Tyrosine dephosphorylation of nuclear proteins mimics transforming growth factor beta 1 stimulation of alpha 2(I) collagen gene expression.

Transforming growth factor beta 1 (TGF-beta 1) exerts a positive effect on the transcription of genes coding for several extracellular matrix-related products, including collagen I. We have previously identified a strong TGF-beta 1-responsive element (TbRE) in the upstream promoter sequence of the alpha 2(I) collagen (COL1A2) gene. Our experiments have shown that TGF-beta 1 stimulates COL1A2 transcription by increasing binding of an Sp1-containing complex (TbRC) to the TbRE. They have also suggested that the change occurs via posttranslational modification of a protein(s) directly or indirectly interacting with Sp1. Here, we provide evidence showing that tyrosine dephosphorylation of nuclear proteins mimics the stimulation of COL1A2 transcription by the TGF-beta 1-activated signaling pathway. Preincubation of nuclear extracts with protein tyrosine phosphatase (PTPase) but not with protein phosphatase type 2A (PP2A), a serine/threonine phosphatase, enhanced binding of the TbRC to the same degree as culturing cells in TGF-beta 1. Consistent with these in vitro findings, genistein, a tyrosine kinase inhibitor, led to markedly increased COL1A2 gene expression, whereas sodium orthovanadate, a tyrosine phosphatase inhibitor, decreased it substantially. These results were supported by transfection experiments showing that genistein and sodium orthovanadate have opposite effects on TbRE-mediated transcription. Moreover, nuclear proteins isolated from genistein-treated cells were found to interact with the TbRE significantly more than those from untreated cells. Furthermore, pretreatment of cells with sodium orthovanadate virtually abrogated nuclear protein binding to the TbRE, but not to a neighboring cis-acting element unresponsive to TGF-beta 1. The results of this study, therefore, provide the first correlation between tyrosine dephosphorylation, increased binding of a transcriptional complex, and TGF-beta 1 stimulation of gene expression.

A binding site for multiple transcriptional activators in the fushi tarazu proximal enhancer is essential for gene expression in vivo.

The Drosophila homeobox gene fushi tarazu (ftz) is expressed in a highly dynamic striped pattern in early embryos. A key regulatory element that controls the ftz pattern is the ftz proximal enhancer, which mediates positive autoregulation via multiple binding sites for the Ftz protein. In addition, the enhancer is necessary for stripe establishment prior to the onset of autoregulation. We previously identified nine binding sites for multiple Drosophila nuclear proteins in a core 323-bp region of the enhancer. Three of these nine sites interact with the same cohort of nuclear proteins in vitro. We showed previously that the nuclear receptor Ftz-F1 interacts with this repeated module. Here we purified additional proteins interacting with this module from Drosophila nuclear extracts. Peptide sequences of the zinc finger protein Ttk and the transcription factor Adf-1 were obtained. While Ttk is thought to be a repressor of ftz stripes, we have shown that both Adf-1 and Ftz-F1 activate transcription in a binding site-dependent fashion. These two proteins are expressed ubiquitously at the time ftz is expressed in stripes, suggesting that either may activate striped expression alone or in combination with the Ftz protein. The roles of the nine nuclear factor binding sites were tested in vivo, by site-directed mutagenesis of individual and multiple sites. The three Ftz-F1-Adf-1-Ttk binding sites were found to be functionally redundant and essential for stripe expression in transgenic embryos. Thus, a biochemical analysis identified cis-acting regulatory modules that are required for gene expression in vivo. The finding of repeated binding sites for multiple nuclear proteins underscores the high degree of redundancy built into embryonic gene regulatory networks.

Intrasteric inhibition of ATP binding is not required to prevent unregulated autophosphorylation or signaling by the insulin receptor.

