Properties of the Insulin Receptor of Isolated Fat Cell Membranes

[The insulin receptor discovery is 50 years old - A review of achieved progress]

The isolation of insulin from the pancreas and its purification to a degree permitting its safe administration to type 1 diabetic patients were accomplished 100 years ago at the University of Toronto by Banting, Best, Collip and McLeod and constitute undeniably one of the major medical therapeutic revolutions, recognized by the attribution of the 1923 Nobel Prize in Physiology or Medicine to Banting and McLeod. The clinical spin off was immediate as well as the internationalization of insulin's commercial production. The outcomes regarding basic research were much slower, in particular regarding the molecular mechanisms of insulin action on its target cells. It took almost a half-century before the determination of the tri-dimensional structure of insulin in 1969 and the characterization of its cell receptor in 1970-1971. The demonstration that the insulin receptor is in fact an enzyme named tyrosine kinase came in the years 1982-1985, and the crystal structure of the intracellular kinase domain 10 years later. The crystal structure of the first intracellular kinase substrate (IRS-1) in 1991 paved the way for the elucidation of the intracellular signalling pathways but it took 15 more years to obtain the complete crystal structure of the extracellular receptor domain (without insulin) in 2006. Since then, the determination of the structure of the whole insulin-receptor complex in both the inactive and activated states has made considerable progress, not least due to recent improvement in the resolution power of cryo-electron microscopy. I will here review the steps in the development of the concept of hormone receptor, and of our knowledge of the structure and molecular mechanism of activation of the insulin receptor.

Microenvironment proteinases, proteinase-activated receptor regulation, cancer and inflammation

We propose that in the microenvironment of inflammatory tissues, including tumours, extracellular proteinases can modulate cell signalling in part by regulating proteinase-activated receptors (PARs). We have been exploring this mechanism in a variety of inflammation and tumour-related settings that include tumour-derived cultured cells from prostate and bladder cancer, as well as immune inflammatory cells that are involved in the pathology of inflammatory diseases including multiple sclerosis. Our work showed that proteinase signalling via the PARs affects prostate and bladder cancer-derived tumour cell behaviour and can regulate calcium signalling in human T-cell and macrophage-related inflammatory cells as well as in murine splenocytes. Further, we found that the tumour-derived prostate cancer cells and immune-related cells (Jurkat, THP1, mouse splenocytes) can produce PAR-regulating proteinases (including kallikreins: kallikrein-related peptidases), that can control tissue function by both a paracrine and autocrine mechanism. We suggest that this PAR-driven signalling process involving secreted microenvironment proteinases can play a key role in cancer and inflammatory diseases including multiple sclerosis.

Influenza A virus hemagglutinin and neuraminidase act as novel motile machinery

Influenza A virus (IAV) membrane proteins hemagglutinin (HA) and neuraminidase (NA) are determinants of virus infectivity, transmissibility, pathogenicity, host specificity, and major antigenicity. HA binds to a virus receptor, a sialoglycoprotein or sialoglycolipid, on the host cell and mediates virus attachment to the cell surface. The hydrolytic enzyme NA cleaves sialic acid from viral receptors and accelerates the release of progeny virus from host cells. In this study, we identified a novel function of HA and NA as machinery for viral motility. HAs exchanged binding partner receptors iteratively, generating virus movement on a receptor-coated glass surface instead of a cell surface. The virus movement was also dependent on NA. Virus movement mediated by HA and NA resulted in a three to four-fold increase in virus internalisation by cultured cells. We concluded that cooperation of HA and NA moves IAV particles on a cell surface and enhances virus infection of host cells.

Proteinases, Their Extracellular Targets, and Inflammatory Signaling

Given that over 2% of the human genome codes for proteolytic enzymes and their inhibitors, it is not surprising that proteinases serve many physiologic-pathophysiological roles. In this context, we provide an overview of proteolytic mechanisms regulating inflammation, with a focus on cell signaling stimulated by the generation of inflammatory peptides; activation of the proteinase-activated receptor (PAR) family of G protein-coupled receptors (GPCR), with a mechanism in common with adhesion-triggered GPCRs (ADGRs); and by proteolytic ion channel regulation. These mechanisms are considered in the much wider context that proteolytic mechanisms serve, including the processing of growth factors and their receptors, the regulation of matrix-integrin signaling, and the generation and release of membrane-tethered receptor ligands. These signaling mechanisms are relevant for inflammatory, neurodegenerative, and cardiovascular diseases as well as for cancer. We propose that the inflammation-triggering proteinases and their proteolytically generated substrates represent attractive therapeutic targets and we discuss appropriate targeting strategies.

Microfluidic Platform for Assessment of Therapeutic Proteins Using Molecular Charge Modulation Enhanced Electrokinetic Concentration Assays

Therapeutic proteins (TPs) are critical in modern medicine, yet shortage of TPs in disaster situations and remote areas remains a worldwide challenge. Manufacturing and real-time release of TPs on demand at the point-of-care is considered the key to this issue, which requires reliable and rapid analytics techniques for quality assurance. Herein we report a microfluidic platform that could be implemented in-line and at the point-of-care for real-time decision-making about the quality of a TP. The in vivo efficacy and duration of efficacy of TPs were assessed by the equilibrium and kinetics of TP and TP receptor (TPR) binding, using electrokinetic concentration (EC) and molecular charge modulation (MCM). EC can simultaneously concentrate and separate bound and unbound species in an assay based on electrical mobility, allowing for the quantification of binding. MCM enables the application of EC to arbitrary TPs by enhancing the mobility differences between TPs, TPRs, and TP-TPR complexes. This technology is homogeneous and overcomes many practical challenges of conventional heterogeneous assays. We developed various formats of assays for equilibrium and kinetic analysis and rapid determination of degradation of TPs, obtaining results comparable to state-of-the-art technologies with significantly less time (<1 h) and simpler setup. Finally, we demonstrated that the results of MCM-EC based assays correlated well with those from mass spectrometry and cell-based assay, which are the industrial standards for quality testing of TPs.

