Library

Notes: Abstract   Recent studies have reported that elevated proinsulin levels are indicative of an increased cardiovascular risk. Renal proximal tubular cells represent a major site for the metabolism of insulin-like hormones after glomerular filtration into the tubular lumen. To determine the binding and degradation of proinsulin in comparison with insulin and insulin-like growth factor-1 (IGF-1), we have used a rabbit proximal tubular cell line (PT-1). As confirmed by electron microscopy, PT-1 cells exhibit bipolar differentiation, demonstrating apical microvilli and invaginations of the basolateral membrane. To allow selective incubation of both compartments, cells were grown on filter membranes. Performing equilibrium binding assays with 125I-labelled hormones, severalfold higher binding was found at the apical than at the basolateral cell membrane, with the capacity range IGF-1〉insulin〉proinsulin. Half-maximal displacement of 125I-labelled insulin and IGF-1 was observed at 0.6 and 2 nM, respectively, while crossover binding to the alternate receptor occurred with a 10- to 100-fold lower affinity. Half-maximal displacement of 125I-proinsulin binding was obtained at approx. 8 nM proinsulin and insulin, whereas IGF-1 was 10-fold less potent. The relative degradation of specifically bound tracer was lowest for proinsulin (apical: 10%, basolateral: 13%). IGF-1 was degraded by 20% at the apical cell membrane, and up to 78% at the basolateral membrane. In contrast, almost the total amount of insulin bound was degraded at both membrane sites (apical: 99%, basolateral: 83%). These results suggest separate insulin and IGF-1 receptors, while proinsulin binds with high affinity to a third insulin-like receptor on the apical membrane of PT-1 cells.

Notes: Abstract Recent studies have reported that elevated proinsulin levels are indicative of an increased cardiovascular risk. Renal proximal tubular cells represent a major site for the metabolism of insulin-like hormones after glomerular filtration into the tubular lumen. To determine the binding and degradation of proinsulin in comparison with insulin and insulin-like growth factor-1 (IGF-1), we have used a rabbit proximal tubular cell line (PT-1). As confirmed by electron microscopy, PT-1 cells exhibit bipolar differentiation, demonstrating apical microvilli and invaginations of the basolateral membrane. To allow selective incubation of both compartments, cells were grown on filter membranes. Performing equilibrium binding assays with125I-labelled hormones, severalfold higher binding was found at the apical than at the basolateral cell membrane, with the capacity range IGF-1〉insulin〉proinsulin. Half-maximal displacement of125I-labelled insulin and IGF-1 was observed at 0.6 and 2 nM, respectively, while crossover binding to the alternate receptor occurred with a 10- to 100-fold lower affinity. Half-maximal displacement of125I-proinsulin binding was obtained at approx. 8 nM proinsulin and insulin, whereas IGF-1 was 10-fold less potent. The relative degradation of specifically bound tracer was lowest for proinsulin (apical: 10%, basolateral: 13%). IGF-1 was degraded by 20% at the apical cell membrane, and up to 78% at the basolateral membrane. In contrast, almost the total amount of insulin bound was degraded at both membrane sites (apical: 99%, basolateral: 83%). These results suggest separate insulin and IGF-1 receptors, while proinsulin binds with high affinity to a third insulin-like receptor on the apical membrane of PT-1 cells.