Receptor tyrosine kinases may use intrasteric inhibition to suppress autophosphorylation prior to growth factor stimulation. To test this hypothesis we made an Asp1161Ala mutant in the activation loop that relieved intrasteric inhibition of the unphosphorylated insulin receptor (IR) and its recombinant cytoplasmic kinase domain (IRKD) without affecting the activated state. Solution studies with the unphosphorylated mutant IRKD demonstrated conformational changes and greater catalytic efficiency from a 10-fold increase in k(cat) and a 15-fold-lower K(m ATP) although K(m peptide) was unchanged. Kinetic parameters of the autophosphorylated mutant and wild-type kinase domains were virtually identical. The Asp1161Ala mutation increased the rate of in vitro autophosphorylation of the IRKD or IR at low ATP concentrations and in the absence of insulin. However, saturation with ATP (for the IRKD) or the presence of insulin (for the IR) yielded equivalent rates of autophosphorylation for mutant versus wild-type kinases. Despite a biochemically more active kinase domain, the mutant IR expressed in C2C12 myoblasts was not constitutively autophosphorylated. However, it displayed a 2.5-fold-lower 50% effective concentration for insulin stimulation of autophosphorylation and was dephosphorylated more slowly following withdrawal of insulin than wild-type IR. In tests of the regulation of the unphosphorylated basal state, these results demonstrate that neither intrasteric inhibition against ATP binding nor suppression of kinase activity is required to prevent premature autophosphorylation of the IR. Finally, the lower rate of dephosphorylation suggests invariant residues of the activation loop such as Asp1161 may function at multiple junctures in cellular regulation of receptor tyrosine kinases.

The promyelocytic leukemia zinc finger (PLZF) protein binds DNA in a high molecular weight complex associated with cdc2 kinase.

A binding site selection from a CpG island library for the promyelocytic leukemia zinc finger protein (PLZF) identified two high affinity PLZF binding sites. These sequences also bound RARalpha/PLZF, a fusion protein formed in chromosomal translocation t(11;17)(q23;q21) associated with acute promyelocytic leukemia. PLZF bound DNA as a slowly migrating complex with an estimated mol. wt of 600 kDa whose formation was dependent on the POZ/dimerization domain of PLZF. The PLZF-DNA complex was unable to form in the presence of cdc2 antibodies. A PLZF-cdc2 interaction was further demonstrated by co-immunoprecipitation and a biotin-streptavidin pull-down assay. PLZF is a phosphoprotein and immunoprecipi-tates with a cdc2-like kinase activity. The PLZF-DNA complex was abolished with the addition of a phosphatase. These studies suggest that the activity of PLZF, a regulator of the cell cycle, may be modulated by cell cycle proteins. RARalpha/PLZF did not complex with cdc2, this potentially contributing to its aberrant transcriptional properties and potential role in leukemo-genesis.

Identification and partial purification of the insulin-responsive glucose transporter from 3T3-L1 adipocytes.

The glucose transporter in 3T3-L1 adipocytes has been identified as a polypeptide of average Mr 51000 by means of its reaction with antibodies raised against the purified human erythrocyte glucose transporter and by photolabeling with [3H]cytochalasin B. The finding that the antibodies immunoprecipitated the photolabeled polypeptide demonstrated that both methods detected the same polypeptide. The 3T3-L1 adipocyte glucose transporter has been partially purified. The main steps in the purification procedure were the preparation of salt-washed cellular membranes, Triton X-100 solubilization, and immunoaffinity chromatography on affinity-purified antibodies against the human erythrocyte transporter. A simple method of affinity purification of these antibodies, which consists of adsorption from serum onto protein-depleted erythrocyte membranes and release with acid, and an assay for the 3T3-L1 adipocyte transporter polypeptide, which employs immunoblotting, have been developed.

A novel small molecule that directly sensitizes the insulin receptor in vitro and in vivo.

Insulin resistance, an important feature of type 2 diabetes, is manifested as attenuated insulin receptor (IR) signaling in response to insulin binding. A drug that promotes the initiation of IR signaling by enhancing IR autophosphorylation should, therefore, be useful for treating type 2 diabetes. This report describes the effect of a small molecule IR sensitizer, TLK16998, on IR signaling. This compound activated the tyrosine kinase domain of the IR beta-subunit at concentrations of 1 micromol/l or less but had no effect on insulin binding to the IR alpha-subunit even at much higher concentrations. TLK16998 alone had no effect on IR signaling in mouse 3T3-L1 adipocytes but, at concentrations as low as 3.2 micromol/l, enhanced the effects of insulin on the phosphorylation of the IR beta-subunit and IR substrate 1, and on the amount of phosphatidylinositol 3-kinase that coimmunoprecipitated with IRS-1. Phosphopeptide mapping revealed that the effect of TLK16998 on the IR was associated with increased tyrosine phosphorylation of the activation loop of the beta-subunit tyrosine kinase domain. TLK16998 also increased the potency of insulin in stimulating 2-deoxy-D-glucose uptake in 3T3-L1 adipocytes, with a detectable effect at 8 micromol/l and a 10-fold increase at 40 micromol/l. In contrast, only small effects were observed on IGF-1-stimulated 2-deoxy-D-glucose uptake. In diabetic mice, TLK16998, at a dose of 10 mg/kg, lowered blood glucose levels for up to 6 h. These results suggest, therefore, that small nonpeptide molecules that directly sensitize the IR may be useful for treating type 2 diabetes.

