Insulin receptor/IGF-I receptor hybrids are widely distributed in mammalian tissues: quantification of individual receptor species by selective immunoprecipitation and immunoblotting.

The insulin receptor (IR) and type 1 insulin-like growth factor (IGF-I) receptor (IGFR) are both widely expressed in mammalian tissues, and are known to be capable of heteromeric assembly as insulin/IGF hybrid receptors, in addition to the classically described receptors. By selective immunoadsorption of radioligand/receptor complexes and by immunoblotting we have determined the fraction of insulin receptors and IGF receptors occurring as hybrids in different tissues. Microsomal membranes were isolated from tissue homogenates and solubilized with Triton X-100. Solubilized receptors were incubated with 125I-IGF-I, and radioligand/receptor complexes bound by IR-specific and IGFR-specific monoclonal antibodies were quantified. The fraction of IGF-I binding sites behaving as hybrids (anti-IR-bound/anti-IGFR-bound) was approx. 40% in liver and spleen, 70% in placenta, and 85-90% in skeletal muscle and heart, similar results being obtained in rabbit and human tissues. There was no correlation between the proportion of hybrids and the ratio of 125I-insulin/125I-IGF-I binding in different tissues. The fraction of 125I-insulin bound to hybrids was too low for accurate quantification, because of the relatively low affinity of hybrids for insulin. The fraction of insulin receptors present in hybrids was therefore determined by immunoblotting. Receptors in solubilized human placental microsomal membranes were precipitated with IR-specific or IGFR-specific monoclonal antibodies, and after SDS/PAGE, blots were prepared and probed with IR-specific and IGFR-specific antisera. It was found that 15% of IR and 80% of IGFR were present in hybrids. Consistent with these figures, the overall level of IR was estimated, by blotting with the respective antibodies at concentrations shown to give equal signals with equal amounts of receptor, to be 4-fold greater than IGFR. Overall it was concluded that a significant fraction of both IR and IGFR occurs as hybrids in most mammalian tissues, including those that are recognized targets of insulin and IGF action. The fraction of hybrids in different tissues was not a simple function of the relative levels of IR and IGFR, possibly because of heterogeneity of receptor expression in different cell types. However, in placenta the proportions of IR, IGFR and hybrids were consistent with a process of random assembly reflecting the molar ratio of IR and IGFR half-receptors.

Characterization of the unusual insulin of Psammomys obesus, a rodent with nutrition-induced NIDDM-like syndrome.

Psammomys obesus fed a high-calorie diet develops a NIDDM-like syndrome. The use of reverse-phase high-performance liquid chromatography (HPLC) to study Psammomys insulin biosynthesis and release revealed a very delayed elution time for the Psammomys insulin peak appearing near the position of human proinsulin. This unusual peak was initially thought to represent partially processed insulin on the basis of its molecular size and susceptibility to trimming by carboxypeptidase B (CpB). However, the findings of an active carboxypeptidase E (CpE) enzyme and the normal amidated forms of gastrin and cholecystokinin octapeptide (CCK-8) in Psammomys tissues were inconsistent with CpE-related aberrant processing of insulin. Moreover, amino acid sequencing of the delayed peak of Psammomys insulin revealed fully processed insulin with amino acid sequence as predicted by the cDNA. The unique presence of a B-30 phenylalanine residue, resulting in an increased hydrophobicity of the insulin molecule, probably underlies the marked delay in elution time on HPLC. The unusual structure of Psammomys insulin does not appear to contribute to the proinsulinemia observed in diabetic Psammomys since the HPLC-purified molecule did not inhibit PC1 and PC2 convertase activities in an in vitro assay.

Endoplasmic reticulum Ca2+ is important for the proteolytic processing and intracellular transport of proinsulin in the pancreatic beta-cell.

