Association of prohormone convertase 3 with membrane lipid rafts.

Prohormone convertase 3 (PC3) is a neuroendocrine-specific member of the subtilisin-kexin family, involved in the intracellular processing and maturation of prohormones and proneuropeptides. PC3 is synthesised as a proprotein that undergoes two different cleavages resulting in the mature PC3 and the enzymatically active PC3DeltaC. In vitro translated proPC3 and proPC3DeltaC bind to trans-Golgi network (TGN)/granule-enriched membranes from the AtT20 neuroendocrine cell line in a pH-dependent manner suggesting both a dominant role for the pro-region in membrane association and that the C-terminal region is not essential. However, while PC3 bound to membranes the majority of PC3DeltaC did not, suggesting that either the pro-region or the C-terminal region of PC3 is required for membrane association. Removal of peripheral membrane proteins did not affect the binding properties of any of the in vitro translated proteins. Chromaffin granule membranes (CGMs) were used to study the binding characteristics of endogenous PC3 and its active C-terminal truncated counterpart (PC3DeltaC). Incubation of CGMs with Triton X-100 did not completely solubilise either of these forms of PC3. Moreover, both PC3 and PC3DeltaC remained associated with detergent-resistant membrane microdomains, termed lipid rafts, purified from CGMs. The data raise the possibility that PC3 and PC3DeltaC are sorted to the regulated secretory pathway via their association with membrane lipid rafts.

Basic mechanisms of secretion: sorting into the regulated secretory pathway.

Targeting proteins to their correct cellular location is crucial for their biological function. In neuroendocrine cells, proteins can be secreted by either the constitutive or the regulated secretory pathways but the mechanism(s) whereby proteins are sorted into either pathway is unclear. In this review we discuss the possibility that sorting is either an active process occurring at the level of the trans-Golgi network, or that sorting occurs passively in the immature granules, The possible involvement of protein-lipid interactions in the sorting process is also raised.

Processing of synthetic pro-islet amyloid polypeptide (proIAPP) 'amylin' by recombinant prohormone convertase enzymes, PC2 and PC3, in vitro.

Islet amyloid polypeptide (IAPP), amylin, is the constituent peptide of pancreatic islet amyloid deposits which form in islets of Type 2 diabetic subjects. Human IAPP is synthesized as a 67-residue propeptide in islet beta-cells and colocalized with insulin in beta-cell granules. The mature 37-amino acid peptide is produced by proteolysis at pairs of basic residues at the C- and N-termini of the mature peptide. To determine the enzymes responsible for proteolysis and their activity at the potential cleavage sites, synthetic human proIAPP was incubated (0.5-16 h) with recombinant prohormone convertases, PC2 or PC3 at appropriate conditions of calcium and pH. The products were analysed by MS and HPLC. Proinsulin was used as a control and was cleaved by both recombinant enzymes resulting in intermediates. PC3 was active initially at the N-terminal-IAPP junction and later at the C-terminus, whereas initial PC2 activity was at the IAPP-C-terminal junction. Processing at the basic residues within the C-terminal flanking peptide rarely occurred. There was no evidence for substantial competition for the processing enzymes when the combined substrates proinsulin and proIAPP were incubated with both PC2 and PC3. As proinsulin cleavage is sequential in vivo (PC3 active at the B-chain-C-peptide junction, followed by PC2 at A chain-C-peptide junction), these data suggest that proteolysis of proIAPP and proinsulin is coincident in secretory granules and increased proinsulin secretion in diabetes could be accompanied by increased production of proIAPP.

Involvement of the membrane lipid bilayer in sorting prohormone convertase 2 into the regulated secretory pathway.

Prohormone convertase 2 (PC2) is a neuroendocrine-specific protease involved in the intracellular maturation of prohormones and proneuropeptides. PC2 is synthesised as a proprotein (proPC2) that undergoes proteolysis, aggregation and membrane association during its transit through the regulated secretory pathway. We have previously shown that the pro region of proPC2 plays a key role in its aggregation and membrane association. To investigate this further, we determined the binding properties of a peptide containing amino acids 45-84 of proPC2 (proPC2(45-84)) to trans-Golgi network/granule-enriched membranes from the AtT20 cell line. Removal of peripheral membrane proteins or hydrolysis of integral membrane proteins did not affect the binding properties of proPC2(45-84). Rather, proPC2(45-84) was shown to bind to protein-free liposomes in a pH- and Ca(2+)-dependent manner. To identify the component of the lipid bilayer involved in this membrane association, we used chromaffin-granule membranes and studied the binding properties of the endogenous PC2. Treatment of the membranes with saponin, a cholesterol-depleting detergent, failed to extract PC2 from the membranes, whereas chromogranin A (CgA) was removed. Treatment of the membranes with Triton X-100 yielded a low-density detergent-insoluble fraction enriched in PC2, but not CgA. The detergent-insoluble fraction also contained glycoprotein III, known to be part of the lipid rafts (membrane microdomains rich in sphingolipids). Finally, sphingolipid depletion of AtT20 cells resulted in the mis-sorting of PC2, suggestive of a link between the association of PC2 with lipid rafts in the membrane and its sorting into the regulated secretory pathway.