Conformational changes in the activation loop of the insulin receptor's kinase domain.

Low catalytic efficiency of basal-state protein kinases often depends on activation loop residues blocking substrate access to the catalytic cleft. Using the recombinant soluble form of the insulin receptor's kinase domain (IRKD) in its unphosphorylated state, activation loop conformation was analyzed by limited proteolysis. The rate of activation loop cleavage by trypsin is slow in the apo-IRKD. Bound Mg-adenine nucleoside di- and triphosphates increased the cleavage rate with half-maximal effects observed at 0.4-0.9 mM nucleotide. Adenosine monophosphate at concentrations up to 10 mM was not bound appreciably by the IRKD and had virtually no impact on activation loop cleavage. Amino-terminal and carboxy-terminal core-flanking regions of the IRKD had no statistically significant impact on the ligand-dependent or -independent activation loop cleavages. Furthermore, the core-flanking regions did not change the inherent conformational stability of the active site or the global stability of the IRKD, as determined by guanidinium chloride-induced denaturation. These measurements indicate that the intrasterically inhibitory conformation encompasses > or =90% of the ligand-free basal state kinase. However, normal intracellular concentrations of Mg-adenine nucleotides, which are in the millimolar range, would favor a basal-state conformation of the activation loop that is more accessible.

Post-translational processing and activation of insulin and EGF proreceptors.

We have investigated the role of glycosylation on the post-translational processing of the insulin, and EGF proreceptor polypeptides. Following translation of the insulin proreceptor, by 3T3-L1 adipocytes, about 1.5 h are required for its conversion into active receptor; an additional 1.5 h are needed for the active receptor to reach the plasma membrane. During this 3-hour period the proreceptor undergoes a complex series of processing events, glycosylation being an essential processing step. Thus, treatment of 3T3-L1 adipocytes with tunicamycin caused the loss of cellular insulin binding activity and the accumulation of an inactive aglyco-proreceptor. Similarly, it was demonstrated in human A431 epidermoid carcinoma cells that the initial EGF-proreceptor (160 kDa) translation product undergoes a slow (t 1/2 = 30 min) processing step by which ligand (EGF) binding activity was acquired. It was shown that N-linked core oligosaccharide addition is essential for this critical processing step and the acquisition of EGF binding activity. This was found not to require the conversion of high mannose chains to complex chains which have been capped with fucose and sialic acid. Possible explanations for this activation in terms of translocation of intermediates and/or formation of disulfide bonds are discussed. To investigate post-translational processing of normal insulin proreceptor and the role of glycosylation in active receptor formation, metabolic labeling experiments were conducted. The first 35S-methionine-labeled intermediate detected is a 190 kDa polypeptide (proreceptor) which is rapidly (t 1/2 = 15 min) processed into a 210 kDa species. Both polypeptides contain N-linked core oligosaccharide chains, but in the latter case these chains appear to contain terminal N-acetylglucosamine. The 210 kDa precursor is converted slowly (t 1/2 = 2 h) by proteolytic processing into a 125 kDa (alpha') and 83 kDa (beta') species. Immediately prior to insertion into the plasma membrane, 3 h after its synthesis, the alpha' and beta' precursors are converted to mature receptor comprised of alpha-(135 kDa) and beta-(95 kDa) subunits. The 125 kDa alpha'- and 83 kDa beta'-subunit precursors are endoglycosidase H-sensitive and their oligosaccharide chains do not contain terminal sialic acid. Just prior to insertion into the plasma membrane the alpha' and beta' precursors are sialylated, apparently in the Golgi apparatus, giving rise to the 135 kDa alpha and 95 kDa beta receptor subunits and become Endo H-resistant and neuraminidase-sensitive. A proposed sequence of post-translational processing events for the insulin proreceptor is shown in Figure 10.(ABSTRACT TRUNCATED AT 400 WORDS)

Receptor affinity chromatography.

