The C1 domain of protein kinase C as a lipid bilayer surface sensing module.

The activity of membrane-associated protein kinase C (PKC) is tightly controlled by the physical properties of the membrane lipid bilayer, in particular, curvature stress, which is induced by bilayer-destabilizing lipid components. An important example of this is the weakened lipid headgroup interactions induced by phosphatidylethanolamine (PE) and cholesterol. In this work our previous observation with a mixed isoform PKC showing a biphasic dependence of activity as a function of membrane curvature stress [Slater et al. (1994) J. Biol. Chem. 269, 4866-4871] was here extended to individual isoforms. The Ca(2+)-dependent PKCalpha, PKCbeta, and PKCgamma, along with Ca(2+)-independent PKCdelta, but not PKCepsilon or PKCzeta, displayed a biphasic activity as a function of membrane PE content. The fluorescence anisotropy of N-(5-dimethylaminonaphthalene-1-sulfonyl)dioleoylphosphatidylserine (dansyl-PS), which probes the lipid environment of PKC, also followed a biphasic profile as a function of PE content for full-length PKCalpha, PKCbetaIotaIota, and PKCgamma as did the isolated C1 domain of PKCalpha. In addition, the rotational correlation time of both PKCalpha and PKCdelta C1-domain-associated sapintoxin D, a fluorescent phorbol ester, was also a biphasic function of membrane lipid PE content. These results indicate that the C1 domain acts as a sensor of the bilayer surface properties and that its conformational response to these effects may directly underlie the resultant effects on enzyme activity.

Low- and high-affinity phorbol ester and diglyceride interactions with protein kinase C: 1-O-alkyl-2-acyl-sn-glycerol enhances phorbol ester- and diacylglycerol-induced activity but alone does not induce activity.

Phorbol ester-induced conventional protein kinase C (PKCalpha, -betaIota/IotaIota, and -gamma) isozyme activities are potentiated by 1,2-diacyl-sn-glycerol. This has been attributed to a "cooperative" interaction of the two activators with two discrete sites termed the low- and high-affinity phorbol ester binding sites, respectively [Slater, S. J., Milano, S. K., Stagliano, B. A., Gergich, K. J., Ho, C., Mazurek, A., Taddeo, F. J., Kelly, M. B., Yeager, M. D., and Stubbs, C. D. (1999) Biochemistry 38, 3804-3815]. Here, we report that the 1-O-alkyl ether diglyceride, 1-O-hexadecyl-2-acetyl-sn-glycerol (HAG), like its 1,2-diacyl counterpart, 1-oleoyl-2-acetyl-sn-glycerol (OAG), also potentiated PKCalpha, -betaI/II, and -gamma activities induced by the phorbol ester 4beta-12-O-tetradecanoylphorbol-13-acetate (TPA). Similar to OAG, HAG was found to bind to the low-affinity phorbol ester binding site and to enhance high-affinity phorbol ester binding, and to decrease the level of Ca(2+) required for phorbol ester-induced activity, while being without effect on the Ca(2+) dependence of membrane association. Thus, similar to OAG, HAG may also potentiate phorbol ester-induced activity by interacting with the low-affinity phorbol ester binding site, leading to a reduced level of Ca(2+) required for the activating conformational change. However, HAG was found not to behave like a 1,2-diacyl-sn-glycerol in that alone it did not induce PKC activity, and also in that it enhanced OAG-induced activity. The results reveal HAG to be a member of a new class of "nonactivating" compounds that modulate PKC activity by interacting with the low-affinity phorbol ester binding site.

Effects of ethanol on protein kinase C activity induced by filamentous actin.

