Antibodies directed against phosphothreonine residues as potent tools for studying protein phosphorylation

Here we report the development of novel antibodies which specifically react with phosphothreonine residues [anti-(P-Thr)antibodies]. The specificity of the antibodies was assessed in radioimmunoassays where we could demonstrate that half-maximal and maximal binding of the antibodies to plates coated with BSA - P-Thr occurred at serum dilutions of 1:4000 and 1:1000, respectively. P-Thr inhibited antibody binding with a half-maximal effect at 40 microM. P-Ser was 200-fold less potent while P-Tyr was essentially ineffective. Anti-(P-Thr) antibodies could specifically bind to phosphothreonine-containing proteins on Western blots. Using such a procedure we could demonstrate enhanced threonine phosphorylation of the EGF receptor upon treatment of intact unlabeled A431 cells with EGF. We could further demonstrate antibodies binding to proteins present in extracts of rat hepatoma cells (Fao). P-Thr at 10 microM completely inhibited antibody binding while P-Ser, P-Tyr, Thr or Ser, each present at tenfold higher concentrations, had no such inhibitory effect. Anti-(P-Thr) antibodies were also capable of specifically immunoprecipitating 32P-labeled phosphoproteins present in Triton extracts of Fao cells. Immunoprecipitation of proteins of 38 kDa, 55 kDa, 85 kDa, 100 kDa and 155 kDa was inhibited by 1 mM P-Thr but not by P-Tyr. These findings suggest that anti-(P-Thr) antibodies could be powerful tools in studies aimed at monitoring alterations in threonine phosphorylation of specific proteins as they occur under physiological conditions in response to various extracellular stimuli. Identification of such proteins can be conveniently monitored by immunoblotting.     

Modulation of intercellular adherens-type junctions and tyrosine phosphorylation of their components in RSV-transformed cultured chick lens cells.

Transformation of cultured chick lens epithelial cells with a temperature-sensitive mutant of Rous sarcoma virus (tsRSV) leads to radical changes in cell shape and interactions. When cultured at the restrictive temperature (42 degrees C), the transformed cells largely retained epithelial morphology and intercellular adherens junctions (AJ), whereas on switch to the permissive temperature (37 degrees C) they rapidly became fibroblastoid, their AJ deteriorated, and cell adhesion molecules (A-CAM) (N-cadherin) largely disappeared from intercellular contact sites. The microfilament system that was primarily associated with these junctions was markedly rearranged on shift to 37 degrees C and remained associated mainly with cell-substrate focal contacts. These apparent changes in intercellular AJ were not accompanied by significant alterations in the cellular content of several junction-associated molecules, including A-CAM, vinculin, and talin. Immunolabeling with phosphotyrosine-specific antibodies indicated that both cell-substrate and intercellular AJ were the major cellular targets for the pp60v-src tyrosine-specific protein kinase. It was further shown that intercellular AJ components serve as substrates to tyrosine kinases also in nontransformed lens cells, because the addition of a combination of vanadate and H2O2--which are potent inhibitors of protein tyrosine phosphatases--leads to a remarkable accumulation of immunoreactive phosphotyrosine-containing proteins in these junctions. This finding suggests that intercellular junctions are major sites of action of protein tyrosine kinases and that protein tyrosine phosphatases play a major role in the regulation of phosphotyrosine levels in AJ of both normal and RSV-transformed cells.     

Exposure of thymocytes to a low temperature (4 degrees C) inhibits the onset of their hormone-induced cellular refractoriness

The hormonal response of viable mouse thymocytes is radically dependent of their ambient temperature. While at 37 degrees C the cells respond to isoproterenol by an abrupt rise (within 30 s) followed by a exponential decline in the level of intracellular cAMP, at 4 degrees C the level of cAMP remains high, i.e. there is an inhibition of the hormone-induced refractory state. These distinctly different patterns of response are reflected also in both the state of activation of cAMP-dependent protein kinase and the activity of adenylate cyclase. The inhibition of cellular refractoriness in the cold is shown to be fully reversible, lasting only as long as the hormone is present in the extracellular medium. Washing out the hormone or displacing it by a specific antagonist (propranolol) results in a decline of cAMP, of the activity ratio of the kinase, and of the activity of the adenylate cyclase back to basal values. Evidence is presented to show that at 4 degrees C there is no significant hormone-dependent decreases in cAMP degradation or efflux. On the other hand, the activity of adenylate cyclase remains persistently high, through neither the hormone-binding site of the receptor nor the active site of the catalytic subunit of the cyclase seem to be impaired. The different response pattern observed at 4 degrees C appears, therefore, to be associated with the transfer and the signal between these two sites and probably with the G/F protein (s). The possibility to dissect in a selective and reversible manner the process of hormonal stimulation (coupling) from the process of desensitization, which, under normal physiological conditions constitute consecutive and inseparable chain of events, leads us to a propose that the signal transfer which enables activation of adenylate cyclase is, somewhere along its way, distinct from the signal transfer which brings about the onset of the refractory state, and to conclude that these two processes are partially autonomous and regulated by either two different proteins or two different sites on the same protein. The postulated proteins (or sites) should, therefore, differ in their sensitivity to temperature changes, a difference which may be most useful in the identification and isolation of the molecular species involved and in the study of their properties and their mechanism of action.     