Proteinases, their receptors and inflammatory signalling: the Oxford South Parks Road connection

In keeping with the aim of the Paton Memorial Lecture to 'facilitate the historical study of pharmacology', this overview, which is my distinct honour to write, represents a 'Janus-like' personal perspective looking both backwards and forwards at the birth and growth of 'receptor molecular pharmacology' with special relevance to inflammatory diseases. The overview begins in the Oxford Department of Pharmacology in the mid-1960s and then goes on to provide a current perspective of signalling by proteinases. Looking backwards, the synopsis describes the fruitful Oxford Pharmacology Department infrastructure that Bill Paton generated in keeping with the blueprint begun by his predecessor, J H Burn. Looking forwards, the overview illustrates the legacy of that environment in generating some of the first receptor ligand-binding data and providing the inspiration and vision for those like me who were training in the department at the same time. With apologies, I mention only in passing a number of individuals who benefitted from the 'South Parks Road connection' using myself as one of the 'outcome study' examples. It is also by looking forward that I can meet the complementary aim of summarizing the lecture presented at a 'BPS 2014 Focused Meeting on Cell Signalling' to provide an overview of the role of proteinases and their signalling mechanisms in the setting of inflammation.

Biased signalling and proteinase-activated receptors (PARs): targeting inflammatory disease

Although it has been known since the 1960s that trypsin and chymotrypsin can mimic hormone action in tissues, it took until the 1990s to discover that serine proteinases can regulate cells by cleaving and activating a unique four-member family of GPCRs known as proteinase-activated receptors (PARs). PAR activation involves the proteolytic exposure of its N-terminal receptor sequence that folds back to function as a 'tethered' receptor-activating ligand (TL). A key N-terminal arginine in each of PARs 1 to 4 has been singled out as a target for cleavage by thrombin (PARs 1, 3 and 4), trypsin (PARs 2 and 4) or other proteases to unmask the TL that activates signalling via Gq , Gi or G12 /13 . Similarly, synthetic receptor-activating peptides, corresponding to the exposed 'TL sequences' (e.g. SFLLRN-, for PAR1 or SLIGRL- for PAR2) can, like proteinase activation, also drive signalling via Gq , Gi and G12 /13 , without requiring receptor cleavage. Recent data show, however, that distinct proteinase-revealed 'non-canonical' PAR tethered-ligand sequences and PAR-activating agonist and antagonist peptide analogues can induce 'biased' PAR signalling, for example, via G12 /13 -MAPKinase instead of Gq -calcium. This overview summarizes implications of this 'biased' signalling by PAR agonists and antagonists for the recognized roles the PARs play in inflammatory settings.

Historical perspectives in fat cell biology: the fat cell as a model for the investigation of hormonal and metabolic pathways

For many years, there was little interest in the biochemistry or physiology of adipose tissue. It is now well recognized that adipocytes play an important dynamic role in metabolic regulation. They are able to sense metabolic states via their ability to perceive a large number of nervous and hormonal signals. They are also able to produce hormones, called adipokines, that affect nutrient intake, metabolism and energy expenditure. The report by Rodbell in 1964 that intact fat cells can be obtained by collagenase digestion of adipose tissue revolutionized studies on the hormonal regulation and metabolism of the fat cell. In the context of the advent of systems biology in the field of cell biology, the present seems an appropriate time to look back at the global contribution of the fat cell to cell biology knowledge. This review focuses on the very early approaches that used the fat cell as a tool to discover and understand various cellular mechanisms. Attention essentially focuses on the early investigations revealing the major contribution of mature fat cells and also fat cells originating from adipose cell lines to the discovery of major events related to hormone action (hormone receptors and transduction pathways involved in hormonal signaling) and mechanisms involved in metabolite processing (hexose uptake and uptake, storage, and efflux of fatty acids). Dormant preadipocytes exist in the stroma-vascular fraction of the adipose tissue of rodents and humans; cell culture systems have proven to be valuable models for the study of the processes involved in the formation of new fat cells. Finally, more recent insights into adipocyte secretion, a completely new role with major metabolic impact, are also briefly summarized.

Protein targets of inflammatory serine proteases and cardiovascular disease

Serine proteases are a key component of the inflammatory response as they are discharged from activated leukocytes and mast cells or generated through the coagulation cascade. Their enzymatic activity plays a major role in the body's defense mechanisms but it has also an impact on vascular homeostasis and tissue remodeling. Here we focus on the biological role of serine proteases in the context of cardiovascular disease and their mechanism(s) of action in determining specific vascular and tissue phenotypes. Protease-activated receptors (PARs) mediate serine protease effects; however, these proteases also exert a number of biological activities independent of PARs as they target specific protein substrates implicated in vascular remodeling and the development of cardiovascular disease thus controlling their activities. In this review both PAR-dependent and -independent mechanisms of action of serine proteases are discussed for their relevance to vascular homeostasis and structural/functional alterations of the cardiovascular system. The elucidation of these mechanisms will lead to a better understanding of the molecular forces that control vascular and tissue homeostasis and to effective preventative and therapeutic approaches.

