The biological potency of covalent insulin-receptor complexes. Dependence on site of cross-linkage

A radioactive photosensitive insulin analogue, 125I-N epsilon B29-(4-azido-2-nitrophenyl-acetyl)insulin, was covalently bound to the receptors of isolated rat adipocytes by irradiation with UV light. This caused a stimulation of lipogenesis. The relative potency of the covalent complexes to that of normal reversible complexes was calculated by comparing the amounts of radioactivity required to be covalently or reversibly bound by adipocytes to cause the same levels of stimulation. For several different occupancies , this relative potency was constant at 50 +/- 3%. Previous studies had shown that the relative potency of covalently bound 125I-N alpha B2-(4-azido-2- nitrophenylacetyl )des- PheB1 -insulin was only 25 +/- 4% under identical conditions. This demonstrates that the sites of crosslinking have a marked effect on the potency of the covalent hormone-receptor complex. It appears that attachment through the C-terminus of the B-chain leads to a better stabilization of the biologically active form than linking through the more flexible N-terminus.     

Time-dependence of biological activity induced by covalent insulin-receptor complexes in rat adipocytes.

Lipogenesis in isolated adipocyte preparations is stimulated when photosensitive insulin derivatives are attached covalently to specific receptors. This response was compared quantitatively with that to reversibly associated insulin, and it was shown that both covalent and reversible insulin-receptor complexes behave very similarly. The extent of stimulation of lipogenesis was studied as a function of time. Cells were incubated in buffer for various times before addition to vials containing 0 (basal) or 10 ng of monocomponent insulin/ml (maximal) and [U-3H]glucose. After 60 min, the toluene-soluble [3H]lipids were measured. The maximal stimulation induced by reversibly bound insulin was virtually constant over a period of 4 h. In contrast, adipocytes to which N alpha B2-(2-nitro-4-azidophenylacetyl)-des-PheB1-insulin had been covalently attached at the start of the experiment showed a loss of stimulation with time when incubated at 37 degrees C. This loss was decreased in the presence of lysosomotropic agents such as chloroquine at concentrations (approx. 200 microM) that had very little or no effect on the basal and maximal lipogenesis rates. A simple method was used to transform the measured rate of loss of stimulation into a rate of loss of effective units. A half-time of 80 min was calculated for the effective covalent insulin-receptor units in adipocytes at 37 degrees C at pH 7.4. This is very close to values reported by others for the internalization of covalent complexes in these cells, suggesting that this may be the causative event for the deactivation of the insulin-receptor unit. The inhibitory effect of chloroquine on the deactivation may indicate that the insulin-receptor complex can function even after internalization.     

Receptor binding properties and insulin-like effects of human growth hormone and its 20 kDa-variant in rat adipocytes

The natural 20 kDa-variant of human growth hormone (hGH) binds with high affinity to IM-9 human lymphocyte receptors, in agreement with its potency in biological assays for growth promoting and lactogenic activities. In contrast, 20 kDa-hGH has only 3% of the potency of 22 kDa-hGH in binding to the receptors of normal and hypophysectomized rat adipocytes. In agreement with the binding potency, 20 kDa-hGH is only 3% as potent as 22 kDa-hGH in stimulating lipogenesis in normal rat adipocytes preincubated for a few hours in hGH-free medium. The 20 kDa-hGH is also much weaker than 22 kDa-hGH in stimulating lipogenesis in adipocytes from hypophysectomized rats. These data strongly support the concept that the rat adipocyte receptor, which mediates the insulin-like effects of growth hormone, is different from the receptor found on human IM-9 lymphocytes. Preincubation of rat adipocytes with hGH induces a refractoriness to subsequent activation of lipogenesis by hGH but does not abolish the response to insulin, while preincubation with insulin slightly potentiates the hGH response and does not change the insulin response. Additivity studies and a detailed comparison of the lipogenic effects of insulin and hGH suggest that hGH shares only a subset of the metabolic pathways activated by insulin.     

