Identification of the fourth member of the mammalian endoprotease family homologous to the yeast Kex2 protease. Its testis-specific expression

Frog prohormone convertase PC2 mRNA has a mammalian-like expression pattern in the central nervous system and is colocalized with a subset of thyrotropin-releasing hormone-expressing neurons

The prohormone convertase (PC2) is expressed in the mammalian central nervous system (CNS) and has been shown to play an important role in the processing of certain neuropeptide precursors and prohormones at paired basic residues. Amphibian PC2 cDNA was recently cloned for the frog Xenopus laevis, and both its sequence and its pituitary expression pattern were shown to be very similar to those of mammalian PC2. To investigate further the function of PC2 in the vertebrate CNS, we used in situ hybridization histochemistry to localize the distribution of cells expressing PC2 mRNA in the frog brain and the spinal cord. The distribution of PC2-expressing cells was also compared with that of cells expressing thyrotropin-releasing hormone (TRH) mRNA or peptide. PC2-expressing cells were detected in specific nuclei that were widely distributed in the frog CNS. In forebrain, telencephalic PC2 mRNA was found in the olfactory bulb, pallium, striatum, amygdala, and septum, and diencephalic PC2 mRNA was seen in the preoptic area, thalamus, and hypothalamus. More posteriorly, PC2 cells were localized to midbrain tegmentum, the torus semicircularis, and the optic tectum, as well as the cerebellum, brainstem, and spinal cord. Despite this wide distribution steady-state levels of PC2 mRNA were clearly different in various brain nuclei. Regions with higher levels showed good correspondence to areas shown by others in frog to contain large numbers of neuropeptide-expressing cells, including TRH cells. On the other hand, not all brain areas with high levels of TRH mRNA had high levels of PC2 mRNA. Localization studies combining in situ hybridization and immunocytochemistry showed that, at least in optic tectum and brainstem, PC2 mRNA and pro-TRH peptide coexist. These findings suggest that pro-TRH is processed by PC2 in some, but possibly not all, brain regions. Thus, different converting enzymes may be involved in pro-TRH processing in different brain regions.

The Dfur2 gene of Drosophila melanogaster: genetic organization, expression during embryogenesis, and pro-protein processing activity of its translational product Dfurin2

The gene structure and expression of the Dfur2 gene of Drosophila melanogaster, which encodes the subtilisin-like serine endoprotease Dfurin2, was studied. The Dfur2 gene is very compact in contrast to the related Dfur1 gene, which has an estimated size of over 100 kbp. The 6-kb Dfur2 mRNA is encoded by 16 exons dispersed over a genomic region of about 9 kbp. The exon/intron organization shows conservation of intron positions not only in comparison with Dfur1, but also with the related mammalian genes FUR, PC1/PC3, PC2, and PC4. This conservation supports the hypothesis that all genes belonging to the family of subtilisin-like pro-protein processing enzymes are evolutionary related by descent from a common ancestral gene. In primer extension experiments, Dfur2 transcription initiation sites were identified in the presumed Dfur2 promoter region. This region was found to contain general RNA polymerase II promoter elements like a potential TATA box, a potential CAP signal, and several potential CCAAT boxes. Also, several sequence motifs putatively corresponding to binding sites for Drosophila transcription factors like zeste, bicoid, and engrailed were found to be present. RNA in situ hybridization experiments on Drosophila embryos revealed presumably maternal Dfur2 expression until the syncytial blastoderm (stage 5 of embryogenesis), no expression during gastrulation (stage 9), transient expression in a subset of neurons in the central nervous system of stage 12-13 embryos, and, from stage 13 onwards, expression in the developing tracheal tree. In a vaccinia expression system, the endoprotease Dfurin2 not only cleaved wild-type precursor of von Willebrand factor (pro-vWF) with pro-region cleavage site R-S-K-R decreases, but also, although to a lesser extent, pro-vWF mutants in which the P2 (vWFK-2A) or P4 (vWFR-4A) basic residue with respect to the pro-region cleavage site had been mutated. This cleavage specificity resembles that of human furin. The cleavage of pro-vWF by Dfurin2 shows that the previously reported lack of cleavage of the precursor of the beta A-chain of activin-A by Dfurin2 in this vaccinia expression system is substrate determined.

Chromosomal assignment of the genes for proprotein convertases PC4, PC5, and PACE 4 in mouse and human

The genes for three subtilisin/kexin-like proprotein convertases, PC4, PC5, and PACE4, were mapped in the mouse by RFLP analysis of a DNA panel from a (C57BL/6JEi x SPRET/Ei)F1 x SPRET/Ei backcross. The chromosomal locations of the human homologs were determined by Southern blot analysis of a DNA panel from human-rodent somatic cell hybrids, most of which contained a single human chromosome each. The gene for PC4 (Pcsk4 locus) mapped to mouse chromosome 10, close to the Adn (adipsin, a serine protease) locus and near the Amh (anti-müllerian hormone) locus; in human, the gene was localized to chromosome 19. The gene for PC5 (Pcsk5 locus) mapped to mouse chromosome 19 close to the Lpc1 (lipocortin-1) locus and, in human, was localized to chromosome 9. The gene for PACE4 (Pcsk6 locus) mapped to mouse chromosome 7, at a distance of 13 cM from the Pcsk3 locus, which specifies furin, another member of this family of enzymes previously mapped to this chromosome. This is in concordance with the known close proximity of these two loci in the homologous region on human chromosome 15q25-qter. Pcsk3 and Pcsk6 mapped to a region of mouse chromosome 7 that has been associated cytogenetically with postnatal lethality in maternal disomy, suggesting that these genes might be candidates for imprinting.

