Partial characterization of an enzyme fraction with protease activity which converts the spore peptidoglycan hydrolase (SleC) precursor to an active enzyme during germination of Clostridium perfringens S40 spores and analysis of a gene cluster involved in the activity

A spore cortex-lytic enzyme of Clostridium perfringens S40 which is encoded by sleC is synthesized at an early stage of sporulation as a precursor consisting of four domains. After cleavage of an N-terminal presequence and a C-terminal prosequence during spore maturation, inactive proenzyme is converted to active enzyme by processing of an N-terminal prosequence with germination-specific protease (GSP) during germination. The present study was undertaken to characterize GSP. In the presence of 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid (CHAPS), a nondenaturing detergent which was needed for the stabilization of GSP, GSP activity was extracted from germinated spores. The enzyme fraction, which was purified to 668-fold by column chromatography, contained three protein components with molecular masses of 60, 57, and 52 kDa. The protease showed optimum activity at pH 5.8 to 8.5 in the presence of 0.1% CHAPS and retained activity after heat treatment at 55 degrees C for 40 min. GSP specifically cleaved the peptide bond between Val-149 and Val-150 of SleC to generate mature enzyme. Inactivation of GSP by phenylmethylsulfonyl fluoride and HgCl(2) indicated that the protease is a cysteine-dependent serine protease. Several pieces of evidence demonstrated that three protein components of the enzyme fraction are processed forms of products of cspA, cspB, and cspC, which are positioned in a tandem array just upstream of the 5' end of sleC. The amino acid sequences deduced from the nucleotide sequences of the csp genes showed significant similarity and showed a high degree of homology with those of the catalytic domain and the oxyanion binding region of subtilisin-like serine proteases. Immunochemical studies suggested that active GSP likely is localized with major cortex-lytic enzymes on the exterior of the cortex layer in the dormant spore, a location relevant to the pursuit of a cascade of cortex hydrolytic reactions.     

Unusual structural features of the bacteriophage-associated hyaluronate lyase (hylp2)

Hyaluronate lyases are a class of endoglycosaminidase enzymes, which are of considerable complexity and heterogeneity. Their primary function is to degrade hyaluronan and certain other glycosaminoglycans and facilitate the spread of disease. Among hyaluronate lyases, the bacteriophage-associated enzymes are unique as they have the lowest molecular mass, very low amino acid sequence homology with bacterial hyaluronate lyases, and exhibit absolute specificity for one type of glycosaminoglycan, i.e. hyaluronan. Despite such unique characteristics significant details on structural features of these lyases are not available. The Streptococcus pyogenes bacteriophage 10403 contains a gene, hylP2, which encodes for hyaluronate lyase (HylP2) in this organism. HylP2 was cloned, overexpressed, and purified to homogeneity. The recombinant HylP2 exists as a homotrimer of molecular mass about 110 kDa, under physiological conditions. Limited proteolysis and guanidine hydrochloride denaturation studies demonstrated that the N-terminal region of the protein is flexible, whereas the C-terminal portion has a compact conformation. The enzyme shows sequential unfolding, with the N-terminal unfolding first followed by the simultaneous unfolding and dissociation of the stabilized trimeric C-terminal domain. We isolated a functionally active C-terminal fragment (Ser(128)-Lys(337)) of the protein that was stabilized in a trimeric configuration. Comparative functional studies with full-length protein, N:C complex, and isolated C-terminal domain demonstrated that the active site of HylP2 is present in the C-terminal portion of the enzyme, and the N-terminal portion modulates the substrate specificity and enzymatic activity of the C-terminal domain.     

Expression of a synthetic gene for horseradish peroxidase C in Escherichia coli and folding and activation of the recombinant enzyme with Ca2+ and heme

A synthetic gene encoding horseradish peroxidase isoenzyme C (HRP C) has been synthesized and expressed in Escherichia coli. The nonglycosylated recombinant enzyme (HRP C*) was produced in inclusion bodies in an insoluble inactive form containing only traces of heme. HRP C* was solubilized and conditions under which it folded to give active enzyme were determined. Folding was shown to be critically dependent upon the concentrations of urea, Ca2+, and heme and on oxidation by oxidized glutathione. Purification of active HRP C* from the folding mixture gave a peroxidase, with about half the activity of HRP C. Glycosylation is thus not essential for correct folding and activity. The C-terminal and N-terminal extensions to HRP identified previously in cloned cDNA sequences are also not required for correct folding. However, Ca2+ appears to play a key role in folding to give the active enzyme. The overall yield of purified active enzyme was 2-3%, but this could be increased by reprocessing material that precipitated during folding.     

