cDNA structure, tissue distribution, and chromosomal localization of rat PC7, a novel mammalian proprotein convertase closest to yeast kexin-like proteinases

By using reverse transcription-coupled PCR on rat anterior pituitary RNA, we isolated a 285-bp cDNA coding for a novel subtilisin/kexin-like protein convertase (PC), called rat (r) PC7. By screening rat spleen and PC12 cell lambda gt11 cDNA libraries, we obtained a composite 3.5-kb full-length cDNA sequence of rPC7. The open reading frame codes for a prepro-PC with a 36-amino acid signal peptide, a 104-amino acid prosegment ending with a cleavable RAKR sequence, and a 747-amino acid type I membrane-bound glycoprotein, representing the mature form of this serine proteinase. Phylogenetic analysis suggests that PC7 represents the most divergent enzyme of the mammalian convertase family and that it is the closest member to the yeast convertases krp and kexin. Northern blot analyses demonstrated a widespread expression with the richest source of rPC7 mRNA being the colon and lymphoid-associated tissues. In situ hybridization revealed a distinctive tissue distribution that sometimes overlaps with that of furin, suggesting that PC7 has widespread proteolytic functions. The gene for PC7 (Pcsk7) was mapped to mouse chromosome 9 by linkage analysis of an interspecific backcross DNA panel.

Role of prohormone convertases in the tissue-specific processing of proglucagon

Proglucagon (proG) is processed in a tissue-specific manner to glucagon in the pancreas and to gilcentin, oxyntomodulin, glucagon-like peptide (GLP)-1, and GLP-2 in the intestine. Recombinant vaccinia virus (vv) vectors were used to infect prohormone convertase 1 (PC1) or PC2 into nonendocrine (BHK-proG) cells, which stably express proG. Similarly, endocrine (GH3, AtT-20) cells were coinfected with proG along with PC1 or PC2 alone, or in combination with furin, PACE4, PC5a, or PC5b. Cell extracts were analyzed for various proG-derived peptides by RIA of fractions obtained from HPLC. Upon infection of BHK-proG cells with either vv: furin or vv:PC1, glicentin was produced, while vv: PC2 did not process proG. In GH3 and AtT-20 cells, vv:PC1 produced glicentin, oxyntomodulin, GLP-1(1-37), GLP-1(7-37), and GLP-2. All other enzymes tested produced only glicentin. Interestingly, no enzyme or combination produced glucagon. Coinfection of GH3 cells with vv:PC2 and members of the chromogranin family of peptides, including chromogranin A and B and secretogranin II, as well as the PC2-binding protein 7B2, did not result in processing to glucagon. It is concluded that: 1) PC1 is responsible for the processing of proG to produce the intestinal peptides glicentin, oxyntomodulin, GLP-1(1-37), GLP-1(7-37), and GLP-2, and 2) PC2 processes proG to glicentin but does not produce glucagon, alone or in combination with other enzymes or with known molecular chaperones.

Increased proteolytic processing of protein tyrosine phosphatase mu in confluent vascular endothelial cells: the role of PC5, a member of the subtilisin family

Cleavage and subsequent release of the extracellular domains of receptor protein tyrosine phosphatases (RPTP) occur at high cell density and may have an important role in regulating their activity. Because cleavage of RPTP occurs at a target motif (RXK/RR) recognized by a family of subtilisin/kexin-like endoproteases, we postulated that members of the subtilisin family may have an important role in this cleavage. We show in this report that the membrane-associated RPTPmu--both in its full 200-kDa form and as a 100-kDa cleavage product--is upregulated 4- and 7-fold, respectively, as human umbilical vein endothelial cells (HUVEC) approach confluence. To determine whether RPTPmu cleavage depended on PC5 (a subtilisin/kexin like endoprotease present in endothelial cells), we transfected COS cells with expression plasmids coding for RPTPmu and PC5 or the closely related protease PACE4. PC5, but not PACE4, cleaved RPTPmu, and RPTPmu cleavage was absent in COS cells transfected with an expression plasmid encoding a mutant PC5 whose active-site serine had been mutated to alanine. We also performed RNA blot analysis to determine whether PC5 expression was affected by confluence in HUVEC. PC5 mRNA levels were upregulated by more than 30-fold when confluence in HUVEC increased from 25% to 100%. These results indicate that PC5 may have an important role in mediating the cleavage of RPTPmu in response to contact inhibition in HUVEC.

