Distinct Ca2+ binding properties of novel C2 domains of plant phospholipase dalpha and beta

Of the isoforms of plant phospholipase D (PLD) that have been cloned and characterized, PLDalpha requires millimolar levels of Ca(2+) for optimal activity, whereas PLDbeta is most active at micromolar concentrations of Ca(2+). Multiple amino acid sequence alignments suggest that PLDalpha and PLDbeta both contain a Ca(2+)-dependent phospholipid-binding C2 domain near their N termini. In the present study, we expressed and characterized the putative C2 domains of PLDalpha and PLDbeta, designated PLDalpha C2 and PLDbeta C2, by CD spectroscopy, isothermal titration calorimetry, and phospholipid binding assay. Both PLD C2 domains displayed CD spectra consistent with anticipated major beta-sheet structures but underwent spectral changes upon binding Ca(2+); the magnitude was larger for PLDbeta C2. These conformational changes, not shown by any of the previously characterized C2 domains of animal origin, occurred at micromolar Ca(2+) concentrations for PLDbeta C2 but at millimolar levels of the cation for PLDalpha C2. PLDbeta C2 exhibited three Ca(2+)-binding sites: one with a dissociation constant (K(d)) of 0.8 microm and the other two with a K(d) of 24 micrometer. In contrast, isothermal titration calorimetry data of PLDalpha C2 were consistent with 1-3 low affinity Ca(2+)-binding sites with K(d) in the range of 590-470 micrometer. The thermodynamics of Ca(2+) binding markedly differed for the two C2 domains. Likewise, PLDbeta C2 bound phosphatidylcholine (PC), the substrate of PLD, in the presence of submillimolar Ca(2+) concentrations, whereas PLDalpha C2 did so only in the presence of millimolar levels of the metal ion. Both C2 domains bound phosphatidylinoistol 4,5-bisphosphate, a regulator of PC hydrolysis by PLD. However, added Ca(2+) displaced the bound phosphatidylinoistol 4,5-bisphosphate. Ca(2+) and PC binding properties of PLDalpha C2 and PLDbeta C2 follow a trend similar to the Ca(2+) requirements of the whole enzymes, PLDalpha and PLDbeta, for PC hydrolysis. Taken together, the results suggest that the C2 domains of PLDalpha and PLDbeta have novel structural features and serve as handles by which Ca(2+) differentially regulates the activities of the isoforms.     

In vitro distribution and characterization of membrane-associated PLD and PI-PLC in Brassica napus

Two types of phospholipid degrading enzyme, phospholipase D (PLD; EC 3.1.4.4) and phosphatidyl- inositol-specific phospholipase C (PIP(2)-PLC; PI-PLC 3.1.4.11) were studied during the development of seeds and plants of Brassica napus. PLD exhibits two types of activity; polyphosphoinositide-requiring (PIP(2)-dependent PLD) and polyphosphoinositide-independent requiring millimolar concentrations of calcium (PLDalpha). Significantly different patterns of activity profiles were found for soluble and membrane-associated forms of all three enzymes within both processes. Membrane-associated PIP(2)-dependent PLD activity shows the opposite trend when compared to PLDalpha, while the highest PI-PLC activity appears in the same stages of development of seeds and plants as for PLDalpha. In subcellular fractions of hypocotyls of young plants, phospholipases were localized predominantly on plasma membranes. The biochemical characteristics (Ca(2+), pH) of all three enzymes associated with plasma membrane vesicles, isolated by partitioning in an aqueous dextran- polyethylene glycol two-phase system, are also described. Direct interaction of PLDalpha with G-proteins under in vitro conditions was not confirmed.     

The Arabidopsis phospholipase D family. Characterization of a calcium-independent and phosphatidylcholine-selective PLD zeta 1 with distinct regulatory domains

