Insulin-dependent covalent reassociation of isolated alpha beta heterodimeric insulin receptors into an alpha 2 beta 2 heterotetrameric disulfide-linked complex

The purified human placental alpha 2 beta 2 heterotetrameric insulin receptor complex was reduced and dissociated into functional alpha beta heterodimers by a combination of alkaline pH and dithiothreitol treatment. Insulin treatment of the isolated alpha beta heterodimeric complex was observed to induce the complete reassociation to an alpha 2 beta 2 heterotetrameric state when analyzed by nondenaturing Bio-Gel A-1.5m gel filtration chromatography. Nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis of 125I-insulin affinity cross-linked and 32P-autophosphorylated alpha beta heterodimers demonstrated that the insulin-dependent reassociation to the alpha 2 beta 2 heterotetrameric state occurred both covalently and noncovalently under these conditions. Comparison by reducing and nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that the insulin-dependent covalent reassociation to an alpha 2 beta 2 heterotetrameric complex was due to the formation of a disulfide linkage(s) between the alpha beta heterodimers. beta subunit autophosphorylation of the control alpha 2 beta 2 heterotetrameric insulin receptor preparation was maximally stimulated within 5 min of insulin preincubation and occurred exclusively in the Mr = 400,000 alpha 2 beta 2 complex. Similarly, maximal insulin-stimulated beta subunit autophosphorylation of the alpha beta heterodimeric preparation occurred within 5 min of insulin pretreatment in the Mr = 210,000 alpha beta complex. However, 4 h of insulin pretreatment of the alpha beta heterodimer preparation induced the formation (6-fold) of a covalent 32P-labeled alpha 2 beta 2 heterotetrameric complex. Maximal stimulation of substrate phosphorylation for the alpha 2 beta 2 heterotetrameric complex was also observed to occur within 5 min of insulin treatment, whereas maximal insulin-stimulated substrate phosphorylation of the alpha beta heterodimeric complex required greater than 4 h. These data demonstrate that (i) insulin treatment can induce the reassociation of the alpha beta heterodimeric complex into a covalent alpha 2 beta 2 heterotetrameric state, and (ii) insulin-dependent protein kinase activation of the alpha beta heterodimeric insulin receptor correlates with the covalent reassociation into a disulfide-linked alpha 2 beta 2 heterotetrameric complex.     

Insulin-dependent intermolecular subunit communication between isolated alpha beta heterodimeric insulin receptor complexes

The dissociation of the purified human placental alpha 2 beta 2 heterotetrameric insulin receptor complex into an alpha beta heterodimeric state was found to occur in a pH- and dithiothreitol (DTT)-dependent manner. Formation of the alpha beta heterodimeric complex, under conditions which preserved tracer insulin binding and protein kinase activities (pH 8.75 for 25 min followed by 2.0 mM DTT for 5 min) occurred with an approximate 50% efficiency. The resulting nondissociated alpha 2 beta 2 heterotetrameric complexes could then be separated effectively by Bio-Gel A-1.5m gel filtration chromatography at neutral pH. The isolated DTT-treated but nondissociated alpha 2 beta 2 heterotetrameric complex was resistant to any further dissociation by a second round of DTT and alkaline pH treatment, whereas the isolated alpha beta heterodimeric complex was stable to spontaneous reassociation for at least 72 h at pH 7.60. Kinetic analyses of the insulin receptor protein kinase activity demonstrated that the insulin stimulation of glutamic acid:tyrosine (4:1) synthetic polymer phosphorylation for both the alpha 2 beta 2 heterotetrameric and alpha beta heterodimeric complexes occurred via an increase in Vmax without any significant change in Km. Examination of beta subunit autophosphorylation of the alpha beta heterodimeric complex, in the presence but not in the absence of insulin, demonstrated the appearance of the covalent 32P-labeled alpha 2 beta 2 heterotetrameric complex. Further, the initial rate of insulin-stimulated beta subunit autophosphorylation in the isolated alpha beta heterodimeric complex occurred in a dilution-dependent (intermolecular) manner. These data demonstrate that the isolated alpha beta heterodimeric insulin receptor complex is fully capable of expressing insulin-dependent activation of the beta subunit protein kinase domain with the covalent reassociation of the alpha beta heterodimeric complex into an alpha 2 beta 2 heterotetrameric disulfide-linked state.     