Insulin receptor was purified in high yield from cultured 3T3-L1 mouse adipocytes using the bifunctional ligand N alpha B1-(biotinyl-epsilon-aminocaproyl)insulin in conjunction with avidin-Sepharose CL-4B. This ligand is 100% competent as insulin and 60% competent as biotin, as measured by competitive binding assays. The procedure requires preliminary removal of biotin-containing proteins on "native" avidin-Sepharose CL-4B. This matrix shows nearly the same biotin-binding characteristics as uncoupled avidin and can be regenerated by washing with 0.02 N HCl, causing only a minor loss of nonexchangeable biotin-binding sites. Insulin receptor is isolated by formation of a complex between the bifunctional ligand and the receptor, and then adsorption to "monomeric" avidin-Sepharose via the biotin moiety. This affinity matrix binds [14C]biotin with a Kd approximately equal to 0.2 microM and has exchangeable/nonexchangeable biotin binding sites in the ratio 9:1. Displacement of homogeneous insulin receptor is achieved by the addition of biotin; the elution is time-dependent, suggesting that it is accomplished by the prevention of rebinding.

Absence of insulin receptor gene mutations in three insulin-resistant women with the polycystic ovary syndrome.

Women with polycystic ovary syndrome (PCOS) are markedly insulin-resistant, but the molecular mechanisms of these changes and their relationship to the hyperandrogenic state remain to be clarified. Mutations have recently been identified in the insulin receptor gene of patients with extreme forms of insulin resistance associated with hyperandrogenism (eg, type A insulin resistance), and these mutations account for the insulin resistance in such patients. We performed this study to determine whether mutations in the coding portion of the insulin receptor gene were responsible for insulin resistance in PCOS. Insulin binding studies using cultured skin fibroblasts of three obese (body mass index > 27 kg/m2) women with PCOS (ie, mild hyperandrogenemia and chronic anovulation of unknown etiology) and documented insulin resistance showed no apparent abnormalities in either the number or affinity of insulin binding sites. Direct sequencing of all 22 exons of the insulin receptor gene from two of the women with PCOS did not reveal any mutations. Furthermore, both alleles of the gene were expressed at equal levels. In a third insulin-resistant PCOS woman, there was no evidence for a mutation in the coding portion of the insulin receptor gene as determined by denaturing gradient gel electrophoresis (DGGE). We conclude that the insulin resistance in these PCOS women was caused by a defect extrinsic to the insulin receptor.

Insulin receptor aggregation and autophosphorylation in the presence of cationic polyamino acids.

Aggregation and autophosphorylation of the insulin receptor-protein kinase, from cultured 3T3-L1 adipocytes, were studied in the presence of cationic polyamino acids. Poly-L-lysine and poly-L-arginine produced the following effects with the purified receptor: first, the autophosphorylation rate was increased by polycations. Half-maximal stimulation was proportional to polymer length. The rate enhancement was greater at lower ATP concentrations. Second, near-endpoint (equilibrium) autophosphorylation was greater in the presence of the polycations. Polycations inhibited the reverse reaction: ADP + phosphoreceptor yielding ATP + aporeceptor. Third, the [32P]phosphopeptides generated by trypsin digestion of the 32P-beta-subunit, showed that no new autophosphorylation sites resulted from the presence of polycations. Fourth, the polycations, but not insulin, promoted receptor aggregation, and phosphoreceptor aggregated more readily than aporeceptor. Insulin receptor enriched through the wheat germ agglutinin eluate step was compared with purified receptor. Higher concentrations of poly-L-arginine were required to stimulate autophosphorylation and to promote aggregation. Finally, several polycation-dependent substrates present in the wheat germ agglutinin eluate co-aggregated with the insulin receptor. Polycation-stimulated receptor autophosphorylation is linked to a lower KM,app for ATP, but substrate phosphorylation may require the aggregation.

Insulin receptor autophosphorylation. II. Determination of autophosphorylation sites by chemical sequence analysis and identification of the juxtamembrane sites.

