Identification of a cDNA encoding a second putative prohormone convertase related to PC2 in AtT20 cells and islets of Langerhans

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.

Differences in pH optima and calcium requirements for maturation of the prohormone convertases PC2 and PC3 indicates different intracellular locations for these events

PC2 and PC3, which is also known as PC1, are subtilisin-like proteases that are involved in the intracellular processing of prohormones and proneuropeptides. Both enzymes are synthesized as propolypeptides that undergo proteolytic maturation within the secretory pathway. An in vitro translation/translocation system from Xenopus egg extracts was used to investigate mechanisms in the maturation of pro-PC3 and pro-PC2. Pro-PC3 underwent rapid (t1/2 < 10 min) processing of the 88-kDa propolypeptide at the sequence RSKR83 to generate the 80-kDa active form of the enzyme. This processing was blocked when the active site aspartate was changed to asparagine, suggesting that an autocatalytic mechanism was involved. In this system, processing of pro-PC3 was optimal between pH 7.0 and 8.0 and was not dependent on additional calcium. These results are consistent with pro-PC3 maturation occurring at an early stage in the secretory pathway, possibly within the endoplasmic reticulum, where the pH would be close to neutral and the calcium concentration less than that observed in later compartments. Processing of pro-PC2 in the Xenopus egg extract was much slower than that of pro-PC3 (t1/2 = 8 h). It exhibited a pH optimum of 5.5-6.0 and was dependent on calcium (K0.5 = 2-4 mM). The enzymatic properties of pro-PC2 processing were similar to that of the mature enzyme. Further studies using mutant pro-PC2 constructs suggested that cleavage of pro-PC2 was catalyzed by the mature 68-kDa PC2 molecule. The results were consistent with pro-PC2 maturation occurring within a late compartment of the secretory pathway that contains a high calcium concentration and low pH.

Nucleotide sequence and analysis of the mouse SPC3 promoter region

Insulin is converted from the higher molecular weight proprotein, proinsulin by highly specific proteolytic cleavage at two dibasic amino acid sites. SPC3 and SPC2, two recently identified prohormone convertase that are specifically expressed in beta cells and other neuroendocrine cells, appear to be responsible for those cleavages. We have sequenced the 5'-upstream region of the SPC3 gene and examined its promotor/enhancer activity and most of several deletion mutants in several cell lines. This region contains no CAAT box but has several non-functional TATA-like sequences and several putative transcriptional regulatory elements, including AP-1, Sp1 and cAMP response elements. These features are not unlike those of the human SPC2 upstream region. In beta TC3 insulinoma cells, the sequence between the EcoRI (620 bp) and NsiI (702 bp) sites seems to be important for gene expression, while the sequence between the NsiI and DraI (775 bp) sites may contain strong enhancer element(s).

Maturation of the trans-Golgi network protease furin: compartmentalization of propeptide removal, substrate cleavage, and COOH-terminal truncation

We have cloned a bovine cDNA encoding the trans-Golgi network (TGN) protease furin and expressed it via recombinant vaccinia viruses to investigate intracellular maturation. Pulse-chase labeling reveals that the 104-kD pro-furin bearing high mannose N-glycans is rapidly processed into the 98-kD protease whose N-glycans remain sensitive to endoglycosidase H for a certain period of time. Furthermore, in the presence of brefeldin A, pro-furin cleavage occurs. From these data we conclude that the ER is the compartment of propeptide removal. Studies employing the ionophore A23187 and DTT show that autocatalysis is Ca2+ dependent and that it does not occur under reducing conditions. Pro-furin produced under these conditions never gains endo H resistance indicating that it is retained in the ER. Coexpression of furin with the fowl plague virus hemagglutinin in the presence of brefeldin A and monensin reveals that furin has to enter the Golgi region to gain substrate cleaving activity. N-glycans of furin are sialylated proving its transit through the trans-Golgi network. A truncated form of furin is found in supernatants of cells. Truncation is inhibited in the absence of Ca2+ ions and in the presence of acidotropic agents indicating that it takes place in an acidic compartment of cells. Comparative analysis with furin expressed from cDNA reveals that the truncated form prevails in preparations of biologically active, endogenous furin obtained from MDBK cells. This observation supports the concept that secretion of truncated furin is a physiological event that may have important implications for the processing of extracellular substrates.