Cellular processing of the nerve growth factor precursor by the mammalian pro-protein convertases

In order to define the enzymes responsible for the maturation of the precursor of nerve growth factor (proNGF), its biosynthesis and intracellular processing by the pro-protein convertases furin, PC1, PC2, PACE4, PC5 and the PC5 isoform PC5/6-B were analysed using the vaccinia virus expression system in cells containing a regulated and/or a constitutive secretory pathway. Results demonstrate that in both cell types furin, and to a lesser extent PACE4 and PC5/6-B, are the best candidate proNGF convertases. Furthermore, two processed NGF forms of 16.5 and 13.5 kDa were evident in constitutively secreting cell lines such as LoVo and BSC40 cells, whereas only the 13.5 kDa form was observed in AtT20 cells, which contain secretory granules. Both forms display the same N-terminal sequence as mature NGF, and were also produced following site-directed mutagenesis of the C-terminal Arg-Arg sequence of NGF into Ala-Ala, suggesting that the difference between them is not at the C-terminus. Co-expression of proNGF with furin and either chromogranin B or secretogranin II (but not chromogranin A) in BSC40 cells eliminated the 16.5 kDa form. Data also show that N-glycosylation of the pro-segment of proNGF and trimming of the oligosaccharide chains are necessary for the exit of this precursor from the endoplasmic reticulum and its eventual processing and secretion. Sulphate labelling experiments demonstrated that proNGF is processed into mature NGF following the arrival of the precursor in the trans-Golgi network. This comparative study shows that the three candidate mammalian subtilisin/kexin-like convertases identified process proNGF into NGF and that the nature of the final processed products is dependent on the intracellular environment.

Comparative cellular processing of the human immunodeficiency virus (HIV-1) envelope glycoprotein gp160 by the mammalian subtilisin/kexin-like convertases

We present here the pulse and pulse-chase analysis of the biosynthesis of the envelope glycoprotein gp160 and its intracellular processing by the subtilisin/kexin-like convertases furin, PACE4, PC1, PC5 and its isoform PC5/6-B. We demonstrate that furin and to a much lesser extent PACE4, PC5/6-B and PC1 are candidate enzymes capable of processing gp160 intracellularly. Furthermore we show that furin can also process gp160/gp120 into gp77/gp53 products by cleavage at the sequence RIQR/GPGR just preceding the conserved GPGR structure found at the tip of the hypervariable V3 loop. The results show that processing into gp120 could occur at or before the trans-Golgi network (TGN) where sulphation of the oligosaccharide moieties of gp160 was detected. In contrast, the formation of gp77/gp53 by furin is a late event occurring after exit from the TGN. Our data also revealed that the alpha glucosidase I inhibitor N-butyldeoxynojirimycin, although affecting the oligosaccharide composition of gp160, does not impair the processing of either gp160 or gp120 by either furin or PACE4. Finally, the co-expression of the [Arg355, Arg358]-alpha-1-antitrypsin Portland variant was shown to potently inhibit the processing of both gp160 and gp120 by these convertases.

Cellular processing of the neurotrophin precursors of NT3 and BDNF by the mammalian proprotein convertases

In order to define the enzymes responsible for the maturation of the precursors of brain-derived neurotrophic factor (proBDNF) and neurotrophin-3 (proNT3), we have analysed their biosynthesis and intracellular processing by the proprotein convertases furin, PC1, PC2, PACE4, PC5 and its isoform PC5/6-B. In these studies, we utilized a vaccinia virus expression system in either BSC40 or the furin activity-deficient LoVo cells. Results demonstrated that in both cells furin and, to a lesser extent, PACE4 and PC5/6-B effectively process proBDNF and proNT3. Furthermore, we have determined that human proNT3 is sulfated, suggesting that processing of proNT3 occurs following the arrival of the precursor to the Trans Golgi Network.

