Relationship between Phospholipase D Activation and Endothelial Vasomotor Dysfunction in Rabbit Aorta

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Vol. 283, Issue 1, 305-311, 1997

Relationship between Phospholipase D Activation and Endothelial Vasomotor Dysfunction in Rabbit Aorta

David A. Cox and Marlene L. Cohen

Lilly Research Laboratories, Eli Lilly and Company, Indianapolis, Indiana

	Abstract

Top Abstract Introduction Methods Results Discussion References

Lysophosphatidylcholine (lysoPC) causes endothelial vasomotor dysfunction in isolated blood vessels, although the signalingpathways involved in this effect remain to be established. AlthoughlysoPC stimulated phospholipase D (PLD) activity in cultured endothelialcells, the role of PLD in the vascular effects of lysoPC remainsunclear. This study investigated the hypothesis that PLD is involvedin lysoPC-induced endothelial vasomotor dysfunction in isolatedrabbit aorta. LysoPC (3-30 µM) stimulated vascular PLD activityand inhibited endothelium-dependent vasorelaxation to acetylcholinewithin an identical concentration range. In contrast, lysoPC-inducedinhibition of vasorelaxation was not prevented by the selectiveprotein kinase C (PKC) inhibitor, GF109203X (3 µM), which suggestedthat this enzyme was not involved in the endothelial vasomotordysfunction produced by lysoPC. The ability of two other lysophospholipids,lyso-platelet-activating factor (3-30 µM) and lysophosphatidylserine(10-30 µM) to induce endothelial vasomotor dysfunction was alsoassociated closely with their ability to stimulate vascular PLDactivity. Parallel stimulation of PLD activity and inhibitionof acetylcholine-induced relaxation was also observed with orthovanadate(0.1-3 mM), which suggested that the association between PLD activationand endothelial vasomotor dysfunction was not a phenomenon particularto lysophospholipids. The magnitude of PLD stimulation and theextent of endothelial dysfunction induced by these diverse stimuliwere highly correlated (r² = 0.88). These observations suggest that the PLD signal transductionpathway is important in the endothelial vasomotor dysfunctionproduced by lysophospholipids and perhaps other agents.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Endothelial vasomotor dysfunction accompanies a variety of cardiovascular pathologies and risk factors, including hypercholesterolemia,atherosclerosis, hypertension and reperfusion injury (Stewart,1995). Disruption of nitric oxide-mediated vasodilation (Gilliganet al., 1994; Panza et al., 1995) along with an increase in vascularoxidant stress (Ohara et al., 1993; Jun et al., 1996) have beenimplicated in endothelial dysfunction. Recent studies in humanshave suggested that the clinical benefit of lipid-lowering therapy(Levine et al., 1995) and antioxidants (Anderson et al., 1995)may be mediated in part by their ability to normalize endothelialfunction in pathological conditions in vivo. These findings areconsistent with previous suggestions that oxidized LDL, whichwas present in atherosclerotic human blood vessels in vivo (Yla-Herttualaet al., 1989) and selectively enhanced coronary vasoconstrictionin vitro (Cox and Cohen, 1996a), plays an important role in endothelialvasomotor dysfunction and the clinical manifestations of atherosclerosis(Steinberg et al., 1989; Cox and Cohen, 1996b)

Lysophosphatidylcholine is an inflammatory lipid responsible for many of the proatherogenic effects of oxidized LDL, includinginhibition of endothelium-dependent vasodilation, increased leukocyteadhesion to the endothelium and enhanced expression of cell adhesionmolecules on endothelial cells (Steinberg et al., 1989). LysoPCitself exerts chemotactic effects on monocytes (Quinn et al.,1987), is mitogenic for vascular smooth muscle cells (Chai etal., 1996), enhances superoxide anion release from neutrophils(Ginsburg et al., 1989) and isolated blood vessels (Ohara et al.,1994) and enhances mast cell secretion (Marquardt and Walker,1991). Because the concentration of lysoPC was increased severalfold in the blood vessel walls of rabbits (Keaney et al., 1995)and monkeys (Portman and Alexander, 1969) with atherosclerosis,this spectrum of proinflammatory effects documented for lysoPCin vitro may also occur in vivo.