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.     

The propeptide is not required to produce catalytically active neutral protease from Bacillus stearothermophilus

The thermolysin-like neutral protease from Bacillus stearothermophilus (TLP-ste) is usually produced extracellularly in Bacillus subtilis, where it is expressed as preproenzyme and subsequently processed in an autocatalytic, intramolecular process. To create the basis for the production of inactive mutants of TLP-ste, which cannot be processed in B. subtilis, we studied the expression of TLP-ste and its propeptide in cis and in trans in Escherichia coli. In contrast to thermolysin, subtilisin and alpha-lytic protease, which could be obtained only in the presence of the corresponding propeptides, TLP-ste could be produced as an active mature enzyme in E. coli in the absence of its prosequence. Surprisingly, however, a much more effective access to active mature protease was found when TLP-ste (devoid of its prosequence) was expressed as protein with an N-terminal His6 tag which accumulated in the form of inclusion bodies. Completely unexpected, the protein could be renatured from the inclusion bodies after solubilization in guanidine hydrochloride solutions in high yields. Purification to homogeneity was possible by affinity chromatography on Bacitracin silica as well as by immobilized metal ion affinity chromatography. By addition of separately expressed propeptide to the renaturation mixture yields of renaturation could not be increased significantly, confirming that the propeptide is not essential for proper folding of the enzyme or its stabilization during the folding process. Also in vivo, the expression levels of active mature TLP-ste in Escherichia coli did not significantly differ when the mature sequence was expressed alone or coexpressed with the prosequence in cis or in trans.     

Endoproteolytic cleavage of human thyroperoxidase: role of the propeptide in the protein folding process

Human thyroperoxidase (hTPO), the key enzyme involved in thyroid hormone synthesis, is synthesized in the form of a 933-amino acid polypeptide that subsequently undergoes posttranslational modifications such as N- and O-glycosylation and heme fixation. In the present study, it was established that the N-terminal part of hTPO is cleaved during the maturation of the enzyme. In the first set of experiments performed in this study, Chines hamster ovary (CHO) cells transfected with hTPO cDNA generated four different species after deglycosylation, namely a 98-kDa species, which corresponds to the full-length deglycosylated hTPO, and two 94-kDa and one 92-kDa species, which were truncated in the N-terminal parts. The three latter forms were detected only at the cell surface. A proprotein convertase inhibitor prevented these cleavages, and experiments using monensin and brefeldin A showed that they occurred in a post-endoplasmic reticulum compartment. Site-directed mutagenesis studies were performed in which Arg65 was identified as one of the cleavage sites. In the second part of the study, hTPO from human thyroid glands was purified using a monoclonal antibody recognizing the folded form of hTPO. Amino acid determination showed that the N-terminal part of this protein begins at Thr109. This cleavage process differs from that observed in CHO cells. The fact that this hTPO was endoglucosaminidase H-sensitive indicated that the cleavage of the propeptide occurs in the endoplasmic reticulum. To analyze the role of the hTPO prosequence, cDNAs with and without prosequence (Cys15-Lys108) were transfected into CHO cells. hTPO propeptide deletion drastically decreased the proportion of the folded hTPO form, and under these conditions the cell surface activity disappeared completely. These results strongly suggest that the prosequence plays a crucial role as an intramolecular chaperone, facilitating the folding of hTPO.     

Generation of the BfiI restriction endonuclease from the fusion of a DNA recognition domain to a non-specific nuclease from the phospholipase D superfamily

The BfiI endonuclease cleaves DNA at fixed positions downstream of an asymmetric sequence. Unlike other restriction enzymes, it functions without metal ions. The N-terminal half of BfiI is similar to Nuc, an EDTA-resistant nuclease from Salmonella typhimurium that belongs to the phosphoplipase D superfamily. Nuc is a dimer with one active site at its subunit interface, as is BfiI, but it cuts DNA non-specifically. BfiI was cleaved by thermolysin into an N-terminal domain, which forms a dimer with non-specific nuclease activity, and a C-terminal domain, which lacks catalytic activity but binds specifically to the recognition sequence as a monomer. On denaturation with guanidinium, BfiI underwent two unfolding transitions: one at a relatively low concentration of guanidinium, to a dimeric non-specific nuclease; a second at a higher concentration, to an inactive monomer. The isolated C-terminal domain unfolded at the first (relatively low) concentration, the isolated N-terminal at the second. Hence, BfiI consists of two physically separate domains, with catalytic and dimerisation functions in the N terminus and DNA recognition functions in the C terminus. It is the first example of a restriction enzyme generated by the evolutionary fusion of a DNA recognition domain to a phosphodiesterase from the phospholipase D superfamily. BfiI may consist of three structural units: a stable central core with the active site, made from two copies of the N-terminal domain, flanked by relatively unstable C-terminal domains, that each bind a copy of the recognition sequence.     