Degradation, receptor binding affinity, and potency of insulin from the Atlantic hagfish (Myxine glutinosa) determined in isolated rat fat cells

Insulin from the Atlantic hagfish, Myxine glutinosa, a primitive vertebrate, was studied with respect to degradation, receptor binding, and stimulation of glucose transport and metabolism in isolated rat adipocytes. The degradation was studied in a concentrated suspension with about 100mul of cells/ml of suspension. 125I-labeled hagfish insulin and 125I-labeled pig insulin were degraded at the same rate when present in concentrations of 0.3nM. Native hagfish insulin inhibited the rate of degradation of 125I-labeled pig insulin half-maximally at a concentration of 12+/-2 nM (S.D., n=6) as compared to 130+/-32 nM (S.D.,n=6) for pig insulin. Native hagfish insulin in a concentration of 130 nM was biologically inactivated at a rate several times slower than pig insulin in the same concentration. The results indicate that the maximal velocity (Vmax) of degradation of hagfish insulin as well as the concentration causing half-maximal velocity (Km) are about 10 times lower for hagfish insulin than for pig insulin. The receptor binding and the biological effects of hagfish insulin were studied in dilute cell suspensions where the degradation of hormone in the medium was negligible. The receptor binding affinity of hagfish insulin was 23+/-7 per cent (S.D., n=10) of that of pig insulin. Hagfish insulin was able to elicit the same maximal stimulation of both 3-o-methylglucose exchange and lipogenesis from glucose as pig insulin. However, the potency of hagfish insulin with respect to activation of lipogenesis was only 4.6+/-0.6 per cent (S.D., n=15) of that of pig insulin. Hagfish insulin thus constitutes the first described insulin which exhibits a discrepancy between relative binding affinity and relative potency. This discrepancy was not due to the methionine residue (B31) at the COOH-terminal end of the B chain of hagfish insulin, since removal of this residue caused no marked change in the binding affinity or the potency. The results indicate that the receptor occupancy must be 5 times higher with hagfish insulin than with pig insulin to cause a particular degree of activation of lipogenesis. Hagfish insulin might therefore be characterized as a "partial antagonist" on the receptors. However, it was not possible to demonstrate antagonistic properties of hagfish insulin on the cells. The effect of hagfish insulin plus pig insulin in submaximally stimulating concentrations was additive. Furthermore, the decay of activation of adipocytes after incubation with hagfish insulin followed the same time course as the decay of activation after incubation with pig insulin in a concentration of equal potency. These phenomena are in agreement with the concept that adipocytes possess a large excess of receptors which can mediate the effect of insulin on lipogenesis from glucose.     

Biological activity of covalently-linked insulin-receptor complexes in rat adipocytes. Effect of pH

The relative molar potencies of covalently and reversibly-bound insulin-receptor complexes were studied as a function of pH. The insulin derivatives used were 125I-B2 (2-nitro-4-azidophenylacetyl)des-PheB1-insulin and 125I-B29(2-nitro-4-azidophenylacetyl)des-PheB1-insulin. The potencies of both types of reversible complexes were effectively identical and constant between pH 7 and 8. The relative potency of the covalent B2-complex increased from 25 to 75%, and of the covalent B29 complex from 30 to nearly 100%. This indicates that the covalently linked partners in the complex are able to flex about the cross-linkages. Variations in the potency are due to variations in the number of correctly associated, reversibly or covalently bound insulin-receptor complexes. The form of the pH dependance suggests that an ionizable group, possibly an amino group, must be deprotonated to allow effective interaction.     