Interchain disulfide bonding in the regulatory subunit of cAMP-dependent protein kinase I

The two protomers of the purified regulatory subunit from porcine cAMP-dependent protein kinase I have been shown to be covalently cross-linked by interchain disulfide bonding. Limited proteolysis which cleaves the polypeptide chain into two fragments demonstrated that the disulfide bonding was associated exclusively with the fragment that corresponded to the NH2-terminal region of the polypeptide chain. This NH2-terminal fragment accounted for approximately 15 to 20% of the molecule. The disulfide bonding was further characterized by alkylating the cysteines in the native regulatory subunit. Following oxidation with performic acid, each regulatory subunit contained 7 cysteic acid residues; however, under denaturing conditions, but without prior reduction, only 5 cysteine residues could be alkylated with iodoacetic acid. Following limited proteolysis, all five of these cysteines were associated with the larger COOH-terminal, cAMP binding domain. In contrast, if the denatured subunit was first reduced prior to alkylation, all 7 cysteine residues were alkylated. The 2 cysteines that were only accessible to alkylation after prior reduction were both associated with the NH2-terminal end of the polypeptide chain ultimately with a 5,400 peptide. Alkylation of the isolated, denatured NH2-terminal domain with iodoacetic acid resulted in no covalent modification unless the fragment was first reduced with dithiothreitol. The NH2-terminal and COOH-terminal domains were shown to be linked by a region of the polypeptide chain that is rich in both proline and arginine. It is the arginine-rich site that is readily prone to proteolytic cleavage.     

Extracellular matrix proteins modulate endocytosis of the insulin receptor

Internalization of the insulin receptor (IR) is a highly regulated multi-step process whose underlying molecular basis is not fully understood. Here we undertook to study the role of extracellular matrix (ECM) proteins in the modulation of IR internalization. Employing Chinese hamster ovary cells that overexpress IR (CHO-T cells), our results indicate that IR internalization proceeds unaffected even when Tyr phosphorylation of IR substrates, such as IRS-1, is impaired (e.g. in CHO-T cells overexpressing IRS-1 whose pleckstrin-homology domain has been deleted or in CHO-T cells that overexpress the PH/PTB domain of IRS-1). In contrast, IR internalization is affected by the context of the ECM proteins to which the cells adhere. Hence, IR internalization was inhibited 40-60% in CHO-T cells adherent onto galectin-8 (an ECM protein and an integrin ligand of the galectin family) when compared with cells adherent onto fibronectin, collagen, or laminin. Cells adherent to galectin-8 manifested a unique cytoskeletal organization, which involved formation of cortical actin and generation of F-actin microspikes that contrasted with the prominent stress-fibers formed when cells adhered to fibronectin. To better establish a role for actin filament organization in IR endocytosis, this process was assayed in CHO-T cells (adherent onto fibronectin), whose actin filaments were disrupted upon treatment with latrunculin B. Latrunculin B did not affect insulin-induced Tyr phosphorylation of IR or its ability to phosphorylate its substrates; still, a 30-50% reduction in the rate of IR internalization was observed in cells treated with latrunculin B. Treatment of cells with nocodazole, which disrupts formation of microtubules, did not affect IR internalization. These results indicate that proper actin, but not microtubular, organization is a critical requirement for IR internalization and suggest that integrin-mediated signaling pathways emitted upon cell adhesion to different extracellular matrices and the altered cytoskeletal organizations generated thereof affect the itinerary of the insulin receptor.     

Voluntary disclosure of BRCA1 mutation test results

This study assessed the probability that individuals tested for a BRCA1 gene mutation share their test results with family members, co-workers, and insurers. Members of a large kindred known to be at-risk for carrying a BRCA1 gene mutation were tested and they learned their results from a genetic counselor. During a follow-up interview, 4 months later, subjects were asked with whom they had shared their results. Respondents were most likely to have communicated results to family members, followed by co-workers, and insurers. Carrier status affected their willingness to disclose results to insurers. High rates of disclosure to family members should promote awareness of hereditary cancer risk. Selective disclosure to co-workers and insurers may promote information asymmetries that could affect employment and insurance markets.     