A second lysine-specific serine protease from Lysobacter sp. strain IB-9374

A second lysyl endopeptidase gene (lepB) was found immediately upstream of the previously isolated lepA gene encoding a highly active lysyl endopeptidase in Lysobacter genomic DNA. The lepB gene consists of 2,034 nucleotides coding for a protein of 678 amino acids. Amino acid sequence alignment between the lepA and lepB gene products (LepA and LepB) revealed that the LepB precursor protein is composed of a prepeptide (20 amino acids [aa]), a propeptide (184 aa), a mature enzyme (274 aa), and a C-terminal extension peptide (200 aa). The mature enzyme region exhibited 72% sequence identity to its LepA counterpart and conserved all essential amino acids constituting the catalytic triad and the primary determining site for lysine specificity. The lepB gene encoding the propeptide and mature-enzyme portions was overexpressed in Escherichia coli, and the inclusion body produced generated active LepB through appropriate refolding and processing. The purified enzyme, a mature 274-aa lysine-specific endopeptidase, was less active and more sensitive to both temperature and denaturation with urea, guanidine hydrochloride, or sodium dodecyl sulfate than LepA. LepA-based modeling implies that LepB can fold into essentially the same three-dimensional structure as LepA by placing a peptide segment, composed of several inserted amino acids found only in LepB, outside the molecule and that the Tyr169 side chain occupies the site in which the indole ring of Trp169, a built-in modulator for unique peptidase functions of LepA, resides. The results suggest that LepB is an isozyme of LepA and probably has a tertiary structure quite similar to it.     

Function of the prosequence for in vivo folding and secretion of active Rhizopus oryzae lipase in Saccharomyces cerevisiae

The role of the prosequence of Rhizopus oryzae lipase (ROL) with a preprosequence was analyzed by an expression system using Saccharomyces cerevisiae. When the mature portion of ROL (mROL) fused to the pre-alpha-factor leader sequence was expressed, secretion of active mROL was not observed. However, when mROL was synthesized together with the prosequence in trans (individually and coincidentally), secretion of active mROL was observed. The results indicate that the prosequence of ROL helped correct folding of mROL and its subsequent secretion from the yeast cells, and that physical linkage (cis) of the prosequence to the mature region was not prerequisite. From the expression of the ROL mutants with deletions at the N-terminal end of the prosequence together with mROL in trans, the residues from 20 to 37 in the prosequence were essential for the secretion, and those from 38 to 57 were essential for the formation of the active ROL and might play a role as an intramolecular chaperone. The results using the fragment of the prosequence confirmed that these residues (20-57) were significant for in vivo folding and secretion of active mROL.     

Efficient production of active Vibrio proteolyticus aminopeptidase in Escherichia coli by co-expression with engineered vibriolysin

The Vibrio proteolyticus aminopeptidase is synthesized as a preproprotein and then converted into an active enzyme by cleavage of the N-terminal propeptide. In recombinant Escherichia coli, however, the aminopeptidase is not processed correctly and the less-active form that has the N-terminal propeptide accumulates in the culture medium. Recently, we isolated a novel vibriolysin that was expressed as an active form in E. coli by random mutagenesis; this enzyme shows potential as a candidate enzyme for the processing of aminopeptidase. The E. coli cells were engineered to co-express the novel vibriolysin along with aminopeptidase. Co-expression of vibriolysin resulted in an approximately 13-fold increase in aminopeptidase activity, and a further increase was observed in the form lacking its C-terminal propeptide. The active aminopeptidase was purified from the culture supernatant including the recombinant vibriolysin by heat treatment and ion exchange and hydroxyapatite chromatography with high purity and 35% recovery rate. This purified aminopeptidase effectively converted methionyl-human growth hormone (Met-hGH) to hGH. Thus, this co-expression system provides an efficient method for producing active recombinant V. proteolyticus aminopeptidase.     

