Baculoviral expression and characterization of human recombinant PGCP in the form of an active mature dimer and an inactive precursor protein

The human-blood plasma glutamate carboxypeptidase (PGCP) is a proteinase that acts on the unsubstituted N- and C-termini of dipeptides. It has been suggested that this PGCP is involved in the release of thyroxine. Furthermore, research has suggested that its activity is up-regulated in hepatitis-C-virus-infected patients with hepatocellular carcinoma. In this study expressed human PGCP in the baculovirus expression system was produced by a Sf9 insect cell line with aim to prepare sufficient amounts of active recombinant enzyme for a subsequent biological characterization. Recombinant PGCP was expressed and secreted into the medium in the form of an inactive proenzyme. It was gradually converted into an active form in the medium after three days, with the highest expression of the active form on day six. The protein was sequentially purified by a combination of various liquid chromatographies, such as hydroxyapatite, ion exchange, and gel chromatography, and as final step with affinity chromatography on Phe-Leu-Sepharose. The human PGCP was purified as an active enzyme in the dimer form and as inactive precursor protein. The dipeptidase activity was confirmed by measuring the hydrolysis of the Ser-Met dipeptide at a slightly acidic pH.     

The deduced protein sequence of the human carboxypeptidase N high molecular weight subunit reveals the presence of leucine-rich tandem repeats

Human plasma carboxypeptidase N is a 280-kDa tetramer with two high molecular mass (83-kDa) glycosylated subunits which protect the two 50-kDa catalytic subunits and keep them in the circulation. An initial clone for the 83-kDa subunit was obtained by screening two lambda gt11 human liver cDNA expression libraries with antiserum specific for carboxypeptidase N or the 83-kDa subunit. The libraries were rescreened with the labeled cloned cDNA, and the largest clone obtained (2536-base pair insert) was completely sequenced. The deduced protein sequence matched the sequence of several tryptic peptides from the 83-kDa subunit but did not contain the NH2-terminal sequence. The remaining portion of the protein coding sequence was synthesized by the polymerase chain reaction, cloned, and sequenced. The composite cDNA sequence is 2870 base pairs long with an open reading frame of 1608 base pair coding for a protein of 536 amino acids (Mr = 58,762). The protein sequence contains seven potential N-linked glycosylation sites and a threonine/serine-rich region which is a potential site for attachment of O-linked carbohydrate. The most striking feature is a region (residues 68-355) containing 12 leucine-rich tandem repeats of 24 residues with the following consensus sequence: P-X-X-alpha-F-X-X-L-X-X-L-X-X-L-X-L-X-X-N-X-L-X-X-L (X = any amino acid and alpha = aliphatic amino acids, I, L, or V). This repeating pattern is found in the leucine-rich alpha 2-glycoprotein and in other proteins where it might mediate interactions with macromolecules. This region also contains five sequences with heptad repeating leucine residues comprising a leucine zipper motif. The leucine-rich domain likely constitutes an important structural or functional element in the interactions of the 83- and 50-kDa subunits to form the active tetramer of carboxypeptidase N.     

Expression of lysosomal protective protein/cathepsin A in a stably transformed human neuroblastoma cell line during bi-directional differentiation into neuronal and Schwannian cells

