cDNA structure and in situ localization of the Aplysia californica pro-hormone convertase PC2

The complete cDNA structure of the Aplysia californica pro-protein and pro-hormone convertase PC2 (aPC2) was obtained from a cDNA library of the nervous system. The deduced amino acid sequence revealed that aPC2 exhibits an 85%, 61% and 62% sequence identity to the Lymnaea stagnalis, Xenopus laevis and mouse PC2 homologues, respectively. The deduced stagnalis, Xenopus laevis and mouse PC2 homologues, respectively. The deduced primary sequence suggested a protein of 653 amino acids which includes a 27- and 88-amino acid signal peptide and pro-segment. The signal peptide and the C-terminal segments are the least conserved regions. On Northern blots of nervous system we detected a transcript of 6.8 kb. The in situ hybridization histochemistry on the abdominal ganglion revealed intense labeling of the bag cells. Large peptidergic cells and clusters of sensory and motor neurons also contained high levels of aPC2 mRNA.

Comparative biosynthesis, covalent post-translational modifications and efficiency of prosegment cleavage of the prohormone convertases PC1 and PC2: glycosylation, sulphation and identification of the intracellular site of prosegment cleavage of PC1 and PC2

We present herein the pulse-chase analysis of the biosynthesis of the prohormone convertases PC1 and PC2 in the endocrine GH4C1 cells infected with vaccinia virus recombinants expressing these convertases. Characterization of the pulse-labelled enzymes demonstrated that pro-PC1 (88 kDa) is cleaved into PC1 (83 kDa) and pro-PC2 (75 kDa) into PC2 (68 kDa). Secretion of glycosylated and sulphated PC1 (84 kDa) occurs about 30 min after the onset of biosynthesis, whereas glycosylated and sulphated PC2 (68 kDa) is detected in the medium after between 1 and 2 h. Furthermore, in the case of pro-PC2 only, we observed that a fraction of this precursor escapes glycosylation. A small proportion (about 5%) of the intracellular glycosylated pro-PC2 (75 kDa) is sulphated, and it is this glycosylated and sulphated precursor that is cleaved into the secretable 68 kDa form of PC2. Major differences in the carbohydrate structures of PC1 and PC2 are demonstrated by the resistance of the secreted PC1 to endoglycosidase H digestion and sensitivity of the secreted PC2 to this enzyme. Inhibition of N-glycosylation with tunicamycin caused a dramatic intracellular degradation of these convertases within the endoplasmic reticulum, with the net effect of a reduction in the available activity of PC1 and PC2. These results emphasize the importance of N-glycosylation in the folding and stability of PC1 and PC2. Pulse-labelling experiments in uninfected mouse beta TC3 and rat Rin m5F insulinoma cells, which endogenously synthesize PC2, showed that, as in infected GH4C1 cells, pro-PC2 predominates intracellularly. In order to define the site of prosegment cleavage, pulse-chase analysis was performed at low temperature (15 degrees C) or after treatment of GH4C1 cells with either brefeldin A or carbonyl cyanide m-chlorophenylhydrazone. These results demonstrated that the onset of the conversions of pro-PC1 into PC1 and non-glycosylated pro-PC2 into PC2 (65 kDa) occur in a pre-Golgi compartment, presumably within the endoplasmic reticulum. In contrast, pulse labelling in the presence of Na(2)35SO4 demonstrated that the processing of glycosylated and sulphated pro-PC2 occurs within the Golgi apparatus. In order to test the possibility that zymogen processing is performed by furin, we co-expressed this convertase with either pro-PC1 or pro-PC2. The data demonstrated the inability of furin to cleave either proenzyme.

cDNA structure of the mouse and rat subtilisin/kexin-like PC5: a candidate proprotein convertase expressed in endocrine and nonendocrine cells

