Christopher D. Stubbs

Interaction of alcohols and anesthetics with protein kinase Calpha.

The key signal transduction enzyme protein kinase C (PKC) contains a hydrophobic binding site for alcohols and anesthetics (Slater, S. J., Cox, K. J. A., Lombardi, J. V., Ho, C., Kelly, M. B., Rubin, E., and Stubbs, C. D. (1993) Nature 364, 82-84). In this study, we show that interaction of n-alkanols and general anesthetics with PKCα results in dramatically different effects on membrane-associated compared with lipid-independent enzyme activity. Furthermore, the effects on membrane-associated PKCα differ markedly depending on whether activity is induced by diacylglycerol or phorbol ester and also on n-alkanol chain length. PKCα contains two distinct phorbol ester binding regions of low and high affinity for the activator, respectively (Slater, S. J., Ho, C., Kelly, M. B., Larkin, J. D., Taddeo, F. J., Yeager, M. D., and Stubbs, C. D. (1996) J. Biol. Chem. 271, 4627-4631). Short chain n-alkanols competed for low affinity phorbol ester binding to the enzyme, resulting in reduced enzyme activity, whereas high affinity phorbol ester binding was unaffected. Long chain n-alkanols not only competed for low affinity phorbol ester binding but also enhanced high affinity phorbol ester binding. Furthermore, long chain n-alkanols enhanced phorbol ester induced PKCα activity. This effect of long chain n-alkanols was similar to that of diacylglycerol, although the n-alkanols alone were weak activators of the enzyme. The cellular effects of n-alkanols and general anesthetics on PKC-mediated processes will therefore depend in a complex manner on the locality of the enzyme (e.g. cytoskeletal or membrane-associated) and activator type, apart from any isoform-specific differences. Furthermore, effects mediated by interaction with the region on the enzyme possessing low affinity for phorbol esters represent a novel mechanism for the regulation of PKC activity.

The effects of non-lamellar forming lipids on membrane protein-lipid interactions

The role of lipid polymorphism in the regulation of membrane-associated protein function is examined, based on recent studies which showed that changes in the levels of phosphatidylethanolamine (PE), cholesterol and phospholipid unsaturation, modulate the activity of the key signal transduction enzyme, protein kinase C (PKC). It is shown that effects of membrane compositional changes on PKC activity involve a perturbation of protein-lipid interactions with the head group region rather than with the hydrophobic interior of the bilayer. A key determinant in the perturbation of these interactions is suggested to be an elastic curvature energy, termed curvature stress, which results from the unfavorable packing of non-lamellar forming lipids in a planar bilayer. PKC activity is shown to be a biphasic function of curvature stress, with an optimum value of this parameter corresponding to an optimally active PKC conformation. Thus, it is shown that the maximal activity of conformationally distinct PKC isoforms may require a different optimum value of curvature stress. Furthermore, it is hypothesized that curvature stress may have differing effects on the conformation of membrane-associated PKC activity induced by diacylglycerols, phorbol esters or other activators, based on recent studies showing that these agents induce the formation of disparate active conformers of the enzyme.

Polyunsaturation in cell membranes and lipid bilayers and its effects on membrane proteins.

The effect of variation of the degree ofcis-unsaturation on cell membrane protein functioning was investigated using a model lipid bilayer system and protein kinase C (PKC). This protein is a key element of signal transduction. Furthermore it is representative of a class of extrinsic membrane proteins that show lipid dependent interactions with cell membranes. To test for dependence of activity on the phospholipid unsaturation, experiments were devised using a vesicle assay system consisting of phosphatidylcholine (PC) and phosphatidylserine (PS) in which the unsaturation was systematically varied. Highly purified PKCα and ε were obtained using the baculovirus-insect cell expression system. It was shown that increased PC unsaturation elevated the activity of PKCα. By contrast, increasing the unsaturation of PSdecreased the activity of PKCα, and to a lesser extent PKCε. This result immediately rules out any single lipid bilayer physical parameter, such as lipid order, underlying the effect. It is proposed that while PC unsaturation effects are explainable on the basis of a contribution to membrane surface curvature stress, the effects of PS unsaturation may be due to specific protein-lipid interactions. Overall, the results indicate that altered phospholipid unsaturation in cell membranes that occurs in certain disease states such as chronic alcoholism, or by dietary manipulations, are likely to have profound effects on signal transduction pathways involving PKC and similar proteins.

Effect of ethanol on platelet phospholipase A2

Platelet aggregation is known to be inhibited by ethanol, and this has been suggested to be one of the attenuating effects of ethanol in cardiovascular disease. Recent studies have implicated an inhibition of phospholipase A2 induced arachidonic acid release, since the production of prostanoids that are formed from arachidonic acid and are involved in the aggregation process has been shown to be diminished by ethanol. Phospholipase A2 is found in platelets in both a cytosolic form, from where it may translocate to the plasma membrane to release arachidonic acid, and in a secretory form which is released extracellularly upon activition. In the present study, the effect of ethanol on the secretion of phospholipase A2 and on its activity was determined. It was found that ethanol inhibited trast, the activity of the cytosolic form of phospholipase A2 was inhibited by ethanol.