Human neuroblastoma GOTO cell lines were established that stably express recombinant human lysosomal protective protein/cathepsin A (PPCA) cDNA by transfection. Intracellular cathepsin A (acid serine carboxypeptidase) activity increased four-fold compared with in those of the parent and mock-transfected cell lines. The immunoreactive 54 kDa precursor/zymogen and mature 32/20 kDa two-chain forms were produced in the cells. The amount of the latter form expressed in the GOTO cells was significantly larger than those in the PPCA-overexpressing CHO cell lines previously established. The intracellular proteins showed a typical lysosomal granular distribution and the glycosylated 54 kDa precursor was secreted into the culture medium without the addition of an alkalizing agent. The PPCA-overexpressing cell lines also retained the ability to differentiate bi-directionally as well as the parent cells; into neuronal cells on induction by dibutyryl cAMP in serum-free medium and into Schwannian cells on induction by bromodeoxyuridine. During the course of differentiation into neuronal and Schwannian cells, the intracellular cathepsin A activity further increased two and five times, respectively, which was associated with an increase in the expression of the 32/20 kDa two-chain form. The glycosylated precursor proteins were taken up via the mannose 6-phosphate receptors, and the cathepsin A, alpha-neuraminidase and beta-galactosidase (beta-Gal) activities deficient in the fibroblasts derived from a patient with PPCA deficiency (galactosialidosis) were restored. These results suggest that the bi-directional differentiation of GOTO cell lines stably expressing the recombinant human PPCA gene could be a model system for analyzing the functions of PPCA in peripheral neuronal cells and Schwannian cells as well as the recombinant PPCA could be a useful source for enzyme replacement therapy (ERT) for galactosialidosis patients.     

An Active 32-kDa Cathepsin L Is Secreted Directly from HT 1080 Fibrosarcoma Cells and Not via Lysosomal Exocytosis

Cathepsin L [EC 3.4.22.15] is secreted via lysosomal exocytosis by several types of cancer cells, including prostate and breast cancer cells. We previously reported that human cultured fibrosarcoma (HT 1080) cells secrete cathepsin L into the medium; this secreted cathepsin is 10-times more active than intracellular cathepsin. This increased activity was attributed to the presence of a 32-kDa cathepsin L in the medium. The aim of this study was to examine how this active 32-kDa cathepsin L is secreted into the medium. To this end, we compared the secreted active 32-kDa cathepsin L with lysosomal cathepsin L by using a novel gelatin zymography technique that employs leupeptin. We also examined the glycosylation and phosphorylation status of the proteins by using the enzymes endoglycosidase H [EC 3.2.1.96] and alkaline phosphatase [EC 3.1.3.1]. Strong active bands corresponding to the 32-kDa and 34-kDa cathepsin L forms were detected in the medium and lysosomes, respectively. The cell extract exhibited strong active bands for both forms. Moreover, both forms were adsorbed onto a concanavalin A-agarose column. The core protein domain of both forms had the same molecular mass of 30 kDa. The 32-kDa cathepsin L was phosphorylated, while the 34-kDa lysosomal form was dephosphorylated, perhaps because of the lysosomal marker enzyme, acid phosphatase. These results suggest that the active 32-kDa form does not enter the lysosomes. In conclusion, our results indicate that the active 32-kDa cathepsin L is secreted directly from the HT 1080 cells and not via lysosomal exocytosis.     

Mutations of the C-terminal end of cathepsin K affect proenzyme secretion and intracellular maturation

Transfection of the human cathepsin K cDNA into CHO cells results in the expression of mature catalytically active 27-kDa protein and in cells secreting the 39-kDa proenzyme form. Monensin, which neutralizes the pH of acidic organelles, was found to inhibit intracellular processing of the proenzyme and to stimulate its secretion into the culture medium. Brefeldin A caused alterations in immunofluorescence staining consistent with interference of lysosomal targeting and inhibited both intracellular processing and secretion of cathepsin K. Inhibition of glycosylation by tunicamycin also abolished cathepsin K maturation. Furthermore, the processing of the proenzyme to the mature form was abolished by a single mutation of the terminal Met(329) to Ala. The triple mutation of Ser(325), Pro(327), and Met(329) (all to Ala) inhibited both maturation and secretion, using either transient or stable expression systems. The results indicate that intracellular maturation and secretion of cathepsin K can be affected differentially by various treatments and by mutations of the C-terminal end of the protein. These results are consistent with the involvement of both the secreted proenzyme and the intracellularly processed enzyme in cathepsin K-mediated processes.     