The signal transduction pathways involved in lysoPC-induced endothelial vasomotor dysfunction and other cellular effects remainill-defined. However, many of the actions of lysoPC can be mimickedby processes that increase phosphatidylcholine-specific PLD activity.PLD catalyzes the hydrolysis of phosphatidylcholine to phosphatidicacid, and has been implicated in cellular secretion, mitogenicsignaling and neutrophil superoxide production (Thompson et al.,1993; Cockcroft, 1996). Prompted by the similarity in cellulareffects associated with PLD activation and the cellular effectsof lysoPC, we hypothesized that this signaling pathway may beinvolved in lysoPC-induced alterations in endothelial cell function.In support of this hypothesis, lysoPC stimulated PLD activityin a time- and concentration-dependent manner in cultured humancoronary artery endothelial cells (Cox and Cohen, 1996c). AlthoughlysoPC can stimulate PLD activity, the relationship between increasesin PLD activity and endothelial vasomotor dysfunction remainsto be established.

The present study was designed to investigate the role of the PLD signal transduction pathway in endothelial vasomotor dysfunctioninduced by lysoPC and other stimuli. To relate these functionaleffects in the same preparation, we have used isolated rabbitaortae to compare the effects of lysoPC and other lysophospholipidson vascular PLD activity and endothelial vasomotor function.

	Methods

Top Abstract Introduction Methods Results Discussion References

Measurement of vasomotor activity. Aortae were removed from New Zealand White rabbits (4-6 lbs) with careful attention to retaining the endothelium, cleanedof connective tissue, and cut into ring segments 5 mm in length.Rings were suspended between two stainless steel hooks, one fixedimmobile and the other attached to a force transducer, and changesin force were measured in grams with a computerized data acquisitionsystem (MP100, BIOPAC Systems, Inc., Santa Barbara, CA). Tissueswere suspended at optimum passive force (5 g) in 10 ml modifiedKrebs' buffer with the following composition: NaCl (113.2); KCl(4.6); CaCl₂·2H₂O (1.6); KH₂PO₄ (1.2); MgSO₄ (1.2); glucose (10);NaHCO₃ (24.8), continuously oxygenated and maintained at 37°C.After equilibration for 60 min, washing the tissues via bufferreplacement every 15 min, a depolarization-induced contractionwas induced by KCl (67 mM) to confirm viability of the tissueand provide a reference contraction for normalization. Tissueswere returned to base-line force by washing and were re-equilibratedfor 30 min. After incubation with test agents as described inthe text or figure legends, endothelial vasomotor function wasassessed by contracting the tissue with phenylephrine (1 µM) and,on achieving a stable contraction, cumulatively adding increasingconcentrations of acetylcholine (1 nM to 10 µM) to induce relaxation.

Assay of PLD activity. PLD activity was assessed in intact tissue by measuring the production of PEt in the presence of ethanol as a specific markerof PLD activity (Hu et al., 1996). Tissue was equilibrated for30 min at 37°C in HEPES-buffered Krebs' solution of the followingcomposition (mM): NaCl (113.2); KCl (4.6); CaCl₂·2H₂O (1.6); KH₂PO₄(1.2); MgSO₄ (1.2); glucose (10); NaHCO₃ (24.8), and HEPES (10mM), bubbled continuously with 5% CO₂ in O₂. Tissues were thentransferred to a labeling buffer (7.5 ml/well of 6-well cell cultureplate) consisting of Krebs-HEPES + 0.02% bovine serum albuminand [³H]myristic acid (6 µCi/ml). Tissue was incubated in labeling bufferfor 3 hr in a 37°C incubator under 5% CO₂, followed by three washesin Krebs-HEPES without bovine serum albumin or label and re-equilibrationin the same for 30 min at 37°C. Tissues were then transferredto wells of a 6-well plate (1-2 rings/well) containing Krebs-HEPESsupplemented with 1% ethanol and further additions as indicatedin the text and figure legends, and incubated as above for 45min. The reaction was terminated by freezing the tissue in tongscooled in liquid N₂ and homogenizing in 1 ml choroform/methanol(1:2). Homogenates were centrifuged (1000 × g 10 min), supernatantswere transferred to clean tubes and chloroform (1.25 ml) was added,followed by vortexing. After incubation for 10 min at 4°C, phaseswere split by addition of water (1.25 ml) followed by vortexingand centrifugation (1000 × g 10 min). The upper phase was aspiratedand the lower phase was evaporated to dryness under vacuum. Lipidresidues were redissolved in 10 µl chloroform along with authenticPEt (75 µg) as a tracer, spotted onto Whatman LK6DF thin-layerchromatography plates, and resolved in a solvent system of chloroform/methanol/aceticacid (65:15:2). Lipid spots were visualized by exposure to iodinevapor. Spots corresponding to PEt were scraped into scintillationvials, extracted for 10 min in 1 ml methanol, and radioactivitydetermined by liquid scintillation spectroscopy.