Enhancement of transglycosylation activity by construction of chimeras between mesophilic and thermophilic beta-glucosidase

The family 3 beta-glucosidase from Thermotoga maritima is a highly thermostable enzyme (85 degrees C) that displays transglycosylation activity. In contrast, the beta-glucosidase from Cellvibrio gilvus is mesophilic (35 degrees C) and displays no such transglycosylation activity. Both enzymes consist of two domains, an N-terminal and a C-terminal domain, and the amino acid identities between the two enzymes in these domains are 32.4 and 36.4%, respectively. In an attempt to identify the molecular basis underpinning the display of transglycosylation activity and the requirements for thermal stability, eight chimeric genes were constructed by shuffling the two parental beta-glucosidase genes at four selected borders, two in the N-terminal domain and two in the C-terminal domain. Of the eight chimeric genes constructed, only two chimeric enzymes (Tm578/606Cg and Tm638/666Cg) gave catalytically active forms and these were the ones shuffled in the C-terminal domain. For these active chimeric enzymes, 80% (Tm578/606Cg) and 88% (Tm638/666Cg) of their amino acid sequences originated from T. maritima. With regard to their thermal profiles, the two active chimeric enzymes, Tm578/606Cg and Tm638/666Cg, displayed profiles intermediate to those of the two parental enzymes as they were optimally active at 65 and 70 degrees C, respectively. These two chimeric enzymes were optimally active at pH 4.1 and 3.9, which is closer to that observed for the T. maritima enzyme (pH 3.2-3.5) than that for the C. gilvus enzyme (pH 6.2-6.5). Kinetic parameters for the chimeric enzymes were investigated with five different substrates including pNP-beta-D-glucopyranoside. The kinetic parameters obtained for the chimeric enzymes were closer to those of the T. maritima enzyme than to those of the C. gilvus enzyme. Transglycosylation activity was observed for both chimeric enzymes and the activity of the Tm578/606Cg chimera was at a level twice that observed with the T. maritima enzyme. This study is an effective demonstration of the usefulness of chimeric enzymes in altering the characteristics of an enzyme.     

Two sites of primary degradation of the D1-protein induced by acceptor or donor side photo-inhibition in photosystem II core complexes.

Depending on experimental conditions we have found that photo-inhibitory treatment of photosystem II (PSII) core complexes, isolated from wheat, can generate two fragments of about 23-24 kDa that contain either the C-terminal or N-terminal regions of the D1-protein. A 24 kDa C-terminal fragment appears when the water splitting reaction is not functional and an electron acceptor is present. This 'donor'-side inhibition also generates an N-terminal fragment of about 10 kDa and is suggested to be due to the cleavage of a peptide bond in the region connecting transmembrane segments I and II of the D1-protein. In contrast, an N-terminal 23 kDa D1-protein fragment is detected when the water splitting reactions of the isolated complex are active, and occurs in the absence of an added electron acceptor. This 'acceptor'-side photo-inhibition also generates a C-terminal fragment of about 10 kDa.     

Identification of the lysine residue modified during the activation of acetimidylation of horse liver alcohol dehydrogenase.

A single amino group in horse liver alcohol dehydrogenase was modified with methyl(14C)acetimidate by a differential labeling procedure. Lysine residues outside the active site were modified with ethyl acetimidate while a lysine residue in the active site was protected by the formation of an enzyme-NAD+-pyrazole complex. After the protecting reagents were removed, the enzyme was treated with methyl(14C)acetimidate. Enzyme activity was enhanced 13-fold as 1.1 (14C)acetimidyl group was incorporated per active site. A labeled peptide was isolated from a tryptic-chymotryptic digest of the modified enzyme in 35% overall yield. Amino acid composition and sequential Edman degradations identified the peptide as residues 219-229; lysine residue 228 was modified with the radioactive acetimidyl group.     

The crystal structure of a Cys25 -> Ala mutant of human procathepsin S elucidates enzyme-prosequence interactions

The crystal structure of the active-site mutant Cys25 --> Ala of glycosylated human procathepsin S is reported. It was determined by molecular replacement and refined to 2.1 Angstrom resolution, with an R-factor of 0.198. The overall structure is very similar to other cathepsin L-like zymogens of the C1A clan. The peptidase unit comprises two globular domains, and a small third domain is formed by the N-terminal part of the prosequence. It is anchored to the prosegment binding loop of the enzyme. Prosegment residues beyond the prodomain dock to the substrate binding cleft in a nonproductive orientation. Structural comparison with published data for mature cathepsin S revealed that procathepsin S residues Phe146, Phe70, and Phe211 adopt different orientations. Being part of the S1' and S2 pockets, they may contribute to the selectivity of ligand binding. Regarding the prosequence, length, orientation and anchoring of helix alpha3p differ from related zymogens, thereby possibly contributing to the specificity of propeptide-enzyme interaction in the papain family. The discussion focuses on the functional importance of the most conserved residues in the prosequence for structural integrity, inhibition and folding assistance, considering scanning mutagenesis data published for procathepsin S and for its isolated propeptide.     