Inhibitory effect of pax4 on the human insulin and islet amyloid polypeptide (IAPP) promoters.

Pax4 is a paired-box transcription factor that plays an important role in the development of pancreatic beta-cells. Two Pax4 cDNAs were isolated from a rat insulinoma library. One contained the full-length sequence of Pax4. The other, termed Pax4c, was identical to Pax4 but lacked the sequences encoding 117 amino acids at the COOH-terminus. Pax4 was found to inhibit the human insulin promoter through a sequence element, the C2 box, located at -253 to -244, and the islet amyloid polypeptide promoter through a sequence element located downstream of -138. The inhibitory activity of Pax4 was mapped to separate regions of the protein between amino acids 2-230 and 231-349.

The propeptide of prohormone convertase PC2 acts as a transferable aggregation and membrane-association signal.

Prohormone convertase 2 (PC2) is a subtilisin-like protease involved in the intracellular processing of prohormones and proneuropeptides. Like its substrates, it is synthesised as a prepropeptide which undergoes proteolysis during transit through the regulated secretory pathway. Previous studies have shown that aggregation and membrane association of proPC2 occurs in a calcium-dependent and pH-dependent manner and that the pro-region of PC2 may be involved in this process. These events may be involved in the sorting of proteins to the regulated secretory pathway. To investigate this further, we made a chimeric protein containing both the signal peptide and pro-region of PC2 and the N-terminal part of alpha1-antitrypsin, called pro2alpha1. PC2, alpha1-antitrypsin and pro2alpha1 were compared with regard to their membrane association and aggregation properties using, respectively, sucrose gradient centrifugation after expression in Xenopus oocytes, and an in vitro aggregation assay. The chimeric protein, pro2alpha1, underwent low-pH-dependent aggregation and membrane association similar to wild-type PC2. Membrane association occurred at pH 5.5 in the absence of calcium and at pH 6.0 in the presence of 10 mM calcium but not at pH 6.5 or 7.0. alpha1-antitrypsin, as expected of a constitutively secreted protein, did not aggregate at low pH, nor associate with membranes. Pro2alpha1 thus exhibits the membrane association and aggregation properties of PC2, confirming the role of the pro-region in these processes. A series of deletions were performed within the 84-residue propeptide in order to define the sequences involved. Deletion of amino acids 52-77 reduced aggregation but large deletions in the pro-region had only a minimal effect on membrane association. These data suggest that several regions within the propeptide are important in these events.

Sorting of PC2 to the regulated secretory pathway in AtT20 cells.

PC2 and PC3 are neuroendocrine specific members of the eukaryotic subtilisin-like proprotein convertase (PC) family. Both are sorted via the regulated secretory pathway into secretory granules. In order to identify sequences in PC2 which are involved in targeting to the regulated secretory pathway we expressed a series of PC2 cDNAs containing mutations in the C terminal or propeptide domains in the mouse corticotrophic AtT20 cell line. Sorting of endogenous PC3 was used as a control. PC2 and PC3 were secreted with similar kinetics and sorted to secretory granules with similar efficiencies. Deletions of up to 50 amino acids from the C-terminus of proPC2 had no effect on secretion or sorting, but larger deletions completely prevented maturation or secretion. Two large deletions within the propeptide also prevented secretion. Smaller deletions between the primary and secondary cleavage sites, or of the primary cleavage site, reduced the amount of protein secreted but did not affect sorting to secretory granules. Replacement of the propeptide of PC2 with that of the endogenous PC3 also had no effect on secretion or sorting. The results indicate that targeting of proPC2 to the regulated secretory pathway is dependent on more than one region within the proPC2 molecule.

Differences in the autocatalytic cleavage of pro-PC2 and pro-PC3 can be attributed to sequences within the propeptide and Asp310 of pro-PC2.