Kex2p: a model for cellular endoprotease processing human immunodeficiency virus type 1 envelope glycoprotein precursor

The endoproteolytic cleavage of the envelope glycoprotein precursor (gp160) of the human immunodeficiency virus type 1 (HIV-1) by a cellular protease is required for full activation of the virus. In this study, processing of gp160 was analyzed in vitro using the Kex2p endoprotease from the yeast Saccharomyces cerevisiae as a processing enzyme model. Endoproteolytic processing was examined using a synthetic peptide that mimics the cleavage site of HIV-1 glycoprotein, and a recombinant gp160 bearing the entire sequence of the env gene product, including the conserved cleavage site Arg508-Glu-Lys-Arg511. Coexpression in BHK-21 of Kex2p and gp160 by recombinant vaccinia viruses demonstrates that Kex2p can correctly process the HIV-1 glycoprotein to gp120 and gp41. Furthermore, recombinant gp160 and peptide were used as substrates and subjected to proteolysis with purified membranes from an S. cerevisiae strain overproducing the Kex2p endoprotease. Treatment of recombinant gp160, which has an apparent molecular mass of 127 kDa, with Kex2p and Western blot analysis showed that the precursor was cleaved into two products of about 101 and 34 kDa apparent molecular mass. Amino acid sequencing of the NH2-terminus of the 34-kDa product showed that the cleavage site of recombinant gp160 was between Arg511 and Ala512. Recombinant gp160 mutated at the sequence coding for the potential cleavage site, and mature recombinant gp120, however, were not cleaved when treated with Kex2p. In summary, our results show that Kex2p cleaves both the HIV-1 envelope glycoprotein precursor and a synthetic peptide mimicking the cleavage site of HIV-1 gp160 at the dibasic site, suggesting functional analogy between yeast Kex2p and the cellular protease responsible for the maturation of HIV-1 envelope glycoproteins in infected human cells.

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.

Proinsulin processing in the regulated and the constitutive secretory pathway

Proinsulin is converted to insulin in beta-cell granules. Conversion involves endoproteolytic cleavage at the two pairs of basic residues linking the insulin A- and B-chains to C-peptide. The sequence of events leading to complete conversion differs from one proinsulin species to the next. In man, the structure of the proinsulin molecule is such as to favour cleavage at the B-chain/C-peptide junction leading to the generation of des-31,32 split proinsulin as the predominant, naturally occurring conversion intermediate. Under normal circumstances, proinsulin conversion is largely completed before secretion, and neither the intact prohormone nor conversion intermediates are thus encountered in large quantities in the circulation. In some pathological situations, including non-insulin-dependent diabetes, insulinoma and familial hyperproinsulinaemia, unusually high ratios of des-31,32 split proinsulin and/or proinsulin to insulin have been reported. As we understand the biochemistry of proinsulin conversion in increasingly fine molecular detail, it should become possible to make use of such unusual ratios to provide insight into lesions underlying altered beta-cell function in disease states.

Proprotein-processing endoproteases PC6 and furin both activate hemagglutinin of virulent avian influenza viruses

Among the proprotein-processing subtilisin-related endoproteases, furin has been a leading candidate for the enzyme that activates the hemagglutinin (HA) of virulent avian influenza viruses. In the present study, we examined the cleavage activity of two other recently isolated ubiquitous subtilisin-related proteases, PACE4 and PC6, using wild-type HA of A/turkey/Ireland/1378/83 (H5N8) and a series of its mutant HAs. Vaccinia virus-expressed wild-type HA was not cleaved in human colon adenocarcinoma LoVo cells, which lack active furin. This processing defect was corrected by the expression of furin and PC6 but not of PACE4 and a control wild-type vaccinia virus. PC6 showed a sequence specificity similar to that with the endogenous proteases in cultured cells. When LoVo cells were infected with a virulent avian virus, A/turkey/Ontario/7732/66 (H5N9), only noninfectious virions were produced because of the lack of HA cleavage. However, when the cells were coinfected with vaccinia virus that expressed either furin or PC6, the avian virus underwent multiple cycles of replication, indicating that both furin and PC6 specifically cleave the virulent virus HA at the authentic site. These data suggest that PC6, as well as furin, can activate virulent avian influenza viruses in vivo, implying the presence of multiple HA cleavage enzymes in animals.

