Insulin-induced rapid decrease of a major protein in fat cell plasma membranes

In order to increase our understanding of the mode of action of insulin in rat fat cells, we investigated the effect of insulin on protein concentrations in purified fat cell fractions using two-dimensional electrophoresis in combination with an ultrasensitive color silver stain technique. Incubation of fat cells with insulin caused a 90% decrease in the plasma membrane concentration of a major plasma membrane protein with a molecular mass of 90 kDa. The insulin effect was dose-dependent with a half-maximal effect at 9.5 microunits/ml, and time-dependent with a t 1/2 of less than 20 s. Insulin-like growth factor I, orthovanadate, and lanthanum mimicked the effect of insulin. Likewise, fractionation of adipocytes in the presence of divalent cation chelating agents caused a similar reduction in the concentration of the 90 kDa protein, and it was possible to overcome the effects of the chelating agents by adding equivalent amounts of calcium. This suggests the involvement of calcium. The 90 kDa protein was also found in low and high density microsomes, but it was not affected in those fractions by either insulin or chelators. It is suggested from the study that the movement of a 90 kDa protein in fat cell plasma membranes probably represents part of the transmission system in the mechanism of insulin action in rat adipocytes.     

Insulin-receptor interactions in liver cell membranes

The specific binding of ¹²⁵I-insulin to liver cell membranes is a saturable process with respect to insulin. Binding is displaced by low concentrations of native insulin but not by biologically inactive insulin derivatives or by other peptide hormones. The rate constants of association (3.5 × 10⁶ mole⁻¹ sec⁻¹) and of dissociation (2.7 × 10⁻⁴ sec⁻¹) of the insulin-membrane complex can be determined independently. The dissociation constant of the complex, determined from the rate constants and from equilibrium data, is about 7 × 10⁻¹¹M. Complex formation does not result in degradation of the insulin molecule. The binding interaction is a dissociable process involving a homogeneous membrane structure which is almost certainly the biologically significant receptor. The kinetic properties, and the effects of enzymic perturbations of the membrane, suggest that the insulin receptors of liver and of adipose tissue cells may be very similar structures.     

Effect of adrenalectomy and hydrocortisone on insulin receptors of rat fat cell plasma membranes

Specific insulin binding with insulin receptors of fatty acid plasma membranes is established to be intensified 10 days after adrenalectomy in rats due to an increase in the receptor number. Hydrocortisone administered for 10 days in a dose of 1 mg per 100 g of body mass to adrenalectomized rats for substitution therapy and to intact ones for 14 days in a dose of 5 mg per 100 g of body mass to induce hypercorticism inhibits the expression of insulin receptors of fatty plasma membranes because of their number and affinity for the hormone. The data obtained confirm information on an inhibitory effect of glucocorticoids on the expression of insulin receptors.     

Protein-lipid interactions in antipodal plasma membranes of rat colonocytes

The isolation of apical membranes from rat proximal colonic epithelial cells is described. Differential centrifugation yielded a ‘crude’ membrane fraction which was further purified using sucrose density centrifugation. The final membrane fraction was enriched 20–28-fold over homogenate in alkaline phosphatase and cysteine-sensitive alkaline phosphatase specific activities. Lipid-protein interactions and lipid dynamics examined in apical and basolateral membranes prepared from colonocytes demonstrated: (1) apical membrane, as assessed by steady-state fluorescence polarization studies have a low lipid fluidity; (2) colonic basolateral membranes possess a greater lipid fluidity than apical membranes; (3) compositional differences in these antipodal membranes appear to explain these differences in lipid fluidity; (4) fluorescence polarization studies using diphenylhexatriene detect a thermotropic transition at 21–23°C in apical membranes and liposomes prepared from lipid extracts of these membranes; (5) alkaline phosphatase and l-cysteine-sensitive alkaline phosphatase activities appear to be functionally dependent on the physical state of the apical membrane's lipid.     

Avian tumor virus interactions with chicken fibroblast plasma membranes

A method is described which will rapidly measure the binding of avian tumor viruses (ATV) to plasma membrane receptors. With this procedure it may be shown that Rous sarcoma virus pseudotypes bind to protease-labile, heat-stable structures on the surface of chicken embryo fibroblast (CEF) plasma membranes. The binding sites for ATV subgroups A and B appear distinct, and membranes from genetically resistant CEF bind as well those of sensitive CEF.     

Membrane bound guanylate cyclase in rat fat cell plasma membranes: influence of divalent cations on calcium activation

Rat fat cell plasma membrane preparations were used to study the effect of Mn2+, Mg2+, Ca2+ on guanylate cyclase activity. Among these three cations, Mn2+ was the most effective in activating the enzyme; Mg2+ and Ca2+ were 23% and 10% respectively as effective as Mn2+ in activating the enzyme. Low concentrations of Ca2+ (1 microM) increased the rate of cGMP formation at MgGTP concentrations ranging from 0.3 to 2 mM. This effect was less at higher concentrations of Ca2+ and was independent of the presence of excess Mg2+. Ca2+ (100 microM) had only a marginal stimulatory effect on the MnGTP-dependent enzyme.     