Implications of the subtilisin/kexin-like precursor convertases in the development and function of nervous tissues

Furin, PC1, PC2, and PC5 represent mammalian convertases (PCs) found in endocrine, central and peripheral nervous tissues, which cleave a number of precursors at basic residues normally processed in vivo. Typical bonds cleaved by PCs include the pairs Lys-Arg, Arg-Arg and Arg-X-Lys/Arg-Arg. These cleavage sites have been detected following coexpression of each convertase in cell lines together with different precursors as models, including proopiomelanocortin (POMC), proinsulin and proNGF and proBDNF. The presence of PCs and different precursors was revealed by in situ hybridization or immunocytochemistry in cultured AtT-20 cells, in the developing CNS, pituitary, and pancreatic islets. In an experimental model of epilepsy in which epileptiform activities were provoked by kainic acid administration, we observed a similar transient expression of furin and PC1 as compared to that of NGF and BDNF. In conclusion, it is proposed that under different stimuli various precursors are activated by a unique cocktail of convertases, each of which either alone or in combination with others acts to process inactive precursors, and thereby playing an important role in development and in the plasticity of the neuronal system.

Application of the multiple antigenic peptides (MAP) strategy to the production of prohormone convertases antibodies: synthesis, characterization and use of 8-branched immunogenic peptides

Antiserum against an N-terminal sequence of murine prohormone convertase-1 (mPC1) incorporating the sequence immediately following the junction between the putative pro-region and the active enzyme was obtained. This was accomplished using the multiple antigenic peptide (MAP) approach whereupon an 8-branched polylysine core to which are grafted multiple copies of a 16 amino acid peptide representing the N-terminal sequence of mPC1 (positions 84-99) was synthesized by solid-phase Fmoc chemistry. The ensuing peptide was purified and fully characterized by RP-HPLC, 1H-NMR, amino acid composition, peptide sequencing and ion-spray mass spectrometry. The immunological properties of the resulting antibodies in detecting recombinant PC1 in both crude and purified preparations were compared with antibodies raised against a similar N-terminal segment of PC1 but using the conventional method of peptide-carrier protein conjugation and also developed against a C-terminal fusion protein of PC1. Our data indicate that the MAP antibody was as efficient as both the amino and carboxy-terminal antibodies in qualitative as well as quantitative analysis of PC1 encoded protein by radioimmunoassay. Following an identical approach, antibodies against other prohormone convertases like furin, PC5/6 and PACE4 were also developed and subsequently applied to a number of biochemical and immunological studies. In each case, the case of preparation and high immunogenicity of the MAP approach were confirmed and reside in the simplicity and rapidity with which a potent and useful antiserum is obtained.

Heterologous processing of rat prosomatostatin to somatostatin-14 by PC2: requirement for secretory cell but not the secretion granule

The role of PC2 in prosomatostatin (PSS) processing was investigated in GH3/GH4C1 pituitary cells. These cells are sparsely granulated, express different amounts of PC2 and no PC1. We described heterologous processing of rat PSS (rPSS) co-expressed with PC2 in stably transfected cells, correlate PC2 protein levels under different conditions of transfection with efficiency of PSS processing to somatostatin-14 (SS-14), determine the effect of modulating cell granularity on enzyme expression and PSS processing, and compare the relative potency of PC2 with that of PC1, PSS and cleavage products were monitored by HPLC and radioimmunoassay of SS-like immunoreactivity (SSLI). Radioimmunoassay analysis of N-terminal PC2-like immunoreactivity (PC2 LI) in GH4C1:rPSS, GH4C1:rPSS + PC2 and GH3:rPSS transfectants showed a gradient of PC2 protein of 1:2.6:3.4 in cell extracts and 1:4.7:9 in secretion media from these cells respectively. The concentration of PC2 protein correlated with SS-14 conversion efficiency was 36 +/- 3% in GH4C1:rPSS cells, 56 +/- 7% in GH4C1:rPSS-PC2 cells and 100% in GH3:rPSS cells. Treatment of GH4C1:rPSS + PC2 cells with epidermal growth factor, insulin, and beta-estradiol to induce granules, significantly increased basal and forskolin-stimulated co-release of SS LI and PC2 LI, but had no influence on SS-14 processing efficiency. Hormone treatment led to a small increase in the ratio of mature PC2 (68 kDa) to proPC2 (75 kDa) forms. PC1 stably transfected in GH4C1 cells produced significantly greater SS-14 conversion (62% in cells, 66% in media) compared with PC2 transfectants (53% in cells, 47% in media) These results provide the first proof that PC2 can effect dibasic processing of mammalian PSS, and, along with PC1, qualifies as an authentic SS-14 convertase. The activity of PC2 requires the milieu of the secretory cell but not the secretory granule.