Data presentation and statistical analysis. Unless indicated otherwise, data are expressed as the mean ± S.E. for the number of rings shown in parentheses. For all experiments,the data represent tissue from at least four animals. Acetylcholine-inducedrelaxation is expressed as percent (100% = base-line tone beforecontraction with phenylephrine, 1 µM). PLD activity is expressedas the amount of [³H] PEt formed normalized as a percentage of the total ³H-labeled phospholipids in each sample. Where appropriate, unpairedStudent's t test was used to compare means; P < .05 was consideredstatistically significant.

Drugs and chemicals. Phenylephrine, acetylcholine chloride, sodium nitroprusside, lysoPC (palmitoyl), lysoPS (palmitoyl) and PDBu were purchasedfrom Sigma Chemical Co. (St. Louis, MO). [³H]Myristic acid (1 mCi/ml) was purchased from NEN (Boston, MA).LysoPAF, GF109203X and PEt were purchased from BIOMOL (Plymouth,MA). Lysophospholipids were dissolved in phosphate-buffered salineand sonicated 3 to 4 min immediately before use. PDBu and GF109203Xwere dissolved in DMSO, and PEt was dissolved in chloroform. Allother compounds were made in deionized water.

	Results

Top Abstract Introduction Methods Results Discussion References

Effect of lysoPC on PLD activity and endothelial function. To study the role of PLD activation in lysoPC-induced endothelialdysfunction, the effects of a range of lysoPC concentrations onvascular PLD activity and endothelium-dependent relaxation werecompared. LysoPC concentration-dependently (10-30 µM) stimulatedPLD activity in isolated rabbit aorta (fig. 1A). PLD activityin untreated segments was unchanged during the same time (45 min)period ([³H]PEt at 45 min = 100.7% of initial level at t = 0; n = 2). Thus,lysoPC stimulated PLD activity in isolated rabbit blood vessels,similar to its effect in cultured human coronary artery endothelialcells (Cox and Cohen, 1996c).

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Fig. 1. Effect of lysoPC on (A) PLD activity and (B) acetylcholine-induced relaxation of rabbit aortic rings. Rabbit aortic ringswere incubated for 40 min with lysoPC as indicated and then assayedfor PLD activity or endothelial function as described under "Methods."Asterisks denote a significant difference from basal as determinedby Students' t test (P < .05). Data represent the mean ± S.E.of the number of rings indicated and represent tissue from atleast four animals. CONT, control.

Preincubation of blood vessels with lysoPC caused a progressive loss of endothelium-dependent relaxation evoked by acetylcholinein arteries preconstricted with phenylephrine (1 µM) (fig. 1B).LysoPC had no effect on the magnitude of precontraction inducedby 1 µM phenylephrine (% 67 mM KCl contraction = 123.4 ± 2.6,126.7 ± 5.5, 130.5 ± 5.0, 119.8 ± 6.7 and 112.7 ± 9.5 for control,3 µM, 10 µM, 20 µM, and 30 µM lysoPC, respectively; n = 4-6).The concentrations of lysoPC required to inhibit endothelium-dependentrelaxation and stimulate vascular PLD activity were identical.

Effect of other lysophospholipids on PLD activity and endothelial function. Because other lysolipids in addition to lysoPC can inhibit endothelial vasomotor function (Mangin et al., 1993), the effectsof lysoPAF and lysoPS on PLD activity and endothelium-dependentrelaxation in isolated blood vessels were compared. LysoPAF andlysoPS both stimulated vascular PLD activity (fig. 2, A and B)and inhibited acetylcholine-induced relaxation (fig. 2, C andD) in isolated blood vessels. The concentrations of both lysolipidsrequired to inhibit endothelium-dependent relaxation were identicalwith those that stimulated vascular PLD activity. Furthermore,the reduced potency of lysoPS on vascular PLD activity (fig. 2B)relative to lysoPC and lysoPAF was reflected in a reduced inhibitionof endothelium-dependent relaxation (fig. 2D). Thus, endothelialdysfunction induced by lysophospholipids was closely associatedwith their ability to stimulate vascular PLD activity.