Proteinases as hormones: targets and mechanisms for proteolytic signaling

Proteinases, such as kallikrein-related peptidases, trypsin and thrombin, can play hormone-like 'messenger roles in vivo. They can regulate cell signaling by cleaving and activating a novel family of G-protein-coupled proteinase-activated receptors (PARs 1-4) by unmasking a tethered receptor-triggering ligand. Short synthetic PAR-derived peptide sequences (PAR-APs) can selectively activate PARs 1, 2 and 4, causing physiological responses in vitro and in vivo. Using the PAR-APs to activate the receptors in vivo, it has been found that PARs, like hormone receptors, can affect the vascular, renal, respiratory, gastrointestinal, musculoskeletal and nervous systems (central and peripheral). PARs trigger responses ranging from vasodilatation to intestinal inflammation, increased cytokine production and increased nociception. These PAR-stimulated responses have been implicated in various disease states, including cancer, atherosclerosis, asthma, arthritis, colitis and Alzheimer's disease. In addition to targeting the PARs, proteinases can also cause hormone-like effects by other signaling mechanisms that may be as important as the activation of PARs. Thus, the PARs themselves, their activating serine proteinases and their signaling pathways can be considered as attractive targets for therapeutic drug development. Further, proteinases can be considered as physiologically relevant 'hormone-like' messengers that can convey signals locally or systemically either via PARs or by other mechanisms.

Membrane topology as revealed by the binding of macromolecules

Binding sites for specific molecules at the cell surface can be localized with the electron microscope in thin-section, freeze-etch and shadow-casting preparations. The receptors tested were binding sites to concanavalin A (Con A) labelled with haemocyanin and binding sites to insulin labelled with ferritin. Con A-binding sites were localized in endocrine cells of the pancreas and insulin-binding sites in isolated liver plasma membranes. The relevance of the topographical distribution of the binding sites to cell membrane organization is discussed.

Proteinases and signalling: pathophysiological and therapeutic implications via PARs and more

Proteinases like thrombin, trypsin and tissue kallikreins are now known to regulate cell signaling by cleaving and activating a novel family of G-protein-coupled proteinase-activated receptors (PARs 1-4) via exposure of a tethered receptor-triggering ligand. On their own, short synthetic PAR-selective PAR-activating peptides (PAR-APs) mimicking the tethered ligand sequences can activate PARs 1, 2 and 4 and cause physiological responses both in vitro and in vivo. Using the PAR-APs as sentinel probes in vivo, it has been found that PAR activation can affect the vascular, renal, respiratory, gastrointestinal, musculoskeletal and nervous systems (both central and peripheral nervous system) and can promote cancer metastasis and invasion. In general, responses triggered by PARs 1, 2 and 4 are in keeping with an innate immune inflammatory response, ranging from vasodilatation to intestinal inflammation, increased cytokine production and increased or decreased nociception. Further, PARs have been implicated in a number of disease states, including cancer and inflammation of the cardiovascular, respiratory, musculoskeletal, gastrointestinal and nervous systems. In addition to activating PARs, proteinases can cause hormone-like effects by other signalling mechanisms, like growth factor receptor activation, that may be as important as the activation of PARs. We, therefore, propose that the PARs themselves, their activating serine proteinases and their associated signalling pathways can be considered as attractive targets for therapeutic drug development. Thus, proteinases in general must now be considered as 'hormone-like' messengers that can signal either via PARs or other mechanisms.

BIOCHEMICAL EVALUATION OF ANTIDIABETOGENIC PROPERTIES OF SOME COMMONLY USED INDIAN PLANTS ON STREPTOZOTOCIN-INDUCED DIABETES IN EXPERIMENTAL RATS

1. Diabetes mellitus is a serious metabolic disorder with micro- and macrovascular complications that results in significant morbidity and mortality. 2. The aim of the present study was to evaluate the hypoglycaemic efficacy of commonly used traditional Indian plants, such as Murraya koenigii, Mentha piperitae, Ocimum sanctum and Aegle marmelos, in streptozotocin (STZ)-induced experimental rats. 3. Oral administration of the ethanolic extract of these plants resulted in a significant decrease in the levels of blood glucose, glycosylated haemoglobin and urea, with a concomitant increase in glycogen, haemoglobin and protein, in diabetic rats. Treatment with these plant extracts also resulted in an increase in insulin and C-peptide levels and glucose tolerance. 4. The decreased activities of carbohydrate-metabolising enzymes, such as hexokinase, glucose-6-phosphate dehydrogenase and glycogen synthase, in diabetic rats were significantly elevated towards near normal in rats treated with extracts of M. koenigii, O. sanctum and A. marmelos; the increased activities of lactate dehydrogenase, fructose-1,6-bisphosphatase, glucose-6-phosphatase and glycogen phosphorylase in STZ diabetic rats were significantly reduced following treatment with the plant extracts. 5. Elevated specific binding of [(125)I]-labelled insulin to the receptor found in diabetic rats was markedly decreased in extract-treated groups. However, treatment of diabetic rats with M. piperitae did not result in any significant modification in all parameters. 6. Phytochemical screening conducted by us revealed the presence of biologically active ingredients in the ethanolic extracts of M. koenigii, O. sanctum and A. marmelos, which may readily account for the observed hypoglycaemic activity.

Absence of the lipid phosphatase SHIP2 confers resistance to dietary obesity

Genetic ablation of Inppl1, which encodes SHIP2 (SH2-domain containing inositol 5-phosphatase 2), was previously reported to induce severe insulin sensitivity, leading to early postnatal death. In the previous study, the targeting construct left the first eighteen exons encoding Inppl1 intact, generating a Inppl1(EX19-28-/-) mouse, and apparently also deleted a second gene, Phox2a. We report a new SHIP2 knockout (Inppl1(-/-)) targeted to the translation-initiating ATG, which is null for Inppl1 mRNA and protein. Inppl1(-/-) mice are viable, have normal glucose and insulin levels, and normal insulin and glucose tolerances. The Inppl1(-/-) mice are, however, highly resistant to weight gain when placed on a high-fat diet. These results suggest that inhibition of SHIP2 would be useful in the effort to ameliorate diet-induced obesity, but call into question a dominant role of SHIP2 in modulating glucose homeostasis.