Mechanism of inhibition of fatty acid amide hydrolase by sulfonamide-containing benzothiazoles: long residence time derived from increased kinetic barrier and not exclusively from thermodynamic potency

Fatty acid amide hydrolase (FAAH) has emerged as a potential target for developing analgesic, anxiolytic, antidepressant, sleep-enhancing, and anti-inflammatory drugs, and tremendous efforts have been made to discover potent and selective inhibitors of FAAH. Most known potent FAAH inhibitors described to date employ covalent mechanisms, inhibiting the enzyme either reversibly or irreversibly. Recently, a benzothiazole-based analogue (1) has been described possessing a high potency against FAAH yet lacking a structural feature previously known to interact with FAAH covalently. However, covalent inhibition of FAAH by 1 has not been fully ruled out, and the issue of reversibility has not been addressed. Confirming previous reports, 1 inhibited recombinant human FAAH (rhFAAH) with high potency with IC(50) ~2 nM. It displayed an apparently noncompetitive and irreversible inhibition, titrating rhFAAH stoichiometrically within normal assay times. The inhibition appeared to be time dependent, but the time dependence only improved potency by a small degree (from ~8 to ~2 nM). However, mass spectrometric analyses of the reaction mixture failed to reveal any cleavage product or covalent adduct and showed full recovery of the parent compound, ruling out covalent, irreversible inhibition. Dialysis revealed recovery of enzyme activity from enzyme-inhibitor complex over a prolonged time (>10 h), demonstrating that 1 is indeed a reversible, albeit slowly dissociating inhibitor of FAAH. Molecular docking indicated that the sulfonamide group of 1 could form hydrogen bonds with several residues involved in catalysis, thereby mimicking the transition state. The long residence time displayed by 1 does not appear to derive exclusively from great thermodynamic potency and is consistent with an increased kinetic energy barrier that prevents dissociation from happening quickly.     

The effect of placement of tryptophan residues in selected A-chain positions on the biological profile of insulin

In continuation of our efforts to study the solution structure and conformational dynamics of insulin by time-resolved fluorescence spectroscopy, we have synthesized and examined the biological activity of five insulin analogues in which selected naturally occurring residues in the A-chain have been replaced with the strongly fluorescent tryptophan residue. The potency of these analogues was evaluated in lipogenesis assays in isolated rat adipocytes, in receptor binding assays using rat liver plasma membranes, and in two cases, in receptor binding assays using adipocytes. [A3 Trp]insulin displays a potency of 3% in receptor binding assays in both liver membranes and in adipocytes, but only 0.06% in lipogenesis assays as compared to porcine insulin. [A10 Trp] insulin displays a potency ofca. 40% andca. 25% in rat liver receptor binding and lipogenesis assays, respectively. [A13 Trp]insulin displays a potency ofca. 39% in rat liver receptor binding assays, but onlyca. 9% in receptor binding in adipocytes; in lipogenesis assays, [A13 Trp] insulin displays a potency ofca. 12%, comparable to its potency in adipocyte receptor binding assays. [A15 Trp]insulin exhibits a potency of 18% and 9% in rat liver receptor binding and lipogenesis assays, respectively. The doubly substituted analogue, [A14 Trp, A19 Trp] insulin, displays a potency ofca. 0.7% in both rat liver receptor binding assays and lipogenesis assays. These data suggest two major conclusions: (1) the A3 and A15 residues lie in sensitive regions in the insulin molecule, and structural modifications at these positions have deleterious effects on biological activity of the hormone; and (2) [A13 Trp]insulin appears to be a unique case in which an insulin analogue exhibits a higher potency when assayed in liver tissue than when assayed in fat cells.     

