EC:3.4.24.11 - FACTA Search

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Query: EC:3.4.24.11 (CD10)
9,792 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A Ca(2+)-dependent endopeptidase cleaving at the carboxyl side of the paired Lys-Arg residues has been found in the neurosecretory granules of the rat neurointermediate pituitary. The specificity pattern on synthetic fluorogenic substrates, the inhibitor profile, the pH optimum of 5.0 and the Ca(2+)-dependence are compatible with an involvement of this enzyme in the prooxytocin and the provasopressin processing within the granules. The enzymatic features of the neurohypophysial granule endopeptidase resemble those of the insulinoma granule type II endopeptidase and suggest that the same Ca(2+)-dependent protease or closely related enzymes could be involved in processing Lys-Arg-containing prohormones in neuroendocrine cells.
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PMID:A neurosecretory granule Lys-Arg Ca(2+)-dependent endopeptidase putatively involved in prooxytocin and provasopressin processing. 150 25

A novel fluorogenic substrate Cbz-Arg-Ser-Lys-Arg-AMC (RSKR-AMC) was used to characterize Ca(++)-activated proteolytic activity present in purified insulinoma secretory granules. Secretory granules efficiently cleaved this substrate in a time- and protein-dependent manner; the hydrolysis rate was between 2 and 4 pmol/min/ug of protein, with an apparent Km of 55 microM. Greater than 90% of the activity against this substrate was dependent on the presence of Ca++, with half-maximal stimulation obtained at 100 microM Ca++. The pH optimum of enzymatic activity was 5.5-6, and the profile of inhibition by various proteinase inhibitors was similar to that previously described for the type I and II proinsulin processing enzymes. These biochemical characteristics and co-elution of the RSKR-AMC processing activity with the type II endopeptidase activity on anion-exchange chromatography suggest that the new assay selectively detects the Lys-Arg-directed, or type II, proinsulin processing endopeptidase. This fluorogenic assay is more quantitative, sensitive and rapid than methods previously used, and therefore presents a significant improvement for the study of similar Ca(++)-activated processing endopeptidases.
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PMID:Fluorometric assay of a calcium-dependent, paired-basic processing endopeptidase present in insulinoma granules. 154 79

Enzymological studies have implicated two Ca(2+)-dependent endopeptidases in the conversion of proinsulin to insulin; a type 1 activity which cleaves on the C-terminal side of Arg31-Arg32 and a type 2 activity which cleaves C-terminally to Lys64-Arg65 in the proinsulin sequence. The possibility that these enzymes are related to the recently discovered family of mammalian subtilisin-like gene products (furin, PC2, and PC3) and the yeast propheromone-converting enzyme (KEX-2), was investigated. Degenerate oligonucleotide primers flanking the putative catalytic domain within this gene family were used in a polymerase chain reaction to amplify related sequences from rat insulinoma cDNA. One major product of 700 base pairs was obtained which was greater than 99% identical to the corresponding rat PC2 sequence. This cDNA was subcloned into the bacterial expression vector pGEX-3X to generate a recombinant protein for antibody production. Western blot analysis showed the immunoreactivity was prominent in neuroendocrine tissues as a 65-kDa protein. It was concentrated in secretory granule-enriched fractions of insulinoma tissue, where it was present as a readily solubilized monomeric protein. Deglycosylation studies using endoglycosidase H and N-glycanase showed that the 65-kDa protein was comprised of approximately 9% carbohydrate, consistent with the presence of three consensus sequences for N-linked glycosylation in rat PC2. The immunoreactivity co-eluted with the type 2 proinsulin endopeptidase on gel filtration and ion-exchange chromatography and the antisera specifically immunoprecipitated type 2 activity from insulin granule extracts. N-terminal sequence analysis of the immunoreactive protein gave two sequences which corresponded to residues 109-112 and 112-119 of rat PC2. This indicated that posttranslational processing of PC2 itself occurs C-terminally to basic amino acids to produce the mature enzyme. It is concluded that PC2 is the type 2 endopeptidase involved in proinsulin conversion. Localization of PC2 immunoreactivity to other tissues of the diffuse neuroendocrine system suggests that the type 2 endopeptidase also functions in the processing of precursor forms of other prohormones and polypeptide neurotransmitters.
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PMID:Identification of the type 2 proinsulin processing endopeptidase as PC2, a member of the eukaryote subtilisin family. 163 53