The involvement of CD44 and its novel ligand galectin-8 in apoptotic regulation of autoimmune inflammation

The synovial fluid (SF) cells of rheumatoid arthritis (RA) patients express a specific CD44 variant designated CD44vRA. Using a cellular model of this autoimmune disease, we show in this study that the mammalian lectin, galectin-8 (gal-8), is a novel high-affinity ligand of CD44vRA. By affinity chromatography, flow cytometry, and surface plasmon resonance, we demonstrate that gal-8 interacts with a high affinity (K(d), 6 x 10(-9) M) with CD44vRA. We further demonstrate that SF cells from RA patients express and secrete gal-8, to a concentration of 25-65 nM, well within the concentration of gal-8 required to induce apoptosis of SF cells. We further show that not all gal-8 remains freely soluble in the SF and at least part forms triple complexes with CD44 and fibrinogen that can be detected, after fibrinogen immunoprecipitation, with Abs against fibrinogen, gal-8 and CD44. These triple complexes may therefore increase the inflammatory reaction by sequestering the soluble gal-8, thereby reducing its ability to induce apoptosis in the inflammatory cells. Our findings not only shed light on the receptor-ligand relationships between CD44 and gal-8, but also underline the biological significance of these interactions, which may affect the extent of the autoimmune inflammatory response in the SF of RA patients.     

Transactivation of ErbB2 and ErbB3 by tumor necrosis factor-alpha and anisomycin leads to impaired insulin signaling through serine/threonine phosphorylation of IRS proteins.

The cellular pathways involved in the impairment of insulin signaling by cellular stress, triggered by the inflammatory cytokine tumor necrosis factor-alpha (TNF) or by translational inhibitors like cycloheximide and anisomycin were studied. Similar to TNF, cycloheximide and anisomycin stimulated serine phosphorylation of IRS-1 and IRS-2, reduced their ability to interact with the insulin receptor, inhibited the insulin-induced tyrosine phosphorylation of IRS proteins, and diminished their association with phosphatidylinositol 3-kinase (PI3K). These defects were partially reversed by wortmannin and LY294002, indicating that a PI3K-regulated step is critical for the impairment of insulin signaling by cellular stress. Induction of cellular stress resulted in complex formation between PI3K and ErbB2/ErbB3 and enhanced PI3K activity, implicating ErbB proteins as downstream effectors of stress-induced insulin resistance. Indeed, stimulation of ErbB2/ErbB3 by NDFbeta1, the ErbB3 ligand, inhibited IRS protein tyrosine phosphorylation and recruitment of downstream effectors. Specific inhibitors of the ErbB2 tyrosine kinase abrogated the activation of ErbB2/ErbB3 and in parallel prevented the reduction in IRS protein functions. Taken together, our results suggest a novel mechanism by which cellular stress induces cross-talk between two different signaling pathways. Stress-dependent transactivation of ErbB2/ErbB3 receptors triggers a PI3K cascade that induces serine phosphorylation of IRS proteins culminating in insulin resistance.     

Insulin and insulin-like growth factor-I stimulate a common endogenous phosphoprotein substrate (pp185) in intact neuroblastoma cells

Mouse neuroblastoma N18 cells contain specific high affinity insulin and insulin-like growth factor-I (IGF-I) receptors. Insulin and IGF-I induce phosphorylation, in intact cells, of their respective receptor beta subunits. The insulin receptor beta subunit is represented by a 95-kDa phosphoprotein that is recognized by a specific antiserum (B10). The IGF-I receptor beta subunit is represented by two phosphoproteins of molecular mass 95 and 105 kDa. The hormone-induced phosphorylation was rapid and dose-dependent occurring on both phosphoserine and phosphotyrosine residues. In addition, both insulin and IGF-I induced phosphorylation of an endogenous protein of molecular mass 185 kDa (pp185). The rapidity and dose dependency of the phosphorylation of pp185 suggested that it may represent a common endogenous substrate for the insulin and IGF-I receptors in these neural-derived cells. Phosphorylation was primarily on phosphoserine and phosphotyrosine residues. pp185 did not absorb to wheat germ agglutinin-agarose and was not stimulated by either epidermal growth factor or platelet-derived growth factor. The finding of pp185 in these neural-related cells as well as in non-neural tissues suggests that it may represent a ubiquitous endogenous substrate for both the insulin and IGF-I receptor kinases.