Receptor binding and biological potency of despentapeptide insulin

The receptor binding and biological potency of despentapeptide insulin (DPI) was assessed in human adipocytes, rat adipocytes and rat hepatocytes. DPI displayed a lower affinity for binding to both human adipocytes (half-maximum displacement at 0.89 +/- 0.04 and 0.20 +/- 0.02 nmol/l for DPI and insulin respectively; P less than 0.001) and rat adipocytes (half-maximum displacement at 7.12 +/- 1.06 and 1.14 +/- 0.18 nmol/l respectively, P less than 0.05). However, although DPI was less potent than unmodified insulin in stimulating glucose uptake in rat adipocytes (half-maximal stimulation at 2.0 +/- 0.67 and 0.47 +/- 0.18 nmol/l respectively; P less than 0.05), DPI was equipotent with insulin in human adipocytes (half-maximal stimulation at 0.034 +/- 0.001 and 0.027 +/- 0.001 nmol/l respectively; P greater than 0.2). In rat hepatocytes, DPI was twofold less potent in binding displacement activity (half-maximum displacement at 3.8 +/- 0.9 and 1.7 +/- 0.3 nmol/l respectively; P less than 0.01) but appeared to be equivalent in stimulating amino butyric acid uptake (half-maximum stimulation at 0.98 +/- 0.12 and 0.95 +/- 0.26 nmol/l respectively). The difference in affinity of DPI binding to rat liver membranes was less marked (1.3 fold decreased compared with insulin: 5.3 +/- 0.7 and 4.2 +/- 0.6 nmol/l respectively; P less than 0.001). Thus, the decreased receptor affinity of DPI was reflected in decreased biological potency in rat adipocytes, but not in human adipocytes nor rat hepatocytes. These data suggest differences in the binding-action linking in the cells of different tissues and different species.     

Novel mechanisms of the regulation of protein kinase B in adipocytes; implications for protein kinase A, Epac, phosphodiesterases 3 and 4

Crosstalk between insulin and cAMP signalling pathways has a great impact on adipocyte metabolism. Whilst Protein kinase B (PKB) is a pivotal mediator of insulin action, in some cells regulation of PKB by cAMP has also been demonstrated. Here we provide evidence that, in a phosphatidyl inositol 3-kinase dependent manner, beta3-adrenergic stimulation (using CL316243) in adipocytes induces PKB phosphorylation in the absence of insulin and also potentiates insulin-induced phosphorylation of PKB. Interestingly, insulin- and CL316243-induced PKB phosphorylation was found to be inhibited by pools of cAMP controlled by PDE3B and PDE4 (mainly in the context of insulin), whereas a cAMP pool controlling protein kinase A appeared to mediate stimulation of PKB phosphorylation (mainly in the context of CL316243). Furthermore, an Epac (exchange protein directly activated by cAMP) agonist (8-pCPT-2'-O-Me-cAMP) mimicked the effect of the PDE inhibitors, giving evidence that Epac has an inhibitory effect on PKB phosphorylation in adipocytes. Further, we put the results obtained at the level of PKB in the context of possible downstream signalling components in the regulation of adipocyte metabolism. Thus, we found that overexpression of PKB induced lipogenesis in a PDE3B-dependent manner. Furthermore, overexpression or inhibition of PDE3B was associated with reduced or increased phosphorylation of the key lipogenic enzyme acetyl-CoA carboxylase (ACC), respectively. These PDE3B-dependent effects on ACC correlated with changes in lipogenesis. The Epac agonist, 8-pCPT-2'-O-Me-cAMP, mimicked the effect of PDE3B inhibition on ACC phosphorylation and lipogenesis.     

Stimulation of triacylglycerol synthesis in rat adipocytes by plasma very-low-density lipoproteins.

The effect of human plasma lipoproteins on lipogenesis from glucose has been studied in isolated rat adipocytes. The very-low-density lipoproteins increased lipogenesis specifically, whereas low-density lipoproteins and high-density lipoproteins were without effect. Such stimulation could be reproduced with partially delipidated very-low-density lipoproteins. Nod-esterified fatty acids and glycerol were also without effect. Pretreatment of the adipocytes with trypsin did not alter the effect of very-low-density lipoprotein. The presence of Ca2+ was required for the full activation of lipogenesis. The synthesis of acylglycerol fatty acids and of acylglycerol glycerol were equally increased. The effect of very-low-density lipoprotein was not additive to that of insulin. It is suggested that very-low-density lipoprotein may directly stimulate lipogenesis in fat-cells, particularly in states when the lipoproteins are present at high concentration in the circulation.     