Enzymological studies have implicated two Ca2+ dependent endopeptidases in the conversion of proinsulin to insulin: a type 1 activity and a type 2 activity which cleave on the C-terminal side of R31R32 and K64R65 in proinsulin, respectively. These activities were further characterized and their relationship to the mammalian family of subtilisin-like proteases was investigated. PC2 was expressed in neuroendocrine tissues and in insulinoma secretory granule fractions predominantly as a 65kDa protein. On anion-exchange chromatography of solubilized granules, PC1/3 immunoreactivity comigrated with a peak of type 1 activity whereas PC2 immunoreactivity coeluted with the peak of type 2 endopeptidase activity. PC2 antiserum gave a specific immunoprecipitation of type 2 activity from insulin granule extracts. It was concluded that the PC2 gene-product has type 2 endopeptidase activity.
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PMID:Proprotein-processing endopeptidases of the insulin secretory granule. 184 83

Two endopeptidases are involved in the conversion of proinsulin; a type I activity directed at the B chain, Arg31,Arg32, C-peptide junction, and type II which cleaves the C-peptide, Lys64,Arg65, A chain junction. To define further the substrate specificities of these enzymes, a series of mutant preproinsulin cDNAs were generated by site-directed and deletion mutagenesis. These were inserted into pT7 plasmids and capped cRNA transcripts synthesized, that were then microinjected into Xenopus oocytes. Oocytes were biosynthetically radiolabeled with [3H]leucine and the secreted peptides (greater than 95% present as unprocessed proinsulins) then incubated with types I and II endopeptidase activities prepared from isolated insulinoma secretory granules. The reaction products were analyzed by high performance liquid chromatography. Des-38-62-proinsulin, in which all but six amino acids of C-peptide were deleted was not processed by either enzyme. The mutant Lys64,Arg65 to Thr64,Arg65 was not cleaved by the type II enzyme but was still a substrate for the type I enzyme. The mutant Arg31,Arg32 to Arg31,Gly32 correspondingly was not cleaved by the type I enzyme; however, in this case it was not attacked by the type II enzyme. These results indicate that not only is the presence of a dibasic sequence essential, but also that the secondary structure of the protein is important in determining whether the prohormone is susceptible to proteolytic processing.
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PMID:Proinsulin endopeptidase substrate specificities defined by site-directed mutagenesis of proinsulin. 247 43

A lysate of purified insulin secretory granules, which contains two types of proinsulin processing activity (type 1, Arg-Arg-directed and type II, Lys-Arg-directed (Davidson, H.W., Rhodes, C.J., and Hutton, J. C. (1988) Nature 333, 93-96), was found to process proalbumin by specific proteolytic cleavage of the COOH-terminal side of the Arg-2-Arg-1 sequence. The subcellular distribution of proalbumin processing activity in insulinoma tissue paralleled that for proinsulin conversion and occurred principally in a secretory granule fraction. Cleavage appeared to result from the Arg-Arg-directed type 1 proinsulin processing endo-peptidase. It was Ca2+-dependent (K0.5 activation = 1.0-1.5 mM Ca2+), unaffected by group-specific inhibitors of serine, cysteinyl, or aspartyl proteinases, and had an acidic pH optimum (5.5). Active-site inhibitor studies showed this activity had a preference for dibasic over monobasic amino acid sequences and indicated that the sequence of the dibasic site was an important determinant of the susceptibility of the substrate to cleavage. The activity did not process the proalbumin Christchurch mutant (Arg-2-Arg-1 to Arg-2-Gln-1). It was inhibited by the variant alpha 1-antitrypsin Pittsburgh (Met358 to Arg358; K0.5 = 100 nM) but not by other related proteins normally co-secreted with albumin from hepatocytes, namely alpha 1-antitrypsin M, alpha 2-macroglobulin, or antithrombin III. The insulin secretory granule proalbumin processing activity was indistinguishable from a proalbumin endopeptidase reported in rat liver membranes and similar to the yeast KEX-2 protease. These findings suggest that a highly conserved set of proprotein endopeptidases exists, which are specific for a dibasic sequence but broadly specific for proprotein substrates. Such enzymic activities appear to be active within both the constitutive and regulated pathways of secretion. Intraorganellar Ca2+ and pH appear to play a key role in regulating their activities.
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PMID:Proalbumin to albumin conversion by a proinsulin processing endopeptidase of insulin secretory granules. 250 14