Autophosphorylation sites of the human insulin receptor were identified by microsequence analysis of 19 discrete tryptic [32P]phosphopeptides, purified from the autophosphorylated cytoplasmic kinase domain (CKD). Seventeen phosphopeptides were generated by cleavage at Arg and/or Lys, but two phosphopeptides were generated reproducibly by anomalous cleavages. Two new sites were identified in the juxtamembrane region of the intact insulin receptor beta-subunit (the amino terminus of the CKD), including phosphotyrosines 965 and 972. Three sites in the central region, including phosphotyrosines 1158, 1162, and 1163, were identified from six phosphopeptides; tyrosine at 1158 was the least phosphorylated. Monophosphopeptides contained phosphotyrosine at either residue 1158 or 1163, but not at 1162. Bisphosphorylation included phosphotyrosines only at 1162 and 1163. The two autophosphorylation sites near the carboxy terminus were found in seven phosphopeptides, including phosphotyrosines at 1328 and 1334. When mapped by reverse-phase high-performance liquid chromatography, these phosphopeptides eluted in the order central domain, first; carboxy-terminal region, second; and juxtamembrane (amino-terminal) domain, last.

Insulin receptor autophosphorylation. I. Autophosphorylation kinetics of the native receptor and its cytoplasmic kinase domain.

Kinetic analysis of autophosphorylation was done using a non-Michaelis-Menten kinetic model. This model describes autophosphorylation in terms of a fast reaction phase, a slow reaction phase, and a partition function for the two phases. Kinetic parameters determined by this new approach show that insulin stimulates autophosphorylation by promoting (1) a 10-fold increase in the rate constant for the fast phase of the reaction and (2) a 2-fold increase in the partition function favoring the fast phase. Insulin did not significantly affect the binding constant for ATP in this fast phase. Kinetic parameters obtained for the cytoplasmic kinase domain were similar to those obtained for the native insulin receptor in the absence of insulin. The insulin receptor has three subdomains encompassing its seven autophosphorylation sites. The juxtamembrane sites react primarily in the slow kinetic phase, favored by the absence of stimulation and low ATP concentrations. The carboxy-terminal and central autophosphorylation subdomains react primarily in the fast kinetic phase, favored by raising the ATP concentration and/or the presence of insulin. These observations demonstrate that: (1) both ATP and insulin regulate reaction in each autophosphorylation subdomain, (2) insulin stimulation occurs predominantly in the central and carboxy-terminal regions, and (3) autophosphorylation observed with the cytoplasmic kinase domain was similar to native insulin receptor in the absence of insulin. These findings are consistent with conclusions based on the kinetic analysis of autophosphorylation.

Conformational states of the insulin receptor.

Insulin binding to the alpha-subunit of the purified insulin receptor changed the interaction between beta-subunits. This conformational change was demonstrated after labeling the receptor's beta-subunit by autophosphorylation in the absence of insulin, and then crosslinking the subunits to each other with bis (sulfosuccinimidyl) suberate. The convalent oligomers were resolved by reduction and denaturing gel electrophoresis. Insulin increased the rate of crosslinking, especially the formation of beta-beta dimers. These results support a conformational change following insulin binding, and may reflect the insulin-induced activation of autophosphorylation.

Homogeneous functional insulin receptor from 3T3-L1 adipocytes. Purification using N alpha B1-(biotinyl-epsilon-aminocaproyl)insulin and avidin-sepharose.

Insulin receptor was purified 10,000-fold from cultured mouse 3T3-L1 adipocytes in 35% overall yield. The specific activities of 125I-insulin binding and autophosphorylation increased in parallel, following the initial Triton X-100 extraction of membranes. The isolation protocol, performed entirely at pH 8.45, entailed adsorption by avidin-Sepharose CL-4B of a complex formed between Triton X-100-solubilized insulin receptor and N alpha B1-(biotinyl-epsilon-aminocaproyl)insulin, and the specific elution of the complex with biotin. The avidin-Sepharose CL-4B was a partially denatured preparation, showing estimated dissociation constants of 0.2 microM for biotin and approximately 1 microM for the bifunctional ligand at, pH 7, 4 degrees C. The bifunctional ligand was characterized by 70% competency in binding to avidin, 100% competency in binding to solubilized insulin receptor, full stimulation of autophosphorylation of the isolated receptor, and maximal stimulation of hexose uptake by intact 3T3-L1 adipocytes. The insulin binding properties of the insulin receptor were uniform throughout this purification procedure. At pH 8.45, 4 degrees C, an average Kd = 0.72 nM was determined for a single class of noninteracting insulin binding sites. The apparent autophosphorylation of the beta-subunit was also unchanged following affinity chromatography. A single oligomeric structure was established for the purified receptor, composed only of 135,000- and 95,000-Da subunits, whose association was lost by denaturation in the presence of reducing agent. This single structure occurred in the initial Triton X-100 extract. The purified insulin receptor was capable of autophosphorylating the beta-subunit and catalyzed phosphorylation of protein substrates.

