Hypoglycemic effects of peroxovanadium compounds in Sprague-Dawley and diabetic BB rats.

Highly purified peroxovanadium (pV) compounds, each containing an oxo ligand, one or two peroxo anions, and an ancillary ligand in the inner coordination sphere of vanadium, were shown to decrease plasma glucose markedly in both normal Sprague-Dawley and insulin-deprived diabetic BB rats. Maximal decreases in plasma glucose were at 60-100 min after intravenous, intraperitoneal, or subcutaneous administration. Synergism between these compounds and insulin was observed. Whereas parenterally administered orthovanadate or vanadyl sulfate did not induce hypoglycemia before inducing acute mortality, pV compounds effected hypoglycemia at doses much lower than those inducing acute mortality. When administered subcutaneously over a period of 3 days to insulin-deprived diabetic BB rats, pV compounds, but not vanadate, caused a significant decrease in plasma glucose concentrations and prevented the appearance of ketosis in these animals. Thus, pV compounds are the first agents other than insulin that acutely and markedly reduce plasma glucose in hypoinsulinemic diabetic BB rats.

Intracellular signal transduction: The role of endosomes.

Polypeptide hormones, growth factors, and other biologically significant molecules are specifically internalized by target cells. Exposure of cells to these ligands results in the formation of ligand-receptor complexes on the cell surface and subsequent internalization of these complexes into the endosomal apparatus (endosomes, or ENs). The study of ENs has identified several important functions for this unique cellular organelle. These include the dissociation of ligand from receptor and receptor recycling to the cell surface and the degradation of some internalized ligands, as well as the delivery of others to lysosomes. More recently, it has become apparent that ENs fulfill another critical role, that of signal transduction. In this article, we review the evidence substantiating this role for ENs and propose three models by which ENs participate in cell signaling.

A role for tyrosine phosphorylation in both activation and inhibition of the insulin receptor tyrosine kinase in vivo.

Upon insulin binding, a conformational change in the insulin receptor (IR) leads to IR beta-subunit autophosphorylation, an increase in IR beta-subunit exogenous tyrosine kinase activity, and the rapid endocytosis of the ligand-receptor complex into endosomes. Previous work has shown that upon internalization, rat hepatic endosomal IRs manifest increased autophosphorylating and exogenous tyrosine kinase activity compared to IRs located at the plasma membrane. As this period of enhanced activity is associated with reduced endosomal IR beta-subunit phosphotyrosine content, it has been proposed that partial dephosphorylation of the internalized IR beta-subunit by an endosomally located phosphotyrosine phosphatase(s) [PTPase(s)] mediates this effect. To test whether endosomal PTPase activity was required for internalization-dependent augmentation of IR tyrosine kinase activity, the present study used the peroxovanadium PTPase inhibitor, bisperoxo(1,10-phenanthroline)oxovanadate anion [bpV(phen)], to block IR dephosphorylation within this subcellular compartment. Rats were pretreated with bpV(phen) before receiving insulin (1.5 micrograms/100 g BW). bpV(phen) inhibited the dephosphorylation of 32P-labeled hepatic endosomal IR by approximately 97% at 15 min post-bpV(phen) injection and prevented a decrease in IR beta-subunit phosphotyrosine content after IR internalization. Fifteen-minute bpV(phen) pretreatment produced a significant reduction (75%; P < 0.001) in maximal insulin-stimulated endosomal IR exogenous kinase activity and decreased IR autophosphorylating activity by 4.3-fold in this subcellular fraction. In conclusion, these findings suggest that an hepatic endosomal PTPase(s) regulates internalization-dependent increases in IR exogenous tyrosine kinase activity.

The role of insulin dissociation from its endosomal receptor in insulin degradation.

Mechanisms that terminate signals from activated receptors have potential to influence the magnitude and nature of cellular responses to insulin. The aims of this study were to determine in rat liver endosomes (the subcellular site of insulin signal termination) whether dissociation of insulin from its receptor was a pre-requisite for ligand degradation and whether the state of receptor phosphorylation influenced the dissociation and hence endosomal degradation of insulin and/or receptor recycling. Following in vivo administration of 125I-[A14]-insulin or analogues (native, X10 or H2, relative binding affinities 1:7:67) livers were removed and endosomes prepared. In the endosomal preparations a significantly greater percentage of both analogues were receptor-bound than native insulin with concomitantly less ligand degradation. When rats were injected with protein-tyrosine phosphatase inhibitors (peroxovanadium compounds bpV(phen) or bpV(pic)) before insulin, endosomal insulin receptor phosphotyrosine content, assessed by Western blotting, was increased as was receptor-bound 125I-[A14]-insulin, whilst insulin degradation was decreased. Peroxovanadiums also completely inhibited recycling of insulin receptors from endosomes. However, treatment of freshly isolated endosomes with acid phosphatase which completely dephosphorylated the insulin receptor, did not return the rate of insulin dissociation and degradation to control values, suggesting that peroxovanadium compounds elicit their effect on binding and degradation via a mechanism other than as protein-tyrosine phosphatase inhibitors. We conclude that promotion of sustained receptor binding decreases endosomal insulin degradation and extends the half-life of the activated endosomal receptor, which in turn would be expected to potentiate insulin signalling from this intracellular compartment.