Four types of phospholipase D (PLD), PLD alpha, beta, gamma, and delta, have been characterized in Arabidopsis, and they display different requirements for Ca(2+), phosphatidylinositol 4,5-bisphosphate (PIP(2)), substrate vesicle composition, and/or free fatty acids. However, all previously cloned plant PLDs contain a Ca(2+)-dependent phospholipid-binding C2 domain and require Ca(2+) for activity. This study documents a new type of PLD, PLD zeta 1, which is distinctively different from previously characterized PLDs. It contains at the N terminus a Phox homology domain and a pleckstrin homology domain, but not the C2 domain. A full-length cDNA for Arabidopsis PLD zeta 1 has been identified and used to express catalytically active PLD in Escherichia coli. PLD zeta 1 does not require Ca(2+) or any other divalent cation for activity. In addition, it selectively hydrolyzes phosphatidylcholine, whereas the other Arabidopsis PLDs use several phospholipids as substrates. PLD zeta 1 requires PIP(2) for activity, but unlike the PIP(2)-requiring PLD beta or gamma, phosphatidylethanolamine is not needed in substrate vesicles. These differences are described, together with a genomic analysis of 12 putative Arabidopsis PLD genes that are grouped into alpha, beta, delta, gamma, and zeta based on their gene architectures, sequence similarities, domain structures, and biochemical properties.     

In vivo substrates and the contribution of the common phospholipase D, PLDalpha, to wound-induced metabolism of lipids in Arabidopsis

The common plant phospholipase D (PLD), PLDalpha, has been proposed to be involved in wound-induced production of jasmonic acid. To better understand the role(s) of PLDalpha in the wound response, detailed lipid analysis was carried out to determine the in vivo substrates and the contribution of PLDalpha in wound-induced lipid metabolism in Arabidopsis thaliana. Mechanical wounding of Arabidopsis leaves resulted in significantly less hydrolysis of phosphatidylcholine (PC) in PLDalpha-deficient than in wild-type plants. Hydrolysis of phosphatidylethanolamine, phosphatidylglycerol (PG), and phosphatidylinositol within 30 min of wounding was not significantly different in PLDalpha-deficient and wild-type leaves. Phosphatidic acid (PA) levels increased rapidly in wild-type and, to a lesser extent, in PLDalpha-deficient plants. The acyl composition of the PA generated by wounding suggests that the major in vivo substrate of PLD in wild-type leaves was PC, and that PG hydrolysis accounted for 10-15% of the wound-induced PA in wild-type leaves. Comparison of the acyl compositions of the wound-induced PA of wild-type and PLDalpha-deficient leaves indicated that PLDalpha hydrolyzed PG more readily than other PLD isoforms did. Wounding produced substantial increases in free linoleic and linolenic acids in wild-type plants, whereas PLDalpha-deficient plants showed only a slight increase in linoleic acid and no significant increase in linolenic acid. These results demonstrate that PLDalpha and at least one other PLD isoform, as well as other hydrolytic enzymes, are active in mechanically wounded Arabidopsis leaves, and PLDalpha is involved in wound-induced metabolism of polyunsaturated fatty acids.     

Evidence for and characterization of Ca2+ binding to the catalytic region of Arabidopsis thaliana phospholipase Dbeta

Most types of plant phospholipase D (PLD) require Ca(2+) for activity, but how Ca(2+) affects PLD activity is not well understood. We reported previously that Ca(2+) binds to the regulatory C2 domain that occurs in the N terminus of the Ca(2+)-requiring PLDs. Using Arabidopsis thaliana PLDbeta and C2-deleted PLDbeta (PLDbetacat), we now show that Ca(2+) also interacts with the catalytic regions of PLD. PLDbetacat exhibited Ca(2+)-dependent activity, was much less active, and required a higher level of Ca(2+) than the full-length PLDbeta. Ca(2+) binding of the proteins was stimulated by phospholipids; phosphatidylserine was the most effective among those tested. Scatchard plot analysis of Ca(2+) binding data yielded an estimate of 3.6 high affinity (K(d) = 29 mum) binding sites on PLDbeta. The Ca(2+)-PLDbetacat interaction increased the affinity of the protein for the activator, phosphatidylinositol 4,5-bisphosphate, but not for the substrate, phosphatidylcholine. This is in contrast to the effect of Ca(2+) binding to the C2 domain, which stimulates phosphatidylcholine binding but inhibits phosphatidylinositol 4,5-bisphosphate binding of the domain. These results demonstrate the contrasting and complementary effects of the Ca(2+)- and lipid-binding properties of the C2 and catalytic domains of plant PLD and provide insight into the mechanism by which Ca(2+) regulates PLD activity.     

