Spin-labeled stearates as probes for microenvironment of murine thymocyte adenylate cyclase-cyclic adenosine 3':5'-monophosphate system

Effects of insulin on the lipid structure of liver plasma membrane measured with fluorescence and ESR spectroscopic methods

Insulin increased the lipid order of rat and mouse liver plasma membrane domains sampled by the hydrophobic fluorescent probe 1,6-diphenyl-1,3,5-hexatriene in a concentration-dependent saturable manner. The ordering is half maximal at 5.1 X 10(-11) M and fully saturated at 1.7 X 10(-10) M insulin. Membranes prepared from obese hyperglycemic (ob/ob) mice demonstrated a right-shift in the dose-dependent ordering induced by insulin, such that ordering was half maximal at 1.2 X 10(-10) M and fully saturated at 2.0 X 10(-10) M. Insulin also increased the order of rat liver plasma membranes labeled with the cis- and trans-parinaric acid methyl esters. The ordering caused by insulin as detected with cis methyl parinarate was complete within approx. 15 min. after hormone addition at 37 degrees C, and the ordering was approximately double that observed with the trans isomer. Additional ESR experiments demonstrated that the addition of insulin increased the outer hyperfine splittings of spectra recorded from membranes labeled with the steroid-like spin labels, nitroxide cholestane and nitroxide androstane, but not the fatty acid spin probe, 5-nitroxide stearate. Studies utilizing model membrane systems strongly suggest that the 5-nitroxide stearate samples a cholesterol-poor domain of the membrane, while the steroid-like probes preferentially sample cholesterol-rich regions of the membrane. Finally, insulin-induced membrane ordering was dose-dependently inhibited by cytochalasin B in the range 1-50 microM. From these results, we conclude that (1) the ordering effect of insulin addition to isolated liver plasma membrane fractions occurs within the physiological range of hormone concentration, and the dose-response is right-shifted in membranes from 'insulin resistant' animals; (2) the relative responses of the fluorescent and spin probes suggest that the effects of insulin are confined to specific domains within the membrane matrix; and (3) the direct effects of insulin on the membranes may involve protein components having cytochalasin B binding sites.

Effects of ethanol on Arrhenius parameters and activity of mouse striatal adenylate cyclase

Arrhenius plots of basal and dopamine (DA)-stimulated adenylate cyclase activities exhibited discontinuities at 20 degrees, while the plot of fluoride-stimulated adenylate cyclase activity was linear over the studied temperature range. None of the Arrhenius parameters were altered by in vitro addition of ethanol (75 or 750 mM) to enzyme assay mixtures, and Arrhenius parameters were found to be unchanged when enzyme obtained from animals rendered tolerant to, and physically dependent on, ethanol was assayed. The differences between the response to ethanol of adenylate cyclase and the response of other membrane-bound enzymes [e.g. (Na+-K+)ATPase], as measured by Arrhenius plots, may indicate different sites of action of ethanol. When the specific activity of adenylate cyclase was examined, ethanol was found to stimulate activity at all temperatures tested. The dose-response curve for ethanol activation of basal adenylate cyclase activity was shifted to the right for enzyme obtained from mice chronically treated with ethanol. Analysis of the data indicated that activation of adenylate cyclase by ethanol (as well as by DA) was an entropy-driven process. Since ethanol treatment did not affect the Arrhenius parameters, which appear to be associated with membrane lipids, it is suggested that enzyme activation by ethanol results from direct effects on the enzyme or regulatory protein. Resistance to this effect occurs through changes in protein conformation following chronic ethanol treatment.

Effects of spin-labeled stearates on duck erythrocyte adenylate cyclase

The effects of various spin-labeled stearates on duck erythrocyte adenylate cyclase were investigated. Only 2-(3-carboxypropyl)-4,4-dimethyl-2-tridecyl-3-oxazolidinyloxyl caused an increase in adenylate cyclase activity. It increased the basal rate by about 50%, and the activities stimulated by isoproterenol and isoproterenol plus guanosine 5'-[beta,gamma-imido]triphosphate by 35%. Upon analysis of the width parameter delta1 in the electron spin resonance spectra for both the basal enzyme activity and the stimulation obtained with effectors such as guanosine 5'-[beta,gamma-imido]triphosphate, isoproterenol, isoproterenol plus guanosine 5'-[beta,gamma-imido]triphosphate and NaF, a correlation of the changes of modification in adenylate cyclase activities was found. These findings suggest that the molecular environment of the enzyme has been modified.

Changes in lipid ordering and state of aggregation in lymphocyte plasma membranes after exposure to mitogens

An electron spin probe study was made of the effect of a number of mitogenic agents on the ordering and state of aggregation of the plasma membrane lipids of lymphocytes. These agents, which included phytohemagglutinin, Concanavalin A, the calcium ionophore A23187 and periodate, caused a 20% decrease in lipid ordering in the region of the bilayer probed by 5-nitroxide stearic acid. The corresponding methyl ester probe showed marked probe-probe interaction under the same conditions indicating an aggregation of lipids in the area probed by this label. Studies with mixed lipid vesicles and ganglioside-free cells indicate that these areas are rich in glycolipids capable of hydrogen bonding to the ester probe. The decrease in ordering and the increase in aggregation of the membrane lipids were correlated with the patching and capping of the ligand-receptor complexes. Furthermore, the disappearance of fluorescent ligand from the surface of treated cells corresponded with the return of the spectral parameters of the probes to control cell values. It was concluded that glycolipids might play an important role in ligand-induced cell surface changes either as bearers of receptor groups, as in the case of some gangliosides, or in association by hydrogen-bonding with receptor proteins.

Plasma membrane associated metabolic parameters and the aging of human diploid fibroblasts

Substrate uptake, portions of the cyclic AMP system, membrane fluidity and cellular phospholipid content are some of the parameters which are structurally associated with the plasma membrane and which have been linked to the control of cell proliferation. These parameters were studied with respect to cellular aging of human embryo lung fibroblasts (HELF) in culture. We observed in late passage an increase in the rate of uridine transport and in cellular cyclic AMP levels. These results were examined in relation to the increase in cell volume which occurs in senescing HELF. We also observed an increase in Vmax of uridine transport, and a decrease in the Km of cyclic AMP phosphodiesterase (PDE) as quiescent, passage 18-25, HELF were stimulated to divide with fresh serum. A similar effect of serum occurred in late passage (p. 43) cells despite the inability of these late passage cultures to undergo further proliferation. There was no change in cAMP-PDE activity with increasing passage number suggesting that the observed alterations of the cAMP levels, basal and in response to extracellular effectors, were due to alterations in the adenyl cyclase system. We observed no change in senescent HELF in membrane fluidity or phospholipid and neutral fat content.