Annexin II is a novel player in insulin signal transduction. Possible association between annexin II phosphorylation and insulin receptor internalization.

Annexin II is a Ca2+-, phospholipid-, and actin- binding protein that was implicated in the regulation of vesicular traffic and endosome fusion. It is a known substrate for protein kinases including the platelet-derived growth factor receptor, src protein-tyrosine kinase, and protein kinase C. In the present study we investigated the possible involvement of annexin II in insulin signal transduction. Phosphorylation of annexin II in response to insulin treatment of intact Chinese hamster ovary (CHO)-T cells was detected by 5 min and reached maximal levels after a 2-3-h incubation with the hormone. However, unlike other receptor substrates, annexin II failed to undergo insulin-induced Tyr phosphorylation under conditions where receptor internalization was inhibited. This was evident in CHO cells, overexpressing the insulin receptor, in which internalization was inhibited either by tyrosine kinase inhibitors or by lowering the temperature to 4 degrees C, and in CHO cells overexpressing various insulin receptor mutants in which normal internalization was impaired. Hence, Tyr phosphorylation of annexin II could be part of the internalization and sorting mechanism of the insulin receptor.

Differential activation of mitogen-activated protein kinase and S6 kinase signaling pathways by 12-O-tetradecanoylphorbol-13-acetate (TPA) and insulin. Evidence for involvement of a TPA-stimulated protein-tyrosine kinase.

AG-18, an inhibitor of protein-tyrosine kinases, was employed to study the role of tyrosine-phosphorylated proteins in insulin- and phorbol ester-induced signaling cascades. When incubated with Chinese hamster ovary cells overexpressing the insulin receptor, AG-18 reversibly inhibited insulin-induced tyrosine phosphorylation of insulin receptor substate-1, with minimal effects either on receptor autophosphorylation or on phosphorylation of Shc64. Under these conditions, AG-18 inhibited insulin-stimulated phosphorylation of the ribosomal protein S6, while no inhibition of insulin-induced activation of mitogen-activated protein kinase (MAPK) kinase or MAPK was detected. In contrast, 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced activation of MAPK kinase and MAPK and phosphorylation of S6 were inhibited by AG-18. This correlated with inhibition of TPA-stimulated tyrosine phosphorylation of several proteins, the most prominent ones being pp114 and pp120. We conclude that Tyr-phosphorylated insulin receptor substrate-1 is the main upstream regulator of insulin-induced S6 phosphorylation by p70s6k, whereas MAPK signaling seems to be activated in these cells primarily through the adaptor molecule Shc. In contrast, TPA-induced S6 phosphorylation is mediated by the MAPK/p90rsk cascade. A key element of this TPA-stimulated signaling pathway is an AG-18-sensitive protein-tyrosine kinase.

Polylysine increases the number of insulin binding sites in soluble insulin receptor preparations.

The effects of cationic polyamino acids on insulin binding to soluble insulin receptor preparations were studied. Incubation of partially or fully purified receptor preparations with polylysine (pLys) increased by several-fold the amount of [125I]insulin that remained associated with the receptor, as determined both by precipitation of receptor-insulin complexes by polyethylene glycol or by separation of the complexes from the free hormone by gel filtration. This elevation in the amount of bound insulin resulted from increased number of insulin binding sites, and could not be attributed to an increased affinity of the receptors to insulin. In fact, pLys reduced 2-3-fold the affinity of insulin binding to its receptor as determined by equilibrium binding studies, and by monitoring the rate of exchange of bound [125I]insulin with unlabeled hormone. pLys induced specific interactions between insulin and its native receptor since other basic compounds such as histone, spermidine, polymixin B, compound 48/80, lysine, and arginine failed to reproduce its effects. pLys did not interact with the free ligand, nor did it promote interactions between insulin and denatured receptor forms. Furthermore, pLys did not induce binding of insulin to other proteins present in the partially purified receptor preparations. The effects of pLys were time and dose-dependent and were proportional to the pLys chain length. The longer the chain, the greater was the effect. Enhanced insulin binding and receptor beta-subunit autophosphorylation (in the presence of insulin) exhibited a similar dependency on the chain length of pLys. pLys effects on insulin binding were associated with formation of large protein aggregates that remained trapped at the top of Sephacryl S-300 columns. These aggregates contained substantial amounts of receptor-insulin complexes. Our results suggest that pLys induces formation of receptor clusters that create de novo insulin binding sites among adjacent receptor tetramers. Alternatively, formation of receptor aggregates might facilitate insulin binding to a soluble receptor subfraction that otherwise fails to bind the hormone.