Protein kinase C (PKC) can be activated by interaction with filamentous actin (F-actin) in the absence of membrane lipids (S.J. Slater, S.K. Milano, B.A. Stagliano, K.J. Gergich, J.P. Curry, F.J. Taddeo and C.D. Stubbs, Biochemistry 39 (2000) 271-280). Here, the effects of ethanol on the F-actin-induced activities of a panel of PKC isoforms consisting of 'conventional' (cPKC) alpha, betaI, gamma, 'novel' (nPKC) delta, epsilon and 'atypical' (aPKC) zeta were investigated using purified PKC and F-actin. Ethanol was found to inhibit the Ca2+- and phorbol ester-dependent activities of cPKCalpha and betaI, and the Ca2+- and phorbol ester-independent activity of cPKCgamma, whereas the activities of nPKCdelta, epsilon and aPKCzeta were unaffected. Although the activities of cPKCalpha and betaI induced by saturating levels of phorbol ester were inhibited by ethanol, the binding of these isozymes to F-actin was unaffected within the same phorbol ester concentration range. Conversely, within submaximal levels of phorbol ester, cPKCalpha and betaI activities were unaffected by ethanol whereas binding to F-actin was inhibited. The potency of the inhibition of F-actin-induced cPKCbetaI activity increased with n-alkanol chain length up to n-hexanol, after which it declined. The results indicate that PKC activities associated with F-actin, and therefore cellular processes involving the actin cytoskeleton, are potential targets for ethanol action. The effects of ethanol on these processes may differ according to the particular regulating PKC isoform, its intracellular localization and the presence of activators and cofactors.

Interaction of protein kinase C isozymes with Rho GTPases.

Evidence is provided for direct protein-protein interactions between protein kinase C (PKC) alpha, betaI, betaII, gamma, delta, epsilon, and zeta and members of the Rho family of small GTPases. Previous investigations, based on the immunoprecipitation approach, have provided evidence consistent with a direct interaction, but this remained to be proven. In the study presented here, an in vitro assay, consisting only of purified proteins and the requisite PKC activators and cofactors, was used to determine the effects of Rho GTPases on the activities of the different PKC isoforms. It was found that the activity of PKCalpha was potently enhanced by RhoA and Cdc42 and to a lesser extent by Rac1, whereas the effects on the activities of PKCbetaI, -betaII, -gamma, -delta, -epsilon, and -zeta were much reduced. These results indicate a direct interaction between PKCalpha and each of the Rho GTPases. However, the Rho GTPase concentration dependencies for the potentiating effects on PKCalpha activity differed for each Rho GTPase and were in the following order: RhoA > Cdc42 > Rac1. PKCalpha was activated in a phorbol ester- and Ca(2+)-dependent manner. This was reflected by a substantial decrease in the phorbol ester concentration requirements for activity in the presence of Ca(2+), which for each Rho GTPase was induced within a low nanomolar phorbol ester concentration range. The activity of PKCalpha also was found to be dependent on the nature of the GTP- or GDP-bound state of the Rho GTPases, suggesting that the interaction may be regulated by conformational changes in both PKCalpha and Rho GTPases. Such an interaction could result in significant cross-talk between the distinct pathways regulated by these two signaling elements.

Interaction of protein kinase C with filamentous actin: isozyme specificity resulting from divergent phorbol ester and calcium dependencies.

The mechanism of activation of protein kinase C isoforms by filamentous actin (F-actin) was investigated with respect to isozyme specificity and phorbol ester and Ca(2+) dependencies. It was found that the "conventional" (cPKC), alpha, betaI, betaII, and gamma, "novel" (nPKC) delta and epsilon, and "atypical" (aPKC) zeta isoforms were each activated by F-actin with varying potencies. The level of activity along with the affinity for binding to F-actin was further potentiated by the phorbol ester 4beta-12-O-tetradecanoylphorbol 13-acetate (TPA), the potency of which again varied for each isoform. By contrast to the other cPKC isoforms, the level of cPKC-gamma activity was unaffected by TPA, as was also the case for aPKC-zeta. It was found that whereas in the absence of F-actin the soluble form of cPKC-betaI contained two phorbol ester binding sites of low and high affinity, respectively, as previously reported for cPKC-alpha [Slater et al. (1998) J. Biol. Chem. 273, 23160-23168], the F-actin-bound form of the isozyme contained only a single site of relatively low affinity. The level of TPA required to induce cPKC-alpha, -betaI, and -betaII activity and the binding of these isozymes to F-actin was reduced in the presence of Ca(2+). By contrast, the activity of cPKC-gamma was unaffected by Ca(2+), as were the activities of nPKC-delta and -epsilon and aPKC-zeta, as expected. Thus, the interaction with F-actin appears to be a general property of each of the seven PKC isozymes tested. However, isoform specificity may, in part, be directed by differences in the phorbol ester and Ca(2+) dependences, which, with the notable exception of cPKC-gamma, appear to resemble those observed for the activation of each isoform by membrane association. The observation that cPKC isoforms may translocate to F-actin as well as the membrane as a response to an elevation of Ca(2+) levels may allow for the functional coupling of fluctuations of intracellular Ca(2+) levels through cPKC to F-actin cytoskeleton-mediated processes.

