C-terminal KDEL sequence of a KDEL-tailed cysteine proteinase (sulfhydryl-endopeptidase) is involved in formation of KDEL vesicle and in efficient vacuolar transport of sulfhydryl-endopeptidase

Sulfhydryl-endopeptidase (SH-EP) is a papain-type vacuolar proteinase expressed in cotyledons of germinated Vigna mungo seeds, and the enzyme possesses a C-terminal propeptide containing KDEL tail, an endoplasmic reticulum retention signal for soluble proteins. SH-EP is transported to vacuoles via a KDEL vesicle (KV) through a Golgi complex-independent route. To see the function of the KDEL sequence of SH-EP, wild-type SH-EP and its KDEL deletion mutant (SH-EPDeltaKDEL) were heterologously expressed in Arabidopsis and in cultured tobacco Bright Yellow 2 cells, and their intracellular transport pathways and localizations were analyzed. A combination of the results from analyses for transformed Arabidopsis and tobacco (Nicotiana tabacum) cells indicated that wild-type SH-EP is packed into KV-like vesicles through the KDEL sequence and is transported to vacuoles in the cells of transformants. In contrast, KV was not formed/induced in the cells expressing SH-EPDeltaKDEL, and the mutant protein was mainly secreted. Therefore, the C-terminal KDEL sequence of the KDEL-tailed cysteine proteinase is thought to be involved in the formation of KV, and in the efficient vacuolar transport of the proteins through KV.     

Mass transport of proform of a KDEL-tailed cysteine proteinase (SH-EP) to protein storage vacuoles by endoplasmic reticulum-derived vesicle is involved in protein mobilization in germinating seeds

A vacuolar cysteine proteinase, designated SH-EP, is expressed in the cotyledon of germinated Vigna mungo seeds and is responsible for the degradation of storage proteins. SH-EP is a characteristic vacuolar proteinase possessing a COOH-terminal endoplasmic reticulum (ER) retention sequence, KDEL. In this work, immunocytochemical analysis of the cotyledon cells of germinated V. mungo seeds was performed using seven kinds of antibodies to identify the intracellular transport pathway of SH-EP from ER to protein storage vacuoles. A proform of SH-EP synthesized in ER accumulated at the edge or middle region of ER where the transport vesicle was formed. The vesicle containing a large amount of proSH-EP, termed KV, budded off from ER, bypassed the Golgi complex, and was sorted to protein storage vacuoles. This massive transport of SH-EP via KV was thought to mediate dynamic protein mobilization in the cotyledon cells of germinated seeds. We discuss the possibilities that the KDEL sequence of KDEL-tailed vacuolar cysteine proteinases function as an accumulation signal at ER, and that the mass transport of the proteinases by ER-derived KV-like vesicle is involved in the protein mobilization of plants.     

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.     

Posttranslational removal of the carboxyl-terminal KDEL of the cysteine protease SH-EP occurs prior to maturation of the enzyme

SH-EP is a cysteine protease from germinating mung bean (Vigna mungo) that possesses a carboxyl-terminal endoplasmic reticulum (ER) retention sequence, KDEL. In order to examine the function of the ER retention sequence, we expressed a full-length cDNA of SH-EP and a minus-KDEL control in insect Sf-9 cells using the baculovirus system. Our observations on the synthesis, processing, and trafficking of SH-EP in Sf-9 cells suggest that the KDEL ER-retention sequence is posttranslationally removed either while the protein is still in the ER or immediately after its exit from the ER, resulting in the accumulation of proSH-EP minus its KDEL signal. It is this intermediate form that appears to progress through the endomembrane system and is subsequently processed to form mature active SH-EP. The removal of an ER retention may regulate protein delivery to a functional site and present an alternative role for ER retention sequences in addition to their well established role in maintaining the protein composition of the ER lumen.     

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.     

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 Slow Maturation of a Cysteine Protease with a Granulin Domain in the Vacuoles of Senescing Arabidopsis Leaves

Arabidopsis RD21 is a cysteine protease of the papain family. Unlike other members of the papain family, RD21 has a C-terminal extension sequence composed of two domains, a 2-kD proline-rich domain and a 10-kD domain homologous to animal epithelin/granulin family proteins. The RD21 protein was accumulated as 38- and 33-kD proteins in Arabidopsis leaves. An immunoblot showed that the 38-kD protein had the granulin domain, whereas the 33-kD protein did not. A pulse-chase experiment with Bright-Yellow 2 transformant cells expressing RD21 showed that RD21 was synthesized as a 57-kD precursor and was then slowly processed to make the 33-kD mature protein via the 38-kD intermediate. After a 12-h chase, the 38-kD intermediate was still detected in the cells. These results indicate that the N-terminal propeptide was first removed from the 57-kD precursor, and the C-terminal granulin domain was then slowly removed to yield the 33-kD mature protein. Subcellular fractionation of the Bright-Yellow 2 transformant showed that the intermediate and mature forms of RD21 were localized in the vacuoles. Under the acidic conditions of the vacuolar interior, the intermediate was found to be easily aggregated. The intermediate and the mature protein were accumulated in association with leaf senescence. Taken together, these results indicate that the intermediate of RD21 was accumulated in the vacuoles as an aggregate, and then slowly matured to make a soluble protease by removing the granulin domain during leaf senescence.     

