Association between FTO, MC4R, SLC30A8, and KCNQ1 gene variants and type 2 diabetes in Saudi population.

Recent genome wide association studies identified many loci in several genes that have been consistently associated with type 2 diabetes mellitus in various ethnic populations. Among the genes that were most strongly associated with diabetes were fat mass- and obesity-associated, melanocortin 4 receptor, solute carrier family 30 member 8 (SLC30A8), and a member of the potassium voltage-gated channels. In the present study, we examined the association between variants in fat mass- and obesity-associated [rs9939609 (A/T)], melanocortin 4 receptor [rs17782313 (C/T), and rs12970134 (A/G)], SLC30A8 [rs13266634 (C/T)], and a member of the potassium voltage-gated channels [rs2237892(C/T)] genes in diabetes patients from Saudi Arabia. Genotypes were determined using the TaqMan single-nucleotide polymorphism genotype analysis technique. Minor allele frequency of the 4 variants tested was comparable between type 2 diabetes cases and controls. We observed an association between allele variants of SLC30A8 [rs13266634 (C/T)] and type 2-diabetes (P = 0.04). The other single-nucleotide polymorphisms examined in this study showed moderate or no correlation with diabetes in Saudis. Our data indicate that the SLC30A8 polymorphisms are associated with type 2 diabetes in the Saudi population. There is no evidence supporting an association between variants in the fat mass- and obesity-associated and melanocortin 4 receptor, and a member of the potassium voltage-gated channels genes and type 2 diabetes in the Saudi population.

Interleukin 17A and F and asthma in Saudi Arabia: gene polymorphisms and protein levels.

BACKGROUND: Asthma is a multifactorial disorder, and both genetic and environmental factors contribute to its development. We investigated the possible association between asthma and 5 single-nucleotide polymorphisms (SNPs) in the interleukin 17 (IL17) gene--rs17880588 (G/A) and rs17878530 (C/T) in IL17A and rs763780 (T/C), rs11465553 (T/C), and rs2397084 (G/A) in IL17F--and compared levels of the proteins IL17A and IL17F in asthma patients with those of controls. PATIENTS AND METHODS: The study group included 100 asthma patients and 102 ethnically matched controls. Genotyping was performed on purified DNA using reverse transcriptase-polymerase chain reaction with specific primers and probes. Levels of IL17A and IL17F were measured in plasma using enzyme-linked immunosorbent assay. RESULTS: Genotyping showed that AG heterozygotes of rs17880588 in IL17A were significantly more common in the control group than among the asthma patients (P < .05); no significant associations were observed for any of the other SNPs examined. Levels of IL17A and IL17F were both higher in asthma patients (IL17A, 2.242 [0.099] vs 2.752 [0.287] pg/mL; IL17F, 236.01 [38.28] vs 700 [201.078] pg/mL). The difference was statistically significant for IL17F (P = .025, t test). Levels of IL17A and IL17F were positively and significantly correlated in the asthma patients CONCLUSION: Of all the SNPs analyzed, only rs17880588 showed a significant association with asthma in the Saudi population we studied. Levels of IL17A and IL17F were significantly upregulated in the asthma patients. The morphology of IL17F appeared to affect expression levels.

Interaction of camel lens zeta-crystallin with quinones: portrait of a substrate by fluorescence spectroscopy.

Interaction of camel lens zeta-crystallin, an NADPH:quinone oxidoreductase, with several quinone derivatives was examined by fluorescence spectroscopy and activity measurements. Fluorescence of zeta-crystallin was quenched to different levels by the different quinones:juglone (5-OH, 1,4 naphthoquinone), 1,4 naphthoquinone (1,4-NQ), and 1,2 naphthoquinone (1,2-NQ) considerably quenched the fluorescence of zeta-crystallin, where as the commonly used substrate, 9,10-phenanthrenequinone (PQ) did not induce significant quenching. Activity measurements showed only PQ served as a substrate for camel lens zeta-crystallin, while juglone, 1,4-NQ, and 1,2-NQ were inhibitors. Thus quinones that interacted with zeta-crystallin directly inhibited the enzyme, whereas the substrate had very low affinity for the enzyme in the absence of NADPH. Another substrate, dichlorophenol indophenol (DCIP), conformed to the same pattern; DCIP did not quench the fluorescence of the enzyme significantly, but served as a substrate. This pattern is consistent with an ordered mechanism of catalysis with quinone being the second substrate. All three naphthoquinones were uncompetitive inhibitors with respect to NADPH and noncompetitive with respect to PQ. These kinetics are similar to those exhibited by cysteine- and/or lysine-modifying agents. Juglone, 1,4-NQ, and 1,2-NQ interacted with and quenched the fluorescence of camel lens alpha-crystallin, but to lesser extent than that of zeta-crystallin.