Conformation of the C1 phorbol-ester-binding domain participates in the activating conformational change of protein kinase C.

The fluorescent phorbol ester 12-N-methylanthraniloylphorbol 13-acetate [sapintoxin D (SAPD)] was used as both the activator and the probe for the activating conformational change of the C1 domain of recombinant protein kinase C (PKC)alpha. Fluorescence emission spectra and steady-state anisotropy measurements of SAPD in fully active membrane-associated PKC show that there is a relatively hydrophobic environment and restricted motional freedom characterizing the phorbol-ester-binding site. SAPD also interacts with the membrane lipids so that it was necessary to resort to time-resolved anisotropy measurements to resolve the signals corresponding to PKC-bound SAPD from that associated with buffer and lipid. In the presence of membrane lipids (unilamellar vesicles of phosphatidylcholine and phosphatidylserine, 4:1 molar ratio) and Ca(2+), at a concentration sufficient to activate the enzyme fully, a long correlation time characteristic of highly restricted motion was observed for PKC-associated SAPD. The fraction of SAPD molecules displaying this restricted motion, in comparison with the total SAPD including that in lipids and in buffer, increased with increasing concentrations of Ca(2+) and paralleled the appearance of enzyme activity, whereas the rotational correlation time remained constant. This could be rationalized as an increase in the number of active PKC conformers in the total population of PKC molecules. It therefore seems that there is a distinct conformation of the C1 activator-binding domain associated with the active form of PKC. The addition of SAPD and dioleoyl-sn-glycerol together produced an activity higher than that achievable by either activator alone both at concentrations that alone induced maximal activity for the respective activator; this higher activity was associated with a further restriction in SAPD motion. Increasing the cholesterol concentration, the phosphatidylethanolamine concentration, the sn-2 unsaturation in phosphatidylcholine and the vesicle curvature each also elevated SAPD-induced PKC activity and again increased the PKC-associated SAPD rotational correlation time. In summary, the rotational correlation time of PKC-bound SAPD, extractable from a single time-resolved fluorescence anisotropy measurement, provides a novel probe for the involvement of interactions between the C1 domain and phorbol ester in the modulation of PKC activity.

Ethanol and protein kinase C.

Protein kinase C (PKC) is involved in the control of many key signaling pathways in cells. Investigations over the past decade have shown that many effects of ethanol on cell function are closely interconnected with PKC. Three distinct areas of investigation have emerged; they are reviewed in this article. In vitro studies show that ethanol and higher alcohols can both inhibit or enhance PKC activity, depending on the experimental conditions. These studies show that alcohols interact directly with PKC, suggesting at least some role of this interaction in intoxication and anesthesia. Most ion channel systems are modulated by ethanol to varying degrees, and inhibition of PKC attenuates this effect; however, the mechanism by which ethanol brings about this effect is not known. Lastly, prolonged or chronic ethanol exposure up-regulates PKC, an effect that has important consequences, for example, in neuronal development; again, the mechanism leading to this process is not understood. The current consensus is that PKC is intimately involved in acute and chronic ethanol action, and the challenge now is to determine the mechanisms involved so that strategies can be developed to control these effects.

Synergistic activation of protein kinase Calpha, -betaI, and -gamma isoforms induced by diacylglycerol and phorbol ester: roles of membrane association and activating conformational changes.