Involvement of phospholipase D in wound-induced accumulation of jasmonic acid in arabidopsis

Multiple forms of phospholipase D (PLD) were activated in response to wounding, and the expressions of PLDalpha, PLDbeta, and PLDgamma differed in wounded Arabidopsis leaves. Antisense abrogation of the common plant PLD, PLDalpha, decreased the wound induction of phosphatidic acid, jasmonic acid (JA), and a JA-regulated gene for vegetative storage protein. Examination of the genes involved in the initial steps of oxylipin synthesis revealed that abrogation of the PLDalpha attenuated the wound-induced expression of lipoxygenase 2 (LOX2) but had no effect on allene oxide synthase (AOS) or hydroperoxide lyase in wounded leaves. The systemic induction of LOX2, AOS, and vegetative storage protein was lower in the PLDalpha-suppressed plants than in wild-type plants, with AOS exhibiting a distinct pattern. These results indicate that activation of PLD mediates wound induction of JA and that LOX2 is probably a downstream target through which PLD promotes the production of JA.     

The direct interaction of phospholipase C-gamma 1 with phospholipase D2 is important for epidermal growth factor signaling

The epidermal growth factor (EGF) receptor has an important role in cellular proliferation, and the enzymatic activity of phospholipase C (PLC)-gamma1 is regarded to be critical for EGF-induced mitogenesis. In this study, we report for the first time a phospholipase complex composed of PLC-gamma1 and phospholipase D2 (PLD2). PLC-gamma1 is co-immunoprecipitated with PLD2 in COS-7 cells. The results of in vitro binding analysis and co-immunoprecipitation analysis in COS-7 cells show that the Src homology (SH) 3 domain of PLC-gamma1 binds to the proline-rich motif within the Phox homology (PX) domain of PLD2. The interaction between PLC-gamma1 and PLD2 is EGF stimulation-dependent and potentiates EGF-induced inositol 1,4,5-trisphosphate (IP(3)) formation and Ca(2+) increase. Mutating Pro-145 and Pro-148 within the PX domain of PLD2 to leucines disrupts the interaction between PLC-gamma1 and PLD2 and fails to potentiate EGF-induced IP(3) formation and Ca(2+) increase. However, neither PLD2 wild type nor PLD2 mutant affects the EGF-induced tyrosine phosphorylation of PLC-gamma1. These findings suggest that, upon EGF stimulation, PLC-gamma1 directly interacts with PLD2 and this interaction is important for PLC-gamma1 activity.     

Cholecystokinin-evoked Ca(2+) waves in isolated mouse pancreatic acinar cells are modulated by activation of cytosolic phospholipase A(2), phospholipase D, and protein kinase C.

We employed confocal laser-scanning microscopy to monitor cholecystokinin (CCK)-evoked Ca(2+) signals in fluo-3-loaded mouse pancreatic acinar cells. CCK-8-induced Ca(2+) signals start at the luminal cell pole and subsequently spread toward the basolateral membrane. Ca(2+) waves elicited by stimulation of high-affinity CCK receptors (h.a.CCK-R) with 20 pM CCK-8 spread with a slower rate than those induced by activation of low-affinity CCK receptors (l.a. CCK-R) with 10 nM CCK-8. However, the magnitude of the initial Ca(2+) release was the same at both CCK-8 concentrations, suggesting that the secondary Ca(2+) release from intracellular stores is modulated by activation of different intracellular pathways in response to low and high CCK-8 concentrations. Our experiments suggest that the propagation of Ca(2+) waves is modulated by protein kinase C (PKC) and arachidonic acid (AA). The data indicate that h.a. CCK-R are linked to phospholipase C (PLC) and phospholipase A(2) (PLA(2)) cascades, whereas l.a.CCK-R are coupled to PLC and phospholipase D (PLD) cascades. The products of PLA(2) and PLD activation, AA and diacylglycerol (DAG), cause inhibition of Ca(2+) wave propagation by yet unknown mechanisms.     

Molecular cloning and functional expression of a phospholipase D from cabbage (Brassica oleracea var. capitata)

We cloned and expressed a full-length cDNA encoding a phospholipase D of type alpha (PLDalpha) from cabbage. Analysis of the cDNA predicted an 812-amino-acid protein of 92.0 kDa. The deduced amino acid sequence of cabbage PLD has 83% and 80% identity with Arabidopsis PLDalpha and castor bean PLD, respectively. Expression of this cDNA clone in E. coli shows a functional PLD activity similar to that of the natural PLD.     