PC2 and PC3 are subtilisin-like proteases involved in the maturation of prohormones and proneuropeptides within neuroendocrine cells. They are synthesized as zymogens that undergo autocatalytic maturation within the secretory pathway. Maturation of pro-PC2 is slow (t12 >8 h), exhibits a pH optimum of 5.5 and is dependent on calcium (K0.5 2 mM), while pro-PC3 maturation is relatively rapid (t12 15 min), exhibits a neutral pH optimum and is not calcium dependent. These differences in the rates and optimal conditions for activation of the proteases may contribute to the diversity of products generated by these proteases in different cell types. Although highly similar, there are two major differences between pro-PC2 and pro-PC3: the presence of an aspartate at position 310 in pro-PC2 compared with asparagine at the equivalent position in pro-PC3 (and all other members of the subtilisin family), and the N-terminal propeptides, which exhibit low sequence identity (30%). With a view to establishing the structural features that might be responsible for these differences in the maturation of pro-PC2 and pro-PC3, Asp310 in pro-PC2 was mutated to Asn, and Asn309 in pro-PC3 was mutated to Asp. Chimaeric proteins were also made consisting of the pro-region of PC2 fused to the mature portion of PC3 and the pro-region of PC3 fused to the mature region of PC2. The wild-type and mutant DNA constructs were then transcribed and translated in an in vitro system capable of supporting maturation of pro-PC2 and pro-PC3. The results demonstrated that Asp310 of pro-PC2 is responsible for the acidic pH optimum for maturation. Thus changing Asp310 to Asn shifted the pH optimum for maturation to pH 7.0. However, changing Asn309 of pro-PC3 to Asp had no effect on the optimum pH for maturation of pro-PC3. A chimaeric construct containing the propeptide of pro-PC2 attached to PC3 shifted the pH optimum for maturation from pH 7.0 to 6.0 and slowed down the rate of maturation (t12 >8 h). When attached to PC2, the pro-region of pro-PC3 had no effect on the optimum pH for maturation (pH 5.5-6.0), but it did accelerate the rate of maturation (t12 2 h). These results demonstrate that Asp310 and the pro-region of pro-PC2 contribute to the acidic pH optimum and low rate of maturation of this zymogen relative to its closely related homologue PC3.

Expression of GLUT2 in insulin-secreting AtT20 pituitary cells.

The importance of the glucose transporter isoform, GLUT2, in the construction of glucose-sensitive surrogate insulin-secreting cells was evaluated using murine pituitary AtT20 cells. The cells were double transfected with cDNAs for human preproinsulin (hppI-1) driven by the cytomegalovirus promoter, and human GLUT2 driven by the beta-actin promoter. The stably transfected clone, AtTinsGLUT2.36, which strongly expressed both the hppI-1 and GLUT2 genes, constitutively released 7.5 ng/10(6) cells/24 h of immunoreactive insulin-like material, 75% of which was fully processed mature human insulin. Increasing glucose concentrations in the subphysiological range up to 50 microM increased insulin release, but greater glucose concentrations did not further increase insulin release. Suppression of the low-K(m) glucose-phosphorylating enzyme, hexokinase, with 2-deoxy-D-glucose increased glucose-stimulated insulin release by two- to threefold in the presence of subphysiological and physiological glucose concentrations up to 10 mM. Physiological glucose concentrations increased the amount of GLUT2 mRNA, indicating that the beta-actin promoter responds in a glucose-dependent manner. Implantation of 2 x 10(7) AtTinsGLUT2.36 cells intraperitoneally into streptozotocin-diabetic nude mice slowed the progression of hyperglycaemia. The implanted cells formed vascularised tumour-like cell aggregates attached to the peritoneum. The results demonstrate that the beta-actin promoter is partially regulated by glucose. Expression of GLUT2 enables glucose to enter the cell at high K(m), but high-K(m) glucose phosphorylation is also required to signal glucose-stimulated genes affecting insulin release.

Mutations within the propeptide, the primary cleavage site or the catalytic site, or deletion of C-terminal sequences, prevents secretion of proPC2 from transfected COS-7 cells.