Isolation, molecular cloning, and partial characterization of a novel carboxypeptidase B from human plasma

A novel plasminogen-binding protein has been isolated from human plasma utilizing plasminogen-Sepharose affinity chromatography. This protein copurified with alpha 2 antiplasmin when the plasminogen affinity column was eluted with high concentrations of epsilon-aminocaproic acid (greater than 20 mM). Analysis by sodium dodecyl sulfate suggests this protein has an apparent Mr of 60,000. The amino-terminal amino acid sequence showed no similarity to other protein sequences. Based on the amino-terminal amino acid sequence, oligonucleotide probes were designed for polymerase chain reaction primers, and an approximately 1,800 base pair cDNA was isolated that encodes this Mr 60,000 protein. The deduced amino acid sequence reveals a primary translation product of 423 amino acids that is very similar to carboxypeptidase A and B and consists of a 22-amino acid signal peptide, a 92-amino acid activation peptide, and a 309-amino acid catalytic domain. This protein shows 44 and 40% similarity to rat procarboxypeptidase B and human mast cell procarboxypeptidase A, respectively. The residues critical for catalysis and zinc and substrate binding of carboxypeptidase A and B are conserved in the Mr 60,000 plasminogen-binding protein. The presence of aspartic acid at position 257 of the catalytic domain suggests that this protein is a basic carboxypeptidase. When activated by trypsin, it hydrolyzes carboxypeptidase B substrates, hippuryl-Arg and hippuryl-Lys, but not carboxypeptidase A substrates, and it is inhibited by the specific carboxypeptidase B inhibitor (DL-5-guanidinoethyl)mercaptosuccinic acid. We propose that the Mr 60,000 plasminogen-binding protein isolated here is a novel human plasma carboxypeptidase B and that it be designated pCPB.     

Characterization of a digestive carboxypeptidase from the insect pest corn earworm (Helicoverpa armigera) with novel specificity towards C-terminal glutamate residues.

Carboxypeptidases were purified from guts of larvae of corn earworm (Helicoverpa armigera), a lepidopteran crop pest, by affinity chromatography on immobilized potato carboxypeptidase inhibitor, and characterized by N-terminal sequencing. A larval gut cDNA library was screened using probes based on these protein sequences. cDNA HaCA42 encoded a carboxypeptidase with sequence similarity to enzymes of clan MC [Barrett, A. J., Rawlings, N. D. & Woessner, J. F. (1998) Handbook of Proteolytic Enzymes. Academic Press, London.], but with a novel predicted specificity towards C-terminal acidic residues. This carboxypeptidase was expressed as a recombinant proprotein in the yeast Pichia pastoris. The expressed protein could be activated by treatment with bovine trypsin; degradation of bound pro-region, rather than cleavage of pro-region from mature protein, was the rate-limiting step in activation. Activated HaCA42 carboxypeptidase hydrolysed a synthetic substrate for glutamate carboxypeptidases (FAEE, C-terminal Glu), but did not hydrolyse substrates for carboxypeptidase A or B (FAPP or FAAK, C-terminal Phe or Lys) or methotrexate, cleaved by clan MH glutamate carboxypeptidases. The enzyme was highly specific for C-terminal glutamate in peptide substrates, with slow hydrolysis of C-terminal aspartate also observed. Glutamate carboxypeptidase activity was present in larval gut extract from H. armigera. The HaCA42 protein is the first glutamate-specific metallocarboxypeptidase from clan MC to be identified and characterized. The genome of Drosophila melanogaster contains genes encoding enzymes with similar sequences and predicted specificity, and a cDNA encoding a similar enzyme has been isolated from gut tissue in tsetse fly. We suggest that digestive carboxypeptidases with sequence similarity to the classical mammalian enzymes, but with specificity towards C-terminal glutamate, are widely distributed in insects.     

cDNA cloning and complete primary structure of the small, active subunit of human carboxypeptidase N (kininase 1)