By using reverse transcriptase/PCR and oligonucleotide sequences derived from conserved segments (including the conserved RRGDL sequence) of the known proprotein convertases (PCs) PC1, PC2, furin, and PC4, we identified a subtilisin/kexin-like PC called PC5 in both mouse and rat tissues. The composite structure (2.85 kb) was deduced from the analysis of the reverse transcription/PCR products combined with the sequence from a clone isolated from a cDNA library made from corticotropin-activated mouse adrenocortical Y1 cells. The deduced cDNA structures of mouse PC5 and rat PC5 showed that the closest homologue is PACE4. Furthermore, like furin, Drosophila melanogaster (d) dfurin2, and PACE4, PC5 shows the presence of a C-terminal Cys-rich domain containing either 5 (PC5 and PACE4) or 10 (dfurin2) repeats of the consensus motif Cys-Xaa2-Cys-Xaa3-Cys-Xaa(5-7)-Cys-Xaa2-Cys-Xaa (8-15)-Cys-Xaa3-Cys-Xaa(9-16). The richest sources of rat PC5 mRNA (3.8 kb) are the adrenal and gut, but it can also be detected in many endocrine and nonendocrine tissues. Corticotropin-stimulated adrenocortical Y1 cells showed an increased expression of PC5 mRNA, suggesting an upregulation by cAMP. In situ hybridization of rat brain sections demonstrated a unique distribution of PC5 compared to PC1, PC2, and furin.

Processing, release and metabolism of cholecystokinin in SK-N-MCIXC cells

The human cholinergic neuroepithelioma cell line SK-N-MCIXC, which expresses high levels of cholecystokinin (CCK) mRNA and secretes intact CCK into the media, was used to examine CCK processing and metabolism. Our data provide evidence for the existence of specific candidate processing enzymes in SK-N-MCIXC cells which may be involved in processing proCCK in the brain and indicate that SK-N-MCIXC cells provide a model system for studying the regulation of these enzymes. mRNAs for the intracellular processing enzymes, prohormone convertase 1 (PC1), PC2 and furin were present in SK-N-MCIXC cells. PC1 and/or PC2 and/or furin may cleave at the dibasic amino acid pairs Arg-Arg at the C-terminal part of proCCK, and Arg-X-X-Arg at the N-terminal of the CCK-58 sequence in proCCK. The SK-N-MCIXC cell line demonstrated spontaneous and regulated release of CCK and large amounts of CCK-precursors, as measured with region specific radioimmunoassays coupled to high performance liquid chromatography. Storage granules containing glycine-extended CCK were shown in SK-N-MCIXC cells using indirect immunofluorescence. The extracellularly localized CCK-metabolizing enzyme, neutral endopeptidase 24.11 (EC 3.4.24.11), was present in membranes from both SK-N-MCIXC cells and in intact slices of rat cerebral cortex. The rat cerebral cortex is a brain region known to be rich in CCK. The SK-N-MCIXC cell line provides an in vitro model to study the regulation of CCK synthesis and metabolism in neuronal systems since it contains the storage granules, mRNA, intact peptide, and complement of enzymes necessary for biosynthesis and metabolism of CCK.

Tissue-specific and substrate-specific endoproteolytic cleavage of monkey pro-opiomelanocortin in heterologous endocrine cells: processing at Lys-Lys dibasic pairs

This study compares the processing of pro-opiomelanocortin (POMC) at two Lys-Lys cleavage sites, located in the carboxy-terminal domain of the precursor, one site marking the amino terminus of beta-melanocyte-stimulating hormone (beta-MSH) and the other in the carboxy-terminus of beta-endorphin (beta E). These comparisons were carried out by transfecting monkey POMC cDNA into two heterologous cell lines: AtT-20, which endogenously expresses mouse POMC, and Rin m5F, which has been previously used as a host for transfected POMC. These cells lines are known to process POMC differently at Lys-Arg residues, though less is known about their Lys-Lys cleavage. Our results have demonstrated both tissue-specific and site-specific factors controlling Lys-Lys cleavage. The AtT-20 line appears not to perform either Lys-Lys cleavage. Rin m5F cells, on the other hand, fail to process the site at the carboxy terminus of beta E (beta E28-29) but do process, to a significant extent, the N-terminal site to beta-MSH. That this differential processing is unlikely to be due to a POMC conformation which would make the beta E site inaccessible was demonstrated by mutating the sites from Lys-Lys to Lys-Arg. With such mutants, Rin m5F cells fully processed at both locations. Interestingly, the mutant Lys-Arg sites were not fully processed by AtT-20 cells. These results are discussed in terms of the complement of processing enzymes expressed in each of the cell lines, as well as the role of residues surrounding the diabasic cleavage sites in determining the likelihood of proteolysis.