High-affinity binding of NADPH to camel lens zeta-crystallin.

Fluorescence spectrum of camel lens zeta-crystallin, a major protein in the lens of camelids and histicomorph rodents, showed maximum emission at 315 nm. This emission maximum is blue shifted compared to most proteins, including alpha-crystallin, and appeared to be due to tryptophan in highly hydrophobic environment. Interaction of NADPH with zeta-crystallin quenched the protein fluorescence and enhanced the fluorescence of bound NADPH. Analysis of fluorescence quenching suggested high-affinity interaction between NADPH and zeta-crystallin with an apparent Km<0.45 microM. This value is at least an order of magnitude lower than that suggested by activity measurements. Analysis of NADPH fluorescence showed a biphasic curve representing fluorescence of free- and bound-NADPH. The intersection between free- and bound-NADPH closely paralleled the enzyme concentration, suggesting one mole of NADPH was bound per subunit of the enzyme. Phenanthrenequinone (PQ), the substrate of zeta-crystallin, also was able to quench the fluorescence of zeta-crystallin, albeit weaker than NADPH. Quantitative analysis suggested that zeta-crystallin had low affinity for PQ in the absence of NADPH, and PQ binding induced significant conformational changes in zeta-crystallin.

Hydrophobicity of the NADPH binding domain of camel lens zeta-crystallin.

Interaction of camel lens zeta-crystallin with the hydrophobic probe 1-anilinonaphthalene-8-sulfonic acid (ANS) enhanced the ANS fluorescence and quenched the protein fluorescence. Both of these events were concentration-dependent and showed typical saturation curves suggesting specific ANS-zeta-crystallin binding. Quantitative analysis indicated that 1 mole zeta-crystallin bound at most 1 mole ANS. NADPH but not 9,10-phenanthrenequinone (PQ) was able to displace zeta-crystallin-bound ANS. These results suggested the presence of a hydrophobic domain in zeta-crystallin, possibly at the NADPH binding site. alpha-Crystallin as well as NADPH protected zeta-crystallin against thermal inactivation suggesting the importance of this site for enzyme stability. The NADPH:quinone oxidoreductase activity of zeta-crystallin was inhibited by ANS with NADPH as electron donor and PQ as electron acceptor. Lineweaver-Burk plots indicated mixed-type inhibition with respect to NADPH, with a K(i) of 2.3 microM. Secondary plots of inhibition with respect to NADPH indicated a dissociation constant (K'I) of 12 microM for the zeta-crystallin-NADPH-ANS complex. The K(i) being smaller than K'I suggested that competitive inhibition at the NADPH binding site was predominant over non-competitive inhibition. Like ANS-zeta-crystallin binding, inhibition was dependent on ANS concentration but independent of incubation time.

Kinetics of annexin VI, calcium, and phospholipid association and dissociation.

Annexins VI and V are members of the annexin family of proteins that bind to phospholipid membranes in a calcium-dependent manner. The dynamics of protein, calcium, and phospholipid assembly and dissociation were investigated by stopped-flow. At relatively low calcium levels, the kinetics of the binding reaction were sensitive to calcium concentration. However, in the presence of saturating levels of calcium and at relatively low protein/vesicle (w/w) ratios (0.4 or lower), the binding reactions were rapid and the rate constants were comparable to the collisional limit, about 1.4 x 10(10) M-1 s-1 for large unilamellar vesicles (about 120 nm diameter) and about 2.7 x 10(9) M-1 s-1 for small unilamellar vesicles (about 31 nm in diameter). These constants are expressed on the basis of vesicle concentration. These limiting association rate constants were not sensitive to the phospholipid composition of the vesicles. In contrast, at these calcium levels, protein dissociation was so slow that the complexes could be regarded as stable. However, individual calcium ions that were bound to the complexes appeared to exchange rapidly with ions in bulk solution. EGTA-induced protein dissociation was rapid with first-order rate constants ranging from 10 to 50 s-1. These were dependent on the membrane composition and on the protein type (annexin VI or V). Variations in this dissociation process were found to complement the calcium concentration needed to support annexin-membrane association; increasing the acidic phospholipid component or partially replacing phosphatidylcholine by phosphatidylethanolamine in the membrane decreased both the EGTA-induced dissociation rate and the calcium concentration needed to support binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein kinase C and annexins: unusual calcium response elements in the cell.