Molecular characterization of a vacuolar processing enzyme related to a putative cysteine proteinase of Schistosoma mansoni.

Proproteins of various vacuolar proteins are post-translationally processed into mature forms by the action of a unique vacuolar processing enzyme. If such a processing enzyme is transported to vacuoles together with proprotein substrates, the enzyme must be a latent form. Immunocytochemical localization of a vacuolar processing enzyme, a 37-kD cysteine proteinase, in the endosperm of maturing castor bean seeds places the enzyme in the vacuolar matrix, where a variety of proproteins is also present. To characterize a molecular structure of vacuolar processing enzyme, we isolated a cDNA for the enzyme. Deduced primary structure of a 55-kD precursor is 33% identical to a putative cysteine proteinase of the human parasite Schistosoma mansoni. The precursor is composed of a signal peptide, a 37-kD active processing enzyme domain, and a propeptide fragment. Although the precursor expressed in Escherichia coli has no vacuolar processing activity, a 36-kD immunopositive protein expressed in E. coli is active. These results suggest that the activation of the vacuolar processing enzyme requires proteolytic cleavage of a 14-kD C-terminal propeptide fragment of the precursor.     

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.     

Functional analysis of the C-terminal propeptide of keratinase from Bacillus licheniformis BBE11-1 and its effect on the production of keratinase in Bacillus subtilis

The keratinase from Bacillus licheniformis BBE11-1 is a serine protease and expressed as a pre-pro-precursor. To produce a mature and active keratinase, the propeptide must be cleaved on the C-terminal via cis or trans. In this study, to enhance the production of keratinase in Bacillus subtilis, single amino acid substitutions, single residue deletions and linkers were introduced at the C-terminus of the propeptide. The results showed that optimizing the residue of cleavage site of propeptide will affect the cleavage efficiency of propeptide, and the mature enzyme yield of Leu(P1)Ala mutant increases 50% compared with the wild-type. In addition, inserting linkers and deleting individual residues at the C-terminal of the propeptide decreases the mature keratinase production. Our results indicated that the primary structure of the C-terminus of propeptide is crucial for the mature keratinase production. Propeptide engineering at C-terminus may be an effective approach to increase the yield of keratinase.     

Localization of a flavonoid biosynthetic polyphenol oxidase in vacuoles

Aureusidin synthase, a polyphenol oxidase (PPO), specifically catalyzes the oxidative formation of aurones from chalcones, which are plant flavonoids, and is responsible for the yellow coloration of snapdragon (Antirrhinum majus) flowers. All known PPOs have been found to be localized in plastids, whereas flavonoid biosynthesis is thought to take place in the cytoplasm [or on the cytoplasmic surface of the endoplasmic reticulum (ER)]. However, the primary structural characteristics of aureusidin synthase and some of its molecular properties argue against localization of the enzyme in plastids and the cytoplasm. In this study, the subcellular localization of the enzyme in petal cells of the yellow snapdragon was investigated. Sucrose-density gradient and differential centrifugation analyses suggested that the enzyme (the 39-kDa mature form) is not located in plastids or on the ER. Transient assays using a green fluorescent protein (GFP) chimera fused with the putative propeptide of the PPO precursor suggested that the enzyme was localized within the vacuole lumen. We also found that the necessary information for vacuolar targeting of the PPO was encoded within the 53-residue N-terminal sequence (NTPP), but not in the C-terminal sequence of the precursor. NTPP-mediated ER-to-Golgi trafficking to vacuoles was confirmed by means of the co-expression of an NTPP-GFP chimera with a dominant negative mutant of the Arabidopsis GTPase Sar1 or with a monomeric red fluorescent protein (mRFP)-fused Golgi marker (an H+-translocating inorganic pyrophosphatase of Arabidopsis). We identified a sequence-specific vacuolar sorting determinant in the NTPP of the precursor. We have demonstrated the biosynthesis of a flavonoid skeleton in vacuoles. The findings of this metabolic compartmentation may provide a strategy for overcoming the biochemical instability of the precursor chalcones in the cytoplasm, thus leading to the efficient accumulation of aurones in the flower.     

