) is a lysine-specific serine protease which hydrolyzes specifically the lysyl peptide bond. A gene coding for API was cloned from Achromobacter lyticus M497-1. Nucleotide sequence of the cloned DNA fragment revealed that the gene coded for a single polypeptide chain of 653 amino acids. The N-terminal 205 amino acids, including signal peptide and the threonine/serine-rich C-terminal 180 amino acids are flanking the 268 amino acid-mature protein which was identified by protein sequencing. Escherichia coli carrying a plasmid containing the cloned API gene overproduced and secreted a protein of Mr 50,000 (API') into the periplasm. This protein exhibited a distinct endopeptidase activity specific for lysyl bonds as well. The N-terminal amino acid sequence of API' was the same as mature API, suggesting that the enzyme retained the C-terminal extended peptide chain. The present experiments indicate that API, an extracellular protease produced by gram-negative bacteria, is synthesized in vivo as a precursor protein bearing long extended peptide chains at both N and C termini.     

The vacuolar targeting signal of the 2S albumin from Brazil nut resides at the C terminus and involves the C-terminal propeptide as an essential element.

Genetic constructs in which different N- and C-terminal segments of Brazil nut (Bertholletia excelsa H.B.K.) 2S albumin were fused to secretory yeast invertase were transformed into tobacco (Nicotiana tabacum) plants to investigate the vacuolar targeting signal of the 2S albumin. None of the N-terminal segments, including the complete precursor containing all propeptides, was able to direct the invertase to the vacuoles. However, a short C-terminal segment comprising the last 20 amino acids of the precursor was sufficient for efficient targeting of yeast invertase to the vacuoles of the transformed tobacco plants. Further analyses showed that peptides of 16 and 13 amino acids of the C-terminal segment were still sufficient, although they had slightly lower efficiency. When segments of 9 amino acids or shorter were analyzed, a decrease to approximately 30% was observed. These segments included the C-terminal propeptide of four amino acids (Ile-Ala-Gly-Phe). When the 2S albumin was expressed in tobacco, it was also localized to the vacuoles of mesophyll cells. If the C-terminal propeptide was deleted from the 2S albumin precursor, all of this truncated 2S albumin was secreted from the tobacco cells. These results indicate that the C-terminal propeptide is necessary but not sufficient for vacuolar targeting. In addition, an adjacent segment of at least 12 amino acids of the mature protein is needed to form the complete signal for efficient targeting.     

Molecular analysis of the gene encoding α-lytic protease: evidence for a preproenzyme

A 1.7-kb EcoRI fragment containing the structural gene for α-lytic protease has been cloned from Lysobacter enzymogenes 495 chromosomal DNA: the first example of a gene cloned from this organism. The protein sequence deduced from the nucleotide sequence encoding this serine protease matches the published amino acid sequence [Olson et al., Nature 228 (1970) 438–442] precisely. Sequence analysis and S 1 mapping indicate that, like subtilisin [e.g. Wells et al., Nucleic Acids Res. 11 (1983) 7911–7925] α-lytic protease is synthesized as a pre-pro protein (41 kDa) that is subsequently processed to its mature extracellular form (20 kDa). This first finding of a large N-terminal protease precursor in a Gram-negative bacterial protease strengthens the hypothesis that large precursors may be a general property of extracellular bacterial proteases, and suggests that the N- or C-terminal location of the precursor segment may be significant.     

Processing of the prepropeptide portions of the Bacillus amyloliquefaciens neutral protease fused to Bacillus subtilis alpha-amylase and human growth hormone during secretion in Bacillus subtilis.

A set of nested 3'-terminal deletions of the prepropeptide of the Bacillus amyloliquefaciens neutral protease gene was constructed. Alpha-amylase and human growth hormone were secreted using these truncated genes in Bacillus subtilis. The level of the secreted alpha-amylase varied with the region for the truncated prepropeptide contained in the fusion gene but was independent of its length. Even though length of the prepropeptide varied, the mobilities of secreted alpha-amylases were the same as that of the control alpha-amylase derived from the alpha-amylase clone, pTUB4 (Yamazaki et al., 1983). Analyses of the secreted N-terminal amino acid sequences confirmed that they were all identical to that of the authentic one. Precursor proteins of the alpha-amylase were found in the cell-associated fraction, suggesting that the prepropeptide portion was processed during secretion. On the other hand, the N-terminus of hGH secreted using one of these prepropeptide portions varied by 1 to 4 additional N-terminal amino acid residues derived from the junction sequence between the sequence for propeptide portion and mature hGH or from C-terminal region of the propeptide portion. These results suggest that the prepropeptide portion can be generally processed even in the heterogeneous fusion. A probable mechanism of processing and maturation of the fusion gene products is also discussed.     

Overexpression and characterization of thermostable serine protease in Escherichia coli encoded by the ORF TTE0824 from Thermoanaerobacter tengcongensis

A novel extracellular serine protease derived from Thermoanaerobacter tengcongensis, designated tengconlysin, was successfully overexpressed in Escherichia coli as a soluble protein by recombination of an N-terminal Pel B leader sequence instead of the original presequence and C-terminal 6× histidine tags. The purified protein was activated by 0.1% sodium dodecyl sulfate (SDS) treatment but not by thermal treatment. The molecular weight of tengconlysin estimated by SDS-polyacrylamide gel electrophoresis analysis and gel filtration chromatography was 37.9 and 36.2 kDa, respectively, suggesting that the enzyme is monomeric. The N-terminal sequence of mature tengconlysin was LDTAT, suggesting that it is a preproprotein containing a 29 amino acid presequence (predicted from the SigP program) and a 117 amino acid prosequence in the N-terminus. The C-terminal putative propeptide (position 469–540 in the preproprotein) did not inhibit the protease activity. The optimum temperature for tengconlysin activity was 90°C in the presence of 1 mM calcium ions and the optimum pH ranged from 6.5 to 7.0. Activity inhibition studies suggest that the protease is a serine protease. The protease was stable in 0.1% SDS and 1–4 M urea at 70°C in the presence of calcium ions and was activated by the denaturing agents.     

Streptomyces griseus Protease B: Secretion Correlates with the Length of the Propeptide

Streptomyces griseus protease B, a member of the chymotrypsin superfamily, is encoded by a gene that expresses a pre-pro-mature protein. During secretion the precursor protein is processed into a mature, fully folded protease. In this study, we constructed a family of genes which encode deletions at the amino-terminal end of the propeptide. The secretion of active protease B was seen to decrease in an exponential manner according to the length of the deletion. The results underscore the intimate relationship between folding and secretion in bacterial protease expression. They further suggest that the propeptide segment of the zymogen stabilizes the folding of the mature enzyme through many small binding interactions over the entire surface of the peptide rather than through a few specific contacts.     

Cloning and Sequence Analysis of a Protease-encoding Gene from the Marine Bacterium Alteromonas sp. Strain O-7

The gene (aprI) encoding alkaline serine protease (AprI; subtilase) from Alteromonas sp. strain O-7 was cloned and sequenced. The nucleotide sequence of aprI has been identified. The deduced amino acid sequence indicated that aprI codes for a precursor of 715 amino acids and the precursor is composed of four regions including a signal peptide, an N-terminal pro-region, a mature protease region and a C-terminal extension region of 215 amino acids as previously described for aprII [H. Tsujibo et al., Gene, 136, 247–251 (1993)]. The amino acid sequence of the mature AprI (AprI-M) showed high sequence homology with those of other class I subtilases. The C-terminal region was characterized by a repeat of 94 amino acids residues, which showed about 50% similarity with those of the C-terminal pro-region of several known proteases from Gram-negative bacteria.