Dithiothreitol activation of the insulin receptor/kinase does not involve subunit dissociation of the native alpha 2 beta 2 insulin receptor subunit complex

The subunit composition of the dithiothreitol- (DTT) activated insulin receptor/kinase was examined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and gel filtration chromatography under denaturing (0.1% SDS) or nondenaturing (0.1% Triton X-100) conditions. Pretreatment of 32P-labeled insulin receptors with 50 mM DTT followed by gel filtration chromatography in 0.1% SDS demonstrated the dissociation of the alpha 2 beta 2 insulin receptor complex (Mr 400,000) into the monomeric 95,000 beta subunit. In contrast, pretreatment of the insulin receptors with 1-50 mM DTT followed by gel filtration chromatography in 0.1% Triton X-100 resulted in no apparent alteration in mobility compared to the untreated insulin receptors. Resolution of this complex by nonreducing SDS-polyacrylamide gel electrophoresis and autoradiography demonstrated the existence of the alpha 2 beta 2 heterotetrameric complex with essentially no alpha beta heterodimeric or free monomeric beta subunit species present. This suggests that the insulin receptor can reoxidize into the Mr 400,000 complex after the removal of DTT by gel filtration chromatography. Surprisingly, these apparently reoxidized insulin receptors were also observed to be functional with respect to insulin binding, albeit with a 50% decrease in affinity for insulin and insulin stimulation of the beta subunit autophosphorylation. To prevent reoxidation, the insulin receptors were pretreated with 50 mM DTT followed by incubation with excess N-ethylmaleimide prior to gel filtration chromatography in 0.1% Triton X-100. Under these conditions the insulin receptors migrated as the Mr 400,000 alpha 2 beta 2 complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

The beta subunit of the insulin receptor is an insulin-activated protein kinase

In the presence of adenosine 5'-[gamma-32P]triphosphate ([gamma-32P]ATP) and a partially purified human placental insulin receptor preparation, insulin stimulates the phosphorylation of an Mr 94000 protein in a time- and dose-dependent manner. Half-maximal stimulation of 32P incorporation occurs at (2-3) X 10(-9) M insulin, a concentration identical with the Kd for insulin binding in this preparation. Immunoprecipitations with monoclonal anti-insulin receptor antibody demonstrate that the Mr 94000 protein kinase substrate is a component of the insulin receptor, the beta subunit. If the partially purified, soluble placental receptor preparation is immunoprecipitated and then exposed to [gamma-32P]ATP and insulin, phosphorylation of the Mr 94000 protein is maintained. The photoincorporation of 8-azido[alpha-32P]ATP into placental insulin receptor preparations was carried out to identify the ATP binding site responsible for the protein kinase activity. Photoincorporation into numerous proteins was observed, including both subunits of the insulin receptor. However, when photolabeling was performed in the presence of excess adenosine 5'-(beta, gamma-imidotriphosphate), a nonhydrolyzable ATP derivative, the beta subunit of the insulin receptor was the only species protected from label incorporation. These data indicate that the beta subunit of the insulin receptor has insulin-dependent protein kinase activity. Phosphotyrosine formation is the primary result of this activity in placental insulin receptor preparations.     

Relationship of site-specific beta subunit tyrosine autophosphorylation to insulin activation of the insulin receptor (tyrosine) protein kinase activity