PC2 is a neuroendocrine endoprotease involved in the processing of prohormones and proneuropeptides. PC2 is synthesized as a proenzyme which undergoes proteolytic maturation within the cellular secretory apparatus. Cleavage occurs at specific sites to remove the N-terminal propeptide. The aim of the present study was to investigate structural requirements for the transfer of proPC2 through the secretory pathway. A series of mutant proPC2 constructs were transfected into COS-7 cells and the fate of the expressed proteins followed by pulse-chase analysis and immunocytochemistry. Human PC2 was secreted relatively slowly, and appeared in the medium primarily as proPC2 (75 kDa), together with much lower amounts of a processed intermediate (71 kDa) and mature PC2 (68 kDa). Mutations within the primary processing site or the catalytic triad caused the protein to accumulate intracellularly, whereas deletion of part of the propeptide, the P-domain or the C-terminal regions also prevented secretion. Immunocytochemistry showed that wild-type hPC2 was localized mainly in the Golgi, whereas two representative mutants showed a distribution typical of proteins resident in the endoplasmic reticulum. The results suggest that proenzyme processing is not essential for secretion of PC2, but peptides containing mutations that affect the ability of the propeptide (and cleavage sites) to fold within the catalytic pocket are not transferred beyond the early stages of the secretory pathway. C-terminal sequences may be involved in stabilizing such conformations.

Processing of pro-islet amyloid polypeptide (proIAPP) by the prohormone convertase PC2.

Islet amyloid polypeptide (IAPP), 'amylin', is the component peptide of islet amyloid formed in Type 2 diabetes. IAPP is expressed in islet beta-cells and is derived from a larger precursor, proIAPP, by proteolysis. An in vitro translation/translocation system was used to separately examine processing of human proIAPP by the beta-cell endopeptidases PC2, PC3 or furin. ProIAPP was converted to mature IAPP by PC2 but there was little conversion by furin or PC3. These data are consistent with processing of proIAPP in beta-cell secretory granules. Abnormal cellular proteolysis associated with type 2 diabetes could contribute to IAPP amyloidosis.

Differences between the catalytic properties of recombinant human PC2 and endogenous rat PC2.

Human prohormone convertase PC2 was expressed in Xenopus oocytes and its properties were compared with those of the Type-2 endopeptidase of rat insulin secretory granules, previously identified as PC2 [Bennett, Bailyes, Nielson, Guest, Rutherford, Arden and Hutton (1992) J. Biol. Chem. 267, 15229-15236]. Recombinant PC2 had the same substrate specificity as the Type-2 endopeptidase, cleaving at the CA-junction (Lys64, Arg65) of human des-31,32-proinsulin to generate insulin; little activity was found toward human des-64,65-proinsulin or proinsulin itself. Recombinant PC2 was maximally active in 5-7 mM Ca2+ (K0.5 = 1.6 mM) whereas the Type-2 endopeptidase was maximally active in 0.5-1 mM Ca2+ (K0.5 = 40 microM). Both enzymes had a pH optimum of 5.0-5.5 but the Type-2 endopeptidase was active over a wider pH range. Two molecular forms of recombinant PC2 (71 kDa and 68 kDa) were found, both had an intact C-terminus but differed by the presence of the propeptide. The endogenous PC2 comprised several overlapping forms (size range 64-68 kDa), approximately two-thirds of which lacked C-terminal immunoreactivity. Part of the size difference between recombinant and endogenous PC2 was attributable to differences in N-glycosylation. The different post-translational proteolytic modifications of recombinant and endogenous PC2 did not account for the different pH and Ca2+ sensitivities shown by the enzymes. A modulating effect of carbohydrate on enzyme activity could not be excluded.

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.

Calcium- and pH-dependent aggregation and membrane association of the precursor of the prohormone convertase PC2.

PC2 is a subtilisin-like protease which is thought to be involved in the processing of prohormones and proneuropeptides in neuroendocrine cells. The mature 68-kDa enzyme is generated by intracellular proteolytic processing of a 75-kDa pro-PC2 polypeptide. Neuroendocrine cells contain at least two secretory pathways: the regulated pathway whereby secreted products are concentrated, stored in granules, and released in response to external stimulation of the cell, and the constitutive pathway, whereby secretory and plasma membrane proteins are continuously transported to the cell surface without prior concentration or storage. An important step in the sorting of proteins into these pathways is thought to involve the aggregation of proteins destined for storage granules. To define the mechanisms in the intracellular sorting of PC2 to secretory vesicles, the present study was undertaken to investigate the aggregation and membrane association properties of precursor and mature forms of PC2. Using material expressed in microinjected Xenopus oocytes, it was demonstrated that the 75-kDa pro-PC2 polypeptide undergoes calcium- and acid pH-dependent aggregation. Calcium exhibited an effect on the aggregation of pro-PC2 at pH 7.0 and 6.5, whereas below 6.5 aggregation was independent of calcium. Association of pro-PC2 with membranes was observed at pH 5.5, but not at pH 7.0, 6.5, nor 6.0. The mature 68-kDa PC2 polypeptide remained soluble under conditions that caused aggregation and membrane association of the 75-kDa propolypeptide. Deletion of COOH-terminal sequences had no effect on the association of pro-PC2 with membranes, whereas a peptide corresponding to amino acids 57-85 of the propeptide was able to partially compete the membrane associated pro-PC2 away from the membranes.