Action of neurohypophysial granule Lys-Arg endopeptidase on synthetic polypeptides comprising the processing sequence of provasopressin-neurophysin

Neurohypophysial granule Ca(2+)-dependent endopeptidases have been allowed to act on synthetic polypeptides derived from the N-terminal sequence of bovine provasopressin-neurophysin, namely vasopressinyl-glycyl-lysyl-arginyl-alanylamide and vasopressinyl-glycyl-lysyl-arginyl-alanyl-methionyl-serinamide+ ++. Membrane-bound enzymes have been used at pH 5.5 for 16 hr at 37 degrees C. Products have been identified by high-pressure liquid chromatography (HPLC) and by mass spectrometry performed on substances isolated by HPLC. With both substrates, vasopressinyl-Gly-Lys-Arg(OH) has been identified as a product confirming the Lys-Arg specificity previously observed on small peptide fluorogenic substrates. Cleavage yields, however, appear low suggesting that some factors are missing, for example a targeting action of the precursor neurophysin domain to the granule membrane.

Characterization of a metalloprotease from ovine chromaffin granules which cleaves a proenkephalin fragment (BAM12P) at a single arginine residue

A metalloprotease has been identified in ovine chromaffin granules which cleaves the proenkephalin fragment BAM12P to produce adrenorphin-Gly. This cleavage occurs at a single arginine residue and is an intermediate step in the production of the opiate adrenorphin in vivo. The identity of the product was confirmed by reverse-phase and ion-exchange chromatography. The adrenorphin-Gly-generating enzyme (AGE) was determined by chromatofocusing to have a pI value of 5.2 and bound strongly to a metal-chelate affinity column. After purification by gel-filtration and ion-exchange chromatography AGE was free of contaminating activities, as cleavage of radiolabelled BAM12P generated a single product as judged by reverse-phase and ion-exchange chromatography. The enzyme has a molecular mass of approx. 45 kDa and a pH optimum of 8.6 in Mops, Taps and Hepes buffers, but was inhibited by phosphate buffers. It was inhibited by micromolar concentrations of copper and zinc ions, but not by millimolar concentrations of calcium or manganese ions. The addition of BAM22P, dynorphin 1-13 or dynorphin 1-8 to the incubation mixture inhibited the cleavage of radiolabelled BAM12P. The cleavage was also inhibited by the presence of catecholamines at concentrations similar to those found within the chromaffin granule. This may explain the known effect of reserpine on chromaffin cells of reducing catecholamine levels and simultaneously increasing adrenorphin levels. It may also indicate a function for AGE and adrenorphin as reporters of intragranular conditions.

A Kex2-related endopeptidase activity present in rat liver specifically processes the insulin proreceptor

The insulin proreceptor is cleaved by limited proteolysis post-translationally at an Arg-Lys-Arg-Arg site to generate its mature alpha- and beta-subunit form. An 35S-labelled insulin proreceptor substrate preparation and a 15-mer peptide substrate that mimics the amino acid sequence around and including the insulin proreceptor processing site (IRP-peptide) has revealed an endopeptidase activity that catalyses insulin proreceptor cleavage in a rat liver subcellular fraction. Under optimal conditions, normal 35S-labelled insulin proreceptor substrate processing by this fraction was quantitative. This fraction was not able to process an 35S-labelled insulin proreceptor variant substrate (where the Arg-1 of the tetrabasic cleavage site had been replaced by Ala-1), similarly to previous in vivo observations, suggesting that this endopeptidase activity has physiological relevance. Biochemical characterization of the insulin proreceptor/IRP-peptide processing revealed this rat liver endopeptidase activity to have a broad pH range (> 70% maximal activity between pH 5.5 and 10.0) and a pH optimum of pH 8-10. It was Ca(2+)-dependent activity, maximally active between 0.5 and 5 mM Ca2+ and half-maximally activated between 50 and 90 microM Ca2+. Endoproteolytic activity was not inhibited by group-specific inhibitors of serine-, cysteinyl or aspartyl proteinases or by 1,10-phenanthroline; however, EDTA and 1,2-cyclohexanediaminetetraacetic acid did inhibit the activity, but this was accounted for by Ca2+ chelation. The IRP-peptide substrate assay enabled measurement of an apparent Km of 22 microM and a Vmax of 18.6 pmol/min for this endopeptidase activity. These biochemical characteristics suggest that insulin proreceptor processing endopeptidase activity to be a legitimate member of the Kex2-related proprotein convertase family. Immunoblotting detected furin and PACE4 proteins (both members of this family) to be present in the rat liver subcellular fraction containing insulin proreceptor processing activity. Since the biochemical characteristics of the insulin proreceptor processing endopeptidase activity mostly resembled those of furin activity, it is likely that insulin proreceptor proteolytic maturation can be catalysed by furin in the liver.