The ability of insulin to activate the insulin receptor protein kinase is shown to be completely dependent on prior beta subunit tyrosine autophosphorylation. Autophosphorylation in the presence of insulin is a highly concerted reaction; tryptic digestion of insulin receptor beta subunits derived from preparations whose kinase activation ranges from under 5% to 100% of maximal yields the same array of [32P]Tyr(P)-containing peptides over the entire range. Of special note is the significant contribution of multiply phosphorylated forms of tryptic peptides corresponding to proreceptor residues 1144-1152 (from the "tyrosine kinase" domain) and 1314-1329 (near the carboxyl terminus) to overall beta subunit phosphorylation at kinase activations of 5% and under. Thus, partially activated/autophosphorylated receptor preparations consist of mixtures of unactivated unphosphorylated receptors and activated fully (or nearly fully) phosphorylated receptors. The latter can be selectively removed by adsorption to antiphosphotyrosine antibodies. This abrupt multiple phosphorylation of individual receptor molecules explains why, in the presence of insulin, overall beta subunit tyrosine phosphorylation tracks closely with kinase, up to approximately 90% activation. Insulin stimulates phosphorylation into all domains (involving at least 6 of the 13 tyrosines on the intracellular portion of the beta subunit) but does not cause the appearance of "new" 32P-labeled species. Rather, insulin directs 32P incorporation preferentially into those domains most productive of kinase activation. Phosphorylation of the tyrosine residues at 1146, 1150, and 1151 correlates most closely with kinase activation. These residues show the largest 32P incorporation during rapid kinase activation; moreover, in comparisons of receptors with similar overall autophosphorylation but very different activations (or similar activations but different extents of autophosphorylation), achieved by omitting insulin or varying [ATP], the phosphorylation of peptide 1144-1152 tracks closely with kinase activation, and phosphorylation of sites and Mr 4000-5000 tryptic peptide (presumably Tyr 953 and/or 960) tract nearly as well. By contrast the extent of phosphorylation of the carboxy-terminal peptide is frequently dissociated from the extent of kinase activation. Phosphorylation of this latter domain probably underlies a beta subunit function other than tyrosine kinase activity.     

Transmembrane signaling by the human insulin receptor kinase. Relationship between intramolecular beta subunit trans- and cis-autophosphorylation and substrate kinase activation.

To examine the role of intramolecular beta subunit trans- and cis-autophosphorylation in signal transduction, the vaccinia virus/bacteriophage T7 expression system was used to generate insulin holoreceptors composed of a kinase-defective half-receptor precursor (alpha beta A/K or alpha beta A/K.delta CT) and a kinase-active half-receptor precursor (alpha beta delta CT or alpha beta WT). In the alpha beta A/K-alpha beta delta CT hybrid insulin receptor, insulin stimulated a 20-fold increase in intramolecular beta subunit trans-phosphorylation, whereas cis-phosphorylation increased only 3-fold over the basal state. Similarly, in the alpha beta WT-alpha beta A/K.delta CT hybrid insulin receptor, insulin stimulated trans-phosphorylation approximately 30-fold and cis-phosphorylation only 3-fold over the basal state. Although cis-phosphorylation of the kinase-functional alpha beta half-receptor was observed within these hybrid receptor species, this was not sufficient to stimulate exogenous substrate kinase activity. These data demonstrate that insulin primarily activates an intramolecular beta subunit trans-phosphorylation reaction within the insulin holoreceptor and suggest that this reaction is necessary for activation of the holoreceptor. Furthermore, our results suggest a molecular basis for the dominant-negative phenotype observed in insulin-resistant patients possessing one kinase-defective insulin receptor allele.     

Insulin-stimulated Interaction between insulin receptor substrate 1 and p85alpha and activation of protein kinase B/Akt require Rab5

Binding of insulin to the insulin receptor initiates a cascade of protein phosphorylation and effector recruitment events leading to the activation of multiple distinct signaling pathways. Previous studies suggested that the diversity and specificity of insulin signal transduction are accomplished by both subcellular localization of receptor and the selective activation of downstream signaling molecules. The small GTPase Rab5 is a key regulator of endocytosis. Three Rab5 isoforms (Rab5a, -5b, and -5c) have been identified. Here we exploited the RNA interference technique to specifically knock down individual Rab5 isoforms to determine the cellular function of Rab5 in distinct insulin signaling pathways. Small interference RNA against a single Rab5 isoform had no effect on protein kinase B (PKB)/Akt or MAPK activation by insulin in NIH3T3 cells overexpressing human insulin receptor. However, simultaneous knockdown of all three Rab5 isoforms dramatically attenuated PKB/Akt activation by insulin without affecting MAPK activation. This inhibition of PKB/Akt activation was because of the impaired interaction between insulin receptor substrate 1 and the p85alpha subunit of phosphatidylinositol 3-kinase. These results indicate a requirement of Rab5 in presenting p85 to insulin receptor substrate 1. Additional evidence supporting a role for Rab5 was suggested by studies with GAPex-5, a vps9 domain containing exchange factor. Down-regulation of GAPex-5 impaired insulin-stimulated PKB/Akt activation. Collectively, this study indicates the involvement of Rab5 in insulin signaling.     