Peroxovanadium compounds: biological actions and mechanism of insulin-mimesis.

When used alone, both vanadate and hydrogen peroxide (H2O2) are weakly insulin-mimetic, while in combination they are strongly synergistic due to the formation of aqueous peroxovanadium species pV(aq). Administration of these pV(aq) species leads to activation of the insulin receptor tyrosine kinase (IRK), autophosphorylation at tyrosine residues and inhibition of phosphotyrosine phosphatases (PTPs). We therefore undertook to synthesize a series of peroxovanadium (pV) compounds containing one or two peroxo anions, an oxo anion and an ancillary ligand in the inner co-ordination sphere of vanadium, whose properties and insulin-mimetic potencies could be assessed. These pV compounds were shown to be the most potent inhibitors of PTPs yet described. Their PTP inhibitory potency correlated with their capacity to stimulate IRK activity. Some pV compounds showed much greater potency as inhibitors of insulin receptor (IR) dephosphorylation than epidermal growth factor receptor (EGFR) dephosphorylation, implying relative specificity as PTP inhibitors. Replacement of vanadium with either molybdenum or tungsten resulted in equally potent inhibition of IR dephosphorylation. However IRK activation was reduced by greater than 80% suggesting that these compounds did not access intracellular PTPs. The insulin-like activity of these pV compounds were demonstrable in vivo. Intra venous (i.v.) administration of bpV(pic) and bpV(phen) resulted in the lowering of plasma glucose concentrations in normal rats in a dose dependent manner. The greater potency of bpV(pic) compared to bpV(phen) was explicable, in part, by the capacity of the former but not the latter to act on skeletal muscle as well as liver. Finally administration of bpV(phen) and insulin led to a synergism, where tyrosine phosphorylation of the IR beta-subunit increased by 20-fold and led to the appearance of four insulin-dependent in vivo substrates. The insulin-mimetic properties of the pV compounds raises the possibility for their use as insulin replacements in the management of diabetes mellitus.

Chloroquine augments the binding of insulin to its receptor.

The effect of chloroquine on the interaction of insulin with its receptor has been investigated under both equilibrium and non-equilibrium conditions. Chloroquine was found to augment insulin binding in a pH-dependent manner between pH 6.0 and pH 8.5, with the maximum occurring at approximately pH 7.0. Analysis of the equilibrium binding data in terms of independent binding sites gave equivocal results but suggested an increase in the high-affinity component. Analysis using the negative co-operativity binding model of De Meyts, Bianco and Roth [J. Biol. Chem. (1976) 251, 1877-1888] suggested that the affinity at both high and low occupancy was increased equally. The kinetics of association of insulin with the plasma-membrane receptor indicated that, although the net rate of association increased in the presence of chloroquine, this was due to a reduction in the dissociation rate rather than an increase in the association rate. This was confirmed by direct measurement of the rates of dissociation. Dissociation was found to be distinctly biphasic, with fast and slow components. Curve fitting suggested that the decrease in dissociation rate in the presence of chloroquine was not due to a decrease in either of the two dissociation rate constants, but rather to an increase in the amount of insulin dissociating by the slow component. It was also found that the increase in dissociation rate in the presence of excess insulin, ascribed to negative co-operativity, could be accounted for by an increase in the amount of insulin dissociating by the faster pathway, rather than by an increase in the dissociation rate constant. Thus chloroquine appears to have the opposite effect to excess insulin, and evidence was found for the induction of positive co-operativity in the insulin-receptor interaction at high chloroquine concentrations. Evidence was also found for the presence of low-affinity chloroquine binding sites with binding parameters similar to the concentration dependence of the chloroquine-induced augmentation of insulin binding.

Pharmacological doses of insulin equalize insulin receptor phosphotyrosine content but not tyrosine kinase activity in plasmalemmal and endosomal membranes.

