Functional and immunological distinction between insulin-like growth factor I receptor subtypes in KB cells.

Subtypes of insulin-growth factor I (IGF-I) receptors, including hybrid receptors containing insulin receptor alpha beta dimers associated with IGF-I receptor alpha beta dimers, have been described in a number of systems. The molecular basis of the multiple subtypes and their functional significance is not understood. Ligand-dependent phosphorylation of insulin and IGF-I receptors and immunoprecipitation with antipeptide and monoclonal antibodies have been used to characterize the subpopulations of these receptors in the human KB cell line. IGF-I receptors exhibit beta subunits of 95 and 102 kDa in these cells. IGF-I receptors containing 102-kDa beta subunits are immunoprecipitated by the IGF-I receptor-specific antibody alpha-IR3. Antibody alpha-IR3 does not appear to recognize a hybrid receptor in these cells. However, an antipeptide antibody against the carboxyl-terminal domain of the insulin receptor (AbP5) immunoprecipitates a population of receptors phosphorylated in response to IGF-I (1 nM) which contains both 95- and 102-kDa beta subunits. These receptors must be hybrid complexes because AbP5 does not recognize the 102-kDa beta subunit directly. The inability of antibody alpha-IR3 to recognize these complexes suggests that their IGF-I receptor alpha subunits must differ from typical IGF-I receptor alpha subunits either in primary sequence or conformation. Therefore, KB cells may contain more than one type of IGF-I receptor alpha subunit. Hybrid IGF-I receptors can also be distinguished from homotypic IGF-I receptors by their responsiveness to IGF-II. Stimulation of autophosphorylation in hybrid IGF-I receptors by IGF-I is 3-4-fold greater than that seen in response to IGF-II. In contrast, IGF-I and IGF-II are nearly equipotent in stimulating autophosphorylation in the alpha-IR3-reactive receptor population. This suggests the existence of functionally distinct receptor subtypes which may differ in their ability to mediate the biological effects of IGF-II.     

Comparison of insulin-like growth factor I receptor and insulin receptor purified from human placental membranes

Insulin-like growth factor (IGF)-I receptor purified from human placental membranes as previously described (LeBon, T. R., Jacobs, S., Cuatrecasas, P., Kathuria, S., and Fujita-Yamaguchi, Y. (1986) J. Biol. Chem. 261, 7685-7689) was characterized. The IGF-I receptor was similar to the insulin receptor with respect to subunit structure (beta-alpha-alpha-beta), apparent sizes of deglycosylated alpha (Mr = approximately 88,000) and beta (Mr = approximately 67,000) subunits, and amino acid composition of the subunits. Monoclonal antibody specific to each receptor recognized its own receptor whereas polyclonal anti-human insulin receptor antibody cross-reacted with the IGF-I receptor, indicating that the receptors share one or more antigenic sites. Further characterization of the purified IGF-I receptor tyrosine-protein kinase activity indicated that by analogy with the insulin receptor the monomeric alpha beta form of the IGF-I receptor appears to have higher kinase activity than the intact receptor in the alpha 2 beta 2 form. The most significant difference between the two receptors was found in the N-terminal amino acid sequences of their alpha subunits, which apparently show 60% identity. The IGF-I receptor alpha subunit lacks residues corresponding to the N-terminal 4 amino acids of the insulin receptor alpha subunit. These results provide the first direct proof that the IGF-I receptor is a molecule distinct from the insulin receptor despite numerous similarities.     