Intramolecular subunit interactions between insulin and insulin-like growth factor 1 alpha beta half-receptors induced by ligand and Mn/MgATP binding.

We have previously demonstrated that isolated insulin and IGF-1 alpha beta half-receptors can be reconstituted into a functional alpha 2 beta 2 hybrid receptor complex [Treadway et al. (1989) J. Biol. Chem. 264, 21450-21453]. In the present study, we have examined this assembly process by determining the effect of ligand occupancy and Mn/MgATP binding on the dimerization of mutant and wild-type insulin and IGF-1 alpha beta half-receptors. IGF-1 or Mn/MgAMPPCP binding to wild-type IGF-1 alpha beta half-receptors resulted in the specific assembly of the alpha beta half-receptors into an alpha 2 beta 2 heterotetrameric IGF-1 holoreceptor complex. Similarly, insulin binding to the kinase-deficient mutant (A/K1018) insulin alpha beta half-receptor also resulted in the specific assembly into an alpha 2 beta 2 holoreceptor complex. In contrast, Mn/MgAMPPCP treatment of A/K1018 mutant insulin alpha beta half-receptors did not induce heterotetramer assembly, consistent with the inability of this mutant receptor to bind ATP. The ability of the insulin alpha beta receptors to assemble with the IGF-1 alpha beta half-receptors was used to examine the intermolecular subunit interactions responsible for dimerization. In the presence of Mn/MgAMPPCP, the wild-type insulin and wild-type IGF-1 alpha beta half-receptors were observed to assemble into an insulin/IGF-1 alpha 2 beta 2 hybrid receptor complex. Similarly, a combination of insulin and IGF-1 induced hybrid receptor formation between wild-type IGF-1 and A/K1018 mutant insulin alpha beta half-receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preferential degradation of the beta subunit of purified insulin receptor. Effect on insulin binding and protein kinase activities of the receptor

Collagenase preparations (a mixture of enzymes including collagenase, clostripain, and a casein-degrading protease) degraded the beta subunit (Mr = 95,000) of the purified insulin receptor into fragments of Mr less than 15,000, without degrading the alpha subunit. The resulting beta-digested insulin receptor preparations were found to bind insulin as well as control insulin receptor, as assessed by either cross-linking of 125I-insulin to the digested receptor or by separating insulin bound to receptor from free insulin by high performance liquid chromatography. Moreover, the beta-digested insulin receptor preparations were still precipitated by a monoclonal antibody directed against the insulin-binding site. In contrast, the beta-digested insulin receptor lacked protein kinase activity since it no longer phosphorylated either itself, or an exogenous substrate, calf thymus histone. These results support the identification of the beta subunit of the insulin receptor as a protein kinase.     

Monoclonal antibodies mimic insulin activation of ribosomal protein S6 kinase without activation of insulin receptor tyrosine kinase. Studies in cells transfected with normal and mutant human insulin receptors

The effects of species-specific monoclonal antibodies to the human insulin receptor on ribosomal protein S6 phosphorylation were studied in rodent cell lines transfected with human insulin receptors. First, Swiss mouse 3T3 fibroblasts expressing normal human insulin receptors (3T3/HIR cells) were studied. Three monoclonal antibodies, MA-5, MA-20, and MA-51, activated S6 kinase in these cells but had no effects in untransfected 3T3 cells. Both insulin and MA-5, the most potent antibody, activated S6 kinase in a similar time- and dose-dependent manner. To measure S6 phosphorylation in vivo, 3T3/HIR cells were preincubated with [32P]Pi and treated with insulin and MA-5. Both agents increased S6 phosphorylation, and their tryptic phosphopeptide maps were similar. MA-5 and the other monoclonal antibodies, unlike insulin, failed to stimulate insulin receptor tyrosine kinase activity either in vitro or in vivo. Moreover, unlike insulin, they failed to increase the tyrosine phosphorylation of the endogenous cytoplasmic protein, pp 185. Next, HTC rat hepatoma cells, expressing a human insulin receptor mutant that had three key tyrosine autophosphorylation sites in the beta-subunit changed to phenylalanines (HTC-IR-F3 cells), were studied. In this cell line but not in untransfected HTC cells, monoclonal antibodies activated S6 kinase without stimulating either insulin receptor autophosphorylation or the tyrosine phosphorylation of pp 185. These data indicate, therefore, that monoclonal antibodies can activate S6 kinase and then increase S6 phosphorylation. Moreover, they suggest that activation of receptor tyrosine kinase and subsequent tyrosine phosphorylation of cellular proteins may not be crucial for activation of S6 kinase by the insulin receptor.     