Following insulin administration to intact rats, the insulin receptor kinase activity of subsequently isolated cell fractions was significantly augmented. Of interest was the observation that the endosomal insulin receptor tyrosine kinase displayed four- to six-fold greater autophosphorylation activity than that of plasma membrane. Surprisingly, the endosomal insulin receptor tyrosine kinase displayed a decrease in beta-subunit phosphotyrosine content compared with that seen in the plasma membrane. These observations prompted the suggestion that insulin receptor tyrosine kinase phosphotyrosine dephosphorylation mediated by an endosome-specific phosphotyrosine phosphatase(s) yields activation of the endosomal insulin receptor tyrosine kinase. In a previous study we examined the effect of subsaturating doses of injected insulin. In this work we evaluated insulin receptor tyrosine kinase activity and phosphotyrosine content in plasma membrane and endosomes after a receptor-saturating pharmacological dose of insulin (150 micrograms/100 g body weight). At this dose the phosphotyrosine content per receptor was reduced compared with that seen earlier at insulin doses of 1.5 and 15 micrograms/100 g body weight. Endosomal insulin receptor tyrosine kinase was greater than that seen at the lower nonsaturating insulin doses. Furthermore, endosomal insulin receptor tyrosine kinase activity exceeded that of the plasma membrane, despite retaining about the same phosphotyrosine content per receptor. These data are consistent with the view that insulin receptor tyrosine kinase activity may be regulated by a particular pattern of phosphotyrosine content on the beta-subunit wherein both activating and inhibitory phosphotyrosine residues play a role.

Selective activation of the rat hepatic endosomal insulin receptor kinase. Role for the endosome in insulin signaling.

Insulin administration activates the insulin receptor kinase (IRK) in both plasma membrane (PM) and endosomes (ENs) raising the possibility of transmembrane signaling occurring in the endosomal compartment. Peroxovanadium compounds activate the IRK by inhibiting IR-associated phosphotyrosine phosphatase(s). Following the administration of the phosphotyrosine phosphatase inhibitor bisperoxo(1,10-phenanthroline)-oxovanadate (V) anion (bpV(phen)) activation of the hepatic IRK in ENs preceded that in PM by 5 min. When colchicine treatment preceded bpV(phen) administration IRK activation in ENs was unaffected but was totally abrogated in PM. Insulin receptor substrate-1 tyrosine phosphorylation followed the kinetics of IRK activation in ENs not PM and a hypoglycemic response similar to that achieved with a pharmacological dose of insulin ensued. These studies demonstrate that ENs constitute a site for IR-mediated signal transduction.

Chloroquine extends the lifetime of the activated insulin receptor complex in endosomes.

Insulin signal transduction, initiated by binding of insulin to its receptor at the plasma membrane, activates the intrinsic receptor tyrosine kinase and leads to internalization of the activated ligand-receptor complex into endosomes. This study addresses the role played by the activated insulin receptor within hepatic endosomes and provides evidence for its central role in insulin-stimulated events in vivo. Rats were treated with chloroquine, an acidotrophic agent that has been shown previously to inhibit endosomal insulin degradation, and then with insulin. Livers were removed and fractionated by density gradient centrifugation to obtain endosomal and plasma membrane preparations. Chloroquine treatment increased the amount of receptor-bound insulin in endosomes at 2 min after insulin injection by 93% as determined by exclusion from G-50 columns and by 90% as determined by polyethylene glycol precipitation (p < 0.02). Chloroquine treatment also increased the insulin receptor content of endosomes after insulin injection (integrated over 0-45 min) by 31% when compared with controls (p < 0.05). Similarly, chloroquine increased both insulin receptor phosphotyrosine content and its exogenous tyrosine kinase activity after insulin injection (64%; p < 0.01 and 96% and p < 0. 001, respectively). In vivo chloroquine treatment was without any observable effect on insulin binding to plasma membrane insulin receptors, nor did it augment insulin-stimulated receptor autophosphorylation or kinase activity in the plasma membrane. Concomitant with its effects on endosomal insulin receptors, chloroquine treatment augmented insulin-stimulated incorporation of glucose into glycogen in diaphragm (p < 0.001). These observations are consistent with the hypothesis that chloroquine-dependent inhibition of endosomal insulin receptor dissociation and subsequent degradation prolongs the half-life of the active endosomal receptor and potentiates insulin signaling from this compartment.

In vivo insulin mimetic effects of pV compounds: role for tissue targeting in determining potency.