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Fig. 2. Effect of lysoPAF and lysoPS on PLD activity (A, B) and endothelial vasomotor function (C, D). Rabbit aortic rings were incubatedwith lysophospholipids as indicated for 40 min, followed by assayof PLD activity or endothelial function as described under "Methods."Asterisks denote a significant difference from basal as determinedby Students' t test (P < .05). Data represent the mean ± S.E.of the number of rings indicated and represent tissue from atleast four animals. CONT, control.

Effect of lysophospholipids on sodium nitroprusside-induced relaxation. Vasorelaxation induced by sodium nitroprusside, an endothelium-independent vasodilator, was unaffected by these lysophospholipidsin the highest concentration studied (30 µM) (fig. 3). These dataindicate that the inhibition of acetylcholine-induced vasorelaxationobserved with the lysophospholipids described above was mediatedvia an effect on endothelial function and was not a nonspecificeffect on the ability of the blood vessel to relax.

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Fig. 3. Effect of lysophospholipids on sodium nitroprusside-induced relaxation. Rabbit aortic rings were incubated 40 min with eachlysophospholipid (30 µM) and contracted with phenylephrine (1µM), followed by cumulative addition of sodium nitroprusside asshown. Data represent the mean ± S.E. of the number of rings indicatedin parentheses and represent tissue from at least 4 animals. CONT,control.

Role of vascular PKC activity in lysoPC-induced endothelial dysfunction. Because some studies have implicated PKC activation in the mechanism of lysoPC-induced endothelial vasomotor dysfunction (Ohgushiet al., 1993), the ability of GF109203X, a highly selective inhibitorof PKC (Toullec et al., 1991), to prevent lysoPC-induced inhibitionof endothelium-dependent relaxation was tested. GF109203X (3 µM),at a concentration that maximally inhibited PKC activity in isolatedenzyme preparations (Toullec et al., 1991), inhibited PDBu-inducedaortic contraction by 91.2 ± 2.4% (fig. 4). These data confirmthat GF109203X (3 µM) effectively inhibited PKC activity in intactrabbit aorta. In contrast, preincubation of rabbit aorta withGF109203X (3 µM) did not affect the ability of lysoPC (20 µM)to inhibit acetylcholine-induced relaxation (fig. 5). These datasuggest that lysoPC inhibited endothelium-dependent relaxationin rabbit aorta via a mechanism independent of PKC, consistentwith a possible involvement of PLD activation.

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Fig. 4. Effect of GF109203X on PDBu-induced contraction. Original force recordings of rabbit aortic rings incubated 30 min with GF109203X(3 µM) or an equivalent volume of DMSO (0.3%), followed by additionof PDBu (1 µM). Summary data are shown in the inset and representthe mean ± S.E. of the number of rings indicated in parenthesesand represent tissue from at least four animals. CONT, control

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Fig. 5. Effect of GF109203X on lysoPC-induced inhibition of acetylcholine-mediated relaxation. Rabbit aortic rings were incubated30 min with GF109203X (3 µM) or an equivalent volume of DMSO (0.3%),followed by addition of lysoPC (20 µM) for an additional 40 min.After wash-out, phenylephrine (1 µM) was added to induce contraction,followed by cumulative addition of acetylcholine (1 nM to 3 µM).Data represent the mean ± S.E. of the number of rings indicatedin parentheses and represent tissue from at least four animals.

Effect of orthovanadate on PLD activity and endothelial function. To determine whether the association between PLD activation and endothelial vasomotor dysfunction was a phenomenon particularto lipid mediators or was a more general feature of interventionsthat stimulate PLD activity, the effects of orthovanadate on vascularPLD activity and endothelium-dependent relaxation were compared.Sodium orthovanadate is a tyrosine phosphatase inhibitor thatstimulated PLD activity in many systems by increasing the levelof cellular tyrosine phosphorylation (Natarajan et al., 1996).Sodium orthovanadate (0.1-3 mM) stimulated PLD activity (fig.6, circles) and inhibited acetylcholine-induced relaxation (fig.6, triangles) in a parallel manner. Thus, stimulation of vascularPLD activity with a mediator unrelated to lysophospholipids wasalso closely associated with endothelial dysfunction in isolatedblood vessels.