Cross-talk between tyrosine kinase and G-protein-linked receptors. Phosphorylation of beta 2-adrenergic receptors in response to insulin.

Protein kinases play a pivotal role in the propagation and modulation of transmembrane signaling pathways. Two major classes of receptors, G-protein-linked and tyrosine kinase receptors not only propagate signals but also are substrates for phosphorylation in response to stimulation by agonist ligands. Insulin (operating via tyrosine kinase receptors) and catecholamines (operating by G-protein-linked receptors) are counterregulatory with respect to lipid and carbohydrate metabolism. How, on a cellular level, these two distinct classes of receptors may cross-regulate each other remains controversial. In the present work we identify a novel cross-talk between members of two distinct classes of receptors, tyrosine kinase (insulin) and G-protein-linked (beta-adrenergic) receptors. Treatment of DDT1 MF-2 hamster vas deferens smooth muscle cells with insulin promoted a marked attenuation (desensitization) of beta-adrenergic receptor-mediated activation of adenylylcyclase. Measured by immune precipitation of beta 2-adrenergic receptors from cells metabolically labeled with [32P]orthophosphate, the basal state of receptor phosphorylation was increased 2-fold by insulin. Phosphoamino acid analysis revealed that for insulin-stimulated cells, the beta 2-adrenergic receptors showed increased phosphorylation on tyrosyl and decreased phosphorylation on threonyl residues. Phosphorylation of the beta-adrenergic receptor was rapid and peaked at 30 min following stimulation of cells by insulin. beta-Adrenergic receptor phosphorylation and attenuation of catecholamine-sensitive adenylylcyclase provide a biochemical basis for the counterregulatory effects of insulin upon catecholamine action.     

Tyrosine phosphorylation of I-kappa B kinase alpha/beta by protein kinase C-dependent c-Src activation is involved in TNF-alpha-induced cyclooxygenase-2 expression

The signaling pathway involved in TNF-alpha-induced cyclooxygenase-2 (COX-2) expression was further studied in human NCI-H292 epithelial cells. A protein kinase C (PKC) inhibitor (staurosporine), tyrosine kinase inhibitors (genistein and herbimycin A), or a Src kinase inhibitor (PP2) attenuated TNF-alpha- or 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced COX-2 promoter activity. TNF-alpha- or TPA-induced I-kappaB kinase (IKK) activation was also blocked by these inhibitors, which reversed I-kappaBalpha degradation. Activation of c-Src and Lyn kinases, two Src family members, was inhibited by the PKC, tyrosine kinase, or Src kinase inhibitors. The dominant-negative c-Src (KM) mutant inhibited induction of COX-2 promoter activity by TNF-alpha or TPA. Overexpression of the constitutively active PKCalpha (PKCalpha A/E) or wild-type c-Src plasmids induced COX-2 promoter activity, and these effects were inhibited by the dominant-negative c-Src (KM), NF-kappaB-inducing kinase (NIK) (KA), or IKKbeta (KM) mutant. The dominant-negative PKCalpha (K/R) or c-Src (KM) mutant failed to block induction of COX-2 promoter activity caused by wild-type NIK overexpression. In coimmunoprecipitation experiments, IKKalpha/beta was found to be associated with c-Src and to be phosphorylated on its tyrosine residues after TNF-alpha or TPA treatment. Two tyrosine residues, Tyr(188) and Tyr(199), near the activation loop of IKKbeta, were identified to be crucial for NF-kappaB activation. Substitution of these residues with phenylalanines attenuated COX-2 promoter activity and c-Src-dependent phosphorylation of IKKbeta induced by TNF-alpha or TPA. These data suggest that, in addition to activating NIK, TNF-alpha also activates PKC-dependent c-Src. These two pathways cross-link between c-Src and NIK and converge at IKKalpha/beta, and go on to activate NF-kappaB, via serine phosphorylation and degradation of IkappaB-alpha, and, finally, to initiate COX-2 expression.     