The distinct gene expression of the pro-hormone convertases in the rat heart suggests potential substrates

The present study examined the distribution of the pro-hormone convertases PC1, PC2, furin, PACE4 and PC5 in the rat heart. Northern blot analysis of RNA extracted from cardiac tissues showed high levels of furin and PACE4 mRNA in the atria and ventricles, while PC5 mRNA was found to be expressed at high levels in the dorsal aorta. Although undetectable by Northern blot analysis, both PC1 and PC2 mRNA were detected by in situ hybridization and immunohistochemistry in discrete regions of the intracardiac para-aortic ganglia. In situ hybridization studies also showed that furin mRNA was observed in all cardiac tissues and cells, consistent with the previously reported ubiquitous expression of this gene. PACE4 mRNA was highly abundant in both the atria and ventricular cardiomyocytes, with low to undetectable levels observed in blood vessels. Finally, PC5 transcripts were expressed in the endothelial cells lining coronary vessels and the valve leaflets of the heart. The present localization studies in the heart and cardiac blood vessels suggests potential roles for each convertase in the processing of various neuropeptides, hormones and growth factors.

Molecular cloning, cDNA sequence, and localization of a prohormone convertase (PC2) from the Aplysia atrial gland

Neuropeptides and peptide hormones are synthesized as part of larger precursor proteins that are processed post-translationally by subtilisin-related calcium-dependent prohormone convertases (PCs), frequently at multiple basic sites, to generate biologically active peptides. The atrial gland of Aplysia californica produces large quantities of egg-laying hormone (ELH)-related peptides, providing a unique opportunity to study prohormone processing. We have screened an Aplysia atrial gland cDNA library using a Lymnaea stagnalis PC2 probe and have isolated an Aplysia PC2-related 4.6-kb cDNA partial clone that was truncated on the 5' end. The remaining 5' atrial gland PC2 nucleotide sequence was obtained by reverse transcription/polymerase chain reaction (RT-PCR). The composite cDNA structure (5.6 kb) was deduced from sequence analysis of the RT-PCR product combined with the sequence obtained from the cDNA clone. The deduced cDNA of Aplysia atrial gland PC2 encoded a putative preproendoprotease of 653 amino acids that was evolutionarily related to other eukaryotic PC2s, and showed the strongest sequence identity with recently reported Aplysia nervous tissue PC2 sequences. In situ hybridization demonstrated extensive expression of PC2 in atrial gland secretory cells. The cDNA clone contained a relatively long 3'untranslated region (3'-UTR) of 3,632 nucleotides. Strikingly, the 3'-UTR also contained several major nucleotide repeat sequences including the microsatellite repeats, (CA)n and (TG)n, and a TA-rich region comprised largely of the triplet repeat (TTA)n. The characterized Aplysia PC2 is a candidate endoprotease that may play an important role in the processing of ELH-related precursors in the atrial gland and represents the first example of PC2 expression in exocrine tissue.

Maintained PC1 and PC2 expression in the AtT-20 variant cell line 6T3 lacking regulated secretion and POMC: restored POMC expression and regulated secretion after cAMP treatment

Two variant cell lines were recently established from parent AtT-20 cells. Whereas HYA.15.10.T.2 have a reduced level of secretory granules, HYA.15.6.T.3 are completely devoid of both the regulated pathway of secretion and of dense-core secretory granules. AtT-20 cells normally express the processing enzymes PC1, PC2, furin, carboxypeptidase E, and peptidylglycine alpha-amidating monooxygenase, as well as proopiomelanocortin, chromogranin B, and 7B2. We measured the expression of these mRNAs in both variant cell lines. Although some differences in mRNA level were noted, HYA.15.10.T.2 and HYA.15.6.T.3 cell lines maintained their expression of the processing enzymes and of 7B2. Furthermore, PC1 and PC2 were shown to be functionally active in the HYA.15.6.T.3 cells. In contrast, proopiomelanocortin and chromogranin B mRNA levels were no longer detectable in HYA.15.6.T.3 cells. Interestingly, stimulation of the HYA.15.6.T.3 cells with cAMP restored proopiomelanocortin mRNA, beta-endorphin immunoreactivity, and dense-core granules. Furthermore, at the ultrastructural level, beta-lipotropin immunoreactivity was detected in granules of cAMP-induced HYA.15.6.T.3 cells. Finally, depolarization of cAMP-induced HYA.15.6.T.3 cells with 56 mM potassium chloride resulted in a marked increase in the release of beta-endorphin immunoreactivity. These observations demonstrate that cAMP restores the regulated pathway of secretion in HYA.15.6.T.3 cells, which under untreated conditions do not demonstrate regulated release. These variant cell lines are unique models to understand better the relationship of the regulated pathway and the expression of the processing enzymes.

Processing specificity and biosynthesis of the Drosophila melanogaster convertases dfurin1, dfurin1-CRR, dfurin1-X, and dfurin2