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Fig. 6. Effect of orthovanadate on vascular PLD activity and endothelial-dependent relaxation. Rabbit aortic rings were incubated60 min with orthovanadate as indicated and contracted with phenylephrine(1 µM for control and 0.1 mM orthovanadate; 0.8 µM for 1 and 3mM orthovanadate), followed by cumulative addition of acetylcholine(1 nM to 3 µM). Relaxation is expressed as percent relaxationof phenylephrine contraction attained at 1 µM acetylcholine. Datarepresent the mean ± S.E. of the number of rings indicated inparentheses and represent tissue from three to four animals.

Correlation between PLD activity and endothelial dysfunction. To examine the quantitative relationship between PLD stimulation and endothelial dysfunction, the extent of inhibition ofacetylcholine (1 µM)-induced relaxation was plotted versus thevascular PLD activity determined for each concentration of lysophospholipidor orthovanadate tested in this study (fig. 7). Although thesemeasures were derived in separate assays under similar but notidentical conditions, this analysis revealed a positive correlation(r² = 0.88) between increases in vascular PLD activity and the inhibitionof endothelium-dependent relaxation in isolated blood vessels.These data indicate that stimulation of vascular PLD activitywas quantitatively associated with endothelial vasomotor dysfunctionin isolated blood vessels and that low activity of vascular PLDwas necessary for optimal vasomotor functioning of the endothelium.

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Fig. 7. Correlation between vascular PLD activity and endothelial vasomotor dysfunction. Each data point represents the inhibitionof maximal acetylcholine (1 µM)-induced relaxation of phenylephrine-contractedtissue (%) plotted versus the corresponding level of PLD activity(% of basal) resulting from various concentrations of lysophospholipidor orthovanadate. The data were fit with the linear equation y= mx + b (m = 0.25; b = $-$ 0.23; r² = 0.88).

	Discussion

Top Abstract Introduction Methods Results Discussion References

The ability of lysoPC, either independently or as a component of oxidized LDL, to inhibit endothelial-dependent vasorelaxationis well established (Cowan and Steffen, 1995; Freeman et al.,1996). The effect of lysoPC to impair endothelium-dependent relaxationis generalized to a variety of endothelium-dependent vasodilators,including acetylcholine (Kugiyama et al., 1990), 5-hyroxytryptamine(Cox and Cohen, 1996a), thrombin (Murohara et al., 1994) and calciumionophore A23187 (Mangin et al., 1993). However, the cellularpathways affected by lysoPC that ultimately result in endothelialvasomotor dysfunction remain unclear. LysoPC was recently documentedto stimulate PLD activity in cultured human endothelial cells(Cox and Cohen, 1996c), although the role of this effect in thevasomotor actions of lysoPC was not addressed. The present studyhas demonstrated the ability of lysoPC to stimulate vascular PLDactivity in isolated blood vessels and has documented a closeassociation between the ability of lysoPC and other mediatorsto stimulate vascular PLD activity and inhibit endothelium-dependentvasorelaxation. This is the first study to directly correlatechanges in the activity of a signal transduction pathway withthe development of endothelial vasomotor dysfunction in isolatedblood vessels.

Activation of PKC has been implicated in some of the cellular effects of lysoPC. Indeed, lysoPC stimulated PKC purified fromporcine brain (Oishi et al., 1988) and in cultured endothelialcells (Ohgushi et al., 1993), and a role for PKC in lysoPC-inducedendothelial vasomotor dysfunction was suggested in both isolatedporcine coronary arteries and rabbit aortae (Ohgushi et al., 1993).However, more recent studies failed to confirm the ability ofPKC inhibitors or the down-regulation of PKC to affect lysoPC-inducedendothelial dysfunction (Cowan and Steffen, 1995). In part, theseprevious studies used early inhibitors of PKC, such as staurosporineand calphostin C, that are known to exert effects unrelated toPKC inhibition (Kageyama et al., 1991; Hartzell and Rinderknecht,1996). For these reasons, we tested the ability of a highly selectivePKC inhibitor, GF109203X (Toullec et al., 1991), to inhibit vascularPKC activity and to affect lysoPC-induced endothelial vasomotordysfunction in isolated rabbit aortae. The ability of GF109203X(3 µM) to block PDBu (1 µM)-induced contraction while having noeffect on lysoPC-induced inhibition of acetylcholine-mediatedrelaxation argued against a role for PKC in this effect, and itwas consistent with previous reports dissociating PKC from lysoPC-inducedendothelial vasomotor dysfunction (Cowan and Steffen, 1995; Freemanet al., 1996).