Recognition of covalent insulin-receptor complexes on viable adipocytes by anti-insulin antibodies

Isolated rat adipocytes were photo-affinity-labelled with B2-(4-azido-2-nitrophenylacetyl)-des-PheB1-insulin or B29-(4-azido-2-nitrophenylacetyl)insulin. Four anti-insulin antibodies (3 monoclonal, 1 polyclonal) were tested for their ability to inhibit the persistent stimulation of lipogenesis caused by the covalently bound insulin [Brandenburg et al. (1980) Nature (London) 286, 821-822]. The polyclonal and 2 monoclonal antibodies, directed against the C-terminus of the B-chain, gave a significant depression, while one antibody, directed against the region A(8-10), was without effect. Under reversible conditions, without irradiation, all antibodies completely inhibited lipogenesis. For the polyclonal antibody this is shown in a dose-dependent way. It is concluded that the effective antibodies can recognize their epitope because it is accessible on the surface of the complex and does not represent part of the receptor-binding surface of insulin. This binding leads to interference with the generation and/or transmittance of the biological signal.     

Some aspects of metabolic adaptations in lipid metabolism during starvation are mimicked by epinephrine in rat adipocytes

1. The effects of fasting on the neutral lipid synthesis to insulin and/or epinephrine in isolated fat cells have been examined using [1-14C]glucose. 2. The ability of adipocytes from starved rats to synthesize fatty acids from both labeled substrates was markedly diminished compared to adipocytes from control rats. 3. The response of lipogenic stimulation to insulin at all concentrations tested was greatly diminished in adipocytes from 24 hr starved rats. 4. [1-14C]glucose utilization rates in the absence or in the presence of insulin were not significantly different in adipocytes from 24 hr starved rats as compared with control adipocytes, although basal and insulin stimulated glyceride-glycerol synthesis were significantly higher in starved adipocytes. 5. Epinephrine acutely inhibited [1-14C]acetate incorporation into fatty acids for insulin-stimulated lipogenesis in control adipocytes, in contrast, this lipolytic agent strongly increased [1-14C]glucose conversion to triacylglycerols. 6. In both cases, the differences in lipid synthesis capacities found in both nutritional states were abolished by epinephrine.     

Biological action and fate of photoaffinity-labelled insulin-receptor complexes

Covalent linking of two photoactivatable insulin derivatives, B2-(2-nitro,4-azidophenylacetyl)-des-PheB1-insulin and B29-(2-nitro,4-azidophenylacetyl)-insulin to viable rat adipocytes gives a system, which contains a fixed stoichiometry between hormone and receptor. The biological signal of prolonged lipogenesis has been used to study several aspects of insulin binding and action: the role of the site of the crosslink between insulin and receptor, recognition of bound photoinsulin by anti-insulin antibodies, the half-life of the biologically active complex, the pH-dependence of the biological signal, and the possible role of internalization. Furthermore, the effect of trypsin on the insulin receptor, as well as the insulin-receptor complex, has been investigated and a refined model of the receptor is presented.     

Adenosine modulation of fat cell responsiveness to insulin and oxytocin

We have investigated the effects of adenosine on the stimulation of glucose oxidation and lipogenesis by oxytocin and insulin in rat epididymal adipocytes. The addition of adenosine deaminase (1 U/ml) to the assay medium reduced the maximal oxytocin response (glucose oxidation and lipogenesis) to between 25 and 50% of the maximum response in control cells. The maximal response to insulin was not appreciably affected under these conditions. The addition of adenosine (10 or 30 microM) increased the cell sensitivity to oxytocin by elevating the maximum rate of oxytocin-stimulated glucose metabolism. Adenosine also increased the cell sensitivity to insulin by decreasing its ED50. A change in ED50, however, was observed only when control or adenosine-treated cells were compared to adenosine deaminase-treated cells; but not when control and adenosine-treated cells were compared. On its own, adenosine also caused an appreciable increase in both glucose oxidation and lipogenesis (ED50 approximately equal to 3 microM adenosine). The difference in the effect of adenosine on oxytocin action, compared with the effect on insulin action, points to differences in the mechanisms by which insulin and oxytocin stimulate glucose metabolism in adipocytes.     

