Altered proglucagon processing in an alpha-cell line derived from prohormone convertase 2 null mouse islets

The endoproteolytic processing of proproteins in the secretory pathway depends on the expression of selected members of a family of subtilisin-like endoproteases known as the prohormone convertases (PCs). The main PC family members expressed in mammalian neuroendocrine cells are PC2 and PC1/3. The differential processing of proglucagon in pancreatic alpha-cells and intestinal L cells leads to production of distinct hormonal products with opposing physiological effects from the same precursor. Here we describe the establishment and characterization of a novel alpha-cell line (alphaTC-DeltaPC2) derived from PC2 homozygous null animals. The alphaTC-DeltaPC2 cells are shown to be similar to the well characterized alphaTC1-6 cell line in both morphology and overall gene expression. However, the absence of PC2 activity in alphaTC-DeltaPC2 leads to a complete block in the production of mature glucagon. Surprisingly, alphaTC-DeltaPC2 cells are able to efficiently cleave the interdomain site in proglucagon (KR 70-71). Further analysis reveals that alphaTC-DeltaPC2 cells, unlike alphaTC1-6 cells, express low levels of PC1/3 that lead to the generation of glicentin as well as low amounts of oxyntomodulin, GLP-1, truncated GLP-1, and N-terminally extended GLP-2. We conclude that alphaTC-DeltaPC2 cells provide additional evidence for PC2 as the major convertase in alpha-cells leading to mature glucagon production and provide a robust model for further analysis of the mechanisms of proprotein processing by the prohormone convertases.     

Production, purification, and characterization of recombinant prohormone convertase 5 from baculovirus-infected insect cells

The discovery of the prohormone convertase (PC) family of enzymes has provided several good candidates (PC1, PC2, and PC5) for the enzymes responsible for the endoproteolytic cleavage of procholecystokinin (pro-CCK). Determination of the role of individual pro-hormone convertases in the processing of pro-CCK is complicated because several of these enzymes are found in endocrine tumor cells expressing CCK mRNA and in identified neurons in the brain. Production of active recombinant PC5 permits the determination of its ability to cleave substrates related to pro-CCK. Active PC5, secreted from baculovirus-infected Sf9 cells, was partially purified by ion-exchange chromatography. Western blot analysis confirmed the presence of the active form of the enzyme in infected cell media and its absence from uninfected cell media. The enzyme is most active at acidic pH 6.5 and is maximally activated by 5 mM calcium. PC5 was able to cleave both monobasic and dibasic substrates without a requirement for a basic residue at P-4 and it displayed a K(m) in the micromolar range. The enzyme was inhibited by EDTA, 1,10-phenanthroline, and p-CMS, as well as by two specific PC inhibitors. This is the first reported preparation of active recombinant PC5. Like the other members of its family, it has the correct catalytic characteristics in vitro to play a role in the processing of neuropeptide precursor proteins into their final bioactive forms.     

大豆11S球蛋白Gy5(A3B4)的基因克隆和序列分析

大豆11Ｓ球蛋白(Ｇｌｙｃｉｎｉｎ)是大豆种子的主要贮藏蛋白,分子量为360ｋＤ,由6对相同的蛋白亚基(每对亚基的分子量约60ｋＤ)构成。每对亚基又是由一个酸性Ａ肽(35～45ｋＤ)和一个碱性Ｂ肽(22ｋＤ)通过二硫键连接而成。Ａ肽和Ｂ肽源自同一个基因,即首先由一个大的ｍＲ?..     

On the processing of proghrelin to ghrelin

The orexigenic hormone ghrelin is a 28-amino-acid peptide derived from a 99-amino-acid precursor and acylated at Ser-3, which was initially isolated from rat stomach. In addition to stimulating appetite and growth, it also plays various important roles in energy homeostasis and in the cardiovascular and immune systems. Although analysis of its physiological effects has yielded many significant results, much less information is available on its biosynthesis and the mechanism of its acylation. In this report, we have studied the endoproteolytic processing of this molecule from its precursor (proghrelin) into mature ghrelin in various prohormone convertase null mouse strains generated in our laboratory and have identified the convertase responsible for this event. Using Western blotting, mass spectrometry, and immunocytochemical methods, we have demonstrated that (a) in mouse stomach, prohormone convertase 1/3 (PC1/3) is the endoprotease responsible for the conversion of proghrelin to ghrelin, (b) the acylation of this peptide is processing-independent, and (c) the expression of proghrelin mRNA is increased in the processing-deficient (PC1/3 null) mouse.     