The role of intracellular Ca2+ in the proteolytic processing and intracellular transport of secretory granule proproteins was investigated by pulse-chase radiolabelling of isolated rat islets of Langerhans. The conversion of proinsulin was inhibited by depletion of medium Ca2+ with EGTA and by blocking the transport of Ca2+ into cells with the Ca2+-channel antagonists verapamil, nifedipine and NiCl2. Proinsulin conversion was also reduced by the endoplasmic reticulum Ca2+-ATPase inhibitor thapsigargin, indicating that the process requires transport of Ca2+ into the endoplasmic reticulum. This was supported by the finding that proinsulin processing was inhibited when Ca2+ was depleted before or during pulse-labelling, but not after transport of the protein to post-endoplasmic-reticulum compartments. Similarly, the inhibition of proinsulin processing was reversed by re-introduction of medium Ca2+ around the time of radiolabelling, but not after 15 min of chase incubation. Ca2+ depletion also decreased proteolytic maturation of the prohormone convertases PC1, PC2 and carboxypeptidase H. Secretion experiments suggested that the rate and extent of proinsulin transport into secretory granules were inhibited marginally by Ca2+ depletion, whereas those of the convertases were markedly impeded. Inhibition of proinsulin conversion by Ca2+ depletion was thus not simply related to the Ca2+-dependencies of mature PC1 and PC2, but also to a requirement for endoplasmic reticulum Ca2+ in proteolytic maturation of the convertases and in their transfer to secretory granules. The results also suggest that the Ca2+ required for prohormone processing in the granules enters the secretory pathway via the endoplasmic reticulum.

Monoclonal antibodies recognize 2300 years aged alkaline phosphatase.

It was attempted to monitor the immunological response of monoclonal antibodies directed to human alkaline phosphatase in ancient Egyptian bones from the ptolemeic period. The intactness of the respective epitopes of the bone enzyme was successfully demonstrated in an ELISA. Fortunately, the mummified bone was not contaminated by fungi and bacteria due to the fungicidal and bactericidal reactivity of the ancient pretreatment employing resins of pistachio for mummification. The enzyme was enriched using gel chromatography, anion exchange and affinity chromatography to yield 310 +/- 7 mU/mg. The enzymically active fractions of the wheat-germ lectin affinity chromatography were subjected to ELISA. The best binding affinity was detected using the monoclonal antibody BAP A while the reactions of all the other four antibodies BAP B, BAP G, BAP 4A5 and BAP 5D4 were substantially diminished.

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.

Identification of the region within the neuroendocrine polypeptide 7B2 responsible for the inhibition of prohormone convertase PC2.

The highly conserved polypeptide 7B2 and the subtilisin-related prohormone convertases PC1/PC3 and PC2 are broadly distributed in neurons and endocrine cells and are localized to secretory granules. We recently showed that recombinant 7B2 is in vitro a potent inhibitor of PC2 activity, but not of PC1/PC3, and that newly synthesized 7B2 is transiently associated with proPC2 in vivo. In the present study, in vitro mutagenesis was used to identify the region within the 7B2 sequence responsible for the inhibition of PC2. Mutant proteins were produced in a prokaryotic expression system and their effects on PC1/PC3 and PC2 activities were studied by two different in vitro enzyme assays. None of the 7B2 mutant proteins inhibited PC1/PC3 activity. Truncation studies revealed that a short segment within the COOH-terminal portion of 7B2 is critical for its inhibitory effect on PC2. This segment contains a pair of basic amino acid residues which may represent a recognition motif for PC2. Single amino acid substitutions within this Lys171-Lys172 site strongly diminished and a double mutation abolished the inhibitory potency of 7B2. Our results indicate that, although amino acid residues directly surrounding this dibasic pair also contribute to PC2 inhibition, the Lys171-Lys172 site is particularly important for the ability of 7B2 to inhibit PC2.

The post-translational processing of chromogranin A in the pancreatic islet: involvement of the eukaryote subtilisin PC2.

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.

A multiplicity of protein antigens in subcellular fractions of rat insulinoma tissue are able to stimulate T cells obtained from non-obese diabetic mice.