Molecular cloning and expression in Escherichia coli of the extracellular endoprotease of Aeromonas caviae T-64, a pro-aminopeptidase processing enzyme(1).

PA protease (pro-aminopeptidase processing protease) activates the pro-aminopeptidases from Aeromonas caviae T-64 and Vibrio proteolytica by removal of their pro-regions. Cloning and sequencing of the PA protease gene revealed that PA protease was translated as a preproprotein consisting of four domains: a signal peptide; an N-terminal propeptide; a mature region; and a C-terminal propeptide. The deduced amino acid sequence of the PA protease precursor showed significant homology with several bacterial metalloproteases. Expression of the PA protease gene in Escherichia coli indicated that the N-terminal propeptide of the PA protease precursor is essential to obtain the active form of the protease. The N- and C-terminal propeptides of the expressed pro-PA protease were processed autocatalytically.     

Isolation of a putative receptor for KDEL-tailed cysteine proteinase (SH-EP) from cotyledons of Vigna mungo seedlings.

SH-EP is the major papain-type proteinase expressed in cotyledons of germinated Vigna mungo seeds. The proteinase possesses a KDEL sequence at the C-terminus although the mature form of SH-EP is localized in vacuoles. It has also been shown that the proform of SH-EP is accumulated at the edge or middle region of the endoplasmic reticulum, and the accumulated proSH-EP is directly transported to vacuoles via the KDEL-tailed cysteine proteinase-accumulating vesicle, KV. In this study, to address the transport machinery of proSH-EP through KV, putative receptor for proSH-EP was isolated from membrane proteins of cotyledons of V. mungo seedlings using a proSH-EP-immobilized column. The deduced amino acid sequence from cDNA to the protein revealed that the putative receptor for proSH-EP is a member of vacuolar sorting receptor, VSR, that is known to be localized in the Golgi-complex and/or clathrin coated vesicle. We carried out subcellular fractionation of cotyledon cells and subsequently conducted SDS-PAGE/immunoblotting and immunocytochemistry with anti-V. mungo VSR (VmVSR) or SH-EP antibody. The results showed that VmVSR is co-localized in the fraction of the gradient in which KV existed.     

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 ricin propeptide influences the fate of ricin A-chain in tobacco protoplasts

The plant toxin ricin is synthesized in castor bean seeds as an endoplasmic reticulum (ER)-targeted precursor. Removal of the signal peptide generates proricin in which the mature A- and B-chains are joined by an intervening propeptide and a 9-residue propeptide persists at the N terminus. The two propeptides are ultimately removed in protein storage vacuoles, where ricin accumulates. Here we have demonstrated that the N-terminal propeptide of proricin acts as a nonspecific spacer to ensure efficient ER import and glycosylation. Indeed, when absent from the N terminus of ricin A-chain, the non-imported material remained tethered to the cytosolic face of the ER membrane, presumably by the signal peptide. This species appeared toxic to ribosomes. The propeptide does not, however, influence catalytic activity per se or the vacuolar targeting of proricin or the rate of retrotranslocation/degradation of A-chain in the cytosol. The likely implications of these findings to the survival of the toxin-producing tissue are discussed.     

Expression and characterization of recombinant gamma-tryptase

Tryptases are trypsin-like serine proteases whose expression is restricted to cells of hematopoietic origin, notably mast cells. gamma-Tryptase, a recently described member of the family also known as transmembrane tryptase (TMT), is a membrane-bound serine protease found in the secretory granules or on the surface of degranulated mast cells. The 321 amino acid protein contains an 18 amino acid propeptide linked to the catalytic domain (cd), followed by a single-span transmembrane domain. gamma-Tryptase is distinguished from other human mast cell tryptases by the presence of two unique cysteine residues, Cys(26) and Cys(145), that are predicted to form an intra-molecular disulfide bond linking the propeptide to the catalytic domain to form the mature, membrane-anchored two-chain enzyme. We expressed gamma-tryptase as either a soluble, single-chain enzyme with a C-terminal His tag (cd gamma-tryptase) or as a soluble pseudozymogen activated by enterokinase cleavage to form a two-chain protein with an N-terminal His tag (tc gamma-tryptase). Both recombinant proteins were expressed at high levels in Pichia pastoris and purified by affinity chromatography. The two forms of gamma-tryptase exhibit comparable kinetic parameters, indicating the propeptide does not contribute significantly to the substrate affinity or activity of the protease. Substrate and inhibitor library screening indicate that gamma-tryptase possesses a substrate preference and inhibitor profile distinct from that of beta-tryptase. Although the role of gamma-tryptase in mast cell function is unknown, our results suggest that it is likely to be distinct from that of beta-tryptase.     

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.