Identification of a Small Molecule That Selectively Inhibits Mouse PC2 over Mouse PC1/3: A Computational and Experimental Study

The calcium-dependent serine endoproteases prohormone convertase 1/3 (PC1/3) and prohormone convertase 2 (PC2) play important roles in the homeostatic regulation of blood glucose levels, hence implicated in diabetes mellitus. Specifically, the absence of PC2 has been associated with chronic hypoglycemia. Since there is a reasonably good conservation of the catalytic domain between species translation of inhibitory effects is likely. In fact, similar results have been found using both mouse and human recombinant enzymes. Here, we employed computational structure-based approaches to screen 14,400 compounds from the Maybridge small molecule library towards mouse PC2. Our most remarkable finding was the identification of a potent and selective PC2 inhibitor. Kinetic data showed the compound to be an allosteric inhibitor. The compound identified is one of the few reported selective, small-molecule inhibitors of PC2. In addition, this new PC2 inhibitor is structurally different and of smaller size than those reported previously. This is advantageous for future studies where structural analogues can be built upon.     

The C-terminal region of proSAAS is a potent inhibitor of prohormone convertase 1

ProSAAS is a recently discovered 26-kDa neuroendocrine protein that was previously found to inhibit prohormone convertase (PC) 1 and not PC2. In the present study, the specificity of proSAAS toward other members of the prohormone convertase family was determined. Two microm proSAAS selectively inhibits PC1 but not furin, PACE4, PC5A, or PC7. The PC1 inhibitory region of proSAAS was mapped to an 8-12-residue region near the C terminus that includes a critical Lys-Arg sequence. Synthetic peptides corresponding to this region are competitive inhibitors of PC1 with apparent K(i) values of 14-40 nm. The inhibition becomes more effective with incubation time, indicating that the inhibitor is slow binding. A fusion protein containing the inhibitory region of proSAAS linked to the C terminus of glutathione S-transferase binds the 71-kDa form but not the 85-kDa form of PC1. This binding, which occurs at pH 5.5 and not at pH 7.4, is stable to incubation at room temperature for 1 h in the presence or absence of 0.5% Triton X-100 and/or 0.5 m NaCl. The removal of Ca(2+) with chelating agents partially releases the bound PC1. High concentrations of the inhibitory peptide quantitatively release the bound PC1. Taken together, these data support the proposal that proSAAS functions as an endogenous inhibitor of PC1.     

Differential localization of prohormone convertases PC1 and PC2 in two distinct types of secretory granules in rat pituitary gonadotrophs

Prohormone convertases PC1 and PC2 are endoproteases involved in prohormone cleavage at pairs of basic amino acids. There is a report that prohormone convertase exists in the rat anterior pituitary gonadotrophs, where it had previously been considered that proprotein processing does not take place. In addition to luteinizing hormone and follicle-stimulating hormone, rat pituitary gonadotrophs contain chromogranin A (CgA) and secretogranin II (SgII), two members of the family of granin proteins, which have proteolytic sites in their molecules. In the present study we examined whether there is a close correlation between subcellular localization of prohormone convertases and granin proteins. Ultrathin sections of rat anterior pituitary were immunolabeled with anti-PC1 or -PC2 antisera and then stained with immunogold. Immunogold particles for PC1 were exclusively found in large, lucent secretory granules, whereas those for PC2 were seen in both large, lucent and small, dense granules. The double-immunolabeling also demonstrated colocalization of PC2 and SgII in small, dense granules and of PC1, PC2, and CgA in large, lucent granules. These immunocytochemical results suggest that PC2 may be involved in the proteolytic processing of SgII and that both PC1 and PC2 may be necessary to process CgA.     