Enzymic characterization of murine and human prohormone convertase-1 (mPC1 and hPC1) expressed in mammalian GH4C1 cells

Prohormone convertase-1 (PC1), an endopeptidase that is structurally related to the yeast subtilisin-like Kex2 gene product, has been proposed to be involved in mammalian tissue-specific prohormone processing at pairs of basic residues. To better study this enzyme, a rat somatomammotroph cell line, GH4C1, was infected with vaccinia virus recombinants of murine PC1 (mPC1) and human PC1 (hPC1). An enzymically active form of each protein was secreted into the cell medium and partially purified by anion-exchange chromatography. The 80-85 kDa enzyme was shown to be Ca(2+)-dependent and exhibited a pH optimum of 6.0 when assayed against a synthetic fluorogenic substrate, acetyl-Arg-Ser-Lys-Arg-4-methylcoumaryl-1-amide. mPC1 and hPC1 displayed identical cleavage selectivity towards a number of fluorogenic substrates, and those incorporating an Arg at the P4 site were most favoured. Synthetic peptides, encompassing the junction between the putative pro-region and the active enzyme, and between the pro-region and the biologically active parathyroid hormone, were shown to be recognized and cleaved specifically at the pair of basic residues by both enzymes. Group-specific proteinase inhibitors such as metal ion chelators and p-hydroxymercuribenzoate, but not phenylmethanesulphonyl fluoride and pepstatin, strongly inhibit the PC1-associated activity. In addition, it is shown that an enzyme activity displaying identical properties is present in the cell medium of uninfected corticotroph AtT-20 cells and that its level is increased following stimulation of secretion by the secretagogue 8-bromo cyclic AMP.

Synthesis of the segment (11-23) located in the first tandem repeat of plasma kallikrein: comparative binding studies of this and another segment (328-343) to high-molecular-mass kininogen

The synthesis of porcine plasma kallikrein (pPK) segment (11-23), of sequence Phe-Phe-Arg-Gly-Gly-Asp-Val-Ser-Ala-Met-Tyr-Thr-Pro, present in the first tandem repeat sequence of the regulatory chain of PK, has been accomplished following the peptide fragments (5 + 4 + 4) condensation strategy in solution, as well as by fluorenylmethoxycarbonyl solid-phase chemistry. This and another synthetic PK segment of residues (328-343) present in the fourth tandem repeat sequence [Cys(ACM)-Ser-Leu-Arg-Leu-Ser-Thr-Asp-Gly-Ser-Pro-Thr-Arg-Ile-Thr-Tyr] and synthesized by a solid-phase method, were fully characterized by 1H nuclear magnetic resonance, fast atom bombardment mass spectrometry, amino acid composition and reversed-phase high-performance liquid chromatography. Proteolysis of these peptides by either rat PK (rPK) or trypsin resulted in cleavages between Arg decreases Gly for pPK (11-23) and between Arg decreases Leu and Arg decreases Ile for rPK (328-343). Kinetic studies revealed that for peptide pPK (11-23), the catalytic efficiency (kcat/Km) of rPK is congruent to 9-fold higher than that of trypsin, but for the other peptide, rPK (328-343), kcat/Km of trypsin is congruent to 49-fold higher than that of rPK. The facile cleavage of pPK (11-23) by rPK confirms the Arg13 decreases Gly14 position as the site of autolytic degradation of PK and also explains its special preference for Phe-Phe-Arg sequence.