Effects of insulin on lipolysis and lipogenesis in hamster white adipocytes with high sensitivity to hormones

A modified procedure for preparation of hamster adipocytes by collagenase digestion under carefully controlled conditions has been developed. The adipocytes were 4- to 8-fold more sensitive to catecholamine stimulation of lipolysis than cells prepared by a commonly used method (Hittelman, K.J., Wu, C.F. and Butcher, R.W. (1973) Biochim. Biophys. Acta 304, 188-196) and also more sensitive to the anti-lipolytic action of insulin. The effects of insulin on lipogenesis, measured as [3H]glucose conversion to cell lipids, and on catecholamine-stimulated lipolysis were compared under identical conditions with the same cell batch. Isoprenaline-stimulated lipolysis was found to be half-maximally inhibited by an insulin concentration 8-fold lower than that stimulating lipogenesis to a corresponding extent (half-maximal effects at insulin concentrations of 40 vs. 300 pM). A similar difference was found when cells had been stimulated with adrenaline instead of isoprenaline.     

Photoaffinity labeling of serum vitamin D binding protein by 3-deoxy-3-azido-25-hydroxyvitamin D3

3-Deoxy-3-azido-25-hydroxyvitamin D3 was covalently incorporated in the 25-hydroxyvitamin D3 binding site of purified human plasma vitamin D binding protein. Competition experiments showed that 3-deoxy-3-azido-25-hydroxyvitamin D3 and 25-hydroxyvitamin D3 bind at the same site on the protein. Tritiated 3-deoxy-3-azido-25-hydroxyvitamin D3 was synthesized from tritiated 25-hydroxyvitamin D3, retaining the high specific activity of the parent compound. The tritiated azido label bound reversibly to human vitamin D binding protein in the dark and covalently to human vitamin D binding protein after exposure to ultraviolet light. Reversible binding of tritiated 3-deoxy-3-azido-25-hydroxyvitamin D3 was compared to tritiated 25-hydroxyvitamin D3 binding to human vitamin D binding protein. Scatchard analysis of the data indicated equivalent maximum density binding sites with a KD,app of 0.21 nM for 25-hydroxyvitamin D3 and a KD,app of 1.3 nM for the azido derivative. Covalent binding was observed only after exposure to ultraviolet irradiation, with an average of 3% of the reversibly bound label becoming covalently bound to vitamin D binding protein. The covalent binding was reduced 70-80% when 25-hydroxyvitamin D3 was present, indicating strong covalent binding at the vitamin D binding site of the protein. When tritiated 3-deoxy-3-azido-25-hydroxyvitamin D3 was incubated with human plasma in the absence and presence of 25-hydroxyvitamin D3, 12% of the azido derivative was reversibly bound to vitamin D binding protein. After ultraviolet irradiation, four plasma proteins covalently bound the azido label, but vitamin D binding protein was the only protein of the four that was unlabeled in the presence of 25-hydroxyvitamin D3.     

The effects of macrophage-derived cytokines on lipid metabolism in chicken (Gallus domesticus) hepatocytes and adipocytes

1. The effects of avian and mammalian cytokines on avian lipid metabolism were compared using cultured chicken hepatocytes and adipocytes. 2. Conditioned medium from an endotoxin-stimulated chicken macrophage cell line was used as a source of chicken cytokines. Incubation of chicken adipocytes with conditioned medium greatly decreased their lipoprotein lipase activity. 3. Inhibition of lipoprotein lipase synthesis in similar experiments in mammals has been attributed to the effects of TNF-alpha and/or IL-1, but recombinant human TNF-alpha and IL-1 had no effect on lipoprotein lipase activity in chicken adipocytes. 4. Conditioned medium from chicken macrophages produced a 2-fold increase in lipogenesis in chicken adipocytes but had no effect on lipogenesis in chicken hepatocytes. 5. The results point to major differences between mammals and birds in the way that lipid metabolism responds to cytokines and provide further evidence that mammalian cytokines are ineffective in birds.     