Peptidyl substrates containing unnatural amino acid at the P'1 position are potent inhibitors of prohormone convertases

In order to study further the importance of the P'1 residue upon the activity of human PC1 and human furin, two important members of subtilisin/kexin family of enzymes, we have prepared by solid-phase Fmoc or recently introduced FastMoc chemistry a series of 10 peptidyl substrate analogs. The structures of these analogs are based upon the core sequence of pro-mPC1(83-93) namely, D-Tyr-Lys-Glu-Arg-Ser-Lys-Arg-Xaa-Val-Gln-Lys-Asp, where D-Tyr replaces the native L-Tyr residue and Xaa, representing the P'1 position, corresponds to L-Ser or to nonproteinacous amino acids such as Tle, Sarc, MLeu, Aib, D-Tic or L-Tic. Two more analogs with L-Tic at P'1 position but with one amino acid less, namely P5 Glu or P'3 Gln, and one with a Cit residue in place of Arg at P1 site of the dodecapeptide were also obtained. These peptides were all fully characterized by a combination of MS, 1H-NMR and amino acid analysis. In contrast to the Ser analog, which is an excellent substrate for both hPC1 and hfurin, these analogs displayed moderate to strong inhibition of both hPC1 and hfurin activity in a reversible competitive manner. They all exhibited higher potency for hfurin than for hPC1, with an inhibition constant (Ki) ranging from 0.8 to 10 microM and from 1.0 to 170 microM, respectively. Incorporation of L-Tic yielded an analog with a two to four-fold increased inhibition of either enzymes when compared to its D-Tic counterpart, the effect being more pronounced for hPC1 than for hfurin. Comparison of these data with those for the corresponding N-terminal Fmoc protected peptides revealed that the highly hydrophobic N-terminal Fmoc function occupying the P8 position can contribute positively or negatively towards proteinase inhibition depending on the nature of the unnatural amino acid at P'1 and the enzyme used. Finally, none of the analogs was significantly cleaved by either enzyme. FTIR data on these analogs revealed some important structural differences between the substrate and inhibitor analogs, as there appears to be a conformational shift from a more beta-sheet-like structure for the substrates to a more alpha-helical-like structure for the inhibitors.

Fluorescent peptidyl substrates as an aid in studying the substrate specificity of human prohormone convertase PC1 and human furin and designing a potent irreversible inhibitor

The substrate specificities of two human prohormone convertases, furin and PC1, were examined with a series of 7-amino-4-methylcoumarinamide (MCA) containing peptidyl substrates. Using acetyl-Arg-Ser-Lys-Arg-MCA as model, P4 Arg substitution by Lys or Orn resulted for furin in a 538- and a 280-fold lower kcat/Km value, but only in a 14- and 18-fold decrease for PC1. Substitution of P3 Ser by either Pro, Glu, or Lys does not modify significantly the kcat/Km value for PC1, whereas furin activity is seriously impaired by the Glu substitution. Elongating the peptidyl sequence up to the P8 position decreases the kcat/Km value for furin but not for PC1. In both the P3 or P5 Glu substitution, the decrease of kcat/Km was due primarily to lower kcat rather than higher Km, possibly because of the presence of a negatively charged side chain. Finally, an octapeptidyl chloromethane derivative proved to be a potent irreversible inhibitor of either PC1 and ruin. The 811-fold difference in the apparent Kapp/[I] (1.63 x 10(6) s-1 m-1), and kcat/Km determined with the corresponding peptidyl MCA substrate (2.01 x 10(3) s-1 m-1), supports the proposal that cleavage of the acylenzyme represents the rate-limiting step for PC1 and furin.

Structural investigation and kinetic characterization of potential cleavage sites of HIV GP160 by human furin and PC1

A key event in the biosynthesis of the human immunodeficiency virus is the maturation of the gp160 precursor generating gp120 and gp41, two proteins that are fundamental for the infective process. In vivo, gp160 is specifically cleaved at the 515-519 site (REKR decreases A), in spite of the presence in its sequence of another consensus sequence KAKR decreases R (residues 507-511). Comparative kinetic studies on synthetic peptides reproducing different sequences of gp160 by the enzymes PC1 and furin are reported in this paper. The data demonstrate the higher efficiency of furin in the cleavage of peptidic substrates with respect to PC1 and its preference for REKR decreases A vs. KAKR decreases R. Furthermore, furin and PC1 are unable to process peptides patterned on the sequence 307-330 of specific viral strains of the gp120 V3 loop.