Molecular cloning and expression of the ovine testicular follicle stimulating hormone receptor

A sheep testicular cDNA library constructed in pcDNA1 vector was screened with a probe generated by polymerase chain reaction (PCR) and corresponding to a 1.6 kb fragment of the rat luteinizing hormone receptor cDNA. Several clones hybridizing to the rat probe at low stringency were sequenced to obtain 95% of the putative full-length ovine follicle-stimulating hormone receptor (oFSH-R) cDNA. The missing 5' region was obtained by PCR amplification of the cDNA library. Sequencing revealed a 2085 nucleotide open reading frame encoding a mature protein of 678 amino acids (74,580 daltons). The oFSH-R is remarkably similar (> 90%) to the human and rat FSH receptors, has a structural motif like the G protein-coupled family of receptors and contains 3 potential sites for N-linked glycosylation. RNA blot analysis revealed two major transcripts of 2.6 kb and 6.7 kb in size and a smaller transcript of about 1 kb in the sheep testis. A 53 residue segment in the extracellular domain unique to the receptor contains more than 50% of residues bearing functional side chains that could participate in ligand (FSH) interaction and/or signal transduction. Transfection of human fetal kidney cell line (293) with the cloned oFSH receptor cDNA based in pcDNA1/Neo vector revealed functional expression. Labeled oFSH bound to receptor expressed on the membrane with high affinity and specificity. In stably transfected 293 cells, purified oFSH and hFSH but not oLH stimulated cyclic AMP accumulation. Chemically deglycosylated oFSH (DG-oFSH) was inactive in these cells but it effectively blocked the action of native hormone.(ABSTRACT TRUNCATED AT 250 WORDS)

Ontogeny of the prohormone convertases PC1 and PC2 in the mouse hypophysis and their colocalization with corticotropin and alpha-melanotropin

In the adult pituitary, anterior lobe corticotrophs and intermediate lobe melanotrophs differentially process proopiomelanocortin (POMC). Within the corticotrophs, POMC is processed mainly to corticotropin (ACTH) and beta-lipotropin, while alpha-melanotropin (alpha MSH) and beta-endorphin are the major end products in the melanotrophs. The observed transient presence of alpha MSH-like immunoreactivity during ontogeny suggested an age-dependent variation in POMC processing in the adenohypophysis. In this tissue, cell-specific POMC products are likely the result of differential expression of the two known prohormone convertases PC1 and PC2. In the present ontogeny study done in the mouse intermediate and anterior pituitary, we examined how the expression pattern of PC1 and PC2 mRNA transcripts correlates with that of ACTH and alpha MSH-like immunoreactivities. Our data demonstrated that both PC1 and PC2 transcripts can be detected in the presumptive adenohypophysis starting on embryonic day 15 (E15). In the intermediate lobe, PC1 and PC2 mRNAs appear on E18 and E16, respectively, and their levels increased during ontogeny, reaching maximal expression in the adult. Similarly, PC1 expression in the anterior pituitary increased from E15 to adulthood. However, PC2 mRNA expression peaked between postnatal days 1 (P1) and 14 (P14) and then decreased to adult levels. The distribution of PC1 and PC2 immunoreactivity is nicely correlated with the in situ hybridization data. In the anterior lobe, during the P1-P14 postnatal period, PC2 immunoreactivity was detected within cells synthesizing an alpha MSH-like peptide(s). This observation substantiates our earlier biochemical data suggesting that PC2 is the important convertase in the processing of POMC into alpha MSH. Furthermore, the demonstrated variation in the relative ratio of PC1/PC2 expression during ontogeny rationalizes the observed plasticity of POMC processing in the adenohypophysis. It is expected that beta-endorphin processing will follow that of alpha MSH.