Integrin alpha 2 beta 1 promotes activation of protein phosphatase 2A and dephosphorylation of Akt and glycogen synthase kinase 3 beta

Serine/threonine kinase Akt is a downstream effector protein of phosphatidylinositol-3-kinase (PI-3K). Many integrins can function as positive modulators of the PI-3K/Akt pathway. Integrin alpha 2 beta 1 is a collagen receptor that has been shown to induce specific signals distinct from those activated by other integrins. Here, we found that, in contrast what was found for cells adherent to fibronectin, alpha 2 beta 1-mediated cell adhesion to collagen leads to dephosphorylation of Akt and glycogen synthase kinase 3 beta (GSK3 beta) and concomitantly to the induction of protein serine/threonine phosphatase 2A (PP2A) activity. PP2A activation can be inhibited by mutation in the alpha 2 cytoplasmic domain and by a function-blocking anti-alpha 2 antibody. Akt can be coprecipitated with PP2A, and coexpression of Akt with PP2Ac (catalytic subunit) inhibits Akt kinase activity. Integrin alpha 2 beta 1-related activation of PP2A is dependent on Cdc42. These results indicate that cell adhesion to collagen modulates Akt activity via the alpha 2 beta 1-induced activation of PP2A.     

Regions of beta 2 and beta 4 responsible for differences between the steady state dose-response relationships of the alpha 3 beta 2 and alpha 3 beta 4 neuronal nicotinic receptors

We constructed chimeras of the rat beta 2 and beta 4 neuronal nicotinic subunits to locate the regions that contribute to differences between the acetylcholine (ACh) dose-response relationships of the alpha 3 beta 2 and alpha 3 beta 4 receptors. Expressed in Xenopus oocytes, the alpha 3 beta 2 receptor displays an EC50 for ACh approximately 20-fold less than the EC50 of the alpha 3 beta 4 receptor. The apparent Hill slope (n(app)) of alpha 3 beta 2 is near one whereas the alpha 3 beta 4 receptor displays an n(app) near two. Substitutions within the first 120 residues convert the EC50 for ACh from one wild-type value to the other. Exchanging just beta 2:104-120 for the corresponding region of beta 4 shifts the EC50 of ACh dose-response relationship in the expected direction but does not completely convert the EC50 of the dose- response relationship from one wild-type value to the other. However, substitutions in the beta 2:104-120 region do account for the relative sensitivity of the alpha 3 beta 2 receptor to cytisine, tetramethylammonium, and ACh. The expression of beta 4-like (strong) cooperativity requires an extensive region of beta 4 (beta 4:1-301). Relatively short beta 2 substitutions (beta 2:104-120) can reduce cooperativity to beta 2-like values. The results suggest that amino acids within the first 120 residues of beta 2 and the corresponding region of beta 4 contribute to an agonist binding site that bridges the alpha and beta subunits in neuronal nicotinic receptors.     

C2 domains of protein kinase C isoforms alpha,beta, and gamma: activation parameters and calcium stoichiometries of the membrane-bound state