Subunit structure and dynamics of the insulin receptor

A model for the minimum subunit composition and stiochiometry of the physiologically relevant insulin receptor has been deduced based on results obtained by affinity labeling of this receptor in a variety of cell types and species. We propose that the receptor is a symmetrical disulfide-linked heterotetramer composed of two alpha (apparent Mr = 125,000) and two beta (apparent Mr = 90,000) glycoprotein subunits in the configuration (beta-S-S-alpha)-S-S-(alpha-S-S-beta). The disulfide or disulfides linking the two (alpha-S-S-beta) halves (class I disulfides) exhibit greater sensitivity to reduction by exogenous reductants than those linking the alpha and beta subunits (class II disulfides). When the class I disulfides are reduced by addition of diothiothreitol to intact cells, the receptor retains its ability to bind insulin and to effect a biological response. The beta subunit contains a site at about the center of its amino acid sequence that is extremely sensitive to proteolytic cleavage by elastaselike proteases, yielding a beta 1 fragment (Mr = 45,000) that remains disulfide linked to the receptor complex and a free beta 2 fragment. Binding of insulin to the receptor complex appears to result in the formation or stabilization of a new receptor conformation as evidenced by an altered susceptibility of the alpha subunit to exogenous trypsin. A receptor structure with high affinity for insulinlike growth factor (IGF) I and low affinity for insulin in fibroblast and placental membranes has also been affinity labeled. It exhibits the same structural features found for the insulin receptor, including two classes of disulfide bridges and beta subunits highly sensitive to proteolytic cleavage. These recent observations identifying the presence of distinct insulin and IGF-I receptors that share similar complex structures suggest that these hormones may also share common mechanisms of transmembrane signaling.     

The insulin-binding domain of insulin receptor is encoded by exon 2 and exon 3.

Insulin receptors are disulfide-linked oligotetramers composed of two heterodimers each containing a 130-kDa alpha subunit and a 90-kDa beta subunit. Insulin binds to the extracellular alpha subunit, and in the process stimulates the autophosphorylation of the beta subunit and the expression of tyrosine kinase activity. Studies combining the use of photoaffinity labeling and immunoprecipitation with anti-peptide antibody have directly demonstrated that the cysteine-rich domain, encoded by exon 3, in the alpha subunit is part of the insulin-binding site of the receptor. Experiments with chimeric insulin receptors and chimeric insulin-like growth factor I receptors have confirmed that the cysteine-rich domain constitutes a part of the insulin-binding site. In addition, results from these experiments suggest that the N-terminal sequence, encoded by exon 2, in the alpha subunit also participates in insulin binding. In this review it is proposed that, assuming two insulin-binding sites per each holoreceptor oligotetramer, each insulin-binding domain may contain respectively two sub-domains for hydrophobic and charge contact with insulin, and that high-affinity binding would require the interaction of both subunits with the possibility of each subunit reciprocally contributing one of the sub-domains.     

Purification and characterization of the receptor for insulin-like growth factor I

The receptor for insulin-like growth factor I (IGF-I) was purified from the rat liver cell line BRL-3A by a combination monoclonal anti-receptor antibody column and a wheat germ agglutinin column. Analyses of these receptor preparations on reduced sodium dodecyl sulfate-polyacrylamide gels yielded protein bands of Mr 136K (alpha subunit) and Mr 85K and 94K (beta subunit). These receptor preparations bound 5 times more IGF-I than insulin, and the binding of both labeled ligands was more potently inhibited by unlabeled IGF-I than by insulin. These results indicate that these receptor preparations contained predominantly the IGF-I receptor. This highly purified receptor preparation was found to possess an intrinsic kinase activity; autophosphorylation of the receptor beta subunit was stimulated by low concentrations of IGF-I (half-maximal stimulation at 0.4 nM IGF-I). Twentyfold higher concentrations of insulin were required to give comparable levels of stimulation. A monoclonal antibody that inhibits the insulin receptor kinase was found to inhibit the IGF-I receptor kinase with the same potency with which it inhibits the insulin receptor. In contrast, monoclonal antibodies to other parts of the insulin receptor only poorly recognized the IGF-I receptor. A comparison of V8 protease digests of the insulin and IGF-I receptors again revealed some similarities and also some differences in the structures of these two receptors. Thus, the IGF-I receptor is structurally, antigenically, and functionally similar to but not identical with the insulin receptor.     