Altered processing of the neurotensin/neuromedin N precursor in PC2 knock down mice: a biochemical and immunohistochemical study

Neurotensin (NT) and neuromedin N (NN) are generated by endoproteolytic cleavage of a common precursor molecule, pro-NT/NN. To gain insight into the role of prohormone convertases PC1, PC2, and PC7 in this process, we investigated the maturation of pro-NT/NN in the brain of PC7 (PC7-/-), PC2 (PC2-/-), and/or PC1 (PC1+/- and PC2-/-; PC1+/-) knock down mice. Inactivation of the PC7 gene was without effect, suggesting that this convertase is not involved in the processing of pro-NT/NN. By contrast, there was a 15% decrease in NT and a 50% decrease in NN levels, as measured by radioimmunoassay, in whole brain extracts from PC2 null as compared with wild type mice. Using immunohistochemistry, we found that this decrease in pro-NT/NN maturation products was uneven and that it was most pronounced in the medial preoptic area, lateral hypothalamus, and paraventricular hypothalamic nuclei. These results suggest that PC2 plays a critical role in the processing of pro-NT/NN in mouse brain and that its deficiency may be compensated to a regionally variable extent by other convertases. Previous data have suggested that PC1 might be subserving this role. However, there was no change in the maturation of pro-NT/NN in the brain of mice in which the PC1 gene had been partially inactivated, implying that complete PC1 knock down may be required for loss of function.     

Impaired prohormone convertases in Cpe(fat)/Cpe(fat) mice

A spontaneous point mutation in the coding region of the carboxypeptidase E (CPE) gene results in a loss of CPE activity that correlates with the development of late onset obesity (Nagert, J. K., Fricker, L. D., Varlamov, O., Nishina, P. M., Rouille, Y., Steiner, D. F., Carroll, R. J., Paigen, B. J., and Leiter, E. H. (1995) Nat. Genet. 10, 135-142). Examination of the level of neuropeptides in these mice showed a decrease in mature bioactive peptides as a result of a decrease in both carboxypeptidase and prohormone convertase activities. A defect in CPE is not expected to affect endoproteolytic processing. In this report we have addressed the mechanism of this unexpected finding by directly examining the expression of the major precursor processing endoproteases, prohormone convertases PC1 and PC2 in Cpe(fat) mice. We found that the levels of PC1 and PC2 are differentially altered in a number of brain regions and in the pituitary. Since these enzymes have been implicated in the generation of neuroendocrine peptides (dynorphin A-17, beta-endorphin, and alpha- melanocyte-stimulating hormone) involved in the control of feeding behavior and body weight, we compared the levels of these peptides in Cpe(fat) and wild type animals. We found a marked increase in the level of dynorphin A-17, a decrease in the level of alpha-melanocyte-stimulating hormone, and an alteration in the level of C-terminally processed beta-endorphin. These results suggest that the impairment in the level of these and other peptides involved in body weight regulation is mainly due to an alteration in carboxypeptidase and prohormone convertase activities and that this may lead to the development of obesity in these animals.     

Genomic structure of murine mitochondrial DNA polymerase-gamma

We have sequenced a genomic clone of the gene encoding the mouse mitochondrial DNA polymerase. The gene consists of 23 exons, which span approximately 13.2 kb, with exons ranging in size from 53 to 768 bp. All intron-exon boundaries conform to the GT-AG rule. By comparison with the human genomic sequence, we found remarkable conservation of the gene structure; the intron-exon borders are in almost identical locations for the 22 introns. The 5' upstream region contains approximately 300 bp of homology between the mouse and human sequences that presumably contain the promoter element. This region lacks any obvious TATA domain and is relatively GC rich, consistent with the housekeeping function of the mitochondrial DNA polymerase. Finally, within the 5' flanking region, both mouse and human genes have a region of 73 bp with high homology to the tRNA-Arg gene.     