Cleavage of proalbumin peptides by furin reveals unexpected restrictions at the P2 and P'1 sites

Proalbumin is the principal substrate of the in situ hepatic convertase. Here we investigated the specificity of furin using synthetic peptides based on the N-terminal sequence of human proalbumin. The propeptide was rapidly cleaved from the normal ((-6)RGVFRR(-1)DAHKSEAVW(+9)) peptide but as expected, there was no cleavage of the proalbumin Lille analogue with a -2 His (-2H). Surprisingly, the effect of this substitution could not be corrected by introducing a -4 Arg (-4R-2H). In contrast, the peptide -4R-2A was an excellent substrate being cleaved five times faster than normal, indicaabting that His is not allowed as an P2 residue. Replacement of the -4 Val by Glu supported the expected importance of a positive charge at P4 as the cleavage rate dropped to 10% of normal after this substitution. The -6 Arg makes a small contribution to cleavage, its replacement by Ala decreased the cleavage rate to 60% of normal. The Lys-Arg propeptide was almost as good a substrate as the normal Arg-Arg peptide, but the introduction of a Lys at P1 totally abolished processing. The exclusion of P'1 positive charges would be an important requirement for preventing aberrant cleavage in the middle of tetrabasic sequences.

Levels of the conversion endoproteases PC1 (PC3) and PC2 distinguish between insulin-producing pancreatic islet beta cells and non-beta cells

PC1 (PC3) and PC2, members of the mammalian family of proprotein convertases homologous to the yeast Kex2 gene product, are both expressed in pancreatic islets of Langerhans. Recent studies have suggested that PC1 and PC2 are responsible for the conversion of proinsulin to insulin and connecting peptide (C-peptide) in the islet beta cells. However, the insulin-secreting beta cells are not the only cells present in these complex micro-organs, prompting us to evaluate the expression of PC1 and PC2 in islet beta and non-beta cells. Rat islet cells were sorted by autofluorescence-activated flow cytometry to separate beta cells from non-beta cells, and conversion endoprotease levels were analysed by Western blotting. The immunolabel ratio of PC1/PC2 in beta cells was 2.6. Non-beta cells displayed much lower levels of PC1 than beta cells, but twice as much PC2 (PC1/PC2 = 0.05). Post-translational modification of the convertases themselves was found to differ between the cell types. In particular, a 75 kDa precursor form of PC2 (pro-PC2) was found to accumulate in beta cells, whereas only the fully processed 67 kDa form was detected in the non-beta cells. Finally, the quantification of PC1 and PC2 and their precursor forms in transformed cells (insulin-producing beta-TC and glucagon-producing alpha-TC) showed that transformation appeared to be accompanied by unusually high levels of the precursors.

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.

The primary structure of the Pol-RFamide neuropeptide precursor protein from the hydromedusa Polyorchis penicillatus indicates a novel processing proteinase activity

Neuropeptides containing the C-terminal sequence Arg-Phe-NH2 (RFamide) occur throughout the Animal Kingdom and are abundant in evolutionarily 'old' nervous systems such as those of cnidarians. From the hydromedusa Polyorchis penicillatus we have previously isolated two neuropeptides, Pol-RFamide I (<Glu-Leu-Leu-Gly-Gly-Arg-Phe-NH2) and Pol-RFamide II (<Glu-Trp-Leu-Lys-Gly-Arg-Phe-NH2). Here we describe the cloning of a common precursor protein for these peptides from P. penicillatus. The precursor protein contains one copy of Pol-RFamide I, 11 copies of Pol-RFamide II and one putative neuropeptide sequence. The Pol-RFamide I sequence is flanked by pairs of basic residues (Arg-Lys). At the C-termini of all Pol-RFamide II sequences, single basic residues (Arg) occur. Paired and single basic residues are established sites for post-translational precursor cleavage. At the N-termini of the Pol-RFamide II sequences, however, basic residues are lacking and, instead, either single Asp (in eight cases) or single Asn residues (in three cases) occur. This means that processing must take place at Asp and/or Asn residues. This is firm evidence for the presence of one or more unconventional processing enzymes. The first type of processing enzyme could be an endoproteinase or aminopeptidase hydrolysing at the C-terminal side of Asp residues. Proteolytic cleavage at acidic amino acid residues has previously been inferred from other cnidarian neuropeptide precursors. The second type of processing enzyme could be an endoproteinase or aminopeptidase hydrolysing at the C-terminal side of Asn residues.