Pro-protein and pro-hormone convertases are subtilisin/kexin-like enzymes implicated in the activation of numerous precursors by cleavage at sites mostly composed of pairs of basic amino acids. Six members of this family of enzymes have been identified in mammals and named furin (also called PACE), PC1 (also called PC3), PC2, PACE4, PC4, and PC5 (also called PC6). Multiple transcripts are produced for all the mammalian convertases, but only in the cases of PC4, PACE4, and PC5 does differential splicing result in the modification of the C-terminal sequence of these enzymes. A similar molecular diversity is also observed for the convertases of Hydra vulgaris, Caenorhabditis elegans, and Drosophila melanogaster. In the third species, two genes homologous to human furin called Dfur1 and Dfur2 have been identified. The Dfur1 gene undergoes differential splicing to generate three type I membrane-bound proteins called dfurin1, dfurin1-CRR, and dfurin1-X, which differ only in their C-terminal sequence. By using recombinant vaccinia viruses that express each of the dfurin proteins, we investigated the potential effect of the C-terminal domain on their catalytic specificities. For this purpose, these enzymes were coexpressed with the precursors pro-7B2, pro-opiomelanocortin, and pro-dynorphin in a number of cell lines, and the processed products obtained were characterized. Our studies demonstrate that these proteases display cleavage specificities similar to that of mammalian furin but not to that of PC2. In contrast, we noted significant differences in the biosynthetic fates of these convertases. All dfurins undergo rapid removal of their transmembrane domain within the endoplasmic reticulum, resulting in the release of several truncated soluble forms. However, in the media of cells containing secretory granules, such as GH4C1 and AtT-20, dfurin1-CRR and dfurin2 predominate over dfurin1, whereas dfurin1-X is never detected. While pro-segment removal occurs predominantly in the trans-Golgi network for all the dfurins, in the presence of brefeldin A, only dfurin1-CRR and dfurin2 can undergo partial zymogen cleavage. The conclusions drawn from the results of this study may well be applicable to the mammalian convertases PC4, PACE4, and PC5, which also display C-terminal sequence heterogeneity.

Effect of hypophysectomy on pituitary adenylate cyclase-activating polypeptide gene expression in the rat testis

Pituitary adenylate cyclase-activating polypeptide (PACAP) is a member of the secretin/glucagon/vasoactive intestinal peptide (VIP) family. Our immunohistochemical and in situ hybridization histochemical studies indicated that PACAP-like immunoreactivity (PACAP-LI) and its mRNA were present in the germ cells in the rat testis. Because the testicular function is regulated by the pituitary gonadotropins, effect of hypophysectomy on the PACAP gene expression was investigated in the rat testis as an attempt to reveal the regulation of the testicular PACAP by the pituitary. The levels of testicular PACAP mRNA, which were determined by RNase protection assay, increased 2 weeks after hypophysectomy. In contrast, the levels of radioimmunoassayable PACAP decreased 2 weeks after the surgery. Immunohistochemistry showed that hypophysectomy did not change the distribution of PACAP-LI, although the number of immunopositive cells was markedly reduced after hypophysectomy. The replacement treatments of hypophysectomized animals with FSH or LH+FSH restored testicular PACAP mRNA to the levels in the control animals. On the other hand, all of these treatments (testosterone, LH, FSH, or LH+FSH) significantly increased radioimmunoassayable PACAP in the hypophysectomized rat testis. The results suggest that both testicular PACAP and its mRNA expression are regulated by the hypothalamic-pituitary-gonadal activity, and that FSH may play a major role in this regulation.

Analysis of mutations in alleles of the fur gene from an endoprotease-deficient Chinese hamster ovary cell strain

RPE.40 mutant cells differ from wild-type Chinese hamster ovary (CHO-K1) cells in their increased resistance to Pseudomonas exotoxin A and their inability to process the insulin proreceptor and certain viral envelope proproteins. Northern analysis revealed that RPE.40 cells maintained a substantially lower steady-state level of 4.0 kb fur mRNA than did CHO-K1 cells. Analysis of fur cDNAs showed that RPE.40 cells were diploid at the fur locus, and RPE.40 cells had a Cys (TGC) to Tyr (TAC) mutation in codon 196 of one allele (allele I). Approximately 25-30% of the CHO-K1 cells were also heterozygous (Tyr/Cys) at codon 196, and pre-mRNAs transcribed from the second allele (allele II) in RPE.40 cells were defectively spliced. All other pre-mRNAs were correctly spliced. Rapid turnover of defectively spliced transcripts may account for the reduced steady-state level of fur mRNA observed in RPE.40 cells. Our results provide a mechanistic basis for the endoprotease-deficient phenotype of RPE.40 cells.

Distribution and regulation of the candidate prohormone processing enzymes SPC2 and SPC3 in adult rat brain

A number of candidate mammalian prohormone processing enzymes related to the yeast Kex2 endoprotease have been cloned and demonstrated to cleave several prohormone precursors at single, pairs and tetra basic amino acid processing sites. We have mapped the distribution of the mRNAs encoding two of these endoproteases in adult rat brain. SPC3 message levels showed a more restricted distribution and generally lower levels than SPC2 transcripts. The highest levels of SPC2 mRNA were found in the pyramidal cells of the hippocampus, several thalamic nuclei, the habenula and selected nuclei in the hypothalamus. SPC3 mRNA was most abundant in dentate gyrus granule cells, the habenula and selected hypothalamic nuclei. In the hypothalamus overlapping and unique distributions of the two transcripts were seen in the paraventricular nucleus with SPC3 mRNA predominantly expressed in lateral magnocellular cells. Both SPC2 and SPC3 mRNA were upregulated in the paraventricular and supraoptic hypothalamic nuclei following chronic salt loading. Combined immunocytochemistry/in situ hybridization histochemistry demonstrated that SPC2 and SPC3 transcripts were both expressed in the vasopressinergic subpopulation of magnocellular neurons in the supraoptic nucleus. SPC3 mRNA, but not SPC2 transcripts, also colocalized with immunoreactive vasopressin-associated neurophysin in the suprachiasmatic nucleus. These results remain consistent with roles for SPC2 and SPC3 in the biosynthesis of neuropeptides and for a specific role for SPC3 in the processing of provasopressin. Increased levels of SPC2 and SPC3 transcripts following a chronic osmotic stimulus suggests these proteases are coregulated with prohormone substrates and may be useful as an indicator of peptidergic activity.