KCl activates phospholipase D at two different concentration ranges: distinguishing between hyperosmotic stress and membrane depolarization

Hyperosmotic stress induces the rapid formation of phosphatidic acid (PA) in Chlamydomonas moewusii via the activation of two signalling pathways: phospholipase D (PLD) and phospholipase C (PLC), the latter in combination with diacylglycerol kinase (DGK) (Munnik et al., 2000). A concomitant increase in cell Ca(2+) becomes manifest as deflagellation. When KCl was used as osmoticum we found that two concentration ranges activated deflagellation: one between 50 and 100 mm and another above 200 mm. Deflagellation in low KCl concentrations was complete within 30 sec whereas in high concentrations it took 5 min. PLC was not activated, as it was by high KCl concentrations that cause hyperosmotic stress. Moreover PLD was activated more strongly by low than by high KCl concentrations. Potassium was the most potent monovalent cation based on the induction of deflagellation and the formation of PA and PBut. During treatment, the external medium acidified, indicating an increase in H(+)-ATPase activity in order to re-establish the membrane potential. Activation of PLD and deflagellation at low KCl concentrations were abrogated by treatment with La(3+), Gd(3+) and EGTA, indicating the dependency on extracellular Ca(2+). This suggests that low concentrations of KCl depolarize the plasma membrane, resulting in the activation of H(+)-ATPases and opening voltage-dependent Ca(2+) +/- channels, observed as deflagellation and an increase in PLD activity.     

Arabidopsis phospholipase Dalpha1 interacts with the heterotrimeric G-protein alpha-subunit through a motif analogous to the DRY motif in G-protein-coupled receptors

Phospholipase D (PLD) and heterotrimeric G-protein both play important, diverse roles in cellular regulation and signal transduction. Here we have determined the physical interaction between plant PLD and the only canonical alpha-subunit (Galpha) of the G-protein in Arabidopsis thaliana and the molecular basis for the interaction. PLDalpha1 expressed in either Escherichia coli or Arabidopsis was co-precipitated with Galpha. PLDalpha1 contains a sequence motif analogous to the G alpha-interacting DRY motif normally conserved in G-protein-coupled receptors. Mutation of the central Lys residue PLD(K564A) of this motif abolished the PLDalpha1-Galpha binding, whereas mutation of the two flanking residues PLD(E563A) and PLD(F565A) decreased the binding. Addition of Galpha to PLDalpha1 inhibited PLDalpha1 activity, whereas the PLD(K564A) mutation that disrupted the Galpha-PLDalpha1 binding abolished the inhibition. GTP relieved the Galpha inhibition of PLDalpha1 activity and also inhibited the binding between PLDalpha1 and Galpha. Meanwhile, the PLDalpha1-Galpha interaction stimulated the intrinsic GTPase activity of Galpha. Therefore, these results have demonstrated the direct binding between Galpha and PLDalpha1, identified the DRY motif on PLDalpha1 as the site for the interaction, and indicated that the interaction modulates reciprocally the activities of PLDalpha1 and Galpha.     

Direct relationship between intracellular calcium mobilization and phospholipase D activation in prostaglandin E-stimulated human erythroleukemia cells.

The relationship between calcium mobilization and phospholipase D (PLD) activation in response to E-series prostaglandins (PGEs) was investigated in human erythroleukemia cells. Intracellular free Ca2+ concentration ([Ca2+]i) was increased by PGE1 and PGE2 over the same concentration range at which PLD activation was seen. Pretreatment of cells with pertussis toxin greatly inhibited the PGE-stimulated increase in [Ca2+]i, implying that a G protein participates in the PGE receptor signaling process. The peak level and also the plateau level of Ca2+ mobilization stimulated by these prostaglandins were markedly decreased in Ca(2+)-depleted medium, indicating that both extracellular and intracellular Ca2+ stores contribute to the changes in [Ca2+]i. Likewise, activation of PLD by PGE1 and PGE2 was abolished by pertussis toxin pretreatment or incubation in Ca(2+)-depleted medium. U73122, a putative phospholipase C inhibitor, blocked both Ca2+ mobilization and PLD activation in PGE-stimulated cells. Furthermore, the intracellular loading of BAPTA, a Ca2+ chelator, inhibited both Ca2+ mobilization and PLD activation by PGE1 and PGE2 in a similar dose-dependent manner. Simultaneous measurement of [Ca2+]i and PLD activity in the same cell samples indicated that PLD activity increases as a function of [Ca2+]i in a similar fashion in cells stimulated either by PGEs or by the calcium ionophore ionomycin. Taken together, these findings suggest that a rise in [Ca2+]i is necessary for PGE-stimulated PLD activity in human erythroleukemia cells.     

