Kinetic Analysis of Phospholipase C from Catharanthus roseus Transformed Roots Using Different Assays

doi:10.1104/pp.120.4.1075

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Kinetic Analysis of Phospholipase C from Catharanthus roseus Transformed Roots Using Different Assays¹

S.M. Teresa Hernández-Sotomayor^*, César De Los Santos-Briones, J. Armando Muñoz-Sánchez, and Victor M. Loyola-Vargas

Unidad de Biología Experimental, Centro de Investigación Científica de Yucatán, Apartado Postal 87 Cordemex 97310, Merida, Yucatan, Mexico

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

The properties of phospholipase C (PLC) partially purified from Catharanthus roseus transformed roots were analyzed usingsubstrate lipids dispersed in phospholipid vesicles, phospholipid-detergentmixed micelles, and phospholipid monolayers spread at an air-waterinterface. Using [³³P]phosphatidylinositol 4,5-bisphosphate (PIP₂) of high specificradioactivity, PLC activity was monitored directly by measuringthe loss of radioactivity from monolayers as a result of the releaseof inositol phosphate and its subsequent dissolution on quenchingin the subphase. PLC activity was markedly affected by the surfacepressure of the monolayer, with reduced activity at extremes ofinitial pressure. The optimum surface pressure for PIP₂ hydrolysiswas 20 mN/m. Depletion of PLC from solution by incubation withsucrose-loaded PIP₂ vesicles followed by ultracentrifugation demonstratedstable attachment of PLC to the vesicles. A mixed micellar systemwas established to assay PLC activity using deoxycholate. Kineticanalyses were performed to determine whether PLC activity wasdependent on both bulk PIP₂ and PIP₂ surface concentrations inthe micelles. The interfacial Michaelis constant was calculatedto be 0.0518 mol fraction, and the equilibrium dissociation constantof PLC for the lipid was 45.5 µM. These findings will add to ourunderstanding of the mechanisms of regulation of plant PLC.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Ca²⁺ is the principal second messenger in plants. One of the mechanisms that regulates the levels of this messenger involvesthe enzyme PLC. PLC catalyzes the hydrolysis of PIP₂ to generatetwo second messengers: IP₃ and 1,2-diacylglycerol. PLC is a familyof isoenzymes that has been classified into three groups: $beta$ , $gamma$ ,and $delta$ (Rhee and Bae, 1997). In plants several studies have reportedthe biochemical presence of this enzyme (McMurray and Irvine,1988; Tate et al., 1989; Melin et al., 1992; Pical et al., 1992;Yotsushima et al., 1992, 1993; Huang et al., 1995; De Los Santos-Brioneset al., 1997). Different genes for PLC have also been cloned (Hirayamaet al., 1995, 1997; Shi et al., 1995; Yamamoto et al., 1995; Kopkaet al., 1998), all of them resembling the $delta$ type. However, themolecular basis for activation of plant PLC isoforms is not clear,nor is it completely understood how PLCs interact with their membranesubstrates.

Data concerning the manner in which phospholipases interact with lipid substrates are accumulating, and show general similaritiesbut also some remarkable differences between the different isoforms.A variety of assay procedures have been used to measure lipaseactivity. Most involve presentation of enzymes with pre-aggregatedlipids, including phospholipid vesicles, phospholipid-detergentmixed micelles, pre-immobilized and cross-linked lipids, and phospholipidmonolayers. The activity of all PLC isoforms studied to date isaffected by the surface pressure of monolayer substrates (Rebecchiet al., 1992; James et al., 1994). PLCs act on substrates thatform a lipid-water interface, an arrangement that complicateskinetic analyses of the enzyme catalytic activity. To our knowledge,no investigation has been reported thus far on the kinetics ofplant PLCs using different assays. Such studies would provideinformation if PLC binds the substrate in a noncatalytic manneras a prerequisite to anchoring into the membrane to start catalysis,or if the PLC activity from plant sources is affected when itis measured in monolayers. We now report kinetic analyses, vesicle-bindingstudies, and monolayer assays using a semipurified enzyme fromC. roseus transformed roots.