Insulin secretory granule biogenesis and the proinsulin-processing endopeptidases

The insulin storage granule of the pancreatic beta cell is assembled within the trans Golgi network from around 50 or so gene products many of which are synthesized coordinately with the major component, proinsulin. An important contribution to our understanding of the regulation of this process has come from studies of the post-translational processing of proinsulin and of other proteins which are stored in the granule, particularly the processing enzymes themselves. The present review focusses on recent insights into the molecular nature of the processing machinery, and the granule Ca(2+)-dependent subtilisin-related endopeptidases which catalyse the initial rate-limiting step in the enzymic conversion of proinsulin.

Rapid cleavage of the endogenous PC3 prosegment and slow conversion to 74 kDa and 66 kDa proteins in AtT-20 cells

AtT-20 cells synthesize 87 kDa and 66 kDa forms of the prohormone convertase PC3 (also known as PC1). In the present work, using biosynthetic labeling experiments (performed both at 20 degrees C and at 37 degrees C), followed by immunoprecipitation with aminoterminally and carboxyterminally-directed antisera, we have found that the first PC3 translational product was a 94 kDa protein that was then converted to an 84 kDa form. This processing was extremely rapid, occurring with a half-life of less than 2 min at 20 degrees C. The 84 kDa form was endoglycosidase H-sensitive, indicating a lack of acquisition of sugar transferred in the medial golgi. Dithiothreitol, a reducing agent that prevents the disulfide bond formation of newly synthesized proteins in the endoplasmic reticulum (ER), inhibited the processing of the 94 kDa to the 84 kDa form. However, brefeldin A (BFA), an inhibitor of ER/golgi transport, and monensin, an inhibitor of the medial/trans-golgi transport, did not affect the cleavage of the 94 kDa to the 84 kDa protein. The 84 kDa protein was converted to an endoglycosidase H-resistant form of 87 kDa that was sequentially processed to 74 kDa and 66 kDa proteins. The 87 kDa protein was immunoprecipitated by the PC3 aminoterminally and carboxyterminally-directed antisera, while the 74 kDa and 66 kDa protein were only detected with the aminoterminally-directed antibody. Radiosequencing of the 87 kDa and 66 kDa proteins indicated that the biosynthesis of the 87 kDa proteins involves the removal of the 83 amino acid prosegment, and that the processing of the 87 kDa to 66 kDa form occurred by cleavage at the carboxyterminal portion. BFA and monensin effectively interrupted the processing of the 84-87 kDa protein to the 74 and 66 kDa species. In addition, while the 84-87 kDa protein produced in monensin-treated cells was still sensitive to endoglycosidase H, the 66 kDa protein was resistant to this enzyme. These results indicate that the post-translational processing of PC3 occurs in three steps: (1) rapid conversion, probably in the ER, of the 94 kDa precursor to the 84 kDa protein by removal of the aminoterminus prosegment; (2) cleavage of the 87 kDa protein to an intermediate product of 74 kDa; and (3) production of the 66 kDa protein. The second and third steps occur in late cellular compartments such as the trans-golgi network or secretory granules and involve sequential cleavages at the carboxyterminus.(ABSTRACT TRUNCATED AT 400 WORDS)

Homology modelling of the catalytic domain of human furin. A model for the eukaryotic subtilisin-like proprotein convertases

A model is presented for the three-dimensional structure of the catalytic domain of the human serine proteinase furin and its interaction with model substrates. This homology model is based on the crystal structures of subtilisin BPN' and thermitase in complex with the inhibitor eglin, and it also applies to other members of the eukaryotic subtilisin-like proprotein convertases. Predictions are made of the general protein fold, inserted loops, disulfide bonds, Ca(2+)-binding sites and salt bridges. A detailed prediction of the substrate-binding region attempts to explain the basis of specificity for multiple basic residues preceding the cleavage site. Specific acidic residues in the S1, S2 and S4 subsites of the substrate-binding region of furin are identified which appear to be of particular importance, while residues of the S2', S3, S5 and S6 subsites may also contribute to substrate binding. Based on this model, protein engineering can be employed not only to test the predicted enzyme-substrate interactions, as demonstrated for human furin, but, equally importantly, to design proprotein convertases with a desired specificity, or to design novel substrates or inhibitors.

Differential expression of two testis-specific transcripts of the mouse Pdha-2 gene during spermatogenesis

Analysis of the expression of the testis-specific isoform of the mouse pyruvate dehydrogenase E1 alpha subunit gene (Pdha-2) during various stages of spermatogenesis has shown that a 2.0-kb Pdha-2 mRNA is initially transcribed in meiotic prophase. The initial appearance of Pdha-2 mRNA precedes that of Pgk-2 and corresponds to the appearance of Ldh-3 mRNA. A second Pdha-2 1.7-kb transcript is present in post-meiotic round spermatids. Polysomal analysis of purified spermatogenic cell populations demonstrates that the 2.0-kb mRNA species is translated in diploid, pachytene spermatocytes and the 1.7-kb mRNA species is translated in round spermatids, although a large proportion is present on the nonpolysomal fraction and may be stored for use in later stages of spermiogenesis.

Structural characterization of a Lymnaea putative endoprotease related to human furin

A number of peptides have been identified in the central nervous system of the freshwater snail, Lymnaea stagnalis, that function as hormones and neurotransmitters/neuromodulators. These peptides are typically proteolytically processed from larger prohormones mostly at sites composed of single or multiple basic amino acid residues. Previously we demonstrated a diversity of putative prohormone convertases that may be involved in prohormone processing in the Lymnaea brain. In the present report, we have characterized a cDNA clone encoding a putative endoprotease of 837 amino acids. The primary structure of endoprotease (Lfur2) was comparable to that of human furin and contained a putative catalytic domain, a Cys-rich domain, and a transmembrane region. The catalytic domain of Lfur2 demonstrated about 70% residue identity when compared with human furin, PACE4 and Drosophila Dfur1 and dKLIP-1. The Lfur2 gene was expressed in the central nervous system as well as various peripheral tissues of Lymnaea.