Ca(2+)- and phospholipase D-dependent and -independent pathways activate mTOR signaling

The mammalian target of rapamycin (mTOR) promotes increased protein synthesis required for cell growth. It has been suggested that phosphatidic acid, produced upon activation of phospholipase D (PLD), is a common mediator of growth factor activation of mTOR signaling. We used Rat-1 fibroblasts expressing the alpha(1A) adrenergic receptor to study if this G(q)-coupled receptor uses PLD to regulate mTOR signaling. Phenylephrine (PE) stimulation of the alpha(1A) adrenergic receptor induced mTOR autophosphorylation at Ser2481 and phosphorylation of two mTOR effectors, 4E-BP1 and p70 S6 kinase. These PE-induced phosphorylations were greatly reduced in cells depleted of intracellular Ca(2+). PE activation of PLD was also inhibited in Ca(2+)-depleted cells. Incubation of cells with 1-butanol to inhibit PLD signaling attenuated PE-induced phosphorylation of mTOR, 4E-BP1 and p70 S6 kinase. By contrast, platelet-derived growth factor (PDGF)-induced phosphorylation of these proteins was not blocked by Ca(2+) depletion or 1-butanol treatment. These results suggest that the alpha(1A) adrenergic receptor promotes mTOR signaling via a pathway that requires an increase in intracellular Ca(2+) and activation of PLD. The PDGF receptor, by contrast, appears to activate mTOR by a distinct pathway that does not require Ca(2+) or PLD.     

The role of interfacial binding in the activation of Streptomyces chromofuscus phospholipase D by phosphatidic acid

The Streptomyces chromofuscus phospholipase D (PLD) cleavage of phosphatidylcholine in bilayers can be enhanced by the addition of the product phosphatidic acid (PA). Other anionic lipids such as phosphatidylinositol, oleic acid, or phosphatidylmethanol do not activate this PLD. This allosteric activation by PA could involve a conformational change in the enzyme that alters PLD binding to phospholipid surfaces. To test this, the binding of intact PLD and proteolytically cleaved isoforms to styrene divinylbenzene beads coated with a phospholipid monolayer and to unilamellar vesicles was examined. The results indicate that intact PLD has a very high affinity for PA bilayers at pH >/= 7 in the presence of EGTA that is weakened as Ca(2+) or Ba(2+) are added to the system. Proteolytically clipped PLD also binds tightly to PA in the absence of metal ions. However, the isolated catalytic fragment has a considerably weaker affinity for PA surfaces. In contrast to PA surfaces, all PLD forms exhibited very low affinity for PC interfaces with an increased binding when Ba(2+) was added. All PLD forms also bound tightly to other anionic phospholipid surfaces (e.g. phosphatidylserine, phosphatidylinositol, and phosphatidylmethanol). However, this binding was not modulated in the same way by divalent cations. Chemical cross-linking studies suggested that a major effect of PLD binding to PA.Ca(2+) surfaces is aggregation of the enzyme. These results indicate that PLD partitioning to phospholipid surfaces and kinetic activation are two separate events and suggest that the Ca(2+) modulation of PA.PLD binding involves protein aggregation that may be the critical interaction for activation.     

Isolation and characterization of a 66-kDa protein from rat liver plasma membrane with RhoA-stimulated phospholipase D activity.

A 66-kDa molecular weight protein with phospholipase D activity was solubilized and partially purified from rat liver plasma membrane. The activity and regulation of this phospholipase D have been characterized. Immunoblot analyses indicated that the enzyme was distinct from hPLD1 and PLD2, but was recognized by an antibody to the 12 terminal amino acids of PLD1. PLD activity was stimulated by 1-100 microM Ca(2+) and Mg(2+) and displayed a pH optimum of 7.5. Activity was inhibited by both saturated and unsaturated fatty acids. This PLD was activated in an ATP-independent manner by the PKC isozymes alpha and betaII but not activated by other PKC isozymes. It was also stimulated by the small G-proteins RhoA and ARF. RhoA stimulated the greatest activation, followed by ARF and PKC(alpha). This enzyme was further activated in a synergistic manner when combinations of PKC(alpha) and RhoA or ARF were used. This enzyme displayed a greater response activation by RhoA than to activation by ARF. While a potential breakdown product of PLD1, activation by RhoA indicates that the PLD characterized here is distinct from the other PLDs cloned or isolated to date.     