	MATERIALS AND METHODS

Top Abstract Introduction Methods Results Discussion References

Tissue Culture

Hairy root line J1 of Cantharanthus roseus was obtained by infection of leaves with Agrobacterium rhizogenes (Ciau-Uitz etal., 1994

) and maintained in B5 medium (Gamborg et al., 1968

)supplemented with 30 g/L Suc. The pH was adjusted to 5.7 priorto autoclaving of the medium with 0.1 M KOH/HCl. One hundred millilitersof medium was placed in a 250-mL Erlenmeyer flask and autoclavedfor 20 min at 15 p.s.i. Flasks were inoculated with 0.5 g (freshmass) of hairy roots. Roots were subcultured every 14 d. Cultureswere grown in darkness at 25°C on a rotary shaker at 100 rpm.

Preparation of Tissue and Cell Extracts

Roots were quickly frozen with liquid nitrogen and homogenized with a polytron in buffer A (1 g of tissue in 2.5 mL of 50mM NaCl, 1 mM EGTA, 50 mM Tris-HCl, pH 7.4, 250 mM Suc, 10% [v/v]glycerol, 1 mM PMSF, 10 mM sodium pyrophosphate, 0.2 mM orthovanadate,and 1 mM $beta$ -mercaptoethanol). Extracts were passed through gauze,and tissue debris were removed by centrifugation at 14,000g for30 min at 4°C. The supernatant was further centrifuged at 100,000gfor 45 min. The supernatants (protein: 3.5-5.0 mg/mL) was recoveredas the soluble fraction. The pellet was resuspended in the samebuffer A (protein: 0.5-1.2 mg/mL), and was used as a crude membranefraction. All steps during the extraction were performed at 4°C.The cell extracts were quickly frozen in liquid nitrogen and storedat $-$ 75°C. Protein concentrations of samples were measured withbicinchoninic acid protein assay reagent using BSA as a standard(Smith et al., 1985

Partial Purification of C. roseus PLC

A method has been developed for the rapid partial purification of C. roseus membrane-associated PLC, and has been used onat least six different occasions with similar results. Twentygrams of fresh roots from the 6th d of culture were extractedas mentioned above. The microsomal crude fraction was resuspendedin buffer A in the presence of 2 M KCl. This suspension was sonicatedfor 3 min. After this, the suspension was centrifuged at 100,000gfor 45 min at 4°C. The clarified solution was desalted in a SephadexG-25 column (Pharmacia) pre-equilibrated with buffer B (20 mMTris, pH 7.4, 1 mM EDTA, 1 mM DTT, 0.6 mM PMSF, and 2 µg/mL leupeptine)at a flow rate of 2 mL/min. The fractions with PLC activity wereapplied to a heparin-Sepharose CL-6B column (Pharmacia; 1.6 ×17 cm) pre-equilibrated in buffer C (20 mM K₂HPO₄, pH 7.3, 1 mMEDTA, 1 mM DTT, 0.6 mM PMSF, and 2 µg/mL leupeptine). The columnwas developed with a 250-mL linear gradient of 0 to 1.5 M KClin buffer C and 5-mL aliquots were collected. PLC activity waseluted at 0.6 M KCl. PLC was stored in 20% (v/v) glycerol at $-$ 70°C.

PLC Assay

The hydrolysis of [³H]PIP₂ was measured as described by Hernández-Sotomayor and Carpenter (1993)

and De Los Santos-Brioneset al. (1997)

in a reaction mixture (50 µL) that contained 35mM NaH₂PO₄, pH 6.8, 70 mM KCl, 0.8 mM EGTA, 0.8 mM CaCl₂ (finalCa²⁺ concentration, 25 µM), 200 µM PIP₂ (approximately 20,000 cpm),and 0.08% deoxycholate. The reaction was stopped with 100 µL of1% (w/v) BSA and 250 µL of 10% (w/v) TCA. Precipitates were removedby centrifugation (13,000g for 10 min) and the supernatants werecollected for quantification of [³H]IP₃ released by liquid scintillation counting using Aquasol(DuPont-New England Nuclear, Boston).

Monolayer Assays

Monolayer assays were performed in a monolayer trough (16-mL subphase volume) supplied by Nima Technology (Coventry, UK).Monolayer surface pressure was measured continuously using filterpaper Wihelmy plates suspended from an electronic microbalance.Surface radioactivity was monitored continuously using a remotedetector (model FC-006, Bioscan, Washington, DC) suspended 0.5cm above the monolayer, coupled to computer software (LabChromv2.10, Lab Logic, Sheffield, UK) that recorded the data. The subphasebuffer was composed of 35 mM NaH₂PO₄ (pH 6.8), 70 mM KCl, 0.8mM EGTA, and 0.8 mM CaCl₂ (final Ca²⁺ concentration, 25 µM, when added). This buffer was stirred witha Teflon-coated stirrer, and composite lipid monolayers (70% [mol]phosphatidylcoline:27% PS:3% [³³P]PIP₂) were spread at the surface. An aliquot of 0.7 mL of thesubphase was replaced with 0.7 mL of enzyme preparation (20-30µg of protein) only after a stable monolayer with a constant pressurehad formed. After 5 min, Ca²⁺ ions were added to the subphase to start catalysis and the reactionwas either monitored continuously (³³P-labeled monolayer) or 0.5-mL aliquots were taken at differenttimes (³H-labeled lipids).