Expression of candidate pro-GnRH processing enzymes in rat hypothalamus and an immortalized hypothalamic neuronal cell line

Since gonadotropin-releasing hormone (GnRH, also referred to as LHRH) is a major hormone regulating mammalian reproduction, identification of the processing steps involved in the conversion of the pro-LHRH to LHRH is fundamental to our understanding of its physiology. Extracts from immortalized LHRH neurons (GT1) were used to isolate the pro-LHRH intermediate products and to identify the enzymes which may participate in these conversions. The GT1 cells contain and secrete a pro-LHRH species that elutes at approximately 10,000-12,000 molecular weight. The pro-LHRH is metabolized to various N- and C-terminally modified LHRH products and to gonadotropin-releasing hormone-associated peptide (GAP). Analyses of these intermediates suggests that, at least, four different enzymatic steps are involved in pro-LHRH processing. Northern blot analyses reveal that prohormone convertase 2 (PC2), carboxypeptidase E, glutaminyl cyclase, and peptidyl-glycine alpha-amidating monooxygenase are expressed in the GT1 cells and rat hypothalamus. PC2 immunoreactivity is localized to the perikarya and beaded axon-like processes of these cells. SDS-PAGE analyses indicate that PC2 is biosynthesized, processed and secreted by the immortalized LHRH neurons. Our results indicate that the GT1 cell line may serve as a useful model to study the regulation of pro-LHRH processing and that it may also represent an important tool for dissecting the molecular and cellular basis of mammalian reproduction.

Proteolytic processing of the alpha-subunit of rat endopeptidase-24.18 by furin

Endopeptidase-24.18 (EC 3.4.24.18; meprin) is a multisubunit metallopeptidase of the astacin family. It is found in brush-border membranes of rodent kidney and human intestine. The membrane-bound enzyme is composed of alpha/beta dimers. Molecular cloning has shown that both subunits have a similar structural domain organization. Soluble alpha 2 dimers have also been observed in vivo and in transfected cells. The structures of all known alpha-subunits contain, upstream from the transmembrane domain, the sequence RXKR, which corresponds to the RXK/RR consensus sequence for specific cleavage by furin. In order to investigate the involvement of this putative cleavage site in the secretion process of endopeptidase-24,.18 alpha-subunit, we expressed in COS-1 cells rat alpha-subunits in which residues R655 or S656 (within the sequence R652PKRS656) were mutated to valine or leucine respectively. In contrast to the wild-type protein, the alpha R655V and alphaS656L mutants were not secreted in the culture medium. Moreover, when cells expressing the alpha-subunit were infected with a furin-encoding vaccinia virus, immunoblotting showed a shift of the major cell-associated form of endopeptidase-24.18 alpha-subunit from 98 kDa to 85 kDa and an increase in the amounts of secreted alpha-subunit. This shift in molecular mass was not observed with the mutant alpha-subunits. As observed for the 98 kDa species, the 85 kDa cell-associated protein was sensitive to endoglycosidase H treatment, suggesting that the proteolytic cleavage occurred in the endoplasmic reticulum or in an early Golgi compartment. Similar experiments using PACE4 and PC5 instead of furin showed that these enzymes were not able to generate the 85 kDa species. We conclude that furin is most probably the cellular enzyme involved in the proteolysis resulting in secretion of rat endopeptidase-24.18 alpha-subunit.