Purification and characterization of a feline hepatic insulin receptor

OBJECTIVE

To elucidate the functional characteristics of a highly purified soluble liver insulin receptor in cats.

SAMPLE POPULATION

Frozen livers from domestic cats were obtained commercially.

PROCEDURES

The feline hepatic insulin receptor was purified from Triton X-100 solubilized plasma membranes by the use of several chromatography matrices, including affinity chromatography on an insulin-Sepharose matrix.

RESULTS

The receptor, although not homogeneous, was purified 3,000-fold. Two silver-stained protein bands were identified following sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) with molecular weight of 134,000 and 97,000, which are similar to insulin receptors isolated from other animals. This isolated receptor had steady-state insulin binding by 40 minutes at 24 C. Optimal insulin binding occurred at pH 7.8 and with 150 mM NaCl. Under these conditions, a curvilinear Scatchard plot was obtained with the isolated receptor. Using a 2 binding-site model, the feline insulin receptor had a high-affinity low-capacity site with a dissociation constant (KD; nM) of 3 and a low-affinity high-capacity site with a K(D) of 1,180. The receptor also had tyrosine kinase activity toward an exogenous substrate that was stimulated by insulin and protamine.

CONCLUSIONS AND CLINICAL RELEVANCE

Many of the reported characteristics of the liver insulin receptor in cats are similar to those for the receptor isolated from other animals and tissues, although some differences exist. These similarities suggest that characterization of the feline insulin receptor is important to understanding insulin resistance in cats with diabetes as well as in humans with diabetes.

Five-compartment model of insulin kinetics and its use to investigate action of chloroquine in NIDDM

We have constructed a five-compartment model of insulin kinetics. The model structure was chosen to reflect insulin distribution in systemic plasma, hepatic plasma, and interstitial fluid and insulin binding to the liver and peripheral receptors, and it included receptor-mediated and non-receptor-mediated insulin degradation. Model parameters were estimated from plasma insulin concentrations measured during hyperinsulinemic euglycemic clamp studies. In the fasting condition, the model-derived mean residence time of endogenously secreted insulin was 71 min, of which 62 min were spent bound to the liver receptor, 6 min bound to the peripheral receptor, 2 min circulating in hepatic or systemic plasma, and 1 min in the interstitial fluid. More than 80% of total insulin was bound to the liver receptor, indicating that the liver is by far the largest insulin reservoir. The model was employed to assess the effect of chloroquine on insulin kinetics in patients with non-insulin-dependent diabetes mellitus (NIDDM). Chloroquine significantly altered parameter vector. However, the mean residence times of insulin in the system and in the periphery were not affected, indicating that the beneficial effect of chloroquine in patients with NIDDM under conditions of euglycemia could not be attributed to changes in insulin kinetics.

Acute effects of ethanol on hepatic endocytosis and processing of insulin in perfused rat liver

This study utilizes the perfused rat liver combined with subcellular fractionation and compartmental analysis to investigate the effects of ethanol on hepatic uptake, endocytosis, and processing of insulin. At 4 min after the start of a 2-min pulse of radiolabeled insulin, increasing ethanol concentrations progressively inhibited insulin uptake by the liver (57% at 50 mM ethanol). Subcellular fractionation of the perfused livers showed a progressive shift in distribution from a predominantly endosomal location (control) to a bimodal distribution between endosomes and plasma membrane. This could be largely accounted for by a specific reduction in the endosome-associated insulin. Binding studies showed no changes in the binding properties of the plasma membrane insulin receptor. Compartmental analysis of the perfusate efflux curves confirmed the lack of effect of ethanol on the binding constants but showed a significant decrease in the endocytic rate constant (50%) together with an increase in the retroendocytic rate constant (33%). Simulation studies with the compartmental model showed that these changes could account for the observed decrease in uptake by the liver. No changes were found in the subsequent endocytic degradation of insulin.

Internalization and release of insulin from hepatocytes

Degradation of internalized insulin was studied after binding at 25 degrees C and 37 degrees C to isolated hepatocytes. The cells were washed to avoid extracellular insulin contamination. Degradation of both, intracellular and extracellular 125I-insulin, was measured with TCA and insulin antibody. In these conditions binding at 25 degrees C and 37 degrees C was equal but both intra and extracellular degradation were greater at 37 degrees C than at 25 degrees C. At both temperatures, intracellular degradation was greater than extracellular degradation with accumulation of degraded and non-degraded intracellular insulin. To study in what state hepatocytes release internalized insulin into the medium, 125I-insulin association was performed at an intermediate temperature (30 degrees C). Extracellular insulin contamination (whether associated or not) was avoided by three methods: 1) washing; 2) treatment with insulin degrading enzyme(s) and washing; 3) treatment with insulin degrading enzyme(s) then with trypsin and washing. Kinetics of radioactivity released from the cells was identical in the three conditions and the radioactivity was released throughout the experiments. Complete degradation of the released insulin was observed by gel filtration when the previous binding was 0.4 ng insulin/10(6) cells. When the dose of associated insulin increased (25 ng/10(6) cells) 3.5% of non-degraded insulin was liberated and when the dose was 14,300 ng/10(6) cells, the insulin released was 44.3%. In one experiment during the first 30 min, the insulin released was 52.88% and in the last 45 min 39.59%. To study the biologic behavior of the insulin released from cells, a group of mice were injected with this insulin (8.4 mU/mouse) and blood glucose was measured. The released insulin behaved as intact insulin as far as blood glucose responses were concerned. We may conclude that liver cells have the ability to internalize insulin and release biologically active insulin after accumulation.