From proopiomelanocortin to cancer. Possible role of convertases in neoplasia

Melanophore-stimulating hormones (MSHs) are produced from a common precursor called proopiomelanocortin (POMC). These peptides have been at the center of studies on the prohormone theory since 1967. The recent discovery of endoproteases which can convert POMC to MSHs is having more biological implications than previously imagined, most particularly for proliferative diseases like cancer.

Heterologous processing of prosomatostatin in constitutive and regulated secretory pathways. Putative role of the endoproteases furin, PC1, and PC2

Mammalian prosomatostatin (PSS) is cleaved at a dibasic Arg-Lys site to produce somatostatin-14 (SS-14) and at monobasic Arg and Lys sites to yield SS-28 and PSS(1-10) (antrin), respectively. Furin, PC1, and PC2 are three recently discovered mammalian endoproteases localized either to the constitutive (furin) or regulated (PC1, PC2) secretory pathways. In this study we have compared the heterologous processing of PSS in transiently transfected endocrine (AtT-20 pituitary) and nonendocrine (COS-7 monkey kidney, PC12 pheochromocytoma) tumor cells. We have correlated the efficiency of processing of PSS to SS-14, SS-28, and PSS(1-10) with (i) secretion through the constitutive or regulated pathways; (ii) endogenous expression of mRNA for furin, PC1, and PC2; and (iii) exogenous expression of PC1 and PC2 in cells that do not contain these enzymes in order to delineate the putative role of these enzymes in mediating PSS cleavage at dibasic and monobasic sites and to localize the proteolytic events to specific compartments of the secretory pathways. COS-7 and PC12 cells expressed only furin, secreted constitutively, and processed PSS preferentially at monobasic sites to SS-28 (40-43%) and antrin (27-29%). Processing, however, was inefficient as suggested by large amounts of unprocessed PSS. In contrast, AtT-20 cells showed regulated secretion, expressed all three endoproteases (with high levels of PC1), and processed PSS efficiently to mainly SS-14. PC1, but not PC2, exogenously coexpressed with PSS in COS-7 cells produced significant conversion to SS-14 but not SS-28. This study shows that PSS is capable of monobasic cleavage in the constitutive secretory pathway. Such processing could be mediated by a furin-like enzyme but is relatively inefficient. PC1 can effect dibasic cleavage of PSS whereas PC2 is without influence on PSS processing at least within the constitutive secretory pathway. Although monobasic and dibasic processing of PSS in COS-7 cells correlates with furin-like and PC1 activity, respectively, the relative inefficiency of such processing suggests that compartmentalization of proteolytic events in secretory vesicles or other more specific endoproteases may be required.

Gene expression of prohormone and proprotein convertases in the rat CNS: a comparative in situ hybridization analysis

Posttranslational processing of proproteins and prohormones is an essential step in the formation of bioactive peptides, which is of particular importance in the nervous system. Following a long search for the enzymes responsible for protein precursor cleavage, a family of Kexin/subtilisin-like convertases known as PC1, PC2, and furin have recently been characterized in mammalian species. Their presence in endocrine and neuroendocrine tissues has been demonstrated. This study examines the mRNA distribution of these convertases in the rat CNS and compares their expression with the previously characterized processing enzymes carboxypeptidase E (CPE) and peptidylglycine alpha-amidating monooxygenase (PAM) using in situ hybridization histochemistry. Furin mRNA was ubiquitously distributed and detected both in neurons and non-neuronal tissue throughout the brain with a higher abundance in ependyma, the circumventricular organs, the islands of Calleja, hippocampus, and allocortex. The cellular localization of PC1 and PC2 was exclusively neuronal with highest concentrations in known neuropeptide-rich brain regions. In general, PC2 was more widely expressed than PC1 in the CNS, although many regional variations were detected. The identification of specific combinations of convertase expression together with CPE and PAM expression in neuropeptide-rich brain regions suggests that specific enzymatic pathways are involved in neuropeptide precursor processing, and that these specific combinations are responsible for region-specific differences of posttranslational processing.