Protein kinase C and the annexins appear to share some unusual and potentially important membrane- and calcium-binding properties. While these proteins are calcium response elements, they are not calcium-binding proteins in the formal sense; at intracellular calcium concentrations, they only bind significant amounts of calcium when membranes or other suitable surfaces are present. The number of calcium ions bound per protein is large (> 8) and this stoichiometry, at the protein-membrane interface, may provide the large number of contact points needed for the very high-affinity interaction that is observed. The further ability of annexins and PKC to form structures with properties of integral membrane proteins may be important to provide a type of long-term cell signalling that produces a constitutively active kinase or ion channel activity. Selectivity for phospholipids in bilayer form is modest with respect to the acidic phospholipids but there is a surprising preference for phosphatidylethanolamine as the neutral phospholipid matrix. Along with other unusual properties, these proteins offer the potential for unique types of cell regulation events.

Autophosphorylation of protein kinase C may require a high order of protein-phospholipid aggregates.

The activation of protein kinase C (PKC) usually displays cofactor requirements that include phosphatidylserine (PS), diacylglycerol, and calcium. A complicating factor is that good exogenous substrates of PKC are polycationic proteins or peptides that form aggregates with PS in the assay. This study examined the autophosphorylation of PKC using assays with phospholipid provided in the form of vesicles or phospholipid-Triton mixed micelles. The results showed a close correlation between PKC autophosphorylation and the formation of aggregated assay components. Aggregation occurred primarily by the action of Mg2+ on phospholipids and appeared to underlie a number of major features of PKC autophosphorylation. For example, autophosphorylation required higher concentrations of PS than phosphorylation of exogenous substrates. This appeared to be the result of the different PS requirements of aggregation by divalent metal ions and cationic substrates. An unanticipated result was that aggregation of mixed micelles showed specificity for PS, high cooperativity with respect to several agents, and a requirement for calcium. These parameters were remarkably similar to those describing PKC autophosphorylation. Several major implications are evident in this study. Since the autophosphorylation assay is not a well defined system of monodisperse materials, autophosphorylation of PKC may proceed by intra- or interpeptide mechanism. The uniform correlation between aggregation and production of PKC activity suggested that kinetic parameters may represent interactions of assay components other than the enzyme. Aggregation, which appeared necessary for in vitro activation of PKC, may represent the expression of important but undefined in vivo requirements for this enzyme's function.

Interaction of annexin VI with membranes: highly restricted dissipation of clustered phospholipids in membranes containing phosphatidylethanolamine.

Association of annexin VI with membranes induced extensive clustering of acidic phospholipids as detected by self-quenching of fluorescent-labeled acidic phospholipids [Bazzi, M.D., & Nelsestuen, G.L. (1991) Biochemistry 30, 7961]. The present study examined the rates of protein-induced clustering of acidic phospholipids in membranes containing 10-15% fluorescent-labeled phosphatidic acid dispersed in phosphatidylcholine (PC) or phosphatidylethanolamine (PE). Both membranes supported similar levels of protein-induced fluorescence quenching. With membranes containing PC, protein-membrane association and fluorescence quenching were rapid, and were virtually complete within seconds after the reagents were mixed. Membranes containing PE exhibited rapid protein-membrane association, but showed a fluorescence quenching that was several orders of magnitude slower than membranes containing PC. Calcium chelation resulted in rapid dissociation of protein-membrane complexes. Subsequent recovery of the fluorescence signal of both membranes was virtually complete, but the rate of fluorescence recovery was very different. The recovery was rapid in membranes containing PC, while PE-containing membranes showed slow recovery that approached the rate at which the fluorescent-labeled phosphatidic acid exchanged between vesicles. Thus, the presence of PE appeared to severely restrict dissipation of clustered phospholipids in membranes. Membranes containing PE, N-methyl-PE, N,N-dimethyl-PE, and PC showed successive increases in the rates of fluorescence quenching and recovery, suggesting that hydrogen bonding between head groups was the basis for this property. If the restricted dissipation of phosphatidic acid in PE membranes is a general property, the relative mobility of membrane components and even diffusion on interior cell membranes may be greatly influenced by this phenomenon.