ProSAAS and prohormone convertase 1 are broadly expressed during mouse development

ProSAAS (encoded by mouse gene Pcsk1n) is a recently described neuroendocrine secretory pathway protein that is cleaved into smaller peptides that may function in cell-cell signalling. ProSAAS and its processing intermediates are also potent inhibitors of prohormone convertase 1 (PC1), which is encoded by mouse gene Pcsk1. In order to gain insight into the function of proSAAS, we have examined the distribution of several proSAAS-derived peptides and PC1 by immunohistochemistry throughout mouse development. The distribution patterns of both SAAS and PC1 are broad from E9 to E11, with some enrichment in neural tube-derived tissues. By E15, the expression of SAAS is largely restricted to neuroendocrine tissues known to produce bioactive peptides. In general, the expression pattern of PC1 overlaps with that of SAAS and other proSAAS-derived peptides, consistent with the hypothesis that proSAAS functions as an endogenous PC1 inhibitor.     

Gastrin biosynthesis in canine G cells

Gastrin requires extensive posttranslational processing for full biological activity. It is presumed that progastrin is cleaved at pairs of basic amino acids by a prohormone convertase to form a glycine-extended intermediate (G-Gly) that serves as a substrate for peptidyl-glycine alpha-amidating monooxygenase (PAM), resulting in COOH-terminally amidated gastrin. To confirm the nature of progastrin processing in a primary cell line, we performed [(35)S]methionine-labeled pulse-chase biosynthetic experiments in canine antral G cells. Radiolabeled progastrin reached a peak earlier than observed for G-Gly or amidated gastrin. G-Gly radioactivity accumulated in G cells and preceded the appearance of radioactivity in amidated gastrin. The conversion of G-Gly to amidated gastrin was enhanced by the PAM cofactor ascorbic acid. To determine whether one member of the prohormone convertase family (PC2) was responsible for progastrin cleavage, G cells were incubated with PC2 antisense oligonucleotide probes. Cells treated with antisense probes had reduced PC2 expression, an accumulation of radiolabeled progastrin, and a delay in the formation of amidated gastrin. Progastrin in antral G cells is cleaved via PC2 to form G-Gly that is converted to amidated gastrin via the actions of PAM.     

Length polymorphism of PCR-amplified genomic fragments of the Pregnancy-Associated Glycoprotein (PAG) gene family in the pig and some other domestic and wild mammals

Porcine pregnancy-associated glycoprotein genes (pPAG) are known as a multigene family, in which five members have been cloned and sequences of their cDNAs identified. Porcine PAG1 and pPAG3 genes, belonging to the pPAG1-like subfamily, both encode enzymatically inactive precursors. In contrast, cDNAs of pPAG2, pPAG4 and pPAG6 represent the pPAG2-like gene subfamily, encoding enzymatically active precursors. The objective of this study was to investigate the polymorphism of both pPAG-like gene subfamilies in the pig in comparison to other domestic species, including cattle, sheep and goat (Artiodactyla), their wild relatives (red deer and wild pig) and horse (Perissodactyla). This is the first paper indicating the polymorphism of the pPAG gene family, examined by lengths of amplified genomic fragments (PCR). Obtained PCR products were analysed in relation to five characterised cDNAs of pPAGs (pPAG1-like and/or pPAG2-like subfamilies) and according to one recognised structural exon-intron organisation of the pPAG2 gene, among at least eight pPAG2-like genes expected in the porcine genome. The highest polymorphism frequency of both pPAG1- and pPAG2-like gene subfamilies was found in the second region, exons 5 and 6 (with intron E). The length of PCR-amplified genomic fragments was approximately: 1043, 700, 600 and 193 bp. A high polymorphism frequency was found in the 3'-terminal fragment, corresponding to exons 7-9 (with introns G and H), more frequent the pPAG2-like gene subfamily. The length of PCR-amplified genomic fragments was approximately: 733, 650 and 356 bp. In contrast, PAG polymorphism was not detected in another region, encompassing exons 2-4 (with introns B and C). The length of PCR-amplified genomic fragments was approximately 279 bp in all examined genomes. In conclusion, amplification of various regions of the PAG gene family presents a relatively inexpensive PCR method of animal pre-selection with different genotypes. Such a pre-selection of animals is helpful for further gene number inquiry of the PAG gene family in each animal, then in related generations. The obtained results provide a useful background for a genetic marker preparation (by Southern analysis of the PAG family) that will presumably enable an economical early selection of young animals for effective reproduction.     