Synthesis and processing in vivo of the novel mouse thyrotropin beta-presubunit that contains an NH2-terminal extension sequence.

Expression of the single mouse TSH beta gene gives rise to multiple mRNAs, and we have previously shown that in vitro, one of these mRNAs gives rise to a novel TSH beta-presubunit due to initiation of translation at an in-frame start site unique to this mRNA which is up-stream of the normal start site. The novel presubunit contains a 17-amino acid NH2-terminal extension sequence compared to the normal presubunit. Although this extension sequence does not have the characteristics of a normal signal sequence, the novel TSH beta-presubunit was processed in vitro by microsomal membranes. In this study we have examined the translation product of this mRNA in intact cells and whether in vivo it gives rise to a processed secreted TSH beta-subunit that has an NH2-terminal sequence different from that of the established TSH beta-subunit. Firstly, mRNAs encoding alpha-presubunit and either the normal or novel TSH beta-presubunit were microinjected into Xenopus oocytes, and it was found that immunoprecipitable TSH dimer was secreted into the medium regardless of the mRNA used for TSH beta-subunit synthesis. However, less TSH was obtained when the TSH beta-subunit was derived from the extended TSH beta-presubunit. Secondly, when COS cells were transiently transfected with plasmids expressing alpha-presubunit and either the normal or novel TSH beta-presubunit, secreted TSH was obtained when the TSH beta-subunit was derived from either presubunit. TSH dimer was also obtained when the TSH beta-presubunit was derived from a mRNA encoding the extended presubunit in which the down-stream AUG had been eliminated by site-specific mutagenesis. This demonstrated that the up-stream translation start site was used in the intact cell and that secreted TSH beta-subunit was derived from the extended presubunit and not from normal presubunit resulting from translational readthrough to the down-stream AUG. When secreted TSH beta-subunits derived from the normal and extended TSH beta-presubunits were digested with endoproteinase LysC, the NH2-terminal fragments were similar in size, suggesting that the NH2-terminal extension had little if any effect on the site of cleavage by signal peptidase. Our data, therefore, demonstrate that the longer TSH beta-presubunit is synthesized in vivo and strongly suggest that it is processed in the intact cell to give a mature secreted TSH beta-subunit indistinguishable from that derived from the normal TSH beta-presubunit.

Autocatalytic maturation of the prohormone convertase PC2.

PC2 is a member of the eukaryotic family of subtilisin-like proteases, which is thought to participate in the processing of prohormones and proneuropeptides in neuroendocrine cells. PC2 is synthesized as a 69-kDa prepropolypeptide. The NH2-terminal signal sequence is removed during segregation within the endoplasmic reticulum, where glycosylation occurs to generate a 75-kDa propolypeptide. A combination of site-directed mutagenesis and a cell-free translation/translocation system from Xenopus eggs was used to investigate the processing of the pro-PC2 precursor. The 75-kDa polypeptide underwent slow cleavage after the sequence Arg-Lys-Lys-Arg84 to generate a 68-kDa mature enzyme. Cleavage was blocked when the tetrabasic sequence was deleted (PC2M3) or when the active site Asp142 was changed to Asn (PC2M4). This latter observation suggested that cleavage of the 75-kDa propolypeptide to the mature 68-kDa enzyme was autocatalytic. Incubation of the PC2M4 mutant with the wild type PC2 precursor resulted in cleavage of both the wild type polypeptide and the catalytically inactive PC2M4 mutant. This indicates that cleavage could occur through an intermolecular reaction. The results also demonstrate that the novel Xenopus egg extract translation/translocation system represents a powerful cell-free method for studying proteolytic processing of propolypeptides.

A member of the eukaryotic subtilisin family (PC3) has the enzymic properties of the type 1 proinsulin-converting endopeptidase.

PC3, a mammalian homologue of the yeast subtilisin-like proteinase Kex2, was expressed in Xenopus oocytes and its activity was characterized. PC3 cleaved human proinsulin at one of the two dibasic sites (KTRR32 but not LQKR65). The specificity, inhibitor profile, pH optimum (5.5) and Ca(2+)-dependence (K0.5 = 2.5-3 mM) paralleled those of the insulin-granule type 1 endopeptidase activity, suggesting a role for PC3 in the conversion of prohormones.