Direct role of furin in mammalian prosomatostatin processing

We have previously reported that rat prosomatostatin (rPSS) undergoes conversion at Arg decreases and Lys decreases monobasic sites to SS-28 and PSS-(1-10) respectively in COS-7 cells, and have proposed furin or a related enzyme of the constitutive secretory pathway as the endoproteinase responsible. Here we have tested directly the ability of furin to cleave rPSS at the two monobasic sites as well as at the RXRK dibasic site of SS-14 conversion (a furin motif, except for Lys substituting for Arg at P1). Recombinant vaccinia virus (VV) vectors were used to co-express rPSS with graded doses of furin in COS-7 cells and LoVo colon carcinoma cells deficient in furin. PSS and cleavage products in cell extracts and media were characterized by HPLC analysis and C-terminal [SS-14-like immunoreactivity (SS-14 LI)] and N-terminal [PSS-(1-10) LI] directed radioimmunoassays. There was a dose-dependent increase in SS-28 production from rPSS by furin in COS-7 cells from 29% (control) to 58% (high-dose furin) associated with a progressive decrease in unprocessed PSS from > 60% to approximately 20% of total SS-14 LI. Significant SS-14 production occurred only at high levels of furin infection. Control LoVo cells infected with VV:rPSS exhibited production of approximately 21% SS-28, approximately 15% PSS-(1-10) and 3.5% SS-14. Infection of LoVo cells with VV:hfurin (hfurin = human furin) enhanced SS-28 production to 30-34%. SS-14 synthesis also increased to 25-40%, probably by conversion from SS-28. Overexpression of furin in COS-7 or LoVo cells failed to increase PSS-(1-10) production. These results show that furin is a candidate SS-28 convertase. Arginine is the preferred residue at the P1 site of furin cleavage. Furin does not process rPSS to PSS-(1-10), suggesting the existence of another monobasic convertase with a preference for Lys rather than Arg at P1. Such an enzyme could also explain the presence of endogenous SS-28-, PSS-(1-10)- and SS-14-producing activities in LoVo cells.

Age-related alterations in the expression of prohormone convertase messenger ribonucleic acid (mRNA) levels in hypothalamic proopiomelanocortin mRNA neurons in the female C57BL/6J mouse

POMC processing is mediated by the prohormone convertases (PC1 and PC2). The cleavage of beta-endorphin-(1-31) is mediated by PC2. PC2 can also further cleave beta-endorphin-(1-31) to beta-endorphin-(1-27). We previously reported a significant increase in the proportion of beta-endorphin-(1-27) and -(1-27) forms in the arcuate nucleus (ARC) of the hypothalamus in middle-aged females with irregular estrous cycles (5-7 days) compared to young female C57BL/6J mice with regular cycles (4-5 days). Changes in processing enzymes may be a mechanism underlying this change. We compared ARC messenger RNA (mRNA) levels of PC1, PC2, and furin by Northern blot and in situ hybridization analyses in young, middle-aged, and old mice. Antisense complementary RNA probes to mouse PC1, PC2, and furin were radiolabeled and used in single label studies, alone or in combination with a mouse POMC digoxigenin-labeled complementary RNA probe for double label studies. For Northern blot analysis, young (4- to 5-month-old) normally cycling (4-5 days) mice at diestrus were compared to middle-aged (12- to 13-month-old) irregularly cycling (5-7 days) mice at diestrus. By Northern blot analysis, a significant increase (P < 0.05) in ARC PC2 mRNA levels was detected in middle-aged compared to young mice, but ARC PC1 and furin mRNA levels were unaltered. Single label in situ hybridization analysis confirmed these findings in the general neuron population. We also observed a significant reduction in ARC furin mRNA levels in old mice compared to either young or middle-aged mice. Double labeling in situ hybridization histochemistry demonstrated that PC2 mRNA levels were significantly increased (at least 2-fold) in POMC mRNA-containing neurons of middle-aged compared to young mice. Selective changes in PC2 mRNA levels in ARC POMC neurons are correlated with changes in beta-endorphin-(1-31) processing to beta-endorphin-(1-27)/(1-26) in middle-aged animals. Our data suggest that the natural age-related shift in beta-endorphin peptide processing is mediated by PC2.