Protein kinase Calpha (PKCalpha) has been shown to contain two discrete activator sites with differing binding affinities for phorbol esters and diacylglycerols. The interaction of diacylglycerol with a low-affinity phorbol ester binding site leads to enhanced high-affinity phorbol ester binding and to a potentiated level of activity [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]. In this study, the mechanism of this enhancement of activity was examined with respect to the Ca2+ dependences of membrane association and accompanying conformational changes that lead to activation. The association of PKCalpha with membranes containing 12-O-tetradecanoylphorbol 13-acetate (TPA) or 1, 2-dioleoylglycerol (DAG), determined from tryptophan to dansyl-PE resonance energy transfer (RET) measurements, was found to occur at relatively low Ca2+ levels (

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), PKCalpha, 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 PKCalpha 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 PKCalpha 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 4beta-12-O-tetradecanoylphorbol-13-acetate (TPA) and also by the fluorescent analog, SAPD, opposite to its effect on membrane-associated PKCalpha. 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 4alpha-TPA (4alpha-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, 4alpha-TPA was only effective at displacing high affinity SAPD binding from non-membrane-associated PKC. 4alpha-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.

Effect of n-alkanols on lipid bilayer hydration.

The effect of a homologous series of aliphatic n-alkanols on the presence of water within the head group and acyl chain region of lipid bilayers was investigated using time-resolved fluorescence spectroscopy according to a previously published approach [Ho, C., Slater, S. J., & Stubbs, C. D. (1995) Biochemistry 34, 6188-6195]. Upon addition of n-alkanols to phosphatidylcholine bilayers the fluorescence lifetime of N-[5-(dimethylamino)naphthalene-1-sulfonyl]dipalmitoylphosphatidyleth anolamine (dansyl-PE) decreased, indicative of an increased water content within the head group region, the effect being a linear function of n-alkanol chain length (C1-C8), based on the total n-alkanol concentration. The fluorescence lifetimes of 1-palmitoyl-2-[[2-[4-(6-phenyl-trans-1,3, 5-hexatrienyl)phenyl]ethyl]carbonyl]-3-sn-phosphatidylcholine (DPH-PC) and N-[[4-(6-phenyl-1,3, 5-hexatrienyl)phenyl]propyl]trimethylammonium p-toluenesulfonate (TMAP-DPH), and the fluorescence intensity ratio of the latter in D2O compared to that in H2O, were used to probe the level of water in the acyl chain region. There was a decrease in the lifetime and an increase in the D2O/H2O fluorescence intensity ratio upon addition of short-chain n-alkanols (C1-C3), suggestive of increased water content. By contrast, long-chain n-alkanols (C4-C8) increased the lifetime and decreased the ratio, suggestive of decreased water content. Acyl chain order, determined from DPH-PC fluorescence anisotropy, was decreased by all n-alkanols, indicating that the effects were not probe-dependent. The effects of short- and long-chain n-alkanols on the fluorescence lifetime of the tryptophans of gramicidin, incorporated into phosphatidylcholine bilayers as a model membrane protein, were similar to those obtained with TMAP-DPH and DPH-PC; ethanol decreased and hexanol increased the lifetime. Thus the effect of n-alkanols and general anesthetics on changes in the amount of water that may be accommodated within the acyl chain region of the bilayer is not predictable on the basis of the magnitude of effects on head group region or acyl chain order/fluidity.

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 PKCalpha results in dramatically different effects on membrane-associated compared with lipid-independent enzyme activity. Furthermore, the effects on membrane-associated PKCalpha differ markedly depending on whether activity is induced by diacylglycerol or phorbol ester and also on n-alkanol chain length. PKCalpha 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 PKCalpha 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.

Protein kinase Calpha contains two activator binding sites that bind phorbol esters and diacylglycerols with opposite affinities.