Region specific expression of furin mRNA in the rat brain

The distribution of furin mRNA was examined in the rat central nervous system. Northern blot analysis reveals the presence of a 4.4 kb band in all brain tissues examined. In situ hybridization analysis of frozen rat brain sections using a radioactively labeled antisense cRNA probe to rat furin demonstrated moderate to low levels of expression in both neuronal and non-neuronal tissue in all areas examined. Interestingly, higher levels of furin were expressed in selective regions which include the ventricles (the choroid plexus and ependymal cells), the islands of Calleja, the hippocampus and the pineal gland. the ubiquitous localization of furin in the brain is consistent with its postulated role as a vital convertase important in the processing of proproteins negotiating the constitutive pathway of secretion. However, the higher expression of furin mRNA in distinct brain areas suggests a more active role in the processing of proproteins synthesized in these tissues.

The cDNA structure of the porcine pro-hormone convertase PC2 and the comparative processing by PC1 and PC2 of the N-terminal glycopeptide segment of porcine POMC

The complete cDNA structure of the porcine (p) pro-protein and pro-hormone convertase PC2 (pPC2) was obtained from a cDNA library of pituitary neurointermediate lobes mRNA. The deduced amino acid sequence revealed that pPC2 exhibits a 99-97% sequence identity to the human, mouse and rat homologues. The 3' end of the 2.1 kb cDNA is the least conserved segment. On Northern blots of pars intermedia poly A+ RNA two transcripts of 3 and 5 kb were detected. Molecular analysis of the N-terminal glycopeptide products of porcine pro-opiomelanocortin (pPOMC) co-expressed with vaccinia virus recombinants of PC1 or PC2, revealed that in cells devoid or containing secretory granules both convertases can cleave pPOMC with PC1 releasing the 1-80, 1-107 and 1-148 glycopeptide fragments, and PC2 cleaving pPOMC directly into pPOMC 1-107.

Affinity purification of proteinases by a combination of immobilized peptidyl aldehyde and semicarbazone

D-Phe-Phe-argininal semicarbazone and Tyr-Gly-Gly-Phe-Leu-Arg-argininal semicarbazone were prepared using the solution phase synthesis method and characterized by mass spectrometry and nuclear magnetic resonance spectroscopy. The tripeptide and heptapeptide semicarbazones were individually immobilized on affi-Gel 15 resulting in two affinity columns called S3 and S7, respectively. A third affinity column was obtained by hydrolysing the semicarbazone moiety in column S3 to aldehyde (column A3). Serine proteinases such as trypsin or rat plasma kallikrein almost quantitatively bind to either S3 or A3 affinity columns. Under optimized conditions, more than 97% of trypsin bound to both columns S3 and A3. At a lower ionic strength and higher pH, 80-85% of rat plasma kallikrein bound to the same columns. Elution of both enzymes was achieved using mild conditions at near neutral pH and in the presence of a small amount of denaturant. Both proteinases were identified and characterized by high-performance liquid chromatography, sodium dodecylsulphate polyacrylamide gel electrophoresis and by their substrate specificity and inhibition profiles. A single purification (six-to seven-fold) step using either column S3 or A3 allowed the preparation of pure trypsin from commercial sources. Starting from rat plasma partially purified by a phenyl boronate column, fractionation on the S3 column allowed approximately an 87-fold purification of rat plasma kallikrein. However, serial purification of rat plasma kallikrein on column S7 followed by column A3 resulted in a purification factor of about 455.