Preparation of [³³P]PIP₂

[³³P]PIP₂ was prepared using partially purified PIP kinase (James et al., 1994

). PIP (200 µM) was sonicated in PIP kinase buffer(200 mM Hepes, pH 7.4, 40 mM MgCl₂, 4 mM EGTA, 4 mM DTT, and 400mM NaCl) and [³³P]ATP (specific radioactivity > 1,000 Ci/mmol) with no unlabeledATP was added to this substrate suspension. The reaction was initiatedwith the PIP-kinase preparation and incubated at 37°C for 20 min.The reaction was terminated with 750 µL of chloroform:methanol:concentratedHCl (40:80:1, v/v). Radiolabeled [³³P]PIP₂ (specific activity > 1,000 Ci/mmol) was purified by HPLCusing an amino-cyano analytical column pre-equilibrated with chloroform:methanol:water(20:9:1, v/v).

Vesicle Binding

Large unilamellar vesicles were produced by extrusion through 100-nm polycarbonate membranes using a phospholipid extruder(Lipex Biomembranes, Vancouver) according to the manufacturer'sinstructions. Fifteen milligrams of lipid (PC:PS:PIP₂ [70:27:3by molarity]) was dried to a film, resuspended by vortexing in10 mM Hepes, pH 7.4, 200 mM Suc, 3.4 mM EDTA, and 20 mM KCl, andtreated with repeated freeze-thawing in a liquid nitrogen-40°Cwater bath. Lipids were extruded with at least 10 passes throughthe polycarbonate filters, and large unilamellar vesicles werestored at 4°C. For PLC-binding studies, vesicles were dilutedto 100 µM with respect to PIP₂ in buffer D (10 mM Hepes, pH 7.4,3.4 mM EDTA, and 150 mM NaCl), and used as a stock for all lowerconcentrations required in the binding studies.

Binding was performed in 100 µL of buffer D with 10 µg of C. roseus PLC per tube. Ca²⁺ was omitted to eliminate PLC-catalyzed PIP₂ hydrolysis. Enzymewas incubated with vesicles for 10 min on ice followed by ultracentrifugationat 60,000 rpm for 30 min at 4°C (TLA rotor and TL100 centrifuge,Beckman), and PLC activity remaining in the supernatant was assayedagainst 100 µM PIP₂ as described above.

Data Presentation

All experiments were repeated at least three times using extracts prepared on separate occasions, and all gave similar results.Each figure contains data from a single, representative experimentassayed in duplicate and the errors varied by less than 10%.

Analysis of Kinetic Data

The kinetic analysis of the PLC activity from C. roseus was based on the conditions previously described for secretory PLA2(phospholipase A2; Hendrickson and Dennis, 1984

). The bindingof the interface was dependent on the concentration of the substrate(bulk PIP₂ concentration), while the binding into the interfacewas dependent on the substrate mole fraction (case II). All thedata were adjusted to the Hill equation (Eq. 1) using the GraFitprogram (Erithacus Software, Middlesex, UK).

v=V<SUB>max</SUB>×[S]<SUP>n</SUP>/K+[S]<SUP>n</SUP>

(1)

Case I

For the determination of the K_s (binding to the interface), PLC activity was measured increasing concentrations of PIP₂ (bulkconcentration) with a constant mole fraction of 0.052. To achievethis the concentrations of PIP₂ and deoxycholate were varied proportionally,keeping constant the mole fraction.

Equation 1 was reduced to the equation of Henri Michaelis-Menten (Eq. 2) in which the values of K_s were determined.

v=V<SUB>max</SUB>×[S]/K<SUB>s</SUB>+[S] (2)

Case II

To determine the K_m, PLC activity was assayed keeping the concentration (100 µM) constant and increasing the PIP₂ mole fractionby varying the concentrations of deoxycholate. A double-reciprocalLineweaver-Burk approach was used. The interfacial K_m was determinedwith the intercept to the ordinate ([ $-$ 1/K_m]ⁿ).