In contrast to the lack of association with PKC activation, inhibition of endothelial vasomotor function by lysoPC and otherlysophospholipids was closely associated with a stimulation ofvascular PLD activity. This association was not restricted tolysophospholipids, because stimulation of vascular PLD activityby orthovanadate was also associated with an inhibition of endothelial-dependentrelaxation. Indeed, if maintenance of low vascular PLD activityis a prerequisite for normal endothelial function, then we reasonedthat any intervention that stimulates PLD activity should induceendothelial vasomotor dysfunction. In a search of the literaturefor interventions that increase PLD activity, we discovered thatmany proinflammatory agents that stimulated PLD activity in culturedcells also induced endothelial vasomotor dysfunction in isolatedblood vessels (table 1). Although these data represent independentstudies with different experimental systems, there is a remarkablyexcellent quantitative correlation in the concentrations requiredto observe each effect. Thus, we propose that stimulation of PLDactivity may be a common mechanism by which proatherogenic andproinflammatory agents mediate deleterious effects on vascularendothelial function.

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TABLE 1
Agents documented to both stimulate PLD activity and induce endothelial dysfunction^a

The mechanism by which the PLD signaling pathway may be associated with endothelial dysfunction remains unclear. In leukocytes,activation of PLD and the subsequent generation of phosphatidicacid was closely associated with stimulation of the NADPH oxidasecomplex and production of superoxide anion (Bonser et al., 1989).Vascular superoxide production was enhanced in hypercholesterolemia(Ohara et al., 1993), atherosclerosis (Keaney et al., 1995) andcertain forms of hypertension (Jun et al., 1996), and is thoughtto be involved in endothelial vasomotor dysfunction via rapidchemical inactivation of nitric oxide (Gryglewski et al., 1986).In addition, lysoPC stimulated superoxide production in both neutrophils(Ginsburg et al., 1989) and isolated blood vessels (Ohara et al.,1994), and reactive oxygen species were implicated in the cellulareffects mediated by lysoPC and oxidized LDL (Stiko et al., 1996).In light of recent studies suggesting that the source of vascularsuperoxide anion production is an NADPH/NADH oxidase system (Paganoet al., 1995), perhaps similar to the oxidase system in leukocytes,it is tempting to speculate that stimulation of vascular PLD activityby lysoPC and possibly other inflammatory lysophospholipids maybe an important part of the signaling mechanism by which vascularoxidative stress is increased and endothelial vasomotor functionis attenuated in these pathologies.

Although the correlation between vascular PLD activity and endothelial vasomotor dysfunction (r² = 0.88) was compelling, proof that PLD activation is a necessarycomponent of endothelial dysfunction awaits the development ofselective PLD inhibitors or genetically altered animal strainslacking PLD activity in vivo. Furthermore, at least two isoformsof PLD have been distinguished biochemically (Morris et al., 1996),and additional studies are required to establish whether one orboth of these isoforms is responsible for the activity presentin isolated blood vessels. However, the recent cloning and expressionof the first mammalian PLD gene from a human cell line (hPLD1)(Hammond et al., 1995) should hasten the identification of selectivePLD enzyme inhibitors, as well as provide the molecular toolsnecessary to develop animal strains lacking one or more isoformsof PLD. Nevertheless, the direct correlation between vascularPLD activity and inhibition of endothelial vasomotor functiondocumented in the present study, along with data from the literaturesuggesting a coupling between these two events in response tomany diverse interventions, strongly support a role for this signaltransduction pathway in the etiology of endothelial vasomotordysfunction.

	Footnotes

Accepted for publication June 3, 1997.

Received for publication March 17, 1997.

Send reprint requests to: Marlene L. Cohen, Ph.D., Lilly Research Laboratories, Lilly Corporate Center, Indianapolis, IN 47628.

	Abbreviations

LDL, low-density lipoprotein; lysoPAF, lyso-platelet-activating factor; lysoPC, lysophosphatidylcholine; lysoPS, lysophosphatidylserine; PDBu, phorbol dibutyrate; PEt, phosphatidylethanol; PKC, protein kinase C; PLD, phospholipase D; DMSO, dimethyl sulfoxide; HEPES, N-2-hydroxyethylpiperazine-N $'$ -2-ethanesulfonic acid.

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