Gene organization of the mouse pro-hormone and pro-protein convertase PC1

Using a probe consisting of either the 5' end sequence or the full-length cDNA sequence of the mouse prohormone convertase PC1 (mPC1), we isolated from a lambda EMBL3 mouse genomic library two clones that coded for the 5' and 3' ends of the mPC1 gene. The complete gene organization was obtained by combining the results of the sequence of these clones and those of the characterization of polymerase chain reaction-amplified genomic segments. The single-copy mPC1 gene, confirmed by Southern analysis, spans at least 42 kb and is composed of 15 exons and 14 introns of various sizes. The exon lengths varied between 77 to about 1,600 bp, with the longest exon representing the 3' end of the gene. The intron sizes are between 0.4 and 6.5 kb in length. The active sites Asp, His, and Ser, the catalytically important Asn, and the RGD-containing domain are each found on separate exons. The general organization of the 5' end and catalytic domain of the mouse PC1 gene is very similar to that reported for the other pro-protein convertases genes, namely human fur, human PC2, and mouse PC4. However, the four genes differ considerably in their 3' end structure. Primer extension and 5' RACE analysis demonstrated that the mPC1 mRNA contains multiple transcription initiation sites of which major ones are found at either 211, 209, or 207 bp from the 5' end of the initiator methionine. Analysis of the sequence of the available 850-bp promoter segment revealed no functional TATA and CCAAT boxes. However, within this segment we noted the presence of two AP-1, Sp1, and cAMP responsive element (CRE) sequences, an interferon consensus sequence (ICS), and three POU proteins (e.g., GHF-1) binding elements. In tissues and cells. Northern blot analysis demonstrated the presence of two major mRNA transcripts of sizes 3 and 5 kb. The cDNA structure of rat PC1 demonstrated that these two transcripts arise by alternative choice of polyadenylation sites and in the mouse these two alternative sites are found on exons 14 and 15, respectively. Accordingly, we show that exon 14 is found in both the 3- and 5-kb transcripts but exon 15 is only found in the 5-kb mRNA. Using a 3' end probe specifically hybridizing with the 5-kb mRNA, we show that in the mouse pituitary neurointermediate lobe the 3-kb form is negatively regulated by dopamine, while the 5-kb form is not.

Expression of PC2 and PC1/PC3 in human pheochromocytomas

Expressions of two Kex2-related proteases, Pc2 and PC1/PC3, and of one of their possible substrates, proenkephalin, were examined in normal (n = 7) and various pathological (n = 48) human adrenal tissues. Northern blot analysis detected the expression of these genes in pheochromocytomas only. In the 20 pheochromocytomas studied with this technique, PC2, PC1/PC3 and proenkephalin were expressed in 85%, 50% and 90%, respectively. The presence of PC2 and PC1/PC3 was further confirmed using the sensitive RT/PCR techniques. Other evidence of human tumoral adrenal medullary PC2 expression was provided by in situ hybridization and immunohistochemistry. In addition, proenkephalin was expressed only in the pheochromocytomas expressing PC2 and/or PC1/PC3. These results demonstrate that functional Kex2-related endoproteases are expressed in human pheochromocytomas and may be involved in the processing of proenkephalin.

Isolation and in situ localization of a cDNA encoding a Kex2-like prohormone convertase in the nematode Caenorhabditis elegans

1. A cDNA that encodes a Kex2-like prohormone convertase (PC) containing an active site similar to that of mammalian PC2 has been isolated from C. elegans. Total RNA was isolated from a mixed population of strain BA713 worms. After poly-(A)-selection and reverse transcription, degenerate/nested polymerase chain reactions (PCR) were performed using primers based on conserved regions within the active sites of the known vertebrate and invertebrate endoproteases. 2. Two distinct 300-bp PCR products that shared homologies with the active sites of known Kex2-like endoproteases were isolated. These two PCR products were used to screen a C. elegans cDNA library. 3. The complete cDNA for a Kex2-like endoprotease, designated CELPC2, was isolated and determined to be 2527 bp in length. This size was confirmed by northern analysis. The deduced amino acid sequence for the CELPC2 cDNA is very similar to the known Kex2-like endoproteases, especially at conserved regions within the active sites, but not identical to any one of them. The strongest structural homology was to vertebrate and invertebrate PC2 sequences. 4. In situ hybridization suggests that CELPC2 is synthesized primarily in cells associated with the circumpharyngeal nerve ring and the dorsorectal ganglion.

Processing of prodynorphin by the prohormone convertase PC1 results in high molecular weight intermediate forms. Cleavage at a single arginine residue

Processing of rat prodynorphin (proDyn) by the mouse prohormone convertase PC1 was investigated. Recombinant vaccinia virus vectors were used to coexpress proDyn and PC1 in rat PC12 pheochromocytoma and mouse AtT-20 corticotroph cells. In vitro experiments were also conducted by co-incubating purified proDyn and PC1. The results demonstrate that PC1 cleaves proDyn at pairs of basic residues to yield 10 and 16 kDa high molecular weight (HMW) intermediates. Additionally, PC1 cleaves proDyn at a single arginine residue to yield an 8 kDa product and the C-peptide. This demonstrates that PC1 cleaves proDyn at single and pairs of basic residues.