Expression of the human apoE2 isoform in adipocytes: altered cellular processing and impaired adipocyte lipogenesis

Expression of apoE in adipocytes has been shown to have an important role in modulating adipocyte triglyceride (TG) metabolism and gene expression that is independent of circulating and extracellular apoE. The impact of adipocyte expression of common human apoE isoforms was evaluated using adipocytes harvested from human apoE2, -3, and -4 knock-in mice. Expression of the apoE2 isoform was associated with an increase in adipocyte apoE gene expression and apoE synthesis. Newly synthesized apoE2 was unstable in adipocytes and demonstrated increased degradation and decreased secretion. ApoE2-expressing mice were hyperlipidemic, and had increased size of gonadal fat pads and of adipocytes, compared with apoE3 mice. In isolated cells, however, expression of the apoE2 isoform produced defective lipogenesis and increased TG hydrolysis. Incubation of adipose tissue with apoE3-containing TG-rich lipoproteins resulted in a significant increase in TG in adipose tissue from apoE3 and -E4 mice, but not apoE2 mice. Reduced capacity to internalize FFA as lipogenic substrate contributed to defective lipogenesis. Newly synthesized apoE2 is unstable in adipocytes and results in decreased adipocyte TG synthesis and defective FA uptake. These changes recapitulate those observed in apoE knockout adipocytes and have implications for understanding metabolic disturbances in humans expressing the E2 isoform.     

The A1 adenosine receptor. Identification of the binding subunit by photoaffinity cross-linking

Adenosine modifies the catalytic activity of adenylate cyclase through both inhibitory (A1 or Ri) as well as stimulatory (A2 or Ra) cell surface receptors. We developed 125I-labeled N6-2-(4-aminophenyl)ethyladenosine as a selective ligand to probe the structure of A1 receptors. The binding of this radioligand to rat cerebral cortex or adipocyte membranes is saturable, reversible, and of high affinity (KD approximately 2 nM). A1 receptor agonists antagonize binding stereoselectivity and with a potency order appropriate for A1 receptors. The heterobifunctional cross-linking reagent N-succinimidyl-6-(4-azido-2-nitrophenylamino)hexanoate covalently couples the radioligand to a protein of Mr = 38,000 in both tissues as demonstrated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Inhibition of covalent labeling by adenosine analogs exhibited the stereoselectivity and potency order typical of A1 receptor ligands. Guanine nucleotides reduced both specific binding and covalent incorporation of the radioligand, evidence that the radioligand is an A1 receptor agonist. These results suggest that the A1 receptor binding subunit of both brain and adipocytes resides on a protein of Mr = 38,000. The new radioligand should prove useful in studying the structure and regulation of A1 receptors.     

Absence of covalent binding by insulin to erythrocyte and reticulocyte insulin receptors

We investigated whether insulin forms covalent bonds with its receptors on erythrocytes and reticulocytes, as it does in adipocytes (1). Of the [125I]-insulin specifically bound at 37 degrees C to human and rat erythrocytes and rat reticulocytes, only 1.5-2.3% was non-dissociable on extensive washing. When ghosts prepared from the washed cells were solubilized in Triton X-100, only 0.6-1.5% of the specifically bound radioactivity appeared in the void volume of a Sephadex G-50 column. Moreover in contrast to adipocytes, this high molecular weight radioactivity was not immunoprecipitable by antibodies to the insulin receptor and was dissociated during chromatography in sodium dodecyl sulphate. Thus we have been unable to demonstrate the formation of covalent bonds between insulin and its receptors on erythrocytes and reticulocytes. This finding is consistent with the hypothesis that covalent binding of insulin is a necessary receptor modification for insulin's metabolic effects.