An internally quenched fluorogenic substrate of prohormone convertase 1 and furin leads to a potent prohormone convertase inhibitor

Based upon the observed cleavage of various peptidyl substrates by the recombinant prohormone convertases PC1 and furin, an intramolecularly quenched fluorogenic peptidyl substrate, (o-aminobenzoyl)-Lys-Glu-Arg-Ser-Lys-Arg-Ser-Ala-Leu-Arg-Asp-(3-nitro)Ty r-Ala, was synthesized. In spite of the distance (approx. 33 A) separating the fluorescent donor/acceptor pair, the highly fluorescent o-aminobenzoyl group is efficiently quenched by long-range resonance energy transfer to the (3-nitro)Tyr moiety. Both recombinant human PC1 and human furin recognize and cleave specifically this substrate at the expected Arg-Ser site in a sensitive manner. The Km values for human PC1 and human furin were 17 microM and 30 microM respectively, with Vmax. values of 6.4 microM/h and 18 microM/h. These values differ significantly from those obtained when using a 7-amino-4-methylcoumarin-containing pentapeptidyl substrate where, for similar Km values, the Vmax. values were much lower. The peptide sequence was used to synthesize another peptide incorporating a ketomethylene arginyl pseudopeptide bond. This compound proved to be a potent competitive inhibitor of both human PC1 and human furin, displaying Ki values of 7.2 microM and 2.4 microM respectively.

7B2 is a specific intracellular binding protein of the prohormone convertase PC2

Biosynthetic pulse-chase analyses have previously demonstrated that the prohormone convertase PC2 is first synthesized as a precursor pro-PC2 and that zymogen activation to PC2 occurs following the slow exit of pro-PC2 from the endoplasmic reticulum (ER) and its concentration within the trans-Golgi network (TGN). The endocrine and neural protein 7B2 is first synthesized as a nonglycosylated precursor (pro-7B2), which is cleaved within the TGN by a furin-like ubiquitous convertase at the RRKRR155S site to generate 7B2. In this report, we demonstrate that within the ER, pro-7B2 binds pro-PC2 but not any of the other convertases furin, PC1, PACE4, or PC5. This specific binding is Ca2+ dependent and does not require an N-glycosylated pro-PC2. Mutagenesis of the RRKRRS sequence demonstrated that the intact hexapeptide is critical for this binding, because the latter was abolished by mutations of the RR152 and greatly diminished by mutations of either the R151 or S156 residues of pro-7B2. Once the complex is formed in the ER, it is then transported to the TGN where furin or a furin-like convertase cleaves both precursors, even when present as a complex. We also provide evidence that following zymogen cleavage, 7B2 remains bound to PC2, suggesting the presence of at least one other Ca(2+)-dependent binding site within the 7B2 sequence. Coexpression of 7B2 and PC2, although resulting in an elevation of the level of pro-PC2, did not eliminate the processing of pro-PC2 to PC2.(ABSTRACT TRUNCATED AT 250 WORDS)

Proparathyroid hormone is preferentially cleaved to parathyroid hormone by the prohormone convertase furin. A mass spectrometric study

Parathyroid hormone (PTH), an 84-amino acid peptide, is the major regulator of blood calcium homeostasis. Its mRNA, in addition to encoding the mature peptide, also encodes a "pre" sequence of 25 amino acids and a basic "pro" hexapeptide. To assess which of the subtilisin-like prohormone convertases can process proPTH to PTH we coinfected cells with a vaccinia virus construct expressing human preproPTH and vaccinia virus constructs expressing furin, PC1 or PC2. BSC-40 cells, having a constitutive secretory pathway, and GH4C1 cells, having a regulated secretory pathway, were used. PTH biosynthetic products in cell extracts and media were purified by high performance liquid chromatography, identified by radioimmunoassay, and unambiguously defined as either proPTH or PTH by ion-spray mass spectrometry. In both cell types, furin was the most effective in processing proPTH to PTH. In all cases only PTH was released into the medium. In addition, partially purified furin and PC1 were tested for their ability to appropriately cleave a tridecapeptide spanning the prohormone cleavage site found in proPTH. Here too furin was much more effective at cleaving at the correct site. Northern blot analysis and in situ hybridization showed that furin and preproPTH mRNA are co-expressed in the parathyroid, whereas PC1, PC2, and PC5 are not and PACE4 is expressed only at very low levels. Taken together these studies strongly suggest that furin is the enzyme responsible for the physiological processing of proPTH to PTH.