Proglucagon is processed to glucagon by prohormone convertase PC2 in alpha TC1-6 cells

Proglucagon is processed differentially in the pancreatic alpha cells and the intestinal L cells to yield either glucagon or glucagon-like peptide 1, respectively, structurally related hormones with opposing metabolic actions. Here, we have studied the processing of proglucagon in alpha TC1-6 cells, an islet-cell line transformed by simian virus 40 large tumor (T) antigen, a model of the pancreatic alpha cell. We found that these cells process proglucagon at certain dibasic cleavage sites to release glucagon and only small amounts of glucagon-like peptide 1, as demonstrated by both continuous and pulse-chase labeling experiments. Both normal islet alpha cells and alpha TC1-6 cells were shown to express the prohormone convertase PC2 at high levels, but not the related protease PC3. Expression of PC2 antisense RNA in alpha TC1-6 cells inhibited both PC2 production and proglucagon processing concomitantly. We conclude that PC2 is the key endoprotease responsible for proglucagon processing in cells with the alpha-cell phenotype.

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.

Sorting and processing of secretory proteins

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Unique cleavage specificity of 'prohormone thiol protease' related to proenkephalin processing

'Prohormone thiol protease' (PTP) represents the major enkephalin precursor processing activity in chromaffin granules. In this study, cleavage specificity of PTP for paired basic and monobasic residues was examined with a series of model peptide-MCA (-methylcoumarinamide) substrates. Monobasic peptides were cleaved at the COOH- and NH2-terminal sides of the single basic residue. Dibasic peptides, however, were preferentially cleaved at the NH2-terminal side of the pair, or between the two basic residues, with low cleavage at the COOH-terminal side of the pair. Inhibition by the peptide inhibitor (D-Tyr)-Glu-Phe-Lys-Arg-CH2Cl provided further evidence for PTP's specificity for the dibasic Lys-Arg site. Inhibition by Z-Leu-Val-Gly-CHN2 and Z-Arg-Leu-Val-Gly-CHN2 suggests involvement of Val-Gly in substrate binding to PTP; these two cystatin C-related inhibitors also indicate PTP as a cysteine protease. These results demonstrate PTP's unique cleavage specificity that differs from other processing endopeptidases, including the subtilisin-related proprotein convertases, PC1/PC3, and PC2, as well as the pituitary proopiomelanocortin-converting enzyme, PCE. This study provides further evidence for PTP as a novel prohormone processing enzyme that belongs to the class of cysteine proteases.

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.

Furin has the proalbumin substrate specificity and serpin inhibitory properties of an in situ hepatic convertase

Furin, a KEX2 protease homolog with high RNA expression in the liver is an excellent candidate as a hepatic proprotein convertase. Here we show that purified recombinant furin has the same proalbumin specificity and serpin inhibitory properties as the in situ hepatic convertase. There was rapid cleavage at the -RRD- site of normal human proalbumin but there no significant cleavage of natural unprocessed variants with cleavage site sequences of -RRV-, -HRD-, -RQD-, or -CRD-. Cleavage of the latter was not increased by S-aminoethylation. Furin was specifically inhibited by alpha 1-antitrypsin Pittsburgh (358 Met-->Arg), (K1/2 = 3 microM) but not by 50 microM normal antitrypsin M or by antithrombin, however, antithrombin/heparin was a good inhibitor (K1/2 = 9 microM). The pH optimum for proalbumin cleavage was between pH 5.5 and 6.0, indicating that furin is potentially fully active within secretory vesicles, the site of proalbumin cleavage.

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.