Testicular expression of PC4 in the rat: molecular diversity of a novel germ cell-specific Kex2/subtilisin-like proprotein convertase

The rat cDNA sequence of PC4 (rPC4), representing a new member of the Kex2/subtilisin-like proprotein convertases, demonstrated the presence of at least three rPC4 mRNAs resulting in the production of rPC4-A (654 amino acids), rPC4-B (619 amino acids), and rPC4-C (609 amino acids) with different C-terminal sequences. Analogous to rat PC4, three cDNAs were also found for the mouse PC4. The observed molecular diversity of PC4 mRNA possibly results from the differential splicing and/or exon skipping of the parent gene. PC4 mRNA, with a major form at 2.8 kilobases, was highly abundant in the rat testis but could not be detected by Northern analysis in any other tissues including the central nervous system and peripheral tissues. Testicular cell separation studies combined with Northern analysis indicate the high expression levels of PC4 in germ cells but not in Leydig, Sertoli, or peritubular cells. In situ hybridization histochemistry confirms the site of PC4 gene expression as the pachytene spermatocytes and the round spermatids but not in the elongating spermatids. We also demonstrate the colocalization of PC4 with proenkephalin in testicular germ cells by in situ hybridization. A study of the ontogeny of PC4 indicated that PC4 mRNA was first expressed postnatally between days 19 and 22, coinciding with the first stages of spermiogenesis. The stage-specific expression of PC4 in testis indicates its potential role in the developmental maturation of germ cells and that this convertase may play a specific physiological function in reproduction.

Regional localization of three convertases, PC1 (Nec-1), PC2 (Nec-2), and furin (Fur), on mouse chromosomes

The genes for three convertases, PC1 (Nec-1), PC2 (Nec-2), and furin (Fur), have been regionally localized on chromosomes 13, 2, and 7, respectively, by interspecific backcross analysis. These results refine previous localizations by in situ hybridization as well as confirm and extend known regions of homology between mouse and human chromosomes.

Dynamics of 7B2 and galanin expression in solitary magnocellular hypothalamic vasopressin neurons of the homozygous Brattleboro rat

The homozygous Brattleboro rat (di/di), displaying a hypothalamic form of diabetes insipidus, synthesizes a vasopressin (VP) precursor with an abnormal C-terminus. The phenotypic expression of coexisting peptides in mutant magnocellular VP cells shows a differential pattern. 7B2 is one of the peptides which is not detectable, whereas there is a clear galanin expression. During postnatal life a small but increasing number of solitary post-mitotic VP neurons of the di/di rat undergoes a switch to a heterozygous phenotype. Here we report the presence of 7B2 and galanin in these heterozygous cells, which suggests that for the expression of 7B2, but not for that of galanin, the relative amount of mutant VP precursor must be diminished. Possible underlying mechanisms for this differential phenotypic expression of coexisting peptides are compartmentalization of precursor synthesis within the RER or a competition for sites involved in the translocation of the functionally reduced RER.

Proprotein conversion is determined by a multiplicity of factors including convertase processing, substrate specificity, and intracellular environment. Cell type-specific processing of human prorenin by the convertase PC1

Proprotein and prohormone processing at pairs of basic residues is generally thought to be both tissue- and precursor-specific and to be developmentally regulated. Furin, PC1 (also called PC3), and PC2 represent three recently discovered subtilisin-like proteinases which cleave a number of precursors at the same pairs of basic residues normally processed in vivo. Using human prorenin as a model, we show that PC1 can process it to active renin in cells containing secretory granules, such as the somatomammotroph cell line GH4, but not in cells which lack granules, such as the Chinese hamster ovary or African green monkey kidney epithelial (BSC-40) cell lines. In contrast, in both cell types, human prorenin is not activated by either PC2 or furin. Using the vaccinia virus expression system, biosynthetic labeling experiments demonstrated that PC1 and PC2 are themselves cleaved intracellularly at pairs of basic residues and that these two proenzymes are processed to different extents independent of whether the cell line contains dense core secretory granules. Furthermore, we also show that the cells mostly secrete the cleaved forms of PC1 and PC2, and that intracellularly the pro- form of PC2 predominates. Our data demonstrate that propeptide removal from these enzymes, possibly leading to their activation, is not the only criterion which governs precursor processing.