Characterization of the binding sites for glutaraldehyde-polymerized albumin on purified woodchuck hepatocyte plasma membranes

Highly purified woodchuck hepatocyte plasma membranes demonstrated tight specific binding to glutaraldehyde-polymerized serum albumin immobilized on Sepharose macrobeads. This phenomenon was characterized in detail and used for recognition of the plasma membrane constituents involved in binding of the albumin polymer. The hepatocyte membrane-polyalbumin interaction was found to be ligand-specific, saturable, and time-dependent. Other characteristics of a specific receptor-ligand interaction were also noted, including a dependence on the temperature, pH, and ionic strength of the binding medium. Kinetic studies revealed the presence of two classes of binding sites for glutaraldehyde-polymerized albumin on purified membranes. The sites mediating the saturable high-affinity binding of polymer to hepatocyte membranes could not be solubilized by Triton X-100. Binding activity of Triton-insoluble membrane residues was inhibited by heat treatment and proteolysis, and was significantly suppressed by neuroaminidase digestion. These findings suggest a glycoprotein nature for the high-affinity binding sites and indicate that the corresponding receptors apparently are tightly associated with the plasma membrane matrix. In contrast, low-affinity binding of polymeric albumin was inhibited by both Triton X-100 and pronase, was resistant to neuraminidase, and was activated by lipase, suggesting that membrane lipids are important for the binding conduct. In conclusion, these results provide clear evidence that hepatocyte plasma membranes are endowed with at least two classes of chemically distinct binding components, which are able to specifically recognize serum albumin artificially modified by glutaraldehyde treatment. Therefore, they suggest that in vivo hepatocytes may perform a specific receptor-dependent uptake of ligands expressing glutaraldehyde-polymerized albumin specificity. This phenomenon may play an important role in the proposed participation of naturally modified human serum albumin as a bridge in the attachment and penetration into host hepatocyte of hepatitis B virus, which is known to possess a receptor that is specific for glutaraldehyde-cross-linked human serum albumin.

Potentiation of insulin stimulation of hexose transport by kallikrein and bradykinin in isolated rat adipocytes

Kallikrein and bradykinin additively increased adipocyte hexose transport under conditions of maximal intrinsic insulin stimulation, while no such effect occurred in the absence of insulin. The potentiation of insulin action follows a dose-response relationship with kallikrein and bradykinin concentrations consistent with a physiological role for the latter in the modulation of insulin action. Insulin degradation by isolated adipocytes and insulin binding to its receptors on adipocyte plasma membranes were not affected by either kallikrein or bradykinin. Thus, the kallikrein and bradykinin potentiation of insulin action occur at post-insulin binding sites. In conclusion, the kallikrein-bradykinin system increases the supply of substrates to target tissues through vasodilation and augmented blood perfusion, and it also stimulates glucose uptake and metabolism via its potentiation of insulin action. These actions suggest that the kallikrein-bradykinin system regulate both the availability and utilization of metabolic substrates, in target tissues.

Optimisation of conditions for solubilisation of the bovine dopamine D2 receptor

Solubilisation of the dopamine D2 receptor from a membrane preparation of bovine corpus striatum using cholate and NaCl was independently optimised with regard to cholate (0.2%, wt/vol), NaCl (1.5 M), and membrane protein (4 mg/ml) concentrations. A maximum solubilisation yield of 58% was obtained and receptors were measured using a [3H]spiperone binding assay incorporating a polyethylene glycol precipitation step. Solubilisation was confirmed by ultracentrifugation studies, passage of the receptor through fine-pore filters, increased thermolability, and by retention of the prelabelled receptor on gel filtration. The soluble receptor showed saturability and reversibility of binding. Displacement of [3H]spiperone from the soluble receptor by competing compounds correlated closely with displacement from the membrane-bound receptors. [3H]Spiperone binding was found to be pH-dependent, with maximum binding occurring at pH 7.8. A comparison of solubilisation was made with six other agents both with and without added NaCl and it was concluded that the cholate/NaCl solubilisation system provides an efficient, inexpensive, and reliable method for the preparation of functional bovine dopamine D2 receptors.

Insulin binding to differentiating muscle cell line L6

We studied insulin binding to cultured differentiating muscle cell line L6. Insulin binding to the cells reached a plateau after incubation with 125I-insulin for 4 h at 22 degrees C, and was at an optimum at pH 7.8. Preincubation with 10 microM of hydrocortisone for 36 h at 37 degrees C resulted in significantly increased insulin binding (1.73 +/- 0.12 ng/mg protein for treated cells vs. 1.13 +/- 0.025 ng/mg protein for control cells, mean +/- SD, P less than 0.001). Preincubation with 1 microM of hydrocortisone or 1 microM of dexamethasone also led to increased binding. The number of insulin-binding sites per cell increased 2.5-fold in glucocorticoid-treated cells (9.7 X 10(3) sites/cell for treated vs. 3.8 X 10(3) sites/cell for control cells). Preincubation with trifluoperazine (5 microM), a calmodulin inhibitor, did not affect insulin binding to the cells. These results indicate that glucocorticoid might have some important role in regulating the number of insulin receptors in L6 muscle cells.

Evidence for an early degradative event to the insulin molecule following binding to hepatocyte receptors

We have used photoreactive insulin analogues to investigate as related processes, early structural modification of the receptor-bound insulin molecule and internalisation of the insulin-receptor complex. In isolated rat hepatocytes an initial modification of bound insulin leads to the generation of a molecular species unchanged in molecular weight but with reduced receptor and antibody binding affinities and altered electrophoretic mobility. Using photoreactive insulin analogues and density gradient cell fractionation the insulin receptor complex has been shown to undergo internalisation from the plasma membrane to a low density vesicular fraction, the endosome. No labelled material was found in lysosomal fractions after up to 10 min incubation at 37 degrees C. The degree of labelling of the endosome fraction depended on the position of the photoreactive group within the insulin molecule. The data suggest that before or during endocytosis, a small peptide is proteolytically cleaved from the C terminus of the insulin B chain.