Based on marked differences in the enzymatic properties of diacylglycerols compared with phorbol ester-activated protein kinase C (PKC), we recently proposed that activation induced by these compounds may not be equivalent (Slater, S. J., Kelly, M. B., Taddeo, F. J., Rubin, E., and Stubbs, C. D. (1994) J. Biol. Chem. 269, 17160-17165). In the present study, direct evidence is provided showing that phorbol esters and diacylglycerols bind simultaneously to PKC alpha. Using a novel binding assay employing the fluorescent phorbol ester, sapintoxin-D (SAPD), evidence for two sites of high and low affinity was obtained. Thus, both binding and activation dose-response curves for SAPD were double sigmoidal, which was also observed for dose-dependent activation by the commonly used phorbol ester, 4beta-12-O-tetradecanoylphorbol-13-acetate (TPA). TPA removed high affinity SAPD binding and also competed for the low affinity site. By contrast with TPA, low affinity binding of SAPD was inhibited by sn-1,2-dioleoylglycerol (DAG), while binding to the high affinity site was markedly enhanced. Again contrasting with both TPA and DAG, the potent PKC activator, bryostatin-I (B-I), inhibited SAPD binding to its high affinity site, while low affinity binding was unaffected. Based on these findings, a model for PKC activation is proposed in which binding of one activator to the low affinity site allosterically promotes binding of a second activator to the high affinity site, resulting in an enhanced level of activity. Overall, the results provide direct evidence that PKCalpha contains two distinct binding sites, with affinities that differ for each activator in the order: DAG > phorbol ester > B-I and B-I > phorbol ester > DAG, respectively.

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

The effect of variation of the degree of cis-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 PKC alpha and epsilon were obtained using the baculovirus-insect cell expression system. It was shown that increased PC unsaturation elevated the activity of PKC alpha. By contrast, increasing the unsaturation of PS decreased the activity of PKC alpha, and to a lesser extent PKC epsilon. 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.

Hydration and order in lipid bilayers.

The relationship between membrane lipid bilayer hydration and acyl chain order was investigated using time-resolved fluorescence spectroscopy. The degree of hydration in the head group region was assessed from fluorescence lifetime data along with fluorescence intensity measurements in D2O, relative to H2O buffer, using N-(5-dimethylaminonaphthalene-1-sulfonyl)dipalmitoylphosphatidylethan ola mine (dansyl-PE). The degree of hydration in the acyl chain region was estimated from its effect on the fluorescence lifetime of 1-palmitoyl-2-[[2-[4-(6-phenyl-trans-1,3,5-hexatrienyl)phenyl]ethyl] carbonyl]-3-sn-phosphatidylcholine (DPH-PC), and acyl chain order was determined from time-resolved anisotropy measurements of the DPH-PC. Comparisons of sn-2 unsaturation with sn-1,2 diunsaturation in phosphatidylcholine (PC) bilayers with the same number of double bonds/PC revealed a marked difference in interchain hydration and acyl chain order but little difference in terms of head group hydration. For diunsaturated dioleoyl-PC (DOPC) bilayers with two double bonds/PC, the DPH-PC fluorescence lifetime data indicated a greater level of interchain hydration than 1-palmitoyl-2-docosahexaenoyl-PC (PDPC) with six double bonds/sn-2 chain. By contrast, the head group hydration for DOPC was markedly less than for PDPC. A similar lack of correlation of effects on the two regions of the bilayer was found with cholesterol, it having opposite effects on interchain and head group hydration. When DPH-PC fluorescence lifetime data for bilayers composed of a range of different lipids was plotted as a function of acyl chain order, a strong correlation of interchain hydration with acyl chain order was revealed that was independent of lipid composition.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct activation of protein kinase C by 1 alpha,25-dihydroxyvitamin D3.

The key metabolite of vitamin D3, 1 alpha,25-dihydroxyvitamin D3 (1,25-D3), induces rapid cellular responses that constitute a so-called "non-genomic" response. This effect is distinguished from its "classic" genomic role in calcium homeostasis involving the nuclear 1,25-D3 receptor. Evidence is presented that protein kinase C (PKC) is directly activated by 1,25-D3 at physiological concentrations (EC50 = 16 +/- 1 nM). The effect was demonstrable with single PKC-alpha, -gamma, and -epsilon isoform preparations, assayed in a system containing only purified enzyme, substrate, co-factors, and lipid vesicles, from which it is inferred that a direct interaction with the enzyme is involved. The finding that calcium-independent isoform PKC-epsilon was also activated by 1,25-D3 shows that the calcium binding C2 domain is not required. The level of 1,25-D3-induced activation, paired with either diacylglycerol or 4 beta-12-O-tetradecanoylphorbol-13-acetate, was greater than that achievable by any individual activator alone, each at a saturating concentration, a result that implies two distinct activator sites on the PKC molecule. Phosphatidylethanolamine present in the lipid vesicles potentiated 4 beta-12-O-tetradecanoylphorbol-13-acetate- and diacylglycerol-induced PKC activities, whereas 1,25-D3-induced activity decreased, consistent with 1,25-D3-activated PKC possessing a distinct conformation. The results suggest that PKC is a "membrane-bound receptor" for 1,25-D3 and that it could be important in the control of non-genomic cellular responses to the hormone.