Notes: Summary Proinsulin and insulin binding in IM-9 lymphoblasts show curvilinear Scatchard plots, which may be explained by two binding sites, negative cooperativity of receptors, or both. Using flow-cytometric analysis of insulin binding, we were able to distinguish and separate two different IM-9 cell fractions. In both fractions, Scatchard plots for specific binding of insulin and proinsulin were linear, suggesting the presence of two distinct populations of receptors. Type 1 cells showed low capacity but high affinity of insulin binding (16,300±3,000 sites/cell; Kd 0.4±0.1 nmol/l). Proinsulin and insulin-like growth factor 1 (IGF-1) were significantly less potent in competition. MA-20, a specific antibody against human insulin receptors, inhibited insulin binding by 80%, while the specific antibody against human IGF-1 receptors, αIR-3, had no effect. Pretreatment with insulin decreased insulin binding by 90%. 125I-insulin displayed stepwise dissociation with the rate markedly enhanced by cold insulin. Type 2 cells exhibited significantly different binding characteristics with higher capacity but lower affinity of 125I-insulin binding (430,000±25,000 sites/cell, p〈0.001 vs type 1; Kd 2±0.4 nmol/l, p〈0.02 vs type 1). Proinsulin competed with similar potency for insulin binding, while IGF-1 was still less potent. 125I-proinsulin showed a significantly higher binding affinity than 125I-insulin (Kd 0.5±0.3 nmol/l, p〈0.05) with 50,000±10,000 binding sites/cell. C-peptide was able to compete for 125I-proinsulin, but not for 125I-insulin binding. MA-20 did not influence 125I-proinsulin binding, but inhibited 125I-insulin binding by 50%, whereas αIR-3 increased proinsulin binding 1.5-fold with no effect on insulin binding. Preincubation with insulin decreased insulin binding by 50% and proinsulin binding by 10%. The dissociation of 125I-proinsulin showed linear first-order kinetics and was not significantly accelerated by cold proinsulin. Furthermore, the tyrosine phosphorylation of a 65 kDa protein was stimulated to a significantly greater extent by proinsulin than by insulin, indicating activation of different signalling cascades. DNA analysis revealed that type 1 cells were predominantly in the G1 phase, whereas type 2 cells were in the S and G2 + M phases of the cell cycle. We conclude, that IM-9 lymphoblasts were separated by flow-cytometry into one fraction with typical insulin receptors and a second fraction with high affinity binding sites for proinsulin. High affinity proinsulin binding sites were distinguished from typical insulin receptors by: 1) higher affinity for proinsulin than insulin, 2) inhibition of proinsulin binding by C-peptide but not by the insulin receptor antibody MA-20, 3) non-co-operative first order dissociation kinetics of proinsulin binding, 4) resistance to down-regulation by insulin, and 5) differences in signal transduction.

Notes: Summary Proinsulin and insulin binding in IM-9 lymphoblasts show curvilinear Scatchard plots, which may be explained by two binding sites, negative co-operativity of receptors, or both. Using flow-cytometric analysis of insulin binding, we were able to distinguish and separate two different IM-9 cell fractions. In both fractions, Scatchard plots for specific binding of insulin and proinsulin were linear, suggesting the presence of two distinct populations of receptors. Type 1 cells showed low capacity but high affinity of insulin binding (16,300 ± 3,000 sites/cell; Kd 0.4 ± 0.1 nmol/l). Proinsulin and insulin-like growth factor 1 (IGF-1) were significantly less potent in competition. MA-20, a specific antibody against human insulin receptors, inhibited insulin binding by 80 %, while the specific antibody against human IGF-1 receptors, αIR-3, had no effect. Pretreatment with insulin decreased insulin binding by 90 %. 125I-insulin displayed stepwise dissociation with the rate markedly enhanced by cold insulin. Type 2 cells exhibited significantly different binding characteristics with higher capacity but lower affinity of 125I-insulin binding (430,000 ± 25,000 sites/cell, p 〈 0.001 vs type 1; Kd 2 ± 0.4 nmol/l, p 〈 0.02 vs type 1). Proinsulin competed with similar potency for insulin binding, while IGF-1 was still less potent. 125I-proinsulin showed a significantly higher binding affinity than 125I-insulin (Kd 0.5 ± 0.3 nmol/l, p 〈 0.05) with 50,000 ± 10,000 binding sites/cell. C-peptide was able to compete for 125I-proinsulin, but not for 125I-insulin binding. MA-20 did not influence 125I-proinsulin binding, but inhibited 125I-insulin binding by 50 %, whereas αIR-3 increased proinsulin binding 1.5-fold with no effect on insulin binding. Preincubation with insulin decreased insulin binding by 50 % and proinsulin binding by 10 %. The dissociation of 125I-proinsulin showed linear first-order kinetics and was not significantly accelerated by cold proinsulin. Furthermore, the tyrosine phosphorylation of a 65 kDa protein was stimulated to a significantly greater extent by proinsulin than by insulin, indicating activation of different signalling cascades. DNA analysis revealed that type 1 cells were predominantly in the G1 phase, whereas type 2 cells were in the S and G2 + M phases of the cell cycle. We conclude, that IM-9 lymphoblasts were separated by flow-cytometry into one fraction with typical insulin receptors and a second fraction with high affinity binding sites for proinsulin. High affinity proinsulin binding sites were distinguished from typical insulin receptors by: 1) higher affinity for proinsulin than insulin, 2) inhibition of proinsulin binding by C-peptide but not by the insulin receptor antibody MA-20, 3) non-co-operative first order dissociation kinetics of proinsulin binding, 4) resistance to down-regulation by insulin, and 5) differences in signal transduction. [Diabetologia (1996) 39: 421–432]