Importance of phosphatidylethanolamine for association of protein kinase C and other cytoplasmic proteins with membranes.

Biological membranes exhibit an asymmetric distribution of phospholipids. Phosphatidylserine (PS) is an acidic phospholipid that is found almost entirely on the interior of the cell where it is important for interaction with many cellular components. A less well understood phenomenon is the asymmetry of the neutral phospholipids, where phosphatidylcholine (PC) is located primarily on exterior membranes while phosphatidylethanolamine (PE) is located primarily on interior membranes. The effect of these neutral phospholipids on protein-phospholipid associations was examined using four cytoplasmic proteins that bind to membranes in a calcium-dependent manner. With membranes containing PS at a charge density characteristic of cytosolic membranes, protein kinase C and three other proteins with molecular masses of 64, 32, and 22 kDa all showed great selectively for membranes containing PE rather than PC as the neutral phospholipid; the calcium requirements for membrane-protein association of the 64- and 32-kDa proteins were about 10-fold lower with membranes containing PE; binding of the 22-kDa protein to membranes required the presence of PE and could not even be detected with membranes containing PC. Variation of the PS/PE ratio showed that membranes containing about 20% PS/60% PE provided optimum conditions for binding and were as effective as membranes composed of 100% PS. Thus, PE, as a phospholipid matrix, eliminated the need for membranes with high charge density and/or reduced the calcium concentrations needed for protein-membrane association. A surprising result was that PKC and the 64- and 32-kDa proteins were capable of binding to neutral membranes composed entirely of PE/PC or PC only. The different phospholipid headgroups altered only the calcium required for membrane-protein association. For example, calcium concentrations at the midpoint for association of the 64-kDa protein with membranes containing PS, PE/PC, or PC occurred at 6, 100, and 20,000 microM, respectively. Thus, biological probes detected major differences in the surface properties of membranes containing PE versus PC, despite the fact that both of these neutral phospholipids are often thought to provide "inert" matrices for the acidic phospholipids. The selectivity for membranes containing PE could be a general phenomenon that is applicable to many cytoplasmic proteins. The present study suggested that the strategic location of PE on the interior of the membranes may be necessary to allow some membrane-protein associations to occur at physiological levels of calcium and PS.

Extensive segregation of acidic phospholipids in membranes induced by protein kinase C and related proteins.

Protein kinase C and two other proteins with molecular masses of 64 and 32 kDa, purified from bovine brain, constitute a type of protein that binds a large number of calcium ions in a phospholipid-dependent manner. This study suggested that these proteins also induced extensive clustering of acidic phospholipids in the membranes. Clustering of acidic phospholipids was detected by the self-quenching of a fluorescence probe that was attached to acidic phospholipids (phosphatidic acid or phosphatidylglycerol). Addition of these proteins to phospholipid vesicles containing 15% fluorescently labeled phosphatidic acid dispersed in neutral phosphatidylcholine resulted in extensive, rapid, and calcium-dependent quenching of the fluorescence signal. Fluorescence-quenching requirements coincided with protein-membrane binding characteristics. As expected, the addition of these proteins to phospholipid vesicles containing fluorescent phospholipids dispersed with large excess of acidic phospholipids produced only small fluorescence changes. In addition, association of these proteins with vesicles composed of 100% fluorescent phospholipids resulted in no fluorescence quenching. Protein binding to vesicles containing 5-50% fluorescent phospholipid showed different levels of fluorescence quenching that closely resemble the behavior expected for extensive segregation of the acidic phospholipids in the outer layer of the vesicles. Thus, the fluorescence quenching appeared to result from self-quenching of the fluorophores that become clustered upon protein-membrane binding. These results were consistent with protein-membrane binding that was maintained by calcium bridges between the proteins and acidic phospholipids in the membrane. Since each protein bound eight or more calcium ions in the presence of phospholipid, they may each induce clustering of a related number of acidic phospholipids.(ABSTRACT TRUNCATED AT 250 WORDS)

Highly sequential binding of protein kinase C and related proteins to membranes.