Characterization and gene cloning of a cold-active cellulase from a deep-sea psychrotrophic bacterium Pseudoalteromonas sp. DY3

The celX gene encoding an extracellular cold-active cellulase was isolated from a psychrotrophic bacterium, which was isolated from deep-sea sediment and identified as a Pseudoalteromonas species. It encoded a protein consisting of 492 amino acids with a calculated molecular mass of 52.7 kDa. The CelX consisted of an N-terminal catalytic domain belonging to glycoside hydrolase family 5 and a C-terminal cellulose-binding domain belonging to carbohydrate-binding module family 5. The long linker sequence connecting both domains was composed of 105 residues. The optimal temperature for cellulase activity of CelX was 40°C. The enzyme was most active at pH 6–7 and showed better resistance to alkaline condition. The zymogram activity analysis indicated that the CelX consisted of single enzyme component. The cellobiose was main hydrolysate of CelX.     

Effect of His-tag location on the catalytic activity of 3-hydroxybutyrate dehydrogenase

The effect of hexahistidine-tag (His-tag) location at either the C or N-terminus on the catalytic activity of 3-hydroxybutyrate dehydrogenase (3HBDH) from Alcaligenes faecalis was studied. The kinetic parameters of 3HBDHs with C and N-terminal His-tags were investigated, and the enzyme with an N-terminal His-tag was found to have approximately 1,200-fold higher catalytic efficiency than its C-terminal counterpart. Furthermore, the effect of His-tag location on the catalytic activity of 3 engineered variants of 3HBDH that were previously developed for the conversion of levulinic acid to 4-hydroxyvaleric acid was also investigated. All of the N-terminal variants exhibited higher catalytic efficiency for levulinic acid than did the C-terminal counterparts. The structural basis of the His-tag effect was studied by investigating the structure of 3HBDH obtained from in silico His-tag modification, and the results revealed that the modification of the C-terminal structure could deform the hinge region of the active site entry loop, disrupting the catalytic motion of the enzyme. In contrast, due to the location of the N-terminus far from the active site of the enzyme, the catalytic activity of the enzyme was not severely affected by the N-terminal His-tag.     

Lanthionine introduction into nukacin ISK-1 prepeptide by co-expression with modification enzyme NukM in Escherichia coli

We demonstrated lanthionine introduction into hexa-histidine-tagged (His-tagged) nukacin ISK-1 prepeptide NukA by modification enzyme NukM in Escherichia coli. Co-expression of nukA and nukM, purification of the resulting His-tagged prepeptide by affinity chromatography, and subsequent mass spectrometry analysis showed that the prepeptide was converted into a postulated peptide with decrease in mass of 72Da which resulted from dehydration of four amino acids. Characterization of the resultant prepeptide indicated the presence of unusual amino acids, such as dehydrated amino acid, lanthionine or 3-methyllanthionine, in its C-terminal propeptide moiety. The modified prepeptide encompassing the leader peptide attached to the post-translationally modified propeptide moiety was readily obtained by one-step purification. Our findings will thus be a powerful tool for introducing unusual amino acids aimed at peptide engineering and also helpful to provide new insight for further understanding of lanthionine-forming enzymes for lantibiotics.     

Functional phytohemagglutinin (PHA) and Galanthus nivalis agglutinin (GNA) expressed in Pichia pastoris correct N-terminal processing and secretion of heterologous proteins expressed using the PHA-E signal peptide.