Type 1 (insulin-dependent) diabetes mellitus is a T-cell mediated autoimmune disease with a number of different proteins being implicated as target autoantigens. A 38 kDa protein residing in the insulin secretory granule of insulinoma tissue is recognized by T-cell clones from a newly-diagnosed Type 1 diabetic patient. We have investigated the capacity of normal rat pancreatic beta-cell extracts and various subcellular fractions of transplantable RIN tissue to induce proliferation of T cells from non-obese diabetic (NOD) mice and H-2 identical NON.NOD-H-2g7 control mice. Normal rat islet beta-cell protein fractions induced intense, dose-dependent proliferation of NOD splenic T cells, but only marginal proliferative responses of NON.NOD-H-2g7 splenic T cells. To further localize the target antigens, four different subcellular fractions from RIN tissue were used as a source of antigen; here in particular the cytosolic proteins showed dose-dependent activation capacity with splenic T cells in NOD animals. These activities were absent in control mice. There was no proliferation after incubation with microsome preparations from other rat endocrine tissues. Purified carboxypeptidase H did not have any stimulatory activity on NOD T cells. Fractionation of the RIN cytosolic proteins showed a large number of different fractions eliciting proliferative activity. These results demonstrate that NOD T cells respond to a large number of potential islet beta-cell target antigens and it will be necessary to utilize NOD T-cell clones to identify the number and nature of these antigens.

Kinetic analysis of the type-1 proinsulin endopeptidase by a monoclonal antibody-based immunoadsorbent assay.

A simple, rapid and sensitive assay for the type-1 endopeptidase (Arg-Arg cleaving) was developed by using an antiproinsulin monoclonal immunoadsorbent to separate reaction products from the substrate. The values obtained by this assay were identical with those obtained by an h.p.l.c.-based procedure and yielded similar values for the pH optimum (5.6) and Ca2+ activation (K0.5 = 2 mM). It was shown that the type-1 endopeptidase was readily solubilized by Triton X-114 (87 +/- 3%, n = 12) and partitioned principally into the aqueous phase at 30 degrees C (90.1 +/- 2.6%, n = 12). Activity was lost on gel filtration, but could be restored by adenosine 5'-[gamma-thio]triphosphate (K0.5 = 6 microM), 50 microM-dithiothreitol or 50 microM-Ca(2+)-trans-1,2-diaminocyclohexane-NNN'N'-tetra-acetic acid (CDTA), indicating that the enzyme was particularly sensitive to heavy metal ions. The Km obtained with proinsulin as substrate (13 +/- 1.7 microM) indicated that the enzyme works at close to its Vmax. in the nascent secretory granule. The Vmax. of the enzyme prepared from insulin granules (0.6% proinsulin converted/min) corresponded closely to the rate measured in vivo in rat islets. The type-1 endopeptidase also appears to be capable of binding to proinsulin in the region of the C-peptide/A-chain junction, since a peptide spanning this region was found to inhibit the 125I-proinsulin processing measured by this assay.

Identification of the type 2 proinsulin processing endopeptidase as PC2, a member of the eukaryote subtilisin family.

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.

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.

T-cell reactivity to 38 kD insulin-secretory-granule protein in patients with recent-onset type 1 diabetes.

Type 1 diabetes seems to be an autoimmune disease in which T cells have a substantial role. A possible target antigen was suggested by the proliferation of CD4 T cells from a newly diagnosed patient in response to a 38 kD polypeptide of the insulin-secretory-granule membrane. To see whether this reactivity is widespread at disease onset, we have generated T-cell lines in vitro from peripheral blood mononuclear cells of nineteen children of caucasoid origin with newly diagnosed type 1 diabetes and sixteen healthy controls matched for age and HLA antigens. The procedure involved two cycles of incubation with a rat beta-cell tumour subcellular fraction enriched in secretory granules and plasma membrane components, followed by a proliferation assay. Fourteen (74% [95% confidence interval 49-91%]) of the patients' cell lines showed a positive proliferative response on subsequent exposure to the islet-cell antigen preparation compared with only two (13% [2-38%]) of the controls (p = 3 x 10(-4); difference 61% [44-87%]). Two subjects who had high titres of islet-cell autoantibodies (ICA) without clinical diabetes produced responsive T-cell lines. Reactivity towards the 38 kD fraction of insulin-secretory-granule membranes was found only in patients (eight of ten responders tested; 95% CI 44-98%) and one ICA-positive non-diabetic subject. Detection of an ongoing autoimmune T-cell response might be useful diagnostically and could lead to prevention of diabetes through specific immunotherapy.