Cys 786 and Cys 776 in the posttranslational processing of the insulin and IGF-I receptors

The extracellular regions of insulin and IGF-I receptors (IR and IGF-IR) contain fibronectin type III repeats with cysteine residues potentially involved in S==S bond. In this report we show that Cys 786 in the IR and the corresponding Cys 776 in the IGF-IR regulate proreceptor dimerization with high specificity. Both C786S insulin and C776S IGF-I proreceptors reach the monomeric 210-kDa step, but do not proceed further. Mature IR(C786S) and IGF-IR(C776S) expression on plasmamembrane is abolished. No retention of C786S IR precursor was detected in the endoplasmic reticulum, which is degraded by a nonlysosomal mechanism. The rearrangement of the remaining cysteines in the insulin receptor beta subunit ectodomain does not rescue dimerization of C786S insulin proreceptor. As observed in other transmembrane receptors, iuxtamembrane cysteines, specifically Cys 786 in the IR and Cys 776 in the IGF-IR, are critical for correct processing of proreceptors.     

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.     

The insulin receptor. Structural basis for high affinity ligand binding

Treatment of the soluble insulin receptor from human placenta with 1.25 mM dithiothreitol and 75 mM Tris at pH 8.5 results in complete reduction of interhalf disulfide bonds (class 1 disulfides) and dissociation of the tetrameric receptor into the dimeric alpha beta form. The alpha beta receptor halves exhibit a reduced affinity for insulin binding (B?ni-Schnetzler, M., Rubin, J. B., and Pilch, P. F. (1986) J. Biol. Chem. 261, 15281-15287). Kinetic experiments reveal that reduction of class 1 disulfides is a faster process than the loss of affinity for ligand, indicating that events subsequent to reduction of interhalf disulfides are responsible for the affinity change. We show that a third class of alpha subunit intrachain disulfides is more susceptible to reduction at pH 7.6 than at pH 8.5 and appears to form part of the ligand binding domain. Reduction of the intrachain disulfide bonds in this part of the alpha subunit leads to a loss of insulin binding. Modification of this putative binding domain by dithiothreitol can be minimized if reduction is carried out at pH 8.5. When the insulin receptor in placental membranes is reduced at pH 8.5, the receptor's affinity for insulin is not changed when binding is measured in the membrane. However, the Kd for insulin binding is reduced 10-fold when alpha beta receptor halves are subsequently solubilized. Scatchard analysis of insulin binding to reduced or intact receptors in the membrane and in soluble form together with sucrose density gradient analysis of soluble receptors suggests that alpha beta receptor halves remain associated in the membrane after reduction, but they are dissociated upon solubilization. We interpret these results to mean that the association of two ligand binding domains, 2 alpha beta receptor halves, is required for the formation of an insulin receptor with high affinity for ligand.     

Insulin-like growth factor I receptor beta-subunit heterogeneity. Evidence for hybrid tetramers composed of insulin-like growth factor I and insulin receptor heterodimers

In both NIH3T3 cells and HepG2 cells, insulin-like growth factor I (IGF-I) receptors possess two beta-subunits that display different electrophoretic mobilities. Increasing concentrations of IGF-I stimulated the phosphorylation of both beta-subunits to a similar extent, whereas insulin stimulated the phosphorylation of both subunits only at elevated concentrations. Both beta-subunits were immunoprecipitated with p5, an insulin receptor-specific anti-peptide antibody, or with A410, a polyclonal anti-insulin receptor antisera. However, if the tetrameric IGF-I receptor was first dissociated into alpha-beta heterodimers with 1 mM dithiothreitol, only the lower molecular weight beta-subunit was immunoprecipitated. These results suggested that p5 and A410 specifically recognized the lower molecular weight beta-subunit but immunoprecipitated the higher molecular weight beta-subunit because it was present in the same disulfide linked tetramer. Similarly, alpha-IR-3, an antibody specific for the alpha-subunit of the IGF-I receptor, immunoprecipitated both types of beta-subunit from the intact tetramer but only the higher molecular weight beta-subunit from the dissociated heterodimers, suggesting that there are two types of alpha-subunits in the same tetramer and that the alpha-subunit recognized by alpha-IR-3 is only associated with the higher molecular weight beta-subunit. Tryptic phosphopeptide maps of the lower molecular weight beta-subunit of IGF-I receptor were different from the higher molecular weight beta-subunit, but were similar to those of the insulin receptor beta-subunit. Thus, by immunochemical cross-reactivity and structural criteria, the lower molecular weight beta-subunit of the IGF-I receptor was similar to the beta-subunit of insulin receptor. These data suggest that there exists a species of IGF-I receptor that is a hybrid composed of an insulin receptor alpha-beta heterodimer and an IGF-I receptor alpha-beta heterodimer. The existence of such a hybrid receptor could have important functional consequences.     