Evolution of the gastrointestinal endocrine system (with special reference to gastrin and CCK)

The evolution of gut endocrine cells can be seen to have depended in the first instance on the expression of genes encoding regulatory peptides in cells that had evolved the regulated pathway of secretion. It seems probable that the endocrine cells made use of molecules and mechanisms that first emerged in early nervous systems. However, by the start of the vertebrate line of evolution, most of the major families of gut hormones were already found in association with endocrine cells. A single common class of receptor with seven transmembrane domains and acting via association with G-proteins transduces many (perhaps all) gut peptide actions. The duplication and divergence of receptors and peptides can now be traced, in outline at least, for gastrin and CCK in vertebrates. Even in phylogenetically similar groups such as birds and mammals, quite different molecular approaches have been applied to solving the same physiological problem. Evolution of the modern gastrointestinal control system evidently depended in this case both on molecular evolution of peptides and receptors and on cells expressing the genes encoding them.

Furin-mediated proprotein processing activity: involvement of negatively charged amino acid residues in the substrate binding region

Furin, which is encoded by the recently discovered FUR gene, appears to be the first known mammalian member of the subtilisin family of serine proteases with cleavage selectivity for paired or multiple basic residues. A consensus cleavage sequence, Arg-X-Lys/Arg-Arg has been proposed. Most likely, furin is primarily involved in the processing of precursors of proteins that are secreted via the constitutive secretory pathway. Homology modelling of the catalytic domain of this protein suggested that negatively charged amino acid residues near or in the substrate binding region might contribute to the observed specificity for substrate segments with paired and multiple basic amino acid residues. To investigate this hypothesis, furin mutants were generated in which negatively charged residues, predicted to be located near or in the substrate binding pockets and involved in interactions with basic residues of the substrate, were replaced by neutral residues. Analysis of processing by these furin mutants of wild-type and cleavage mutants of pro-von Willebrand factor (pro-vWF) revealed that particular negatively charged residues are critical for specific cleavage activity.

The family of subtilisin/kexin like pro-protein and pro-hormone convertases: divergent or shared functions

Six mammalian processing enzymes were recently discovered which exhibit significant similarities to both yeast kexin and bacterial subtilisins. These subtilisin/kexin-like convertases were called furin/PACE, PC1/PC3, PC2, PACE4, PC4 and PC5/PC6. The analysis of the mRNA expression of these convertases in rat tissues and cell lines by Northern blot analysis demonstrated a unique pattern for each enzyme. Thus, although furin and PACE4 mRNA (4.4 kb each) exhibit a widespread tissue distribution only furin is ubiquitously expressed. PACE4 exhibits a major 4.4 kb mRNA form, and in some tissues a 3.9 kb form is detected. PC5 mRNA (3.8 kb major) is more restricted in its distribution than PACE4 and furin, and it exhibits the presence of multiple mRNA forms, resulting in variable lengths of the C-terminal Cys-rich domain. In addition, like furin and PACE4, PC5 is expressed in both regulated and constitutively secreting cells. In contrast, PC1 (3 and 5 kb) and PC2 (2.8 and 5 kb) are primarily expressed in tissues and cells containing secretory granules. Multiple mRNA forms are also detected, but as far as is known none affect their open reading frame and only result in a variable length of the 3' non-coding sequence. Finally, PC4 mRNA (2.8 kb major and 1.9 kb minor) is only expressed in testicular germ cells. Biosynthetic analysis of the zymogen activation of PC1 and PC2 and their cleavage specificity following their cellular co-expression with a number of precursors, demonstrated that although pro-PC1 is rapidly activated to PC1 in the endoplasmic reticulum, pro-PC2 conversion into PC2 is rather slow. The cleavage of pro-PC2 into PC2 starts in the trans Golgi network and is regulated by an endogenous endocrine and neural precursor called 7B2. Although the genetic organization of the convertase genes is very similar, they exhibit unique promoter sequences and only furin and PACE4 genes are localized on the same chromosome.

Proprotein processing activity and cleavage site selectivity of the Kex2-like endoprotease PACE4

Proprotein processing activity of the Kex2-like mammalian endoprotease PACE4 and its cleavage selectivity for sites with basic amino acid residues were determined. Using a recombinant vaccinia virus-based expression system, PACE4 was expressed in pig kidney PK(15) cells and, like two other Kex2-like endoproteases furin and PC6A, shown to correctly process the precursor of von Willebrand factor (pro-vWF). Furthermore, characteristics of the cleavage site selectivity of PACE4 were compared to those of furin and PC6A using the vWF cleavage site mutants vWFR-1G, vWFK-2A, and vWFR-4A as substrates. Cleavage site selectivity of PACE4 and PC6A appeared to be similar but they differed from that of furin.

PACE4 is a member of the mammalian propeptidase family that has overlapping but not identical substrate specificity to PACE

Proteins that transit the constitutive pathway of secretion frequently require proteolytic processing after a pair of basic amino acids to attain their full functional activity. A ubiquitously expressed calcium-dependent subtilisin-like serine protease, named PACE or furin, can cleave precursor polypeptides specifically at pairs of basic amino acids where an arginine residue is present in the P4 position. Another member of this protease family, PACE4, was cloned recently by a PCR-based strategy and was also shown to be ubiquitously expressed. We have expressed PACE4 by transient DNA transfection of COS-1 cells and have shown that the cDNA encodes a 120-kDa polypeptide that is present in cell extracts but not in conditioned medium of transfected cells. The substrate specificities of PACE and PACE4 for cleavage of pro-von Willebrand factor were studied in parallel using a transient DNA cotransfection system. Like PACE, PACE4 was able to process pro-vWF to its mature form, and efficient cleavage required both the P4 arginine and the P2 lysine. These data, taken together with previously published data showing that PACE4 cannot process pro-factor IX, demonstrate that PACE and PACE4 have overlapping but not identical substrate specificities. Further differences between PACE and PACE4 specificities were elucidated by monitoring inhibition of processing activity mediated by the serine protease inhibitor alpha 1-antitrypsin Pittsburgh mutant. Pro-vWF processing by PACE was inhibited by expression of the alpha 1-antitrypsin Pittsburgh mutant, whereas processing of pro-vWF by PACE4 was not affected.(ABSTRACT TRUNCATED AT 250 WORDS)