Dissociation of insulin binding from insulin stimulation of 2-deoxyglucose transport by ruthenium red

Ruthenium red increased specific insulin binding to isolated adipocytes 5.4 fold and 2.6 fold over binding determined in the absence and presence of Ca2+ and Mg2+. The increase in insulin binding was not accompanied by an increase in insulin sensitivity. The lack of effect of ruthenium red on insulin action argued strongly against an increase in intracellular Ca2+ as a potential messenger/transducer of insulin action and suggested that the enhancing effect of Ca2+ on insulin action was a result of increased receptor affinity.

Characterization of insulin binding to bovine liver and mammary microsomes

Bovine liver and mammary gland (MG) appear metabolically independent of insulin, yet the specificity and kinetics of 125I-insulin (125I-INS) binding to bovine liver and MG microsomes (MIC) indicate the presence of insulin receptors in MIC from both tissues. The insulin receptors from bovine liver (Kd = 7.6 X 10(-10) M) and MG (Kd = 9.6 X 10(-11) M) were similar to each other and to other insulin receptors in their binding affinities and pH optima. Perturbation of rat liver and bovine MG MIC by phospholipase or NaCl treatment increased 125I-INS binding to the membranes, suggesting exposure of cryptic insulin receptors. Different responses in 125I-INS binding to membrane perturbation suggest differences between rat and bovine membranes.

Corticosteroids as long-term regulators of the insulin effectiveness in mouse 3T3 adipocytes

Since corticosteroid treatment is often accompanied by insulin resistance, we explored the role of corticosteroids in the regulation of the insulin effectiveness in cultured 3T3 (mouse) adipocytes. Exposure of the fat cells to dexamethasone or corticosterone (0-5 days) induced a time-, concentration-, and protein synthesis-dependent and reversible decrease in insulin binding and in basal and insulin-stimulated 2-deoxyglucose uptake. The decrease in binding (50%) was primarily due to a decrease in receptor affinity i.e. to an increase in the rate of dissociation of insulin from its receptors, and was independent from the effects of pH and temperature on the affinity. The reduction in the 2-deoxyglucose uptake (30-50%) was due to a decrease in the hexose transport capacity rather than to a decrease in the phosphorylation component of the 2-deoxyglucose uptake process. Lineweaver-Burk analysis revealed the dexamethasone induced a decrease in the apparent Vmax of the transport system i.e. in the number or activity of the hexose transporters. The effect of dexamethasone seemed to be superimposed on that of long-term insulin treatment, suggesting a different mechanism. It is concluded that corticosteroids act as long-term regulators of the insulin effectiveness by influencing the rate at which insulin dissociates from its receptors and by altering the number or activity of the hexose transporters by a common mechanism, which differs from that of the long-term regulatory effect of insulin.

Unmasking of insulin receptors in rat submaxillary gland microsomes: effect of high ionic strength, phospholipase C and S-adenosyl-L-methionine

The specific binding of [125I]insulin to submaxillary gland microsomes was significantly enhanced by increasing the ionic strength of the incubation medium. This effect was neither related to changes in receptor or hormone degradation nor in the polymerization of the tracer. When equilibrium binding data from competition curves of unlabelled insulin versus [125I]insulin were analyzed, a marked increase in total binding capacity in high ionic strength was observed (from 890 to 2440 fmol/mg protein), with no change in binding affinity. Phospholipase C digestion was also able to increase specific [125I]insulin binding to microsomes. These results suggest the presence of masked receptors in submaxillary gland microsomes. Methylation of rat submaxillary gland microsomes by using S-adenosyl-L-methionine as the methyl donor significantly increased [125I]insulin binding. Scatchard analysis of the equilibrium binding data showed that addition of S-adenosyl-L-methionine (0.46 mM) to microsomes resulted in an enhancement of the total binding capacity (from 990 to 1520 fmol/mg protein) with no change in the affinity constants, which suggests the exposure of masked insulin receptors under such conditions. Both the methyl group incorporation into membrane phospholipids and the effect on insulin binding were dependent on the S-adenosyl-L-methionine concentration used and were partially suppressed in the presence of S-adenosyl-L-homocysteine, a specific competitive inhibitor of the methyltransferases activity. When microsomes were treated with S-adenosyl-L-[methyl-3H]methionine, the 3H-labelled methyl groups incorporated were found mainly in the lipid fraction associated to phosphatidylcholine, suggesting in this case that the unmasking of insulin receptors could be a consequence of alterations produced in membrane composition. The effects of phospholipase C, S-adenosyl-L-methionine and high ionic strength on insulin binding were not additive, suggesting that these procedures unmask receptors from the same pool.

Treatment with an ascochlorin derivative, AS-6 increases 45Ca2+ binding on the plasma membrane of adipocytes in db/db mice

Genetically obese diabetic mice (db/db) have greatly diminished 45Ca2+ binding on the plasma membranes of the adipocytes (45-55%) compared with their lean littermates. Treatment for 1 week with a diet admixture of AS-6 (0.1% in the diet) significantly restored the binding to a level comparable to the lean littermates. The addition of AS-6 in vitro had no effect on the binding, which eliminates the possibility that AS-6 is a Ca2+ ionophore. The results suggest that AS-6 treatment enhances the Ca2+ binding by causing structural alteration(s) in the membranes.