The human plasma metallo-protease carboxypeptidase N of Mr 280,000 consists of two small, enzymatically active subunits of Mr 50,000 and two large subunits. Only the large subunits are glycosylated. They may have a function in stabilizing the complex in plasma. The N-terminal sequence of the small subunit was determined from the isolated protein and used to specify a unique 59-mer oligonucleotide probe. A cDNA clone of 1.7 kbp containing the entire coding sequence of the small subunit of carboxypeptidase N was isolated from a human-liver cDNA library. The cDNA clone encodes a signal sequence of 20 amino acids and the 438 amino acids of the mature subunit. There is a remarkable primary structure similarity of 49% to bovine carboxypeptidase E (enkephalin convertase). A more distant relationship to the bovine pancreatic, digestive carboxypeptidases A and B or even to the metallo-endopeptidases is based mainly on the occurrence of conserved, mechanistically important residues.     

Molecular cloning and sequencing of the cDNA for human membrane-bound carboxypeptidase M. Comparison with carboxypeptidases A, B, H, and N

Carboxypeptidase M, a widely distributed membrane-bound carboxypeptidase that can regulate peptide hormone activity, was purified to homogeneity from human placenta (Skidgel, R. A., Davis, R. M., and Tan, F. (1989) J. Biol. Chem. 264, 2236-2241). The NH2-terminal 31 amino acids were sequenced, and two complementary oligonucleotide probes were synthesized and used to isolate a carboxypeptidase M clone from a human placental cDNA library. Sequencing of the cDNA insert (2009 base pairs) revealed an open reading frame of 1317 base pairs coding for a protein of 439 residues. The NH2-terminal protein sequence matched the deduced amino acid sequence starting with residue 14. Hydropathic analysis revealed hydrophobic regions at the NH2 and COOH termini. The NH2-terminal 13 amino acids probably represent part of the signal peptide, and the COOH-terminal hydrophobic region may act either as a transmembrane anchor or as a signal for attachment to a phosphatidylinositol glycan moiety. The carboxypeptidase M sequence contains six potential Asn-linked glycosylation sites, consistent with its glycoprotein nature. The sequence of carboxypeptidase M was 41% identical with that of the active subunit of human plasma carboxypeptidase N, 41% identical with bovine carboxypeptidase H (carboxypeptidase E, enkephalin convertase), and 15% with either bovine pancreatic carboxypeptidase A or B. Many of the active site residues identified in carboxypeptidases A and B, including all of the zinc-binding residues (2 histidines and a glutamic acid), are conserved in carboxypeptidase M. These data indicate that all of the metallocarboxypeptidases are related, but the nondigestive carboxypeptidases with more specialized functions, present in cell membranes, blood plasma, or secretory granules (i.e., carboxypeptidase M, carboxypeptidase N and carboxypeptidase H), are more closely related to each other (41-49% identity) than they are to carboxypeptidase A or B (15-20% identity).     

Cynomolgus Monkey (Macaca fascicularis) Cathepsin K: Cloning, Expression, Purification, and Activation

Methodology for the production of recombinant active cynomolgus monkey (Macaca fascicularis) cathepsin K (EC 3.4.22.38) was elucidated. The cDNA encoding the cathepsin K was cloned from femaleM. cynomolgusmonkey mRNA. The deduced amino acid sequence ofM. cynomolguspreprocathepsin K from the cDNA sequence showed 94.2% identity to human preprocathepsin K. Sequence differences occurred only in the prepro- domains; the mature domains were identical. The recombinantM. cynomolguscathepsin K was expressed as a secreted proenzyme using baculovirus-infected SF21 insect cells having the predicted N-terminus (LYPEEILDTH … ), indicating proper cleavage of the secretion sequence. Purified monkey procathepsin K was activated under autocatalytic conditions at pH 4.0. The mature enzyme was composed of mixture of enzymes having N-termini of Gly¹¹³and Arg¹¹⁴. The molecular weight was determined to be 23,668.3 Da by MALDI-TOF-MS which is consistent with the absence of carbohydrate on the mature enzyme. These results indicate that monkey procathepsin K is able to autoactivate and produces a mature enzyme which is identical to that of human cathepsin K. Since the sequence of monkey and human mature cathepsin K are identical and thein vitroactivation mechanisms appear to be indistinguishable, monkeys are predicted to be a good animal model for evaluating cathepsin K inhibitorsin vivoas therapeutic agents for diseases characterized by excessive bone loss, such as osteoporosis.     