Posttranslational processing of carboxypeptidase E, a neuropeptide-processing enzyme, in AtT-20 cells and bovine pituitary secretory granules

Carboxypeptidase E (CPE) functions in the posttranslational processing of peptide hormones and neurotransmitters. Like other peptide processing enzymes, CPE is present in secretory granules in soluble and membrane-associated forms that arise from posttranslational processing of a single precursor, "proCPE." To identify the intracellular site of proCPE processing, the biosynthesis and posttranslational processing were investigated in the mouse anterior pituitary-derived cell line, AtT-20. Following a 15-min pulse with [35S]Met, both soluble and membrane-bound forms of CPE were identified, indicating that the posttranslational processing event that generates these forms of CPE occurs in the endoplasmic reticulum or early Golgi apparatus. The relative proportion of soluble and membrane-bound forms of CPE changed when cells were chased for 2 h at 37 degrees C but was unaffected when cells were chased at either 20 or 15 degrees C, suggesting that further processing of membrane forms to the soluble form occurs in a post-Golgi compartment. Treatment of the cells with chloroquine did not alter the relative distribution of soluble and membrane forms, suggesting that an acidic compartment is not required for this processing event. Overexpression of CPE did not influence the distribution of soluble and membrane forms of CPE, indicating that the CPE-processing enzymes are not rate-limiting. To examine directly CPE-processing enzymes, bovine anterior pituitary secretory vesicles were isolated. An enzyme activity that releases the membrane-bound form of CPE was detected in the purified secretory vesicle membranes. This enzyme, which removes the C-terminal region of CPE, is partially inhibited by EDTA and phenylmethylsulfonyl fluoride and is activated by CaCl2. Together, the data indicate that posttranslational processing of CPE occurs in secretory granules and that this activity may be mediated by a prohormone convertase-like enzyme.

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.

Proteolytic processing of the hepatocyte growth factor/scatter factor receptor by furin

The hepatocyte growth factor/scatter factor (HGF/SF) receptor consists of an alpha- and a beta-subunit, which are derived from a single-chain precursor by endoproteolytic processing. The precursor is not proteolytically processed in LoVo colon carcinoma cells. The uncleaved receptor immunopurified from the cells was cleaved in vitro by furin. Furthermore, the HGF/SF receptor was proteolytically processed in LoVo cells transfected with furin cDNA. These results indicate that furin is a processing endoprotease for the HGF/SF receptor. Tyrosine autophosphorylation of the uncleaved receptor was induced by HGF/SF, and the growth of the cells expressing the uncleaved receptor was stimulated by HGF/SF, indicating that the proteolytic processing of the receptor is not essential for the signal transduction of HGF/SF.

Release of the prohormone convertase PC1 from AtT-20 cells

AtT-20 cells are known to synthesize two molecular weight forms of the prohormone converting enzyme PC1 with molecular masses of 87 and 66 kDa. In this study we have analyzed basal and stimulated secretion of these proteins. Western blot results show that basal secretion medium of cultured AtT-20 cells contained low concentrations of both the 87 and 66 kDa forms of PC1 with the former protein predominant. During the stimulation period with CRF, cAMP and cAMP + BaCl2, increased release of both proteins was observed, but the 66 kDa protein predominated. Secretion medium obtained from stimulated and unstimulated cells was enzymatically active against the Cbz-Arg-Ser-Lys-Arg-AMC fluorogenic substrate as well as against 35S-proenkephalin. This activity was Ca+2 dependent and was inhibited by the chelating agent EDTA. The activity was insensitive to acid and thiol proteinase inhibitors as well as to N-alpha-p-tosyl-L-Lys-chloromethyl ketone; it was slightly sensitive to phenylmethyl sulfonyl fluoride and was strongly inhibited by D-Tyr-Ala-Lys-Arg-chloromethyl ketone. This inhibitor profile exhibits strong similarities to furin and kexin. After partial purification of medium by gel filtration chromatography, a portion of the enzymatic activity and immunoreactivity for both 87 kDa and 66 kDa proteins eluted with an apparent molecular weight of 400 kDa (suggesting aggregation); however the highest activity appeared in the elution position of the 66 kDa monomer. When the 87 kDa protein was removed from the medium by means of an affinity column containing an antibody against the carboxyl terminal portion of PC1, the column flow-through, which included the 66 kDa protein, still remained enzymatically active. These data support the notion that the 66 kDa protein, which is the most concentrated PC1 product stored in AtT-20 cells and is released during stimulation, is enzymatically active.

Identification of an isoform with an extremely large Cys-rich region of PC6, a Kex2-like processing endoprotease

In the previous study [1993, J. Biochem. (Tokyo) 113, 132-135] we identified PC6, a member of the Kex2 family of processing endoproteases. In this study, we identified another cDNA encoding an isoform of PC6, and designated it as PC6B and redesignated the originally identified PC6 as PC6A. PC6B had a very large Cys-rich region consisting of 22-times repeats of a Cys-rich motif, and a putative transmembrane domain which is not present in PC6A. A PC6B transcript was found mainly in the intestine, while PC6A transcripts were in various tissues. These results suggest distinct roles of PC6A and PC6B in endoproteolytic processing of precursor proteins.