Proprotein and prohormone convertases of the subtilisin family Recent developments and future perspectives

Limited proteolysis of precursors at specific pairs of basic residues and/or at single basic amino acids is a widespread mechanism by which the cell expresses a repertoire of biologically active proteins and peptides. The cloning and cellular expression of the yeast KEX2 gene product demonstrated that this enzyme belongs to the subtilisin family of serine proteinases, and that it exhibits exquisite selectivity for cleavage post pairs of basic residues in a number of yeast and mammalian precursors. The search for the homologous mammalian convertases led to the identification and molecular cloning of three new members of the family, furin, PCI, and PC2. Whereas furin is almost ubiquitous, PCI and PC2 localize mostly in endocrine and neuroendocrine tissues and cells. Coexpression of each gene product with proproteins demonstrated that each proteinase selectively cleaved these precursors at distinct pairs of LysArg and ArgArg residues. In human and mouse, the genes coding for furin, PCI, and PC2 reside on three different chromosomes. Overexpression of PO and PC2 in Sf9 cells in the baculovirus system demonstrated that these enzymes are not secreted and that they both retained their N-terminal prodomain.

The cDNA sequence of the human pro-hormone and pro-protein convertase PC1

Using a probe consisting of the full-length cDNA sequence of the mouse pro-hormone convertase PC1 (mPC1), we isolated from a lambda gt10 human pituitary cDNA library a number of contiguous clones, of which composite sequence of 3.3-kb defined the complete coding sequence of human PC1 (hPC1). The cDNA sequence of hPC1 encodes a protein containing 753 amino acids and potentially two N-glycosylation sites, one carboxy-terminal amidation site, a cAMP-dependent protein kinase Ser phosphorylation site, a tyrosine kinase phosphorylation site, and an ArgGlyAsp (RGD) sequence. Like mPC1, the carboxy-terminal sequence of hPC1 exhibits an amphipathic domain potentially involved in membrane association. The coding region of hPC1 exhibits an overall 92.6% protein sequence identity to the mouse mPC1 sequence, with the highest homology (98%) found in the catalytic segment of the molecule (residues 84-399). Whereas Northern blot analysis of tissues obtained from mouse, rat and porcine demonstrated the presence of two mRNAs of 3 kb and 5 kb, Northern blots of human tissues and cells demonstrated the presence of a dominant transcript of 6.2 kb and the presence of smaller transcripts in some tissues. The major site of production of hPC1 seems to be the pituitary and brain, although detection was also possible in pancreas and heart.

Distribution and regulation of the prohormone convertases PC1 and PC2 in the rat pituitary

PC1 and PC2 are enzymes involved in the activation of prohormones via the cleavage of pairs of basic amino acids. The expression levels of each of these enzymes were evaluated in the rat anterior and neurointermediate pituitary lobes by in situ hybridization and Northern gel analysis and after various pharmacological manipulations. All intermediate lobe melanotrophs expressed high levels of PC2 mRNA and lower levels of PC1 mRNA. PC1 mRNA was highly expressed throughout the anterior lobe; however, appreciable PC2 mRNA levels were also found. Based on colocalization studies, anterior lobe corticotrophs were found to express PC1 mRNA, but very little PC2 mRNA. Neurointermediate lobe levels of PC1, PC2, and POMC mRNA increased 2- to 6-fold in rats treated with haloperidol, while they decreased to 10-25% of their control values after bromocriptine treatment. These results indicate that in the intermediate lobe, dopamine is involved in the regulation of PC1 and PC2. In the anterior lobe, haloperidol had a strong effect on PC2 mRNA, increasing its levels by 8- to 12-fold compared to the control value, while PC1 mRNA was unaffected. Both PC1 and PC2 mRNA levels were increased 5- to 9-fold in animals made hypothyroid by treatment with 6-n-propyl-2-thiouracil. Adrenalectomy had no significant effect on anterior lobe PC1 mRNA levels. However, both PC1 and PC2 mRNA levels were responsive to dexamethasone treatment in the AtT-20 cell lines. Our results indicate that dopamine, thyroid hormones, and corticosteroids are involved in PC1 and/or PC2 gene expression. These data are also consistent with the role of PC1 and PC2 as prohormone-processing enzymes.