Structure-function studies on the biosynthesis and bioactivity of the precursor convertase PC2 and the formation of the PC2/7B2 complex

Site directed mutagenesis of the prohormone convertase PC2 was used to define the effect of certain residues on the zymogen activation of proPC2 and on its binding to the neuroendocrine protein 7B2. These included the oxyanion hole Asp309 (D309N), the N-terminal Glu25 (E25Q and E25K) of proPC2 and the Asp519 (D519E) of the RGD motif within the P-domain of PC2. Heterologous vaccinia virus expression of the wild type and mutant PC2's in endocrine pituitary cells such as AtT20 and GH3 cells demonstrated that the most dramatic effect was observed with the D309N mutant which no longer bound pro7B2 and which exhibited a significant reduction in its capacity to produce beta-endorphin from pro-opiomelanocortin (POMC).

Comparative proteolytic processing of rat prosomatostatin by the convertases PC1, PC2, furin, PACE4 and PC5 in constitutive and regulated secretory pathways

Recombinant vaccinia virus vectors were used to coexpress each of the candidate prohormone convertases PC1, PC2, furin, PACE4 and PC5 with rat prosomatostatin (rProSOM) in the constitutive secreting cell line LoVo and in the endocrine corticotroph cell line AtT-20, which exhibits regulated secretion. Mammalian ProSOM is cleaved at a dibasic Arg-Lys decreases site to produce somatostatin-14 (S-14) and at a monobasic Gln-Arg decreases site to yield somatostatin-28 (S-28). The analysis of processed products by gel-permeation high performance liquid chromatography shows that in LoVo cells PC1, furin and PACE4 generate S-14, S-28 and a mixture of S-14 and S-28, respectively, while PC2 is unable to process ProSOM in these constitutive cells. In contrast, PC2 can generate S-14 in AtT-20 cells. The convertase PC5 is unable to process ProSOM in either cell line. These data suggest that PC2, PC1 and PACE4 are candidate S-14 convertases, while PACE4 and furin are candidate S-28 convertases.

Processing of secretogranin II by prohormone convertases: importance of PC1 in generation of secretoneurin

Secretoneurin is a recently characterized neuropeptide present in the primary amino acid sequence of secretogranin II. We investigated the proteolytic processing of secretogranin II by prohormone convertases in vivo in a cellular system using the vaccinia virus system. Both PC1 and PC2 can cleave the secretogranin II precursor at sites of pairs of basic amino acids to yield intermediate-sized fragments. Other convertases like PACE4, PC5 and furin were not active. For the formation of the free neuropeptide secretoneurin a different pattern was found. Only PC1 but none of the other convertases tested including PC2 were capable of generating secretoneurin. Our results demonstrate that the prohormone convertases PC1 and PC2 are involved in proteolytic processing of secretogranin II. The neuropeptide secretoneurin can only be generated by PC1 suggesting tissue-specific processing of secretogranin II in neurons expressing different subsets of the prohormone convertases.

Distinct mRNA expression of the highly homologous convertases PC5 and PACE4 in the rat brain and pituitary

Posttranslational endoproteolysis is essential for the production of biologically active peptides from inactive precursors. Six kexin/substilisin-like endoproteases have been characterized in mammalian species. To understand the complex physiological functions of each convertase within a cellular context it is necessary to comprehensively define its tissue distribution and cohabitation with other members of the family. Previous studies demonstrated the distinct distribution of PC1, PC2, and furin mRNAs in the pituitary and brain, suggesting a unique function for each enzyme. In the present study, the mRNA tissue distributions of the two most recent and homologous members, PC5 and PACE4, were analyzed in rat pituitary and brain using in situ hybridization histochemistry. In the pituitary, the anterior lobe exhibited moderate levels of PC5 and high levels of PACE4 mRNAs. The intermediate lobe showed low levels of PC5 expression, while PACE4 mRNA levels were undetectable. PACE4 transcripts were detected throughout cells of the neural lobe suggesting expression in pituicytes. In the brain, PC5 expression was more restricted than PACE4. PC5 mRNA was detected only in neuronal cells, whereas PACE4 mRNA was expressed in both neuronal and glial cells. In areas that are rich in neuropeptides such as cortex, hippocampus, and hypothalamus, mRNA levels of PC5 were high but PACE4 were low or undetectable. In regions, such as the amygdaloid body and thalamus, distinct but complementary distributions of PC5 and PACE4 mRNAs were observed. The medial habenular and cerebellar Purkinje cells expressed very high levels of PACE4 mRNA. The present data strongly suggest unique tissue-specific functions of PC5 and PACE4.