Urea treatment allows dithiothreitol to release the binding subunit of the insulin receptor from the cell membrane: implications for the structural organization of the insulin receptor

The sequence of the human insulin receptor has only one identifiable transmembrane region which is located in the beta subunit. The structure predicts that the alpha subunit, which binds insulin, is attached to the cell only by disulfide bonds to the beta subunit. However, treatment of membranes with dithiothreitol is ineffective at releasing the alpha subunit. If the receptor structure is unfolded with urea, dithiothreitol is able to release the alpha subunit. These data provided confirmatory evidence that the alpha subunit is not a transmembrane protein.     

Antisense suppression of GABA(A) receptor beta subunit levels in cultured cerebellar granule neurons demonstrates their importance in receptor expression

GABA(A) receptors in the CNS are pentameric molecules composed of alpha, beta, gamma, delta, epsilon and theta subunits. Studies on transfected cells have shown that GABA(A) receptor beta subunit isoforms can direct alpha1 subunit localization within the cell. To examine the role of selected subunits in governing GABA(A) receptor expression in neurons, cultures of rat cerebellar granule cells were grown with antisense or sense oligodeoxynucleotides (ODNs) specific for the alpha 1, beta 2 or gamma 2 subunits. These subunits are all expressed in granule neurons where they are thought to contribute to an abundant receptor type. Following ODN treatment, subunit expression and distribution were examined by western blotting, immunocytochemistry and RT-PCR. Treatment of the cultures with the antisense, but not the corresponding sense, ODNs reduced the levels of the targeted subunit polypeptides. In addition, the beta 2 antisense ODN reduced the level of the alpha1 subunit polypeptide without altering the level of its mRNA. In contrast, treatment with the beta 2 subunit antisense ODN did not alter gamma 2 subunit polypeptide expression, distribution or mRNA level. These findings suggest that the alpha1 subunit requires a beta subunit for assembly into GABA(A) receptors in cerebellar granule neurons.     

Substructural analysis of the insulin receptor by microsequence analyses of limited tryptic fragments isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the absence or presence of dithiothreitol

Human placental insulin receptor contains 47 Cys per an alpha beta dimer. Most of the 94 Cys in an intact alpha 2 beta 2 receptor are expected to form interchain or intrachain disulfide bonds, since there appears to be only one free cysteine residue in each beta subunit. In order to gain more insight into the three-dimensional organization of the insulin receptor, we have used limited trypsin digestion, SDS-PAGE, and protein microsequencing. The present study revealed the following; major tryptic cleavages occurred at alpha 164, alpha 270, alpha 582, and beta 1115, generating Mr 175,000, 130,000, 100,000, 70,000, and 55,000 disulfide-linked complexes. Under reducing conditions, tryptic fragments of Mr values = 30,000, 70,000, 20,000, 55,000, and 20,000 were identified to be alpha(1-164), alpha(165-582), alpha(165-270), alpha(271-582), and alpha(583-C-terminal), respectively. The major beta subunit tryptic fragment of Mr = 55,000 was assumed to have beta(724-1115) or beta(N-terminal-392). The Mr 175,000 complex appeared to contain two alpha(1-164) and two alpha(165-582), whereas the Mr 70,000 complex contained alpha(583-C-terminal) and beta(724-1115). Tryptic cleavage at alpha 582 apparently produced one Mr 175,000 and two Mr 70,000 complexes, suggesting that the alpha(583-C-terminal) domain interacts with the extracellular domain of the beta subunit by disulfide bonds. Tryptic cleavage at alpha 270 resulting in a formation of one Mr 100,000 complex consisting of two alpha(1-270) and two Mr 130,000 complexes consisting of alpha(271-C-terminal) and beta(724-1115) suggests that Cys residues involved with disulfide bonds between the two alpha subunits are located in the alpha(1-270) domain. The identification of the Mr 55,000 complex consisting of small tryptic fragments between alpha(122-270) indicates that 40 Cys residues in the two alpha(122-270) domains are inter- and intramolecularly associated by disulfide bonds. The alpha(1-121) domain does not appear to be linked to any other domains by disulfide bonds. These results are consistent with the structural model that the N-terminal domains of alpha subunits (122-270) are disulfide-linked together while the C-terminal domain (583-C-terminal) of the alpha subunit is linked to the N-terminal domain of the beta subunit by disulfide bonds.     