The presence and measurement of secretory component in human bile and blood.

Five monoclonal antibodies which recognized three separate epitopes on the free secretory component molecule were produced using free secretory component obtained from human colostrum. Two-site immunoradiometric assays were developed to measure free secretory component and secretory IgA. Monoclonal antibody M9 was used on coated plates as the capture antibody. Monoclonal antibody M7 was used as the labelled signal antibody for the assay of free secretory component and a commercially available monoclonal anti-IgA antibody was used as the labelled signal antibody for the assay of secretory IgA. Free secretory component was found in human serum and bile. In serum, its concentration was raised in patients with high serum alkaline phosphatase due to liver disorders but not in patients with high serum alkaline phosphatase due to non-liver disorders. In bile from bile duct drains collected during the first week after liver transplantation, free secretory component was found in concentrations of up to 33 mg/l, in vast excess of that found in bile from gallstone patients (up to 0.3 mg/l). Bile from gallstone patients but not from liver transplant patients produced proteolytic degradation of free secretory component when incubated in vitro. The finding of large amounts of free secretory component, the free cleaved fragment of the polymeric IgA receptor in human bile, further supports the existence of the blood to bile transhepatocytic pathway in humans.

Insulin secretory granule biogenesis. Co-ordinate regulation of the biosynthesis of the majority of constituent proteins.

Two-dimensional gel-electrophoretic analysis combined with fluorography and densitometric quantification was used to examine the effects of glucose on the biosynthesis of rat pancreatic islet proteins. An increase in the medium glucose concentration from 2.8 to 16.7 mM produced a 10-20 fold stimulation in the synthesis of 10 out of 260 detected islet proteins, as judged by incorporation of [35S]methionine during a 20 min incubation. The synthetic rates of the majority of the remaining proteins were stimulated by 2-4-fold. Greater resolution achieved by pulse-chase labelling and subcellular fractionation showed that, of 32 major proteins localized to insulin secretory granules, the biosynthesis of 25 were stimulated 15-30-fold by glucose. By contrast, only eight of 160 proteins in the soluble fraction showed a response of similar magnitude. It is concluded that there is a major and co-ordinated activation of the biosyntheses of proteins destined for secretory granules, which most likely occurs at the level of translational initiation and signal-recognition-particle-mediated translocation into the endoplasmic reticulum lumen. However, it is clear that not all granule proteins, or the majority of proteins translocated across the endoplasmic reticulum membrane, are affected in an equivalent manner. In addition, the synthesis of a small number of cytosolic proteins may be increased markedly by insulinotropic stimuli.

Proprotein-processing endopeptidases of the insulin secretory granule.

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.

Inositol is a constituent of detergent-solubilized immunoaffinity-purified rat liver 5'-nucleotidase.

myo-Inositol analysis of detergent-solubilized immunoaffinity-purified rat liver 5'-nucleotidase showed the presence of 1 mol of myo-inositol/mol of enzyme monomer. This provides unequivocal evidence that the ectoenzyme 5'-nucleotidase is attached to liver membranes by a glycosyl-phosphatidylinositol lipid anchor.

The inhibition of proinsulin-processing endopeptidase activities by active-site-directed peptides.

Inhibitor studies were performed on the two endopeptidase activities involved in proinsulin conversion in isolated insulin secretory granules [Davidson, Rhodes & Hutton (1988) Nature (London) 333, 93-96]. The active-site-directed peptides L-alanyl-L-arginyl-L-arginylmethyldimethylsulphonium and L-alanyl-L-lysyl-L-arginylmethyldimethylsulphonium inhibited these activities in accordance with the observed cleavage pattern, suggesting that the primary amino acid sequence of the dibasic site was an important determinant of the endopeptidase substrate specificities.