Expression of cDNA encoding the human "protective protein" associated with lysosomal beta-galactosidase and neuraminidase: homology to yeast proteases

The "protective protein" is a glycoprotein that associates with lysosomal beta-galactosidase and neuraminidase and is deficient in the autosomal recessive disorder galactosialidosis. We have isolated the cDNA encoding human "protective protein". The clone recognizes a 2 kb mRNA in normal cells that is not evident in fibroblasts of an early infantile galactosialidosis patient. The cDNA directs the synthesis of a 452 amino acid precursor molecule that is processed in vivo to yield mature "protective protein," a heterodimer of 32 kd and 20 kd polypeptides held together by disulfide bridges. This mature form is also biologically functional since it restores beta-galactosidase and neuraminidase activities in galactosialidosis cells. The predicted amino acid sequence of the "protective protein" bears homology to yeast carboxypeptidase Y and the KEX1 gene product. This suggests a protease activity for the "protective protein."     

Purification and primary structure determination of human lysosomal dipeptidase

The lysosomal metallopeptidase is an enzyme that acts preferentially on dipeptides with unsubstituted N- and C-termini. Its activity is highest in slightly acidic pH. Here we describe the isolation and characterization of lysosomal dipeptidase from human kidney. The isolated enzyme has the amino-terminal sequence DVAKAIINLAVY and is a homodimer with a molecular mass of 100 kDa. So far no amino acid sequence has been determined for this metallopeptidase. The complete primary structure as deduced from the nucleotide sequence revealed that the isolated dipeptidase is similar to blood plasma glutamate carboxypeptidase.     

Cloning and characterization of CPVL, a novel serine carboxypeptidase, from human macrophages

Carboxypeptidases are proteases that cleave single amino acids from the carboxy termini of proteins or peptides. In addition to degradative functions in the gut, carboxypeptidases activate or inactivate bioactive peptides such as angiotensin, bradykinin, and endothelin I. Using differential display PCR, we cloned a novel carboxypeptidase expressed in human macrophages but not in other leukocytes. The 476-amino-acid gene product has a putative signal sequence but no transmembrane domain and has striking sequence similarity to serine carboxypeptidases, a large family of enzymes in eukaryotes. Only one serine carboxypeptidase, lysosomal protective protein, has previously been reported in mammals. Among known proteins, this gene is most similar (43% amino acid identity) to vitellogenic carboxypeptidase, a serine carboxypeptidase expressed in mosquito ovaries. Therefore, we have named this new gene carboxypeptidase, vitellogenic-like (CPVL). In addition to monocyte/macrophage-rich sources such as spleen, leukocytes, and placenta, CPVL mRNA is abundantly expressed in heart and kidney, suggesting a separate role for CPVL outside the immune system. The CPVL gene contains at least 13 exons spread over more than 150 kb on human chromosome 7p14-p15. An affinity-purified polyclonal antiserum recognized a protein of approximately 57 kDa in macrophage lysates, but not in lysates from lymphocytes, neutrophils, or monocytes. CPVL protein expression was induced during maturation of monocytes into macrophages. Possible functions for CPVL in macrophages include digestion of phagocytosed particles in the lysosome, participation in an inflammatory protease cascade, and trimming of peptides for antigen presentation.     