Protein kinase C belongs to a class of proteins that displays simultaneous interaction with calcium and phospholipids. Other members of this class include two proteins (Mr 64K and 32K) isolated from bovine brain. The association of these proteins with membranes exhibited highly unusual properties that were not consistent with a simple equilibrium. Titration of protein-phospholipid binding as a function of calcium showed an apparently normal curve with a low degree of cooperativity. The binding was rapid and quickly adjusted to changes in the calcium concentration. Calcium was readily exchanged from the protein-phospholipid complex. However, at each calcium concentration, membrane-bound protein was not in rapid equilibrium with free protein in solution; the half-time for dissociation exceeded 24 h. Titration of phospholipid vesicles with proteins showed different saturation levels of bound protein at different calcium concentrations. The amount of protein bound was almost entirely determined by the concentration of calcium and was virtually unaffected by the free protein concentration. These properties suggested that protein-phospholipid binding involved a sequence of steps that were each irreversible upon completion. These binding properties were consistent with high-affinity interaction between protein and phospholipid, high cooperativity with respect to calcium (N greater than or equal to 10), clustering of acidic phospholipids, and negative cooperativity with respect to protein density on the membrane. A major apparent problem with the complete titration of PKC-membrane interaction was a requirement for calcium in excess of intracellular levels. However, a highly sequential binding process showed that a number of protein-binding sites on the membrane would be saturated with calcium at physiological levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation and regulation of protein kinase C enzymes.

Protein Kinase C (PKC) has been a principal regulatory enzyme whose function has been intensely investigated in the past decade. The primary features of this family of enzymes includes phosphorylation of serine and threonine residues located on basic proteins and peptide in a manner that is stimulated by calcium, phospholipid, and either diacylglycerol or phorbol esters. An additional intriguing feature of the enzymes is its ability to form two membrane-associated states, one of which is calcium dependent and reversible and the second is an irreversible complex which has the characteristics of an intrinsic membrane protein. Formation of the irreversible membrane-bound form is greatly facilitated by calcium and the tumor-promoting phorbol esters but does not appear to include covalent changes in the PKC structure. The intrinsic membrane-bound form is a very different enzyme in that its activity is no longer dependent on the other cofactors. It is proposed that formation of the irreversible membrane-bound form may be a mechanism for generating long-term cell regulation events where transient cell signals and second messengers induce long-term changes in the distribution of an enzyme in the cell. This property may be common to a number of regulatory proteins that are known to be distributed between the cytosol and membrane-fractions in the cell. Unfortunately, many problems have confronted study of PKC mechanism using the in vitro assay. This assay involves aggregation of the substrate, phospholipid, and enzyme to form a discontinuous mixture. Such a complex system prevents straightforward interpretation of enzyme kinetic data. Although many compounds affect the in vitro activity of PKC, most appear to accomplish this by relatively uninteresting mechanisms such as interference with the aggregation process. While some highly potent inhibitors undoubtedly interact directly with PKC, they also inhibit other enzymes and there are no entirely specific inhibitors of PKC known. Speculation on the possible roles of PKC in cell regulation are abundant and exciting. However, delineation of the regulatory roles of PKC may require another decade of intense effort.

Proteins that bind calcium in a phospholipid-dependent manner.

Three proteins (Mr = 64K, 32K, and 22K) that bind to phospholipids in a calcium-dependent manner were purified from bovine brain. The calcium-binding properties of these proteins were investigated by equilibrium dialysis and by gel filtration chromatography. The 64- and 32-kDa proteins were found to have calcium- and phospholipid-binding properties strikingly similar to those of protein kinase C [Bazzi, M.D., & Nelsestuen, G.L. (1990) Biochemistry 29, 7624]. The free proteins bound limited divalent metal ion even at 200 microM calcium. However, they bound eight to nine calcium ions per protein in the presence of membranes containing acidic phospholipids. The calcium concentrations needed for protein-phospholipid binding were different for these two proteins and were strongly influenced by the phospholipid composition of the vesicles; vesicles of higher phosphatidylserine content required lower concentrations of calcium for protein-membrane association. These properties described a general type of calcium-interacting system where simultaneous interaction of all three components (protein, phospholipids, and calcium) is required. The free proteins may provide only partial coordinate bonds to each calcium ion, but complete calcium-binding sites could be generated at the protein-phospholipid interface. In contrast to the 64- and 32-kDa proteins, the 22-kDa protein bound similar amounts of calcium (two to three ions/protein) in the presence or the absence of phospholipids. The 22-kDa protein had the lowest affinity for phospholipid and the highest affinity for calcium of the three proteins tested. Thus, calcium-dependent phospholipid-binding proteins consist of several types. For example, the 64- and 32-kDa proteins appear to be quite abundant and may even function as a calcium buffer to modulate signaling events.