The nature and subcellular localization of the enzymic activities responsible for the production of the 20 kDa protein betagranin from its 100 kDa chromogranin-A-like precursor was investigated in transplantable insulinoma tissue. [35S]Methionine-labelled precursor was converted by lysed insulin-secretory granules into betagranin and one or more proteins of 47 kDa, via intermediates in the 60-65 kDa range. Lysosome-enriched fractions also processed the precursor, but not into the peptides found in vivo; other fractions, including those enriched in Golgi, were inactive. Conversion of the precursor by granules was quantitative and the products were stable. Inhibitor studies showed that processing occurred by initial endoproteolytic cleavage at sites marked by pairs of basic amino acids, followed by removal of these by carboxypeptidase H. The endopeptidase activity appeared to be a novel metalloenzyme, with a markedly acidic pH optimum (4.8-5). It was inhibited by alanyl-L-lysyl-L-arginyl chloromethane (K0.5 = 1.3 microM), but to a much lesser extent by inhibitor analogues of processing sites defined by single or unpaired basic amino acid residues, e.g. alanyl-L-norleucyl-L-arginylchloromethane (K0.5 greater than 100 microM), leupeptin (K0.5 = 150 microM) and antipain (K0.5 = 40 microM). p-Chloromercuribenzoate (K0.5 = 13 microM), Hg2+ (K0.5 = 16 microM), Zn2+ (K0.5 = 0.8 mM) and vanadate (K0.5 = 7 microM) also abolished activity, as did various anions (SCN- greater than I- greater than Cl- greater than SO4(2-). Group-specific inhibitors of serine, thiol and acidic endopeptidases were without effect. EDTA and CDTA (1,2-cyclohexanediaminetetra-acetic acid), but not 1,10-phenanthroline, abolished endoproteolytic activity. Several bivalent cations could restore activity after EDTA or CDTA inhibition, including Ca2+, Zn2+, Mn2+ and Sr2+; however, the ion of physiological importance appeared to be Ca2+ (K0.5 = 8 microM). The properties of the granule endopeptidase and its subcellular localization suggested that it is of importance in processing chromogranin A in the pancreatic beta-cell.
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PMID:Proteolytic processing of chromogranin A in purified insulin granules. Formation of a 20 kDa N-terminal fragment (betagranin) by the concerted action of a Ca2+-dependent endopeptidase and carboxypeptidase H (EC 3.4.17.10). 282 6

The nature of the endoproteolytic activity involved in the post-translational processing of proinsulin has been investigated in rat insulinoma tissue. 125I-proinsulin was converted by lysed insulin-secretory granules into insulin via an intermediate form identified as des-dibasic-proinsulin. This activity co-localized with immunoreactive (endogenous) insulin and carboxypeptidase H upon subcellular fractionation of the tissue, indicating a secretory-granular location. Under optimized conditions, conversion was quantitative. Inhibitor studies demonstrated that processing occurred by a reaction sequence involving cleavage on the C-terminal side of the pairs of basic amino acids, with subsequent removal of the newly exposed basic residues by carboxypeptidase H. Endoproteolytic activity was abolished by EDTA and CDTA (1,2-cyclohexanediaminetetra-acetic acid), but not by 1,10-phenanthroline or by group-specific inhibitors of serine, thiol or acidic proteinases. Inhibition by EDTA and CDTA could be reversed by both Ca2+ and Zn2+, although the former appeared to be the ion of physiological importance. Addition of Ca2+ in the absence of chelators stimulated endoproteinase activity, with a maximal effect at 5 mM, a concentration consistent with the intragranular environment. Similarly the pH optimum of 5.5 coincides with the prevailing intragranular pH. Together these properties suggest that the Ca2+-dependent endopeptidase described here is involved in vivo in the proteolytic processing of proinsulin.
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PMID:Proteolytic conversion of proinsulin into insulin. Identification of a Ca2+-dependent acidic endopeptidase in isolated insulin-secretory granules. 331 7