Yeast mitochondria (Saccharomyces cerevisiae) contain Ca(2+)-independent phospholipase A1 and A2 activities: effect of respiratory state

We demonstrate that both phospholipase A1 and phospholipase A2 are associated with isolated yeast mitochondria (Saccharomyces cerevisiae). Activity assays indicate that, unlike most other mitochondrial phospholipases A, the yeast enzymes are Ca(2+)-independent with acidic (pH 4-5) as well as alkaline (pH 8-9) pH optima. Data obtained with mitochondria isolated from either fermenting or respiring cells, and initial observations with a petite strain, strongly suggest that a phospholipase A2 with an acidic pH optimum functions in the in vivo adaptation and maintenance of mitochondrial membranes required for respiration.     

A neutral phospholipase D activity from rat brain synaptic plasma membranes. Identification and partial characterization

Rapid activation of phospholipase D (PLD) in response to cell stimulation was recently demonstrated in many systems, raising the hypothesis that PLD participates in transduction of extracellular signals across the plasma membrane. In the present study, we describe the identification of a neutral PLD activity in purified rat brain synaptic plasma membranes, and the in vitro conditions required to assay its catalytic activity with exogenous [3H]phosphatidylcholine as substrate. Production of [3H]phosphatidic acid, the natural lipid product of PLD and of [3H]phosphatidylethanol, catalyzed by PLD in the presence of ethanol via transphosphatidylation, were measured. The synaptic membrane PLD exhibited its highest activity at pH 7.2 and was thus defined as a neutral PLD. Enzyme activity was absolutely dependent on the presence of sodium oleate and was strongly activated by Mg2+ ions (at 1 mM). Ca2+ at concentrations up to 0.25 mM was as stimulatory as Mg2+, but at 2 mM it completely inhibited enzyme activity. Mg2+ extended the linear phase of PLD activity from 2 to 15 min, suggesting that it may stabilize the enzyme under our assay conditions. The production of [3H]phosphatidylethanol was a saturable function of ethanol concentration. Production of [3H] phosphatidic acid was inversely related to the concentration of ethanol and to the accumulation of phosphatidylethanol, indicating that the two phospholipids are indeed produced by the competing hydrolase and transferase activities of the same enzyme. beta,beta-Dimethylglutaric acid, utilized previously as a buffer in studies of rat brain PLD, inhibited enzyme activity at neutral pH but not at acidic pH. The properties of the neutral synaptic membrane PLD and its relationships with other in vitro, acid, and neutral PLD activities, as well as with the signal-dependent PLD detected in intact cells, are discussed.     

Phosphohydrolase and transphosphatidylation reactions of two Streptomyces phospholipase D enzymes: covalent versus noncovalent catalysis

A kinetic comparison of the hydrolase and transferase activities of two bacterial phospholipase D (PLD) enzymes with little sequence homology provides insights into mechanistic differences and also the more general role of Ca(2+) in modulating PLD reactions. Although the two PLDs exhibit similar substrate specificity (phosphatidylcholine preferred), sensitivity to substrate aggregation or Ca(2+), and pH optima are quite distinct. Streptomyces sp. PMF PLD, a member of the PLD superfamily, generates both hydrolase and transferase products in parallel, consistent with a mechanism that proceeds through a covalent phosphatidylhistidyl intermediate where the rate-limiting step is formation of the covalent intermediate. For Streptomyces chromofuscus PLD, the two reactions exhibit different pH profiles, a result consistent with a mechanism likely to involve direct attack of water or an alcohol on the phosphorus. Ca(2+), not required for monomer or micelle hydrolysis, can activate both PLDs for hydrolysis of PC unilamellar vesicles. In the case of Streptomyces sp. PMF PLD, Ca(2+) relieves product inhibition by interactions with the phosphatidic acid (PA). A similar rate enhancement could occur with other HxKx(4)D-motif PLDs as well. For S. chromofuscus PLD, Ca(2+) is absolutely critical for binding of the enzyme to PC vesicles and for PA activation. That the Ca(2+)-PA activation involves a discreet site on the protein is suggested by the observation that the identity of the C-terminal residue in S. chromofuscus PLD can modulate the extent of product activation.