Protein kinase C interaction with calcium: a phospholipid-dependent process.

The calcium-binding properties of calcium- and phospholipid-dependent protein kinase C (PKC) were investigated by equilibrium dialysis in the presence and the absence of phospholipids. Calcium binding to PKC displayed striking and unexpected behavior; the free proteins bound virtually no calcium at intracellular calcium concentrations and bound limited calcium (about 1 mol/mol of PKC) at 200 microM calcium. However, in the presence of membranes containing acidic phospholipids, PKC bound at least eight calcium ions per protein. The presence of 1 microM phorbol dibutyrate (PDBu) in the dialysis buffer had little effect on these calcium-binding properties. Analysis of PKC-calcium binding by gel filtration under equilibrium conditions gave similar results; only membrane-associated PKC bound significant amounts of calcium. Consequently, PKC is a member of what may be a large group of proteins that bind calcium in a phospholipid-dependent manner. The calcium concentrations needed to induce PKC-membrane binding were similar to those needed for calcium binding (about 40 microM calcium at the midpoint). However, the calcium concentration required for PKC-membrane binding was strongly influenced by the phosphatidylserine composition of the membranes. Membranes with higher percentages of phosphatidylserine required lower concentrations of calcium. These properties suggested that the calcium sites may be generated at the interface between PKC and the membrane. Calcium may function as a bridge between PKC and phospholipids. These studies also suggested that calcium-dependent PKC-membrane binding and PKC function could be regulated by a number of factors in addition to calcium levels and diacylglycerol content of the membrane.

Differences in the effects of phorbol esters and diacylglycerols on protein kinase C.

The binding of protein kinase C (PKC) to membranes and appearance of kinase activity are separable events. Binding is a two-step process consisting of a reversible calcium-dependent interaction followed by an irreversible interaction that can only be dissociated by detergents. The irreversibly bound PKC is constitutively active, and the second step of binding may be a major mechanism of PKC activation [Bazzi & Nelsestuen (1988) Biochemistry 27, 7589]. This study examined the activity of other forms of membrane-bound PKC and compared the effects of phorbol esters and diacylglycerols. Like the membrane-binding event, activation of PKC was a two-stage process. Diacylglycerols (DAG) participated in forming an active PKC which was reversibly bound to the membrane. In this case, both activity and membrane binding were terminated by addition of calcium chelators. DAG functioned poorly in generating the constitutively active, irreversible PKC-membrane complex. These properties differed markedly from phorbol esters which activated PKC in a reversible complex but also promoted constitutive PKC activation by forming the irreversible PKC-membrane complex. The concentration of phorbol esters needed to generate the irreversible PKC-membrane complex was slightly higher than the concentration needed to activate PKC. In addition, high concentrations of phorbol esters (greater than or equal to 50 nM) activated PKC and induced irreversible PKC-membrane binding in the absence of calcium. Despite these striking differences, DAG prevented binding of phorbol esters to high-affinity sites on the PKC-membrane complex.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of the protein kinase C-phorbol ester interaction.

The properties of the protein kinase C (PKC)-phorbol ester interaction were highly dependent on assay methods and conditions. Binding to cation-exchange materials or adsorption to gel matrices resulted in PKC that was capable of binding phorbol 12,13-dibutyrate (PDBu). The extraneous interactions were eliminated by measuring phorbol ester binding with a gel filtration chromatography assay in the presence of bovine serum albumin (BSA). In the absence of calcium, free PKC did not bind PDBu or phospholipids. Calcium caused structural changes in PKC which enhanced its interaction with surfaces such as the gel chromatography matrix. While BSA prevented this interaction, it did not interfere with PKC association with acidic phospholipids. Interaction of PKC with phospholipid resulted in two forms of membrane-associated PKC. The initial calcium-dependent and reversible form of membrane-associated PKC was capable of binding PDBu. Both PKC and PDBu were released from this complex by calcium chelation. Sustained interaction with phospholipid vesicles resulted in a PKC-membrane complex that could not be dissociated by calcium chelation and appeared to result from insertion of PKC into the hydrocarbon portion of the phospholipid bilayer. Membrane insertion was observed at calcium concentrations of 2-500 microM and with membrane compositions of 10-50% acidic phospholipid. However, the extent of insertion was dependent on the binding conditions and was promoted by high phospholipid to PKC ratios, high calcium, the presence of phorbol esters, high membrane charge, and long incubations.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of membrane-inserted protein kinase C.