ATP and other nucleoside triphosphates inhibit the binding of insulin to its receptor

ATP, in a dose-dependent manner, inhibited the binding of 125I-insulin to its receptor in rat liver and human placental membranes. With rat liver plasma membranes an effect of ATP was detected at concentrations between 1.0 and 2.5 mmol/L, and maximal effects were seen at 10.0 mmol/L where binding was decreased by approximately 40%. The effect of ATP was one half-maximal within 10 minutes and maximal within 60 minutes. Scatchard analysis indicated that ATP was acting primarily to change the binding affinity of the insulin receptor. The effect of ATP was mimicked by CTP, GTP, and UTP, but not by ADP, 5'-AMP, 3'-AMP, 3'5'-cyclic AMP and adenosine. The ATP analog AMP-PNP had a potency approximately 10% that of ATP. The effect of ATP was not significantly influenced by inhibitors of phosphoprotein kinases and phosphoprotein phosphatases. In human placental membranes, ATP had a similar effect in inhibiting 125I-insulin binding to its receptor. Moreover, ATP was active in inhibiting insulin binding to purified human placental insulin receptors at 0.01 mmol/L, a concentration 1/100 of that needed for inhibiting binding to intact membranes. These studies indicate, therefore, that ATP and other nucleoside triphosphates influence the ability of the insulin receptor to bind insulin.

The effect of phenformin and other adenosine triphosphate (ATP)-lowering agents on insulin binding to IM-9 human cultured lymphocytes

In the present study, we investigated the mechanism by which the antidiabetic drug phenformin increases insulin binding to its receptors in IM-9 human cultured lymphocytes. After a 24-hr preincubation, phenformin induced a twofold increase in specific 125I-insulin binding, and removal of phenformin was followed 6 hr later by a return in binding to control levels. This effect of phenformin on insulin binding was not a consequence of either inhibition of cell growth, changes in cellular cyclic adenosine monophosphate (AMP) levels, or changes in guanosine triphosphate (GTP) content. Since phenformin is known to inhibit various aspects of cellular energy metabolism, the relationship between 125I-insulin binding and energy metabolism in IM-9 cells was investigated. The phenformin-induced increase in insulin binding to IM-9 cells was related to a time- and dose-dependent decrease in ATP levels. Other agents that lowered ATP levels, including antimycin, dinitrophenol, and 2-deoxyglucose, also raised insulin binding. These studies indicated, therefore, that phenformin enhances insulin binding to receptors on IM-9 cells and that this effect on insulin receptors may be related to alterations in metabolic functions that are reflected by a lowering of ATP levels.

Dogfish insulin. Primary structure, conformation and biological properties of an elasmobranchial insulin

Insulin from an elasmobranch, the spiny dogfish (Squalus acanthias) has been purified to near homogeneity by means of acid-ethanol extraction and salt precipitation. The amino acid sequences of the performic-acid-oxidised A and B chains have been determined and exhibit some unusual features. The A chain contains a total of 22 amino acids; only the insulin from coypu (a member of the Rodentia suborder, Hystricomorpha), has previously been reported to contain an extension past the A21 asparagine. The B10 histidine, which is involved in the formation of the insulin hexamers in higher vertebrates through the co-ordination of zinc, is present in this elasmobranch insulin. Several substitutions relative to bovine insulin occur in the proposed receptor binding region (A5Gln leads to His, B21Glu leads to Pro, B22Arg leads to Lys, B25Phe leads to Tyr). In spite of these substitutions, the maximal response in the rat epididymal fat cell assay is the same for bovine and dogfish insulins; the concentration required to produce the half-maximal response is, however, approximately threefold greater for dogfish insulin than that of bovine insulin. The use of interactive computer graphics model-building predicts that the dogfish insulin can attain a three-dimensional structure very similar to that of bovine insulin; circular dichroic spectra are presented which support the model-building studies.

Insulin receptor antiserum and plant lectins mimic the direct effects of insulin on nuclear envelope phosphorylation

Insulin directly inhibits protein phosphorylation in isolated rat liver nuclear envelopes. In the present studies, an antiserum to insulin receptor as well as the plant lectins concanavalin A and phytohemagglutinin mimicked insulin action in isolated nuclear envelopes. These studies suggest that insulin and agents that mimic it may directly regulate nuclear functions.

Further evidence for distinction between sex hormone-binding globulin and an androgen-binding protein in hydatidiform mole serum

We further studied the androgen-binding protein (ABP) that we recently evidenced in the serum from two patients with hydatidiform mole [Ref. 4]. This protein was further shown to be distinct from the sex hormone-binding globulin (SHBG) by concanavalin A and ion-exchange chromatographies, as well as spectrophotometric and kinetic studies. However, the ABP was shown to have a molecular weight and relative affinities for several steroids, similar to those of SHBG. Our results lead us to suppose that the ABP previously evidenced in molar vesicles and fluid [Ref. 5] is secreted in the serum. It is, however, likely that the secretion process alters the binding affinity of this protein. The presence of this additional binding component in the serum of patients with such trophoblastic tumours, may reduce severely the free 17 beta-hydroxyandrogens levels, as well as may help create a release gradient in the serum steroids buffer stores.

Complete monitoring of the purification of the plasma membrane from rabbit skeletal muscle

A fast and reproducible purification procedure for rabbit skeletal muscle plasma membrane is described. Each step was monitored by determination of tetrodotoxin, ouabain and insulin receptors. A ouabain-sensitive K+-stimulated and a Ca2+-dependent phosphatases, probably identical to, respectively the (Na+-K+) and Ca2+-ATPases, were also evaluated. All plasma membrane receptors and the ouabain-sensitive activity accumulated in the lightest fraction separated by sucrose gradient centrifugation (peak at 18% sucrose; purification from crude homogenate, 30-fold).