Expression of neuropeptide processing enzymes and neurosecretory proteins in ependyma and choroid plexus epithelium

Recent studies suggest that brain ependyma and choroid plexus produce neuropeptide processing enzymes. To facilitate the understanding of these cells and their ability to produce biologically active peptides, we developed cultures of defined cell type. Ependymal cells were characterized by morphological criteria, and choroid plexus epithelial cell lines were characterized by the presence of the mRNA for IGF-II and transthyretin, a thyroxine binding protein produced in liver and choroid plexus. The ependymal cells and the choroid plexus epithelial cell lines were then examined for the presence of mRNAs for various neuropeptide processing enzymes. Northern blot analysis revealed high levels of furin, carboxypeptidase E, and peptidyl glycine alpha-amidating monooxygenase mRNAs, with levels in ependymal cells comparable to those in brain or pituitary. Carboxypeptidase E activity was detected in medium from cultured ependymal cells; this activity was identified as carboxypeptidase E based on the acidic pH optimum and sensitivity to various inhibitors. The mRNAs for other neuropeptide processing enzymes, such as prohormone convertases 1 and 2, were not detected on Northern blots of RNA from ependyma or choroid plexus epithelium. Since ependyma and choroid plexus epithelium express a subset of processing enzymes, we suggest that these cells have the capacity to produce biologically active peptides. Initial screening by reverse transcriptase-polymerase chain reaction assays has demonstrated the presence of mRNA for the neurosecretory proteins chromogranin B and secretogranin II in both ependyma and choroid plexus epithelium.

Processing of prodynorphin in BRL-3A cells, a rat liver-derived cell line: implications for the specificity of neuropeptide-processing enzymes

Prodynorphin is post-translationally processed into dynorphin B-13 and other peptides by the action of endopeptidases that cleave at pairs of basic amino acids and at single basic residues, followed by a carboxypeptidase that removes the C-terminal basic residues. To evaluate the specificity of neuropeptide processing enzymes, rat prodynorphin was transfected into BRL-3A cells, a rat liver-derived cell line which produces insulin-like growth factor II, but does not normally express prodynorphin. The transfected prodynorphin was post-translationally processed at both monobasic and dibasic cleavage sites, with the formation of dynorphin B-13 and other peptides. This finding indicates that BRL-3A cells express prodynorphin-processing enzymes. These cells were found to secrete two enzyme activities previously implicated in the processing of dynorphin, a monobasic cleaving 'dynorphin converting enzyme' and 'carboxypeptidase E', based on inhibitor sensitivities and pH optima. The dynorphin converting enzyme secreted from BRL-3A cells elutes from an anion exchange column under the same conditions as the enzyme secreted from pituitary-derived cell lines (AtT-20, GH4C1). Northern blot analysis indicates that BRL-3A cells express carboxypeptidase E mRNA in addition to mRNA encoding furin, a prohormone-processing endopeptidase. The mRNAs for two other related endopeptidases, prohormone convertase 1 and 2, were not detected on Northern blots, suggesting that these enzymes are not required for the processing of prodynorphin. The expression of carboxypeptidase E, furin, and dynorphin converting enzyme in BRL-3A cells suggests that these peptide processing enzymes are not specific for neuropeptides, but are also present in cells which process peptide growth factors.

Positional and additive effects of basic amino acids on processing of precursor proteins within the constitutive secretory pathway

We have recently shown that the Arg/Lys-X-Lys/Arg-Arg or Arg/Lys-X-X-X-Lys/Arg-Arg sequence serves as a signal for cleavage of precursor proteins within the constitutive secretory pathway, and this cleavage is catalyzed by furin, a mammalian homolog of the yeast Kex2 protease. In this study, we further examined sequence requirements for the constitutive precursor cleavage. Based on the data concerning cleavage efficiencies of various prorenin mutants with amino acid substitution(s) around the native cleavage site expressed in CHO cells, we revised the sequence rules that govern the constitutive cleavage as follows: (i) the Arg residue at position -1 is essential; (ii) in addition to the Arg at position -1, at least two out of the three basic residues at positions -2, -4, and -6 are required for efficient cleavage (the presence of all the three basic residues results in most efficient cleavage); (iii) at position +1, a hydrophobic aliphatic amino acid is not suitable.

Conformational analysis and proteolytic processing of synthetic pre-pro-GnRH/GAP protein

Homogeneous pre-pro-GnRH/GAP protein was recently synthesized in 100 mg quantities by solid-phase methods and surprisingly, the synthetic pre-pro-protein, which normally does not escape the endoplasmic reticulum, was found to inhibit the release of prolactin from cultured pituitary cells. This is the first demonstration of significant biological activity associated with a precursor protein and provides the rationale for its further study. We now report the results of our initial examination of the conformational properties of pre-pro-GnRH/GAP protein as a prelude to solving its solution phase conformation by homonuclear 1H-NMR protocols. Thermal and pH titration fluorescence and circular dichroism spectroscopies reveal that the protein is resistant to thermal-induced conformational changes but is particularly sensitive to pH-induced conformational changes; while Asp/Glu and Arg residues may contribute to structural stability, His and Lys residues predominate. Pre-pro-GnRH/GAP is about 30% helix in the range of 2-40 degrees C; however, even at 90 degrees C, the peptide retains nearly 50% of its helix character. There is no evidence for a cooperative transition; for this reason, differential scanning calorimetry failed to yield a defined transition thermogram. Pre-pro-GnRH/GAP apparently does not pass through a transition state as a function of temperature but appears to flex and retain a high percentage of helix structure, resulting in subtle changes in secondary structure. There is no discernible isodichroic point. On either side of the neutral pH range, however, there are dramatic changes in structure that result in nonreversible denaturation of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)