The independently folding C2 domain motif serves as a Ca(2+)-dependent membrane docking trigger in a large number of Ca(2+) signaling pathways. A comparison was initiated between three closely related C2 domains from the conventional protein kinase C subfamily (cPKC, isoforms alpha, beta, and gamma). The results reveal that these C2 domain isoforms exhibit some similarities but are specialized in important ways, including different Ca(2+) stoichiometries. In the absence of membranes, Ca(2+) affinities of the isolated C2 domains are similar (2-fold difference) while Hill coefficients reveal cooperative Ca(2+) binding for the PKC beta C2 domain but not for the PKC alpha or PKC gamma C2 domain (H = 2.3 +/- 0.1 for PKC beta, 0.9 +/- 0.1 for PKC alpha, and 0.9 +/- 0.1 for PKC gamma). When phosphatidylserine-containing membranes are present, Ca(2+) affinities range from the sub-micromolar to the micromolar (7-fold difference) ([Ca(2+)](1/2) = 0.7 +/- 0.1 microM for PKC gamma, 1.4 +/- 0.1 microM for PKC alpha, and 5.0 +/- 0.2 microM for PKC beta), and cooperative Ca(2+) binding is observed for all three C2 domains (Hill coefficients equal 1.8 +/- 0.1 for PKC beta, 1.3 +/- 0.1 for PKC alpha, and 1.4 +/- 0.1 for PKC gamma). The large effects of membranes are consistent with a coupled Ca(2+) and membrane binding equilibrium, and with a direct role of the phospholipid in stabilizing bound Ca(2+). The net negative charge of the phospholipid is more important to membrane affinity than its headgroup structure, although a slight preference for phosphatidylserine is observed over other anionic phospholipids. The Ca(2+) stoichiometries of the membrane-bound C2 domains are detectably different. PKC beta and PKC gamma each bind three Ca(2+) ions in the membrane-associated state; membrane-bound PKC alpha binds two Ca(2+) ions, and a third binds weakly or not at all under physiological conditions. Overall, the results indicate that conventional PKC C2 domains first bind a subset of the final Ca(2+) ions in solution, and then associate weakly with the membrane and bind additional Ca(2+) ions to yield a stronger membrane interaction in the fully assembled tertiary complex. The full complement of Ca(2+) ions is needed for tight binding to the membrane. Thus, even though the three C2 domains are 64% identical, differences in Ca(2+) affinity, stoichiometry, and cooperativity are observed, demonstrating that these closely related C2 domains are specialized for their individual functions and contexts.     

Protein kinase CK2: evidence for a protein kinase CK2beta subunit fraction, devoid of the catalytic CK2alpha subunit, in mouse brain and testicles

Apolipoprotein E (apoE), a key lipid transport protein, displays a heparin-binding property that is critical in several apoE functions. The kinetics of the interaction between apoE isoforms and glycosaminoglycans (GAGs) were studied using surface plasmon resonance. The dissociation constant of equilibrium K(D) for apoE3-heparin interaction was estimated to be 12 nM for apoE3 and three common apoE isoforms revealed similar affinities for heparin. ApoE binds to GAGs in the following order: heparin>heparan sulfate>dermatan sulfate>chondroitin sulfate. The affinity parameter of the binding of low molecular weight heparins to apoE is correlated with the chain length. The effective number Z of electrostatic interactions between plasma apoE3 and heparin was assessed to be three. Metal chelators were able to diminish apoE-binding to heparin, suggesting some stabilizing effect of metal ions while reconstitution with lipids did not affect binding affinities for heparin, suggesting that the N-terminal heparin-binding site is responsible for apoE-containing lipoprotein interactions with heparin.     

Crystallographic and solution studies of an activation loop mutant of the insulin receptor tyrosine kinase: insights into kinase mechanism

The tyrosine kinase domain of the insulin receptor is subject to autoinhibition in the unphosphorylated basal state via steric interactions involving the activation loop. A mutation in the activation loop designed to relieve autoinhibition, Asp-1161 --> Ala, substantially increases the ability of the unphosphorylated kinase to bind ATP. The crystal structure of this mutant in complex with an ATP analog has been determined at 2.4-A resolution. The structure shows that the active site is unobstructed, but the end of the activation loop is disordered and therefore the binding site for peptide substrates is not fully formed. In addition, Phe-1151 of the protein kinase-conserved DFG motif, at the beginning of the activation loop, hinders closure of the catalytic cleft and proper positioning of alpha-helix C for catalysis. These results, together with viscometric kinetic measurements, suggest that peptide substrate binding induces a reconfiguration of the unphosphorylated activation loop prior to the catalytic step. The crystallographic and solution studies provide new insights into the mechanism by which the activation loop controls phosphoryl transfer as catalyzed by the insulin receptor.     

GABAA receptors display association of gamma 2-subunit with alpha 1- and beta 2/3-subunits.