Insulinomimetic homology of concanavalin A

A striking peptide sequence and three dimensional conformational homology between a portion of insulin and the plant lectin concanavalin A is described. This amino acid sequence has been demonstrated to be essential to the bioactivity of the hormone insulin. The insulinomimetic activity of the plant lectin on hormone target cells coupled with the presence of an insulin-homologous sequence and conformation offers insight into the mechanism of insulin action.

Triphenylmethylphosphonium cation distribution as a measure of hormone-induced alterations in white adipocyte membrane potential

Triphenylmethylphosphonium (TPMP+) partitions into the mitochondrial and cytosolic compartments in the rat white adipocyte in a potential-dependent fashion. The relationship between [3H]TPMP+ distribution, intracellular cAMP generation and lipolysis in response to hormones and cAMP-mimetic compounds was examined. Half-maximal [3H]TPMP+ efflux and glycerol release were produced by 15 and 9 nM adrenocorticotropin, 170 and 110 nM 1-epinephrine, 70 and 27 microM isobutylmethylxanthine and 800 and 750 microM dibutyryl cAMP, respectively. Hormone-stimulated cAMP generation was also correlated with [3H]TPMP+ efflux and lipolysis in terms of concentration dependency. In kinetic experiments, glycerol release and [3H]TPMP+ efflux in response to adrenocorticotropin or cholera toxin proceeded over a similar time course, whereas an earlier rise in cAMP generation was detected. The depolarizing effect of lipolytic compounds was localized to the mitochondrial compartment. When cells were incubated in elevated-[K+]0 buffer, the stimulatory effect of dibutyryl cAMP on [3H]TPMP+ efflux and lipolysis persisted, suggesting that maintenance of the plasma membrane potential is not critical for demonstration of these responses. When the extracellular concentration of serum albumin, which provides binding sites for free fatty acids, was increased from 1 to 3%, an increase in glycerol release and a decrease in [3H]TPMP+ efflux was observed. We suggest that intracellular free fatty acid accumulation in response to lipolytic agents causes dissipation of the mitochondrial membrane potential and efflux of [3H]TPMP+ from the organelle and cell.

Similar activities of nerve growth factor and its homologue proinsulin in intracellular hydrogen peroxide production and metabolism in adipocytes. Transmembrane signalling relative to insulin-mimicking cellular effects

Generation of hydrogen peroxide in adipocyte plasma membrane and its intracellular metabolism and regulatory role have been shown by Mukherjee and co-workers to be a major effector system for insulin [Fedn Proc. 35, 1694 (1976); Archs Biochem. Biophys. 184, 69 (1977); Biochem. Pharmac. 27, 2589 (1978); Fedn Proc. 37, 1689 (1978); and Biochem. Pharmac. 29, 1239 (1980)]. The possible involvement of this mechanism in the action of structurally similar polypeptides having some insulin-like metabolic effects was investigated. The beta-subunit of nerve growth factor (2.5 S NGF, mol. wt 13,500) which has a striking structural homology with proinsulin and has been reported to exert certain insulin-like metabolic effects in its own target tissues (e.g. growing neurites and sympathetic ganglia), and the insulin-derived polypeptides, desalanine-insulin and desoctapeptide-insulin, as well as proinsulin, were examined for their effects on rat adipocytes, employing the technique of formate oxidation. Both NGF and proinsulin caused increased [14C]formate oxidation, showing similar intrinsic activities, up to a maximum of 140-160% of the basal rate; insulin increased the rate to 190-210% of the basal rate. The relative potencies of the hormones toward H2O2 formation and stimulation of the pentose phosphate pathway activity were: insulin (EC50: 2.5 x 10(-11) M), desalanine-insulin (EC50: 2.5 x 10(-10) M), proinsulin (EC50: 8 x 10(-9) M), and NGF (EC50: 10(-9) M). The biologically inactive derivative, desoctapeptide-insulin, did not stimulate glucose oxidation, although it caused a small increase in formate oxidation, with an EC50 of 5 x 10(-7) M, indicating a suboptimal level of H2O2 formation in the elevation of the hexose monophosphate shunt activity. 3-Amino-1,2,4-triazole (50 mM), which irreversibly decomposes the peroxidatic compound II of the catalase: H2O2 complex, inhibited formate oxidation to a greater extent in the hormone-treated cells than in the control cells, whereas sodium azide, an inhibitor of the hemoprotein, catalase, completely inhibited it. The abilities of the polypeptides to stimulate H2O2 formation correlated with their abilities to promote lipogenesis from [U-14C]-D-glucose, as expected of insulin. The cellular GSH/GSSG ratio increased concomitantly with the stimulation of glucose oxidation via the shunt, indicating a tight coupling between these processes. The results confirm that the hydrogen peroxide production is a common basis of the metabolic actions of growth-promoting polypeptide hormones or mitogens beyond their respective receptors.

Receptors for a cytotoxic lectin, abrin and their role in cell intoxication

The nature of binding of abrin to Chinese hamster ovary cells was examined in relation to the ensuing intoxication of the treated cells. Approx. 20% of [125I] abrin bound to CHO cells at 37 degree C was found to be resistant to the addition or presence of 0.1 M lactose. The extent of lactose-resistant binding depended inversely upon the temperature of incubation. Among various proteins, lectins and sugars, only non-labeled abrin could strongly inhibit the lactose-resistant binding of [125I] abrin. Lactose-resistant binding could lead to an inhibition of cellular protein synthesis and to a loss of cell viability. Abrin molecules bound at the lactose-sensitive and lactose-resistant binding sites apparently have an equal probability of being internalized by CHO cells. Binding of approx. 3.10(3) abrin molecules per CHO cell was required to elicit 50% loss of cell viability regardless of whether the binding occurs in the presence or absence of lactose. The result of a cross-linking experiment suggested that a membrane protein with an Mr of about 45 000 may be responsible for the lactose-resistant binding of abrin.