The distribution of proteases potentially reactive with peptide sequences containing pairs of basic amino acids or single basic amino acids was studied in subcellular fractions of a transplantable rat insulinoma using the affinity probes 125I-Tyr-Ala-Lys- ArgCH2Cl and 125I-Tyr-Ala-norleucine- ArgCH2Cl . Both probes labeled predominantly proteins of Mr = 39,000, 31,500, and 25,000. The Mr = 25,000 component appeared to be of lysosomal origin, while the Mr = 39,000 and 31,500 proteins were present in both the lysosomes and insulin granules. The Mr = 39,000 and 31,500 proteins were identified as precursor/product forms of the cysteine protease cathepsin B, while assays performed with fluorigenic peptide substrates suggested that the Mr = 25,000 protein was probably cathepsin L and/or H. The greater reactivity of the Mr = 39,000 form with the dibasic probe suggests that the relative proportions of the Mr = 39,000 and 31,500 forms of cathepsin B in different organelles may determine the extent to which the enzyme expresses activity as a specific (prohormone processing) endopeptidase or a more general (degradative) peptidase.
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PMID:Cathepsin B-related proteases in the insulin secretory granule. 632 60

The post-translational processing of chromogranin A (CGA) and the nature of the enzyme(s) involved were investigated in rat pancreatic islet and insulinoma tissue. Pulse-chase radiolabelling experiments using sequence-specific antisera showed that the 98 kDa (determined by SDS/PAGE) precursor was processed to an N-terminal 21 kDa peptide, a C-terminal 14 kDa peptide and a 45 kDa centrally located peptide with a rapid time course (t1/2 approx. 30 min) after an initial delay of 30-60 min. The 45 kDa peptide was, in turn, converted partially into a 5 kDa peptide with pancreastatin immunoreactivity and a 3 kDa peptide with WE-14 immunoreactivity over a longer time period. Incubation of bovine CGA with rat insulinoma secretory-granule lysate produced peptides of 18, 16 and 40 kDa via intermediates of 65 and 55 kDa. N-terminal sequence analysis indicated that cleavage occurred at the conserved paired basic sites Lys114-Arg115 and Lys330-Arg331, suggesting that cleavage of the equivalent sites (Lys129-Arg130 and Lys357-Arg358) in the rat molecule produced the initial post-translational products observed in intact pancreatic beta-cells. The enzyme activity responsible for the cleavage of bovine CGA co-chromatographed on DEAE-cellulose with the type-2 proinsulin endopeptidase and with PC2 immunoreactivity. The type-1 enzyme (PC1/3) appeared inactive towards CGA. The requirement for Ca2+ ions and an acidic pH for conversion was consistent with the involvement of a member of the eukaryote subtilisin family, and the composition of the released peptides in pulse-chase and secretion studies suggested that conversion occurred in the secretory-granule compartment. The overall catalytic rate as well as the relative susceptibilities of the Lys114-Arg115 and Lys330-Arg331 sites to cleavage were affected by pH, suggesting that the ionic environment of the processing compartment may play a role in the differential processing of CGA which is evident in various neuroendocrine cells.
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PMID:The post-translational processing of chromogranin A in the pancreatic islet: involvement of the eukaryote subtilisin PC2. 814 63

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