Phosphorylation of the insulin receptor by casein kinase I

Insulin receptor was examined as a substrate for the multipotential protein kinase casein kinase I. Casein kinase I phosphorylated partially purified insulin receptor from human placenta as shown by immunoprecipitation of the complex with antiserum to the insulin receptor. Analysis of the phosphorylated complex by polyacrylamide gel electrophoresis under nonreducing conditions showed a major phosphorylated band at the position of the alpha 2 beta 2 complex. When the phosphorylated receptor was analyzed on polyacrylamide gels under reducing conditions, two phosphorylated bands, Mr 95,000 and Mr 135,000, were observed which corresponded to the alpha and beta subunits. The majority of the phosphate was associated with the beta subunit with minor phosphorylation of the alpha subunit. Phosphoamino acid analysis revealed that casein kinase I phosphorylated only seryl residues. The autophosphorylated alpha 2 beta 2 receptor purified by affinity chromatography on immobilized O-phosphotyrosyl binding antibody was also a substrate for casein kinase I. Reduction of the phosphorylated alpha 2 beta 2 receptor indicated that casein kinase I incorporated phosphate into seryl residues only in the beta subunit.     

Insulin/IGF-1 hybrid receptors: implications for the dominant-negative phenotype in syndromes of insulin resistance.

Classical insulin and IGF-1 receptors are alpha 2 beta 2 heterotetrameric complexes synthesized from two identical alpha beta half-receptor precursors. Recent data strongly suggests, however, that nonidentical alpha beta half-receptor precursors can assemble to generate hybrid holoreceptor species both in vivo and in vitro. This review focuses primarily on two types of hybrid receptors. The first type is an insulin/IGF-1 hybrid receptor generated by the association of an alpha beta insulin half-receptor with an alpha beta IGF-1 half-receptor. The second type is one formed from a wildtype (kinase-active) insulin or IGF-1 alpha beta half-receptor and a mutant (kinase-inactive) insulin alpha beta half-receptor. Although the functional properties of insulin/IGF-1 hybrid receptors have not yet been completely defined, wildtype/mutant hybrid receptors are essentially substrate kinase inactive. These data indicate that the mutant alpha beta half-receptor exerts a transdominant inhibition upon the wildtype alpha beta half-receptor within the alpha 2 beta 2 holoreceptor complex. This defect in substrate kinase activity may contribute to the molecular defect underlying some syndromes of severe insulin resistance and diabetes. Heterozygous individuals expressing both wildtype and mutant tyrosine kinase-defective insulin receptor precursors demonstrate varying degrees of insulin resistance and diabetes. In addition, cell lines which express both endogenous wildtype and transfected kinase-defective insulin receptors display markedly decreased insulin and IGF-1 sensitivity and responsiveness. Formation of hybrid receptors which results in premature termination of insulin signal transduction may be one mechanism underlying the observation that kinase-inactive receptors inhibit the function of native receptors.     

Amino acid sequence of the human fibronectin receptor

The amino acid sequence deduced from cDNA of the human placental fibronectin receptor is reported. The receptor is composed of two subunits: an alpha subunit of 1,008 amino acids which is processed into two polypeptides disulfide bonded to one another, and a beta subunit of 778 amino acids. Each subunit has near its COOH terminus a hydrophobic segment. This and other sequence features suggest a structure for the receptor in which the hydrophobic segments serve as transmembrane domains anchoring each subunit to the membrane and dividing each into a large ectodomain and a short cytoplasmic domain. The alpha subunit ectodomain has five sequence elements homologous to consensus Ca2+-binding sites of several calcium-binding proteins, and the beta subunit contains a fourfold repeat strikingly rich in cysteine. The alpha subunit sequence is 46% homologous to the alpha subunit of the vitronectin receptor. The beta subunit is 44% homologous to the human platelet adhesion receptor subunit IIIa and 47% homologous to a leukocyte adhesion receptor beta subunit. The high degree of homology (85%) of the beta subunit with one of the polypeptides of a chicken adhesion receptor complex referred to as integrin complex strongly suggests that the latter polypeptide is the chicken homologue of the fibronectin receptor beta subunit. These receptor subunit homologies define a superfamily of adhesion receptors. The availability of the entire protein sequence for the fibronectin receptor will facilitate studies on the functions of these receptors.     