A glycolipid-specific monoclonal antibody modulates Fc epsilon receptor stimulation of mast cells.

In an effort to identify membrane components participating in coupling stimulus to secretion in mast cells, monoclonal antibodies were produced from spleen cells of mice immunized with plasma membranes isolated from rat mast cells of the RBL-2H3 line. The resultant mAbs were screened by their capacity to modulate the secretory response of these cells to crosslinking of their type 1 Fc epsilon receptor (Fc epsilon RI). Following this scheme, we obtained a hybridoma designated B17, which secretes an IgM-class mAb (B17) that binds to and modulates secretion from RBL-2H3 cells. By immunoblotting, B17 was shown to bind to a membrane component of low molecular weight, later identified as a glycolipid. While B17 partially inhibits IgE binding to RBL-2H3 cells, no noticeable inhibition of B17 binding by IgE was observed. mAb B17 does not cause any secretory response on its own, and its modulatory effect on Fc epsilon RI-mediated secretion is bimodal: it either enhances or inhibits secretion, depending on the B17 dose and also on the nature and dose of the agent used for crosslinking the Fc epsilon RI. When secretion was induced by IgE and suboptimal or optimal doses of multivalent antigen, B17 (2-80 nM) caused an increase in secretion. However, higher doses of B17 (greater than 150 nM) inhibited secretion. Secretion induced by supraoptimal doses of antigen, or by the Fc epsilon RI-specific mAb F4 was inhibited by B17 at all the dose range tested (2-200 nM). In contrast, B17 had no effect on secretion induced by Ca2+ ionophores. These results demonstrate that Fc epsilon RI function is modulated by a mAb binding to a membrane glycolipid.

Basic polycations activate the insulin receptor kinase and a tightly associated serine kinase.

The effects of cationic polyamino acids on phosphorylation of the insulin and insulin-like growth factor 1 receptor kinases were studied and the following observations were made. (a) Polylysine stimulated both tyrosine and serine phosphorylation of the insulin receptor and of additional proteins present in lectin-purified membrane preparations from rat liver. (b) Polylysine synergized with insulin to enhance phosphorylation of the insulin receptor and of additional proteins (pp40 and pp110). (c) Polylysine effects were more pronounced upon increasing the polylysine chain length. (d) The effect of polylysine was biphasic with an optimum at 100 micrograms/ml. (e) Polylysine was found ineffective in stimulating the phosphorylation of immobilized insulin receptors. Taken together, these findings support the notion that the action of polylysine involves conformational changes and presumably aggregation of soluble receptors. The same effects of polylysine were obtained with highly purified insulin receptor preparations. Under these conditions polylysine enhanced both serine and tyrosine phosphorylation of the insulin receptor, suggesting that polylysine stimulates the activity of the insulin receptor kinase, and of a serine kinase that is tightly associated with the insulin receptor.

Photoinduction of Massive beta-Carotene Accumulation by the Alga Dunaliella bardawil: Kinetics and Dependence on Gene Activation.

The massive accumulation of beta-carotene by the halotolerant micro alga Dunaliella bardawil, in response to high light intensity and several other environmental factors, has been studied so far under different sets of fixed conditions. To determine the kinetics and characteristics of the induction of beta-carotene accumulation, cells continuously grown under white light of approximately 27 microeinsteins per square meter per second were exposed to light of approximately 1650 microeinsteins per square meter per second. The exposed cells accumulate beta-carotene in two stages: the first stage, lasting for 24 hours, starts shortly after exposure, whereas the second stage starts concomitantly with the onset of the stationary phase and persists until the cells collapse. Actinomycin D, chloramphenicol, or cycloheximide added to low-illuminated cultures abolish the subsequent induction of beta-carotene accumulation by high light intensity. These results, together with the early exponential kinetics of accumulation, point to the role of gene activation in the process. In vivo labeling of proteins and in vitro translation of poly(A)(+) mRNA revealed several pronounced differences between low-illuminated and high-illuminated cells. A strongly light-induced protein of approximately 55 kilodaltons, as well as other light-induced proteins could possibly fulfill a carotenogenic function.