Kinetic evidence for activating and non-activating components of autophosphorylation of the insulin receptor protein kinase.

Reduced and carboxamidomethylated-lysozyme (RCAM-lysozyme) is an excellent substrate (Km = 13 microM) and a potent inhibitor of receptor autophosphorylation (Ki = 0.6 microM). By using these properties of RCAM-lysozyme autophosphorylation was resolved into two kinetically and functionally distinct components involving formation of phosphotyrosine on the receptor's beta-subunits: 1. Insulin-stimulated autophosphorylation is independent of autophosphorylation at other sites; activation of insulin receptor-catalyzed substrate phosphorylation is dependent upon this component of autophosphorylation, which is inhibited by RCAM-lysozyme. 2. Autophosphorylation at saturating RCAM-lysozyme concentration is insensitive to insulin and has little effect on substrate phosphorylation. Thus, only insulin-dependent receptor autophosphorylation is responsible for activation of kinase-catalyzed substrate phosphorylation.

Primary structure of avian hepatic rhodanese.

Rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1.) was purified from chicken livers and its amino acid sequence was determined. The enzyme has a specific activity of 676 IU and a molecular weight of 32,255. The primary structure of 289 amino acids was solved by sequential Edman degradation of overlapping peptides obtained by selected enzymatic and chemical cleavages. The amino terminus was blocked, and the carboxy-terminus was heterogeneous. Comparison of the primary structure with bovine liver rhodanese showed 212 identically matched amino acids, and the majority of amino acid differences were conservative substitutions. Reaction of the enzyme with a 1.4-fold molar excess of [2-14C]iodoacetate led to inactivation of the enzyme and carboxymethylation of Cys-244; this modification was blocked by the substrate thiosulfate.

Activation of the insulin receptor's kinase domain changes the rate-determining step of substrate phosphorylation.

The insulin receptor and many other protein kinases are activated by relief of intrasteric inhibition that is regulated by reversible phosphorylation. The changes accompanying activation of the insulin receptor's kinase domain were analyzed using steady-state kinetics, viscometric analysis, and equilibrium binding measurements. Peptide phosphorylation catalyzed by the unphosphorylated basal-state kinase is limited by a slow rate of the chemical step, and the activated enzyme is limited by product release rates. Underlying these changes were a 36-fold increase in the rate constant for the chemical step of the enzyme-catalyzed reaction, a 5-fold increase in the affinity for MgATP, and an 8-fold increase in the affinity for peptide substrate. This results in binding of substrates that is 2.2 kcal/mol more favorable and a free energy barrier for transition state formation that is lowered by 2.1 kcal/mol in the activated enzyme. Therefore, the change in conformational free energy inherent in the protein after autophosphorylation [Bishop, S. M., Ross, J. B. A., and Kohanski, R. A. (1999) Biochemistry 38, 3079-3089] is equally distributed between formation of the substrate ternary complex and formation of the transition state complex.

The native alpha 2 beta 2 tetramer is the only subunit structure of the insulin receptor in intact cells and purified receptor preparations.

The native subunit structure of the insulin receptor was reinvestigated by two-dimensional nonreducing/reducing gel electrophoresis. Human insulin receptor expressed in murine fibroblasts was found to be a single oligomer, the alpha 2 beta 2 heterotetramer. The structure was assessed using receptor metabolically labeled with [35S]methionine, and using receptor autophosphorylation at two levels of purification: the insulin affinity-purified receptor and the more commonly used wheat germ agglutinin-Sepharose-enriched fraction from whole membrane extracts. Lower molecular weight oligomers and free subunits were observed only upon heating the sample prior to electrophoresis. This artifact of sample handling was dependent upon three factors: (i) temperature, (ii) time of heating, and (iii) impurities typically present in partially purified receptor preparations. We conclude that the alpha 2 beta 2 tetramer is the only insulin receptor subunit structure native in intact cells and subsequently isolated from cell membranes.