Insulin-like growth factor I receptors in neuronal and glial cells. Characterization and biological effects in primary culture

Primary cultures of neuronal and glial cells from 1-day-old neonatal rats contain high affinity receptors for insulin-like growth factor I (IGF-I). The IC50 for displacement of 125I-IGF-I binding by unlabeled IGF-I was 3 nM for neuronal cells and 4 nM for glial cells. Unlabeled insulin was 20-50 times less potent. Apparent molecular mass of the alpha subunits of the IGF-I receptor was 125 kDa in neuronal and 135 kDa in glial cells. IGF-I induced autophosphorylation of the IGF-I receptor beta subunit in lectin-purified membrane preparations in a dose-dependent manner. The major phosphoamino acid of the beta subunit in both cell types was tyrosine in the IGF-I-stimulated state and serine in the basal state. Apparent molecular mass of the beta subunits of the IGF-I receptors was 91 kDa for neuronal and 95 kDa for glial cells. Tyrosine kinase activity of the IGF-I receptors was demonstrated by IGF-I-induced phosphorylation of the exogenous substrate poly(Glu, Tyr) 4:1 in both cell types. IGF-I had no effect on 2-deoxyglucose uptake in neuronal cells. In contrast, in glial cells, IGF-I stimulated 2-deoxyglucose uptake at very high doses, presumably acting via the insulin receptor. The effect of IGF-I as a neurotrophic growth factor in both neuronal and glial cells was demonstrated by its stimulation of [3H]thymidine incorporation. These findings suggest the IGF-I is an important growth factor in nervous tissue-derived cells.     

Identification of amino acid residues important for assembly of GABA receptor alpha1 and gamma2 subunits

Comparative models of GABA(A) receptors composed of alpha1 beta3 gamma2 subunits were generated using the acetylcholine-binding protein (AChBP) as a template and were used for predicting putative engineered cross-link sites between the alpha1 and the gamma2 subunit. The respective amino acid residues were substituted by cysteines and disulfide bond formation between subunits was investigated on co-transfection into human embryonic kidney (HEK) cells. Although disulfide bond formation between subunits could not be observed, results indicated that mutations studied influenced assembly of GABA(A) receptors. Whereas residue alpha1A108 was important for the formation of assembly intermediates with beta3 and gamma2 subunits consistent with its proposed location at the alpha1(+) side of GABA(A) receptors, residues gamma2T125 and gamma2P127 were important for assembly with beta3 subunits. Mutation of each of these residues also caused an impaired expression of receptors at the cell surface. In contrast, mutated residues alpha1F99C, alpha1S106C or gamma2T126C only impaired the formation of receptors at the cell surface when co-expressed with subunits in which their predicted interaction partner was also mutated. These data are consistent with the prediction that the mutated residue pairs are located close to each other.     

Similar control mechanisms regulate the insulin and type I insulin-like growth factor receptor kinases. Affinity-purified insulin-like growth factor I receptor kinase is activated by tyrosine phosphorylation of its beta subunit