Isolation and sequencing of a cDNA clone encoding rat liver lysosomal cathepsin D and the structure of three forms of mature enzymes

We isolated and sequenced a cDNA clone corresponding to the entire coding sequence of rat liver lysosomal cathepsin D. The deduced amino acid sequence revealed that cathepsin D consists of 407 amino acid residues (Mr 44,608) and the 20 NH2-terminal residues seem to constitute a cleavable signal peptide after which 44 amino acid residues follow as a propeptide. Two putative N-linked glycosylation sites and aspartic acid in the active site are as well conserved as those of human lysosomal cathepsin D. In the NH2-terminal sequence analysis of two isolated heavy chains of the mature enzyme, the termini were assigned as tryptophan (118th residue) and glycine (165th or 166th residue), respectively, hence demonstrates that the two heavy chains derive from a split of the single chain of cathepsin D at position between 117th and 118th or between 164th and 165th or 165th and 166th amino acids. We conclude that cathepsin D in rat liver lysosomes is a mixture of three forms composed of a single and two two-chain forms. However, the amounts of the two two-chain forms are low compared with that of the single chain form. Densidometric determination after SDS-PAGE revealed that the two two-chain forms account for less than 5% of the single chain form. There is a 82% similarity in amino acid level between rat and human liver lysosomal cathepsin D.     

Sequence analysis, tissue distribution, and expression of rat cathepsin S.

Cysteine proteases are involved in many diverse cellular processes ranging from processing of precursor proteins to intracellular degradation. In an effort to identify novel cysteine proteases, we used the polymerase chain reaction and primers directed against the catalytic sites of previously cloned cysteine proteases. From rat brain mRNA, a 600-base pair band was amplified; cloning and partial sequence analysis of this band resulted in the identification of cathepsins B and L and five novel sequences. The novel cDNAs contained a number of residues conserved in lysosomal cysteine proteases, including the active site residue His159 (papain numbering). In addition, the amino acid homology between the novel sequences and either cathepsins B, L, or H, ranged from 63 to 32%. The insert with highest homology was used to screen a rat brain cDNA library; a 1334-base pair cDNA was isolated and the nucleotide sequence determined. This sequence encodes an open reading frame of 330 amino acids which is 82% homologous to human cathepsin S, suggesting that this sequence represents rat cathepsin S. Northern blot analysis for rat cathepsin S revealed tissue-specific expression distinct from the distribution of cathepsin B and L. The regulation of expression of rat cathepsin S mRNA in response to thyroid-stimulating hormone was studied in a rat thyroid cell line FRTL-5. The level of cathepsin S mRNA was substantially increased in response to thyroid-stimulating hormone, whereas cathepsin B and cathepsin L mRNA levels were not altered by this treatment. A portion of cDNA encoding the predicted mature protein of rat cathepsin S was expressed as a glutathione S-transferase-fusion protein. The affinity-purified protein exhibited proteolytic activity with properties similar to bovine cathepsin S. Taken together, these results imply highly specific functions for cathepsin S.     

The membrane-bound basic carboxypeptidase from hog intestinal mucosa(1).

The carboxypeptidase activity occurring in hog intestinal mucosa is apparently due to two distinct enzymes which may be responsible for the release of basic COOH-terminal amino acids from short peptides. The plasma membrane-bound carboxypeptidase activity which occurs at neutral optimum pH levels was found to be enhanced by CoCl(2) and inhibited by guanidinoethylmercaptosuccinic acid, o-phenanthroline, ethylenediamine tetraacetic acid and cadmium acetate; whereas the soluble carboxypeptidase activity which occurs at an optimum pH level of 5.0 was not activated by CoCl(2) and only slightly inhibited by o-phenanthroline, ethylenediamine tetraacetic acid, NiCl(2) and CdCl(2). The latter activity was presumably due to lysosomal cathepsin B, which is known to be present in the soluble fraction of hog intestinal mucosa. Although the membrane-bound enzyme was evenly distributed along the small intestine, it was not anchored in the phospholipidic bilayer via a glycosyl-phosphatidylinositol moiety, as carboxypeptidase M from human placenta is. The enzyme was not solubilized by phosphatidylinositol-specific phospholipase C, but was solubilized to practically the same extent by several detergents. The purified trypsin-solubilized form is a glycoprotein with a molecular mass of 200 kDa, as determined by performing SDS-PAGE and gel filtration, which differs considerably from the molecular mass of human placental carboxypeptidase M (62 kDa). It was found to cleave lysyl bonds more rapidly than arginyl bonds, which is not so in the case of carboxypeptidase M, and immunoblotting analysis provided further evidence that hog intestinal and human placental membrane-bound carboxypeptidases do not bear much resemblance to each other. Since the latter enzyme has been called carboxypeptidase M, it is suggested that the former might be carboxypeptidase D, the recently described new member of the carboxypeptide B-type family.     