Fluorescence techniques for probing water penetration into lipid bilayers

Fluorescence spectroscopy can be used as a highly sensitive and localized probe for hydration in lipid bilayers. Water associates with the head-group region, where it participates in an interlipid network of hydrogen bonds. Deeper in the bilayer, water is contained within acyl-chain packing defects. Fluorescence methodology is available to probe both the interstitial and head-group hydration in lipid bilayers, and results are in good agreement with other techniques. Using fluorescence spectroscopic approaches, cholesterol is shown to dehydrate the acyl-chain region, while hydrating the head-group region. Membrane proteins appear to increase acyl-chain hydration at the protein-lipid interface. Overall fluorescence spectroscopic techniques may be most effective in studying the water content of lipid bilayers and especially of biological membranes.

Ethanol causes decreased partitioning into biological membranes without changes in lipid order

One of the adaptive responses of cell membranes to chronic ethanol consumption is the acquisition of a resistance to fluidization or disordering of the lipids by ethanol in vitro and a reduced partitioning of ethanol into the membrane (membrane tolerance). The degree to which the effects on partitioning and lipid disordering share common features has not previously been explored and in addition the relevance of the value of lipid order in the absence of added ethanol (baseline lipid order) to membrane tolerance has not been established. The location in the bilayer and the nature of the modification underlying these effects is also unknown. The effect of chronic ethanol treatment was examined using 5-doxyl decane as a model hydrophobic compound. Its partitioning into the membranes was determined by utilizing its ability to quench fluorophores (1,6-diphenyl-2,3,5-hexatriene and 3- and 12-anthroyl stearates) by collisional quenching. The partition coefficient of 5-doxyl decane into the bilayer central region was reduced as a result of the chronic ethanol treatment. The effect could also be demonstrated in vesicles of phospholipids and was lost 4 days after withdrawal of the ethanol from the diet. These results closely parallel those relating to resistance to lipid disordering and suggest that both techniques detect a common modification. Lipid order was assessed using fluorescence anisotropy measurements of a range of fluorophores, including those used to determine the partitioning properties of the membrane. No effect of chronic ethanol treatment on lipid order was found, either in the intact membranes or in vesicles of extracted phospholipids. This suggests that changes in baseline order are not critical features of membrane tolerance in liver microsomes. In addition it appears that the altered partitioning of the 5-doxyl decane into the central region of the membrane is not related to lipid order changes in this region. The reduced partitioning of 5-doxyl decane may be a reflection of a redistribution in the lipid bilayer, perhaps due to modifications in other locations in the membrane, such as the lipid head group region.

The use of time-resolved fluorescence imaging in the study of protein kinase C localisation in cells

BackgroundTwo-photon-excitation fluorescence lifetime imaging (2P-FLIM) was used to investigate the association of protein kinase C alpha (PKCα) with caveolin in CHO cells. PKCα is found widely in the cytoplasm and nucleus in most cells. Upon activation, as a result of increased intracellular Ca2+ and production of DAG, through G-protein coupled-phospholipase C signalling, PKC translocates to a variety of regions in the cell where it phosphorylates and interacts with many signalling pathways. Due to its wide distribution, discerning a particular interaction from others within the cell is extremely difficultResultsFluorescence energy transfer (FRET), between GFP-PKCα and DsRed-caveolin, was used to investigate the interaction between caveolin and PKC, an aspect of signalling that is poorly understood. Using 2P-FLIM measurements, the lifetime of GFP was found to decrease (quench) in certain regions of the cell from ~2.2 ns to ~1.5 ns when the GFP and DsRed were sufficiently close for FRET to occur. This only occurred when intracellular Ca2+ increased or in the presence of phorbol ester, and was an indication of PKC and caveolin co-localisation under these conditions. In the case of phorbol ester stimulated PKC translocation, as commonly used to model PKC activation, three PKC areas could be delineated. These included PKCα that was not associated with caveolin in the nucleus and cytoplasm, PKCα associated with caveolin in the cytoplasm/perinuclear regions and probably in endosomes, and PKC in the peripheral regions of the cell, possibly indirectly interacting with caveolin.ConclusionBased on the extent of lifetime quenching observed, the results are consistent with a direct interaction between PKCα and caveolin in the endosomes, and possibly an indirect interaction in the peripheral regions of the cell. The results show that 2P-FLIM-FRET imaging offers an approach that can provide information not only confirming the occurrence of specific protein-protein interactions but where they occur within the cell.

Inhibition of membrane lipid-independent protein kinase Calpha activity by phorbol esters, diacylglycerols, and bryostatin-1.