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.

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.

Evidence for discrete diacylglycerol and phorbol ester activator sites on protein kinase C. Differences in effects of 1-alkanol inhibition, activation by phosphatidylethanolamine and calcium chelation.

Stimulation of protein kinase C (PKC) activity is achieved in vivo by diacylglycerol but can also be obtained with tumor-promoting phorbol esters. Evidence is presented indicating that these two classes of activator may interact at different regions of the enzyme. The activity of a calcium-dependent PKC isoform (PKC-I) preparation was determined using 1,2-dioleoylglycerol (DOG) together with the phorbol ester 4 beta-12-O-tetradecanoylphorbol-13-acetate (TPA). The resulting PKC activity was in excess of that attained with either activator alone, each being at a maximum concentration for activation. A similar result was obtained with purified PKC-alpha and -epsilon isoforms, indicating that the additive effect was not due to sites being on distinct enzyme molecules. Support for two dissimilar activator sites came from the observation that the inactive phorbol ester 4 alpha-TPA competed for TPA but not for DOG in PKC activation. Other differences were observed between TPA- and DOG-activated PKC. It was found that 1-butanol inhibited DOG-activated PKC-I, while being without effect on stimulation by TPA. Also, the inclusion of phosphatidylethanolamine in the lipid vesicles led to a potentiation of PKC-I activity which was greater when activation was achieved by DOG compared to TPA. Further, the calcium- and DOG-dependent active conformational change of PKC was fully reversible upon calcium chelation, while that stimulated by TPA was only partially reversible. These experiments taken together suggest that diacylglycerols and phorbol esters bind with different affinities and at different sites on PKC, and induce distinct activated conformational forms of the enzyme.

The modulation of protein kinase C activity by membrane lipid bilayer structure.

The hypothesis that protein kinase C (PKC) activity is sensitive to phospholipid head group interactions was tested using lipid bilayers of defined composition with PKC purified from rat brain. The head group interactions were modulated by varying phosphatidylcholine cis-unsaturation, vesicle curvature, and by the addition of phosphatidylethanolamine and cholesterol. With unilamellar vesicles (including 20 mol% brain phosphatidylserine), increased phosphatidylcholine unsaturation potentiated basal and phorbol ester stimulated PKC activity. By contrast, in the presence of phosphatidylethanolamine, the activity decreased with increasing phosphatidylcholine unsaturation. Weakening phospholipid head group interactions spaces the head group region and increases interstitial water, and this effect was assessed from its effect on the fluorescence intensity of the phospholipid-labeled fluorophore 1-palmitoyl-2-N-(4-nitrobenzo-2-oxa-1,3-diazole)aminohexanoylphosphat idylcholin e (C6-NBD-PC). When the PKC activities with vesicles of varying phosphatidylcholine unsaturation, with and without phosphatidylethanolamine, were plotted as a function of the fluorescence intensity of C6-NBD-PC-labeled vesicles, a biphasic profile was obtained, which had an optimum value of intensity, relating to head group spacing, that corresponded to a maximal enzyme activity. A similar biphasic curve was also found when PKC activities were plotted as a function of published bilayer intrinsic curvature x-ray diffraction data, a parameter closely related to head group spacing. By contrast, no simple relationship was evident between PKC activity and 1,6-diphenyl-1,3,5-hexatriene anisotropy, taken as a measure of lipid order or fluidity. Therefore, increasing the level of phosphatidylcholine unsaturation, phosphatidylethanolamine, or cholesterol either potentiates or attenuates PKC activity, dependent on whether the initial condition is above or below its optimum.