Phytohemagglutinin (Phaseolus vulgaris agglutinin; PHA; E- and L-forms) and snowdrop lectin (Galanthus nivalis agglutinin; GNA) were expressed in Pichia pastoris using native signal peptides, or the Saccharomyces alpha-factor preprosequence, to direct proteins into the secretory pathway. PHA and GNA were present as soluble, functional proteins in culture supernatants when expressed from constructs containing the alpha-factor preprosequence. The recombinant lectins, purified by affinity chromatography, agglutinated rabbit erythrocytes at concentrations similar to the respective native lectins. However, incomplete processing of the signal sequence resulted in PHA-E, PHA-L and GNA with heterogenous N-termini, with the majority of the protein containing N-terminal extensions derived from the alpha-factor prosequence. Polypeptides in which most of the alpha-factor prosequence was present were also glycosylated. Inclusion of Glu-Ala repeats at the C-terminal end of the alpha-factor preprosequence led to efficient processing N-terminal to the Glu-Ala sequence, but inefficient removal of the repeats themselves, resulting in polypeptides with heterogenous N-termini still containing N-terminal extensions. In contrast, PHA expressed with the native signal peptide was secreted, correctly processed, and also fully functional. No expression of GNA from a construct containing the native GNA signal peptide was observed. The PHA-E signal peptide directed correct processing and secretion of both GNA and green fluorescent protein (GFP) when used in expression constructs, and is suggested to have general utility for synthesis of correctly processed proteins in Pichia.     

Selective cleavage of human ACTH, beta-lipotropin, and the N-terminal glycopeptide at pairs of basic residues by IRCM-serine protease 1. Subcellular localization in small and large vesicles

We present a study of the cleavage specificity of IRCM-serine protease 1 from frozen porcine pituitary neurointermediate lobes using polypeptide substrates representing different segments of human pro-opiomelanocortin. Using 125I-labeled ACTH(11-24) and a 125I-labeled model beta-lipotropin (beta-LPH) peptide, the preference of this protease for cleavage C-terminal to the pairs of basic residues Lys-Arg and Lys-Lys was clearly seen. This study was extended to larger unlabeled natural human polypeptides including ACTH(1-39), beta-LPH(1-89), and the N-terminal glycopeptide (1-76), which are known to serve as substrates for further cleavage in vivo. In these substrates IRCM-serine protease 1 cleaved C-terminal to all pairs of basic residues known to be cleaved in vivo. In addition, the enzyme cleaved between two pairs of basic amino acids found in NT(1-76) which are also known to be cleaved in vivo. Many potential "tryptic-like" cleavage sites were not cleaved by the enzyme. However, IRCM-serine protease 1 cleaved C-terminal to Phe-Arg in the three melanocyte-stimulating hormone sequences of pro-opiomelanocortin. In order to better understand the physiological role of IRCM-serine protease 1, differential centrifugation was used to study the subcellular distribution of the enzyme from porcine pituitary anterior lobe homogenates. We present evidence that the active enzyme form, isolated from the subcellular fractions, possesses a similar molecular architecture as the enzyme isolated from frozen tissue (Mr 38,000 catalytic domain linked via disulfide bridge(s) to another polypeptide chain(s) to form an Mr 88,000 monomeric structure). The majority of IRCM-serine protease activity is found to be associated with small vesicles (150,000 X g for 5 h) of as yet undetermined nature. In addition, a latent activity was found to be associated with a 27,000 X g (15 min) pellet containing the majority of mature secretory granules. If IRCM-serine protease 1 participates in prohormone maturation in vivo, we propose a model in which this protease is present in an enzymatically active form in small vesicles, possibly within clathrin-coated structures (prosecretory granules) which are then transformed to mature secretory granules by a process which would also inactivate most of the enzyme.     

The lipase C-terminal domain. A novel unusual inhibitor of pancreatic lipase activity

In vertebrates, dietary fat digestion mainly results from the combined effect of pancreatic lipase, colipase, and bile. It has been proposed that in vivo lipase adsorption on oil-water emulsion is mediated by a preformed lipase-colipase-mixed micelle complex. The main lipase-colipase binding site is located on the C-terminal domain of the enzyme. We report here that in vitro the isolated C-terminal domain behaves as a potent noncovalent inhibitor of lipase and that the inhibitory effect is triggered by the presence of micelles. Lipase inhibition results from the formation of a nonproductive C-terminal domain-colipase-micelle ternary complex, which competes for colipase with the active lipase-colipase-micelle ternary complex, thus diverting colipase from its lipase-anchoring function. The formation of such a complex has been evidenced by molecular sieving experiments. This nonproductive complex lowers the amount of active lipase thus reducing lipolysis. Preliminary experiments performed in rats show that the C-terminal domain also behaves as an inhibitor in vivo and thus could be considered a potential new tool for specifically reducing intestinal lipolysis.