Fluorescence analysis of receptor-G protein interactions in cell membranes

The dynamics of G protein heterotrimer complex formation and disassembly in response to nucleotide binding and receptor activation govern the rate of responses to external stimuli. We use a novel flow cytometry approach to study the effects of lipid modification, isoform specificity, lipid environment, and receptor stimulation on the affinity and kinetics of G protein subunit binding. Fluorescein-labeled myristoylated Galpha(i1) (F-alpha(i1)) was used as the ligand bound to Gbetagamma in competition binding studies with differently modified Galpha subunit isoforms. In detergent solutions, the binding affinity of Galpha(i) to betagamma was 2 orders of magnitude higher than for Galpha(o) and Galpha(s) (IC50 of 0.2 nM vs 17 and 27 nM, respectively), while in reconstituted bovine brain lipid vesicles, binding was slightly weaker. The effects of receptor on the G protein complex were assessed in alpha(2A)AR receptor expressing CHO cell membranes into which purified betagamma subunits and F-alpha(i1) were reconstituted. These cell membrane studies led to the following observations: (1) binding of alpha subunit to the betagamma was not enhanced by receptor in the presence or absence of agonist, indicating that betagamma contributed essentially all of the binding energy for alpha(i1) interaction with the membrane; (2) activation of the receptor facilitated GTPgammaS-stimulated detachment of F-alpha(i1) from betagamma and the membrane. Thus flow cytometry permits quantiatitive and real-time assessments of protein-protein interactions in complex membrane environments.     

Kinetic studies of adenylyl cyclase of fat cell membranes

Summary The kinetic behavior of the adenylyl cyclase activity associated with fat cell membranes purified by centrifugation on sucrose gradients was studied. Under most of the conditions explored, with either Mn⁺⁺ or Mg⁺⁺ as the divalent cation in the assay mixtures, the time courses of the reaction were not linear. In the absence of modifiers (i.e., basal activity) or in the presence of insulin, the rate tended to decrease with time; on the other hand, with fluoride or GMP-P(NH)P the curves were concave upwards. To simplify analysis of the results, two kinetic components were defined: an initial component corresponding to the transient rate measured between zero time and 1.5 min of assay and a final component corresponding to the transient rate determined between 3 and 5 min.Over the entire range of Mn⁺⁺ concentration explored (0.5 to 6.0mm), the basal initial rates were slightly higher than the final ones. With Mg⁺⁺ in the range between 1.5 and 2.5mm, the final rates were fourfold lower than the initial ones. Higher or lower Mg⁺⁺ concentrations gave velocity ratios equivalent to those observed with Mn⁺⁺.Insulin clearly decreased the final rates at Mn⁺⁺ concentrations up to 2.5mm. With higher concentrations the effects were completely reversed. The effects of insulin on initial rates measured with Mn⁺⁺, or the initial or final rates measured with Mg⁺⁺, were less evident.Stimulation of adenylyl cyclase activity by fluoride was most pronounced on the final rates. In addition, this stimulation was higher with Mg⁺⁺ than with Mn⁺⁺.Isoproterenol stimulation of adenylyl cyclase was negligible in the presence of Mn⁺⁺ (0.5 to 6.0mm). With Mg⁺⁺ (0.5 to 6.0mm), stimulation was more evident on the final rates. *** DIRECT SUPPORT *** A0130063 00002     

The interactions of aurein 1.2 with cancer cell membranes

Here, the interactions of aurein 1.2, a defence peptide, with T98G glioblastoma cell membranes are studied. The peptide induced maximal surface pressure changes of circa 9 mN m(-1) in monolayers of endogenous T98G membrane lipid. Reducing monolayer anionic lipid showed a positive correlation (R(2)>0.91) with decreases in maximal surface pressure changes induced by aurein 1.2 (circa 3 mN m(-1) in the absence of this lipid). Cancer cell membrane invasion by the peptide therefore appears not to be mediated by lipid receptors or specific lipid requirements but rather a general requirement for anionic lipid and/or other negatively charged membrane components.     

Lipid-protein interactions in membranes

The interactions of lipids with integral and peripheral proteins can be studied in reconstituted and natural membranes using spin label electron spin resonance (ESR) spectroscopy. The ESR spectra reveal a reduction in mobility of the spin-labelled lipid species, and in certain cases evidence is obtained for a partial penetration of the peripheral proteins into the membrane. The latter may be relevant to the import mechanism of apocytochrome c into mitochondria. Integral proteins induce a more direct motional restriction of the spin-labelled lipid chains, allowing the stoichiometry and specificity of the interaction, and the lipid exchange rate at the protein interface to be determined from the ESR spectra. In this way, a population of very slowly exchanging cardiolipin associated with the mitochondrial ADP-ATP carrier has been identified. The residues involved in the specificity for charged lipids of the myelin proteolipid protein have been localized to the deletion in the DM-20 mutant, and the difference in lipid-protein interactions with the beta-sheet and alpha-helical conformations of the M-13 coat protein, has been characterized.     

Protein-protein interactions in membranes

In this article we review the current status of our understanding of membrane mediated interactions from theory and experiment. Phenomenological mean field and molecular models will be discussed and compared to recent experimental results from dynamical neutron scattering and atomic force microscopy.