Recombinant GABAA (gamma-aminobutyrate-Type A) receptors that are sensitive to benzodiazepine receptor ligands can be generated by coexpression of alpha-, beta-, and gamma 2-subunit cDNAs (Pritchett, D. B., Sontheimer, H., Shivers, B. D., Ymer S., Kettenmann, H., Schofield, P. R., and Seeburg, P. H. (1989) Nature 338, 582-585; Pritchett, D. B., Lüddens, H., and Seeburg, P. H. (1989) Science 245, 1389-1392; Malherbe, P., Sigel, E., Baur, R., Perssohn, E., Richards, J. G., and Mohler, H. (1990) J. Neurosci. 10, 2330-2337). However, in brain tissue, only alpha- and beta-subunit proteins have so far been detected. To identify the size and distribution of the gamma 2-subunit protein in brain tissue, polyclonal antibodies were prepared against two synthetic peptides corresponding to amino acids 1-15 and 336-350 of the cDNA-derived rat gamma 2-subunit sequence. On Western blots, both anti-gamma 2-subunit antisera selectively labeled a 43-kDa protein. gamma 2-Subunit immunoreactivity was detected immunohistochemically in various brain regions, e.g. in the olfactory bulb, cerebral cortex, islands of Calleja, hippocampus, substantia nigra, and cerebellum. Immunoprecipitation with both antisera identified the gamma 2-subunit immunoreactivity in 40 and 50% of the native GABAA receptors purified from bovine and rat brains, respectively. Monoclonal antibody bd24 selectively recognizes the alpha 1-subunit, whereas bd17 recognizes both the beta 2- and beta 3-subunits (Ewert, M., Shivers, B. D., Lüddens, H., Mohler, H., and Seeburg, P. H. (1990) J. Cell Biol. 110, 2043-2048). Since either of these monoclonal antibodies (bd17 and bd24) precipitated approximately 90% of the GABAA receptors, the gamma 2-subunit is frequently associated with the alpha 1-subunit and the beta 2- and/or beta 3-subunit in vivo.     

Physical interaction between interleukin-12 receptor beta 2 subunit and Jak2 tyrosine kinase: Jak2 associates with cytoplasmic membrane-proximal region of interleukin-12 receptor beta 2 via amino-terminus

IL-12 is a heterodimeric cytokine, composed of p40 and p35 subunits, that exerts its biological effects by binding to specific cell surface receptors. Two human IL-12 receptor proteins, designated IL-12R beta 1 and IL-12R beta 2, have been previously identified. IL-12R beta 2 has box 1 motif, box 2 motif, and three tyrosine residues in its cytoplasmic domain. In response to IL-12, Jak2 and Tyk2, family members of Janus family protein tyrosine kinases, are phosphorylated in PHA-activated T lymphocytes. The present study demonstrates that Jak2 binds to the cytoplasmic membrane-proximal region of IL-12R beta 2, and box 2 motif and tyrosine residues in the cytoplasmic domain were not required for binding. The amino-terminus of Jak2 is necessary for association with IL-12R beta 2.     

A novel integrin beta subunit is associated with the vitronectin receptor alpha subunit (alpha v) in a human osteosarcoma cell line and is a substrate for protein kinase C.

We demonstrate that a novel integrin beta subunit is present in association with the vitronectin receptor (VNR) alpha subunit on the surface of MG-63 human osteosarcoma cells. This beta subunit and the glycoprotein IIIa beta subunit (beta 3) were both found complexed with VNR alpha on MG-63 cells and in at least two other human cell types we examined. Tryptic peptide mapping indicated that the two beta subunits are related but distinct. The novel beta chain, referred to here as beta s, was not recognized by the monoclonal antibody AP3, which recognizes GPIIIa, nor by an antiserum raised against a peptide from the COOH-terminal cytoplasmic domain of beta 3. Both receptor complexes bound to and were specifically eluted from a column containing the cell adhesion peptide GRGDSP. The unique beta subunit became phosphorylated at high stoichiometry when MG-63 cells or AG1523 human fibroblasts were treated with the phorbol-ester tumor promoter phorbol 12-myristate 13-acetate. This phosphorylation occurred mainly on serine and probably at one major site, as determined by phosphotryptic peptide mapping. Protein kinase C phosphorylated the beta s subunit of intact receptor in vitro, at the same site phosphorylated in treated cells, indicating that protein kinase C is likely to be responsible for this phosphorylation in vivo.