Biosynthesis and processing of lysosomal cathepsin L in primary cultures of rat hepatocytes

The biosynthesis and proteolytic processing of lysosomal cathepsin L was studied using in vitro translation system and in vivo pulse-chase analysis with [35S]methionine and [32P]phosphate in primary cultures of rat hepatocytes. Messenger RNA prepared from membrane-bound but not free polysomes directed the synthesis of a primary translation product of an immunoprecipitable 37.5-kDa cathepsin L in vitro. The 37.5-kDa form was converted to the 39-kDa form when translated in the presence of dog pancreas microsomes. During pulse-chase experiments with [35S]methionine in cultured rat hepatocytes, cathepsin L was first synthesized as a 39-kDa protein, presumably the proform, after a short time of labeling, and was subsequently processed into the mature forms of 30 and 25 kDa in the cell. On the other hand, considerable amounts of the proenzyme were found to be secreted into the culture medium without further proteolytic processing during the chase. The precursor and mature enzymes were N-glycosylated with high-mannose-type oligosaccharides, and the proenzyme molecule contained phosphorylated oligosaccharides. The effects of tunicamycin and chloroquine were also investigated. In the presence of tunicamycin, a 36-kDa unglycosylated polypeptide appeared in the cell and this protein was exclusively secreted from the cells without undergoing proteolytic processing. These results suggest that cathepsin L is initially synthesized on membrane-bound polysomes as a 37.5-kDa prepropeptide and that the cotranslational cleavage of the 1.5-kDa signal peptide and the core glycosylation convert the precursor to the 39-kDa proform, which is subsequently processed to the mature form during biosynthesis. Thus, the biosynthesis and secretion of lysosomal cathepsin L in rat hepatocytes seem to be analogous to those of the major excreted protein of transformed mouse fibroblasts [S. Gal, M. C. Willingham, and M. M. Gottesman (1985) J. Cell Biol. 100, 535-544] and the mouse cysteine proteinase of activated macrophages [D.A. Portnoy, A. H. Erickson, J. Kochan, J. V. Ravetch, and J. C. Unkeless (1986) J. Biol. Chem. 261, 14697-14703].     

Porcine interleukin 18: cloning, characterization of the cDNA and expression with the baculovirus system

We have isolated and sequenced a cDNA that contains the coding sequence of porcine interleukin 18 (IL-18) and the recombinant protein of porcine IL-18 was expressed using the baculovirus system. The open reading frame (ORF) of the porcine IL-18 cDNA is 579 base pairs (bp) in length and encodes 192 amino acids. The predicted amino acid sequence is 76.7%, 64.7% and 61.6% homologous to the predicted human, murine and rat amino acid sequences, respectively. The porcine precursor and mature IL-18 protein were expressed respectively in Trichoplusia ni -derived (Tn5) cells using the baculovirus Autografha californica nuclear polyhedorosis virus (AcNPV) as a vector. Tn5 cells infected with recombinant virus containing a whole IL-18 protein coding region sequence secreted porcine precursor IL-18 into the culture medium. On the other hand, Tn5 cells infected with recombinant virus containing a mature IL-18 protein coding region sequence expressed several proteins in the cell lysates, but did not secrete mature protein into the culture medium efficiently. Immunoblotting analysis of recombinant protein showed cross-reactivity with anti-human IL-18 polyclonal antibody. The mature form of porcine IL-18 protein induced IFN-gamma production in suboptimal doses of anti-CD3 antibody and concanavalin A- (ConA) stimulated porcine peripheral blood mononuclear cells (PBMC), but the precursor form had little effect.