Insulin-like growth factor I (IGF-I) receptors are partially purified from human placenta by sequential affinity chromatography with wheat germ agglutinin-agarose and agarose derivatized with an IGF-I analog. Adsorption specificity to this affinity matrix demonstrates that low coupling ratios of IGF-I analog to agarose yield preparations that are highly selective in purifying IGF-I receptor with minimal cross-contamination by the insulin receptor present in the same placental extracts. Incubation of the immobilized IGF-I receptor preparation with [gamma-32P]ATP results in a marked phosphorylation of the receptor beta subunits, which appear as a doublet of Mr = 93,000 and 95,000 upon electrophoresis on dodecyl sulfate-polyacrylamide gels. The 32P-labeled receptor beta subunit doublet contains predominantly phosphotyrosine and to a much lesser extent phosphoserine and phosphothreonine residues. The immobilized IGF-I receptor preparation exhibits tyrosine kinase activity toward exogenous histone. The characteristics of the IGF-I receptor-associated tyrosine kinase are remarkably similar to those of the insulin receptor kinase. Thus, prior phosphorylation of the immobilized IGF-I receptor preparation with increasing concentrations of unlabeled ATP followed by washing to remove the unreacted ATP results in a progressive activation of the receptor-associated histone kinase activity. A maximal (10-fold) activation is achieved between 0.25 and 1 mM ATP. The concentration of ATP required for half-maximal (30 microM) activation of the IGF-I receptor kinase is similar to that of the insulin receptor kinase. Like the insulin receptor kinase, the elevated kinase activity of the phosphorylated IGF-I receptor is reversed following dephosphorylation of the receptor beta subunit with alkaline phosphatase. Furthermore, the phosphorylation of the IGF-I receptor beta subunit doublet is enhanced by 7-8-fold when reductant is included in the reaction medium, as is observed for the insulin receptor kinase. Significantly, the dose responses of both receptor types to reductant are identical. Both of the 32P-labeled IGF-I receptor beta subunit bands are resolved into six matching phosphopeptide fractions when the corresponding tryptic hydrolysates are resolved by reverse phase high pressure liquid chromatography. Significantly, four out of the six phosphopeptide fractions derived from the trypsinized IGF-I receptor beta subunits are chromatographically identical to those from the tryptic hydrolysates of 32P-labeled insulin receptor beta subunit.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kainic acid-induced status epilepticus alters GABA receptor subunit mRNA and protein expression in the developing rat hippocampus

Kainic acid-induced status epilepticus leads to structural and functional changes in inhibitory GABAA receptors in the adult rat hippocampus, but whether similar changes occur in the developing rat is not known. We have used in situ hybridization to study status epilepticus-induced changes in the GABAAalpha1-alpha5, beta1-beta3, gamma1 and gamma2 subunit mRNA expression in the hippocampus of 9-day-old rats during 1 week after the treatment. Immunocytochemistry was applied to detect the alpha1, alpha2 and beta3 subunit proteins in the control and treated rats. In the saline-injected control rats, the alpha1 and alpha4 subunit mRNA expression significantly increased between the postnatal days 9-16, whereas those of alpha2, beta3 and gamma2 subunits decreased. The normal developmental changes in the expression of alpha1, alpha2, beta3 and gamma2 subunit mRNAs were altered after the treatment. The immunostainings with antibodies to alpha1, alpha2 and beta3 subunits confirmed the in situ hybridization findings. No neuronal death was detected in any hippocampal subregion in the treated rats. Our results show that status epilepticus disturbs the normal developmental expression pattern of GABAA receptor subunit in the rat hippocampus during the sensitive postnatal period of brain development. These perturbations could result in altered functional and pharmacological properties of GABAA receptors.     

Binding properties of chimeric insulin receptors containing the cysteine-rich domain of either the insulin-like growth factor I receptor or the insulin receptor related receptor.

We constructed and expressed chimeric receptor cDNAs with insulin receptor exon 3 (residues 191-297 of the cysteine-rich region) replaced with either the comparable region of the insulin-like growth factor I receptor (IGF-IR) or the insulin receptor related receptor (IRR). Both chimeric receptors still could bind insulin with as high affinity as the wild-type receptor. In addition, chimeric receptors containing exon 3 of the IGF-IR could also bind with high affinity both IGF-I and IGF-II. In contrast, chimeric receptors containing exon 3 of IRR did not bind either IGF-I, IGF-II, or relaxin. These results indicate that (1) the high affinity of binding of insulin to its receptor can occur in the absence of insulin receptor specific residues encoded by exon 3, the cysteine-rich region; (2) the cysteine-rich region of the IGF-I receptor can confer high-affinity binding to both IGF-I and IGF-II; and 3) the IRR is unlikely to be a receptor for either IGF-I, IGF-II, or relaxin.