Protein kinase C (PKC) interacted with phospholipid vesicles in a calcium-dependent manner and produced two forms of membrane-associated PKC: a reversibly bound form and a membrane-inserted form. The two forms of PKC were isolated and compared with respect to enzyme stability, cofactor requirements, and phorbol ester binding ability. Membrane-inserted PKC was stable for several weeks in the presence of calcium chelators and could be rechromatographed on gel filtration columns in the presence of EGTA without dissociation of the enzyme from the membrane. The activity of membrane-inserted PKC was not significantly influenced by Ca2+, phospholipids, and/or PDBu. Partial dissociation of this PKC from phospholipid was achieved with Triton X-100, followed by dialysis to remove the detergent. The resulting free PKC appeared indistinguishable from original free PKC with respect to its cofactor requirements for activation (Ca2+, phospholipid, and phorbol esters), molecular weight, and phorbol 12,13-dibutyrate (PDBu) binding. The binding of PDBu to free and membrane-inserted PKC was measured under equilibrium conditions using gel filtration techniques. At 2.0 nM PDBu, free PKC bound PDBu with nearly 1:1 stoichiometry in the presence of Ca2+ and phospholipid. No PDBu binding to the free enzyme was observed in the absence of Ca2+. In contrast, membrane-inserted PKC bound PDBu in the presence or the absence of Ca2+; calcium did enhance the affinity of this interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Association of protein kinase C with phospholipid monolayers: two-stage irreversible binding.

The association of protein kinase C (PKC) with phospholipid (PL) monolayers spread at the air-water interface was examined. PKC-PL binding induced surface pressure changes that were dependent on the amount of PKC, the phospholipid composition of the monolayers, the presence of Ca2+, and the initial surface pressure of the monolayer (pi 0). Examination of surface pressure increases induced by PKC as a function of phospholipid surface pressure, pi 0, revealed that PKC-phosphatidylserine (PS) association had a critical pressure of 43 dyn/cm. Above this surface pressure, PKC cannot cause further surface pressure changes. This high critical pressure indicated that PKC should be able to penetrate many biological membranes which appear to have surface pressures of about 30 dyn/cm. PKC-induced surface pressure changes were Ca2+ dependent only for PL monolayers spread at a pi 0 greater than 26 dyn/cm. PKC alone (in the absence of PL) formed a film at the air-water interface with a surface pressure of about 26 dyn/cm. Calcium-dependent binding was studied at the higher surface pressures which effectively excluded PKC from the air-water interface. Subphase depletion measurements suggested that association of PKC with PS monolayers consisted of two stages: a rapid Ca2+-dependent interaction followed by a slower process that resulted in irreversible binding of PKC to the monolayer. The second stage appeared to involve penetration of PKC into the hydrocarbon region of the phospholipid. The commonly used in vitro substrates for PKC, histone and protamine sulfate, also associated with and penetrated PS monolayers with critical pressures of 50 and 60 dyn/cm, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Constitutive activity of membrane-inserted protein kinase C.

Incubation of purified protein kinase C (PKC) with phospholipid vesicles produced two populations of membrane-bound PKC: one population was dissociated by calcium chelation and the other was not. The second population appeared to be inserted into the membrane. The activity of membrane-inserted PKC was Ca2+-independent and was only modestly sensitive to phorbol esters. Insertion was caused by high calcium concentrations or by phorbol esters plus low calcium. These conditions correlated with those needed to activate PKC; insertion into the membrane may be a primary mechanism of PKC activation. PKC may be a long-term cell regulator which becomes inserted into the membrane upon appearance of the second messengers, calcium and diacylglycerol, and remains in an active membrane-bound state when the second messengers have been removed.