Molecular cloning demonstrates structural features of homologous bovine prohormone convertases 1 and 2

PC1 and PC2 (prohormone convertase) represent neuroendocrine members of the mammalian subtilisin-like family of proprotein convertases. The goal of this study was to compare the primary sequence motifs of bovine PC1 and PC2 with those of homologs from other mammalian species to establish the structural basis for PC1 and PC2 activities in bovine that resemble other mammalian homologs. Molecular cloning from bovine adrenal medulla resulted in the isolation of cDNAs for bovine PC1 and PC2 with highly conserved primary sequences with respect to signal sequence, prosegment, catalytic domain, and P domain. Bovine PC1 and PC2 contained the catalytic triad residues Asp, His, Ser, which are identical to the triads in PC1 and PC2 from other mammalian species. Bovine PCl contained Asn as the oxyanion hole residue; in contrast, bovine PC2 contained Asp as the oxyanion hole residue, which is identical to PC2 in other mammalian species. Bovine PC1 and PC2 possessed the P domain that contains the functional RRGDL motif. The cloned cDNAs detected expression of PC1 and PC2 mRNAs in bovine adrenal medulla. These results establish the defined structural domains of bovine PC1 and PC2 that are known to be essential for the activities of these enzymes in various species.     

cDNA structure, alternative splicing and exon-intron organization of the predisposing tuberous sclerosis (Tsc2) gene of the Eker rat model.

The Eker rat hereditary renal carcinoma (RC) is an excellent example of a Mendelian dominant predisposition to a specific cancer in an experimental animal. We recently reported that a germline insertion in the rat homologue of the human tuberous sclerosis gene (TSC2) gives rise to the dominantly inherited cancer in the Eker rat model. We now describe the entire cDNA (5375 bp without exons 25 and 31) and genomic structure of the rat Tsc2 gene. The deduced amino acid sequence (1743 amino acids) shows 92% identity to the human counterpart. Surprisingly, there are a great many (> or = 41) coding exons with small sized introns spanning only approximately 35 kb of genomic DNA. Two alternative splicing events [involving exons 25 (129 bp) and 31 (69 bp)] make for a complex diversity of the Tsc2 product. The present determination of the Tsc2 gene and establishment of strong conservation between the rat and man provide clues for assessing unknown gene functions apart from that already predicted from the GTPase activating proteins (GAP3) homologous domain and for future analysis of intragenic mutations in tumors using methods such as PCR-SSCP and for insights into diverse phenotypes between species.     

Alternative proteolytic processing of mouse mammary tumor virus superantigens

Mouse mammary tumor viruses express a superantigen essential for their life cycle. It has been proposed that viral superantigens (vSags) require processing by prohormone convertases (PCs) for activity. We now observe, using a panel of mutant forms of potential PC cleavage sites and in vitro cleavage assays, that only the CS1 (position 68 to 71) and CS2 (position 169 to 172) sites are utilized by furin and PC5. Other members of the convertase family that are expressed in lymphocytes are not endowed with this activity. Furthermore, mutant forms of two different viral superantigens, vSag7 and vSag9, which completely abrogated in vitro processing by convertases, were efficient in functional presentation to responsive T-cell hybridomas. This effect was observed in both endogenous presentation and paracrine transfer of the vSag. Processing by convertases thus appears not to be essential for vSag function. Finally, we have identified the purified endosomal protease cathepsin L as another protease that is able to cleave convertase mutant vSag in vitro, yielding fragments similar to those detected in vivo, thus suggesting that proteases other than convertases are involved in the activation of vSags.