Peroxovanadium (pV) compounds activate the insulin receptor kinase in hepatocytes and inhibit the dephosphorylation of insulin receptors in hepatic endosomes with highly correlated potencies (Posner, B. I., R. Faure, J. W. Burgess, A. P. Bevan, D. Lachance, G. Zhang-Sun, J. B. Ng, D. A. Hall, B. S. Lum, and A. Shaver J. Biol. Chem. 269: 4596-4604, 1994). After intravenous administration, K2[VO(O2)2(picolinato)].2H2O [bpV(pic)], VO(O2) (picolinato) (H2O)2 [mpV(pic)], K[VO(O2)2(picolinato)].3H2O [bpV(phen)], and K[VO(O2)2(4,7-dimethyl-1,10-phenanthroline)].1/2H2O [bpV(Me2phen)] produced 50% of their maximal hypoglycemic effect at doses of 0.04, 0.04, 0.32, and 0.65 mumol/100 g body wt, respectively. In contrast, their potencies as inhibitors of dephosphorylation were bpV(pic) = bpV(phen) > mpV(pic) = bpV(Me2phen). bpV(pic) stimulated [14C]glucose incorporation into rat diaphragm glycogen in vivo, and its effect was dose dependent, synergistic with insulin, and evident in other skeletal muscles. In contrast, bpV(phen) displayed no effect on glycogen synthesis in skeletal muscle. mpV(pic) stimulated and bpV(Me2phen) had no effect on glycogen synthesis in the diaphragm. bpV(pic) augmented rat diaphragm insulin receptor kinase 2.2-fold with a time-integrated response 70% that of insulin. In contrast, the effect of bpV(phen) was delayed and much reduced. Thus, the in vivo potencies of pV compounds reflect differing capacities to act on skeletal muscle. The ancillary ligand within the pV complex may target one tissue in preference to another.

Differential regulation of phosphoinositide 3-kinase adapter subunit variants by insulin in human skeletal muscle.

The role of phosphoinositide 3-kinase (PI 3-kinase) in insulin signaling was evaluated in human skeletal muscle. Insulin stimulated both antiphosphotyrosine-precipitable PI 3-kinase activity and 3-O-methylglucose transport in isolated skeletal muscle (both approximately 2-3-fold). Insulin stimulation of 3-O-methylglucose transport was inhibited by the PI 3-kinase inhibitor LY294002 (IC50 = 2.5 microM). The PI 3-kinase adapter subunits were purified from muscle lysates using phosphopeptide beads based on the Tyr-751 region of the platelet-derived growth factor receptor. Immunoblotting of the material adsorbed onto the phosphopeptide beads revealed the presence of p85alpha, p85beta, p55(PIK)/p55gamma, and p50 adapter subunit isoforms. In addition, p85alpha-NSH2 antibodies recognized four adapter subunit variants of 54, 53, 48, and 46 kDa, the latter corresponding to the p50 splice variant. Serial immunoprecipitations demonstrated that these four proteins were associated with a large proportion of the total PI 3-kinase activity immunoprecipitated by p85alpha-NSH2 domain antibodies. Antibodies to p85beta, p55(PIK)/p55gamma, and the p50 adapter subunit also immunoprecipitated PI 3-kinase activity from human muscle lysates. A large proportion of the total cellular pool of the 53-kDa variant, p50, and p55(PIK) was present in antiphosphotyrosine immunoprecipitates from unstimulated muscle, whereas these immunoprecipitates contained only a very small proportion of the cellular pool of p85alpha, p85beta, and the 48-kDa variant. Insulin greatly increased the levels of the 48-kDa variant in antiphosphotyrosine immunoprecipitates and caused smaller -fold increases in the levels of p85alpha, p85beta, and the 53-kDa variant. The levels of p50 and p55(PIK) were not significantly changed. These properties indicate mechanisms by which specificity is achieved in the PI 3-kinase signaling system.

Peroxovanadium compounds. A new class of potent phosphotyrosine phosphatase inhibitors which are insulin mimetics.

Twelve peroxovanadium (pV) compounds, each containing an oxo ligand, one or two peroxo anions, and an ancillary ligand in the inner coordination sphere of V, were synthesized, crystallized, and characterized by 51V NMR as > 95% pure. These compounds activated the insulin receptor kinase (IRK) of cultured hepatoma cells, stimulated lipogenesis in adipocytes, and inhibited the in situ dephosphorylation of autophosphorylated IRs and epidermal growth factor receptors of rat liver endosomes. The phosphotyrosine phosphatase inhibitory and IRK activating potencies of these compounds were linearly correlated (r = 0.74; p < 0.003), decayed in parallel in solution, and varied considerably with the ancillary ligands within these compounds. In vivo administration activated rat liver IRK in parallel with its tyrosine phosphorylation. Co-administration of insulin plus pV was markedly synergistic in both respects. pV administration significantly decreased circulating insulin and plasma glucose concentrations; the latter to levels seen after a dose of insulin yielding > or = 50% occupancy of IRs in vivo. Two compounds (mpV(pic) and mpV(2,6-pdc)) displayed relative specificity as phosphotyrosine phosphatase inhibitors by inhibiting IR dephosphorylation to a significantly greater degree than epidermal growth factor receptor dephosphorylation. Thus, pV compounds are the most potent phosphotyrosine phosphatase inhibitors described to date. Their capacity to activate IRK appears to derive from their phosphotyrosine phosphatase inhibitory activity. Their hypoglycemic action is due to a direct tissue effect.