The activity of membrane-associated protein kinase C (PKC) has previously been shown to be regulated by two discrete high and low affinity binding regions for diacylglycerols and phorbol esters (Slater, S. J., Ho, C., Kelly, M. B., Larkin, J. D., Taddeo, F. J., Yeager, M. D., and Stubbs, C. D. (1996) J. Biol. Chem. 271, 4627–4631). PKC is also known to interact with both cytoskeletal and nuclear proteins; however, less is known concerning the mode of activation of this non-membrane form of PKC. By using the fluorescent phorbol ester, sapintoxin D (SAPD), PKCα, alone, was found to possess both low and high affinity phorbol ester-binding sites, showing that interaction with these sites does not require association with the membrane. Importantly, a fusion protein containing the isolated C1A/C1B (C1) domain of PKCα also bound SAPD with low and high affinity, indicating that the sites may be confined to this domain rather than residing elsewhere on the enzyme molecule. Both high and low affinity interactions with native PKCα were enhanced by protamine sulfate, which activates the enzyme without requiring Ca2+ or membrane lipids. However, this “non-membrane” PKC activity was inhibited by the phorbol ester 4β-12-O-tetradecanoylphorbol-13-acetate (TPA) and also by the fluorescent analog, SAPD, opposite to its effect on membrane-associated PKCα. Bryostatin-1 and the soluble diacylglycerol, 1-oleoyl-2-acetylglycerol, both potent activators of membrane-associated PKC, also competed for both low and high affinity SAPD binding and inhibited protamine sulfate-induced activity. Furthermore, the inactive phorbol ester analog 4α-TPA (4α-12-O-tetradecanoylphorbol-13-acetate) also inhibited non-membrane-associated PKC. In keeping with these observations, although TPA could displace high affinity SAPD binding from both forms of the enzyme, 4α-TPA was only effective at displacing high affinity SAPD binding from non-membrane-associated PKC. 4α-TPA also displaced SAPD from the isolated C1 domain. These results show that although high and low affinity phorbol ester-binding sites are found on non-membrane-associated PKC, the phorbol ester binding properties change significantly upon association with membranes.

On the use of N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)phosphatidylethnolamine in the study of lipid polymorphism

The change in the fluorescence properties of dioleoyl-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)phosphatidylethanola mine (N-NBD-PE) as an indicator of the (liquid-crystalline) bilayer-to-non-bilayer hexagonalII (HII) phase transition has been investigated. Lipid bilayer systems which are known to undergo the bilayer-to-HII phase transition on addition of Ca2+ were compared with systems which can undergo aggregation and fusion but not HII phase formation. The former included Ca2+-triggered non-bilayer transitions in cardiolipin and in phosphatidylethanolamine mixed with phosphatidylserine. The latter type of system investigated included the addition of polylysine to cardiolipin and Ca2+ to phosphatidylserine. Freeze-fracture electron microscopy was used to confirm that under the experimental conditions used, the formation of HII phase was occurring in the first type of system, but not in the second, which was stable in the bilayer state. It was found that the fluorescence intensity of N-NBD-PE (at 1 mol% of the phospholipids) increased in both types of system, irrespective of the formation of the HII phase. A dehydration at the phospholipid head group is a common feature of the formation of the HII phase, the interaction of divalent cations with phosphatidylserine and the interaction of polylysine with lipid bilayers, suggesting that this may be the feature which affects the fluorescence properties of the NBD. The finding of a fluorescence intensity increase in systems lacking HII phase involvement clearly indicates that the effect is not unique to the formation of the HII phase. Thus, while offering high sensitivity and the opportunity to follow kinetics of lipid structural changes, changes in the N-NBD-PE fluorescence properties should be interpreted with caution in the study of the bilayer-to-HII phase transition.

The effects of phospholipid unsaturation and alcohol perturbation at the protein/lipid interface probed using fluorophore lifetime heterogeneity

The influence of phospholipid unsaturation and perturbation by alcohols, on the membrane protein/lipid interface, was probed using the fluorescence decay properties of 1,6-diphenyl-1,3,5-hexatriene (DPH) and DPH attached to the sn-2 chain of phosphatidylcholine (DPH-PC), in lipid bilayers and microsomal membranes. With microsomal membranes it was found that it was appropriate to describe the fluorescence decay of DPH-PC as a range of decay rates, accomplished by fitting the data to a bimodal fluorescence lifetime distribution. The major lifetime center had a broad distributional width, indicative of excited state fluorophore heterogeneity. The effect was attributable to protein, and by inference, the protein/lipid interface, since in vesicles made from total microsomal lipids (i.e., without protein) the fluorescence decay was homogeneous. Upon addition of ethanol or hexanol the width of the lifetime distribution of the major lifetime center increased, indicating increased environmental heterogeneity. It was confirmed that the effect was manifest at the protein/lipid interface, and not due to lipid-reorganizational factors, since it could also be obtained using a simple lipid bilayer vesicle system with apocytochrome c as a model membrane protein, and DPH instead of DPH-PC. Environmental heterogeneity was also found to increase with increased phosphatidylcholine (sn-2) unsaturation. The environmental heterogeneity at the protein/lipid interface could arise from a combination of varying polarities of amino acid side chains and of water that may intercalate in packing defects on the hydrophobic surface of the protein. Therefore the results could be explained on the basis of an increased degree of hydration at the protein/lipid interface. Such an effect offers a route whereby acyl chain perturbation and increased unsaturation might influence protein conformation and hence function.