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)

Post-translational processing of progastrin: inhibition of cleavage, phosphorylation and sulphation by brefeldin A

The precursor for the acid-stimulating hormone gastrin provides a useful model for studies of post-translational processing because defined sites of cleavage, amidation, sulphation and phosphorylation occur within a dodecapeptide sequence. The factors determining these post-translational processing events are still poorly understood. We have used brefeldin A, which disrupts transport from rough endoplasmic reticulum to the Golgi complex, to examine the mechanisms of cleavage, phosphorylation and sulphation of rat progastrin-derived peptides. Biosynthetic products were detected after immunoprecipitation using antibodies specific for the extreme C-terminus of progastrin, followed by reversed-phase and ion-exchange h.p.l.c. Gastrin cells incorporated [3H]tyrosine, [32P]phosphate and [35S]sulphate into both progastrin and its extreme C-terminal tryptic (nona-) peptide. Ion-exchange chromatography resolved four forms of the C-terminal tryptic fragment of progastrin which differed in whether they were phosphorylated at Ser96, sulphated at Tyr103, both or neither. The specific activity of [3H]tyrosine in the peak that was both phosphorylated and sulphated was higher than in the others. Brefeldin A inhibited the appearance of [3H]tyrosine-labelled C-terminal tryptic fragment but there was an accumulation of labelled progastrin and a peptide corresponding to the C-terminal 46 residues of progastrin. Brefeldin A also inhibited incorporation of 32P and 35S into both progastrin and its C-terminal fragment. Thus phosphorylation of Ser96, sulphation of Tyr103 and cleavage at Arg94-Arg95 depend on passage of newly synthesized progastrin along the secretory pathway; as brefeldin A is thought to act proximal to the trans-Golgi, these processing steps would appear to occur distal to this point. The data also indicate that the stores of unphosphorylated C-terminal tryptic fragment are not available for phosphorylation, implying that this modification occurs proximal to the secretory granule; cleavage is known to occur in the secretory granule which suggests that it occurs after phosphorylation.

Processing of a fusion protein by endoprotease in COS-1 cells for secretion of mature peptide by using a chimeric expression vector

The subtilisin-related proprotein convertase furin is expressed in various mammalian tissues. Expecting that COS-1 cells have a furin-like endoprotease, we constructed a fusion expression vector for production of a recombinant foreign protein having no signal peptide or a protein in truncated form into secreted mature protein. A cDNA fragment encoding N-terminal procalcitonin (pro-CT) of human calcitonin precursor was inserted into the mammalian expression vector pME18S. We used PCR techniques to generate four kinds of cDNAs encoding the C terminus of the pro-CT with Arg residues at P4 (Arg-Xaa-Lys-Arg), P6 (Arg-Xaa-Xaa-Xaa-Lys-Arg), or both (Arg-Xaa-Arg-Xaa-Lys-Arg), in addition to the Lys-Arg motif at the cleavage site, in order to determine the conditions for efficient processing in nonendocrine cells, such as COS-1 cells. The cDNA coding for the Fc fragment of human immunoglobulin G1 was fused in-frame to the cDNA encoding pro-CT at its C terminus. Upon transfection of the chimeric plasmids into COS-1 cells, almost all of the fusion protein with the Arg residues at both P4 and P6 were processed into secreted Fc product, even without cotransfection of furin. These results indicate that COS-1 cells have a furin-like endoprotease and suggest that pro-CT, with the Arg residues at both P4 and P6, can be used as a carrier peptide for expression of a foreign protein having no signal peptide or a protein in truncated form in COS-1 cells.

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.

Isolated congenital ACTH deficiency: a cleavage enzyme defect?

The pro-opiomelanocortin (POMC) gene encodes adrenocorticotrophin (ACTH) which is derived from precursors by proteolytic cleavage. Congenital, isolated ACTH deficiency is rare but may be familial and fatal. The aetiology is unknown though defects at both hypothalamus and adenohypophysis have been postulated. We have studied a female presenting with hypoglycaemia in the neonatal period. When studied at 6 weeks of age, ACTH was unmeasurable even after injection of corticotrophin releasing hormone (CRH1-41). ACTH precursors, quantitated by two-site immunoradiometric assay, were clearly measurable prior to treatment and were stimulated by CRH1-41 and suppressed by glucocorticoid administration. Concentrations of POMC, N-terminal pro-opiocortin (N-POC) and beta-endorphin (beta-EP) were within the normal adult range during glucocorticoid replacement therapy; ACTH and beta-lipotrophin remained undetectable. The secretion of glucagon, measured by radioimmunoassay, in response to hypoglycaemia was normal. By sequencing polymerase chain reaction products from the patient's genomic DNA, the entire coding region of the POMC gene was established to be normal. The results are compatible with a cleavage enzyme defect.

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.

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.

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.