Case III

To determine if there are several binding sites due to interactions with the lipid interface and the subsequent binding ofthe substrate to the interface, PLC activity was assayed usinga fixed concentration of deoxycholate (1.92 mM) and increasingconcentrations of PIP₂.

Materials

[³H]PIP₂ and Aquasol were purchased from DuPont-New England Nuclear, [³³P]ATP was purchased from Amersham, and unlabeled PIP₂ was purifiedfrom Folch (fraction I) extract of brain lipid (Sigma) by a neomycinaffinity column as described in Waldo et al. (1994)

. The bicinchoninicacid protein assay reagent was supplied by Pierce, and B5 mediumPC, PS, and neomycin were obtained from Sigma.

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Monolayer Surface Pressure and PLC Activity

To determine the molecular interaction of PLC with lipid interfaces and the reciprocal influences that they have on each other,PLC activity as a function of time was measured in monolayer assays(Fig. 1A). The rate of substrate hydrolysis was followed for 20min and PIP₂ hydrolysis was extended in monolayer assays. A typicaltime course for PLC-catalyzed hydrolysis of PC-PS-PIP₂ monolayersat an initial pressure of 20 mN/m and loss of radioactivity frommonolayers due to PIP₂ hydrolysis is shown in Figure 1A. Hydrolysisof PIP₂-containing monolayers was absolutely dependent on theCa²⁺ concentration of the subphase and all data presented were obtainedusing 25 µM Ca²⁺ (final concentration), which sustained the maximum rate of PIP₂hydrolysis. Variations of the initial surface pressure of themonolayer resulted in markedly different rates of loss of radioactivityinto the subphase. PIP₂ hydrolysis in monolayers was transformedinto the percentage of PIP₂ hydrolyzed per unit time and expressedagainst the initial surface pressure of the monolayer (Fig. 1B).The percentage of PIP₂ hydrolyzed per unit of time was calculatedby measuring radioactivities remaining in the monolayer and presentin the subphase after 20 min. In the early portion of the pressure-activitycurve, PLC activity increased as surface pressure increased (Fig.1B). A peak in PLC activity was seen at 20 mN/m but as pressureincreased beyond this point, PLC activity was markedly reduced.

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Figure 1. Surface pressure-PLC activity relationship for PIP₂-containing monolayers. A, Monolayers formed at an initial surface pressure of 20 mN/m and 20 µg of partially purified PLC from C. roseus transformed roots. Ca²⁺ (25 µM free Ca²⁺) was added to the subphase after 5 min. Results show a smooth trace, representative of five experiments performed at that pressure. B, PLC activity determined against monolayers formed at increasing initial surface pressures. Reaction time was 20 min after the addition of Ca²⁺ and data are expressed as percentage of lipid hydrolyzed per minute. Data are means of at least five experiments for each pressure and varied by less than 5%.

PLC-Lipid Binding Effect

Lipid-metabolizing enzymes are considered to bind to and sometimes penetrate lipid interfaces, with subsequent further substratebinding within the interface as component parts of their catalyticmechanism. Therefore, the relationship between bulk substrateconcentration and PLC binding was investigated using a noncatalyticvesicle binding assay as described previously for PLC $delta$ (Rebecchiet al., 1992

). PLC was incubated with Suc-loaded large unilamellarvesicles with a phospholipid composition of PC:PS:PIP₂ (70:27:3by molarity), and the activity of PLC in the supernatant was determinedby assay after ultracentrifugation as described in ``Materials and Methods''. When incubatedwith the vesicles composed of PC-PS-PIP₂, PLC was depleted fromthe supernatant and bound to the large unilamellar vesicle pelletin a manner that was dependent on the total vesicle PIP₂ concentration(Fig. 2).

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Figure 2. Binding of C. roseus PLC to Suc-loaded vesicles. Ten micrograms of PLC was incubated with a range of concentrations of PIP₂-containing vesicles (PIP₂:PC:PS, 3:70:27 mol/mol), followed by ultracentrifugation as described in ``Materials and Methods''. PLC activity remaining in the supernatant was assayed against PIP₂ and compared with vesicle-free controls in which the activity was 10 pmol/min.

PLC Activity and Dependency on Bulk and Surface Concentrations of PIP₂

PIP₂ hydrolysis by C. roseus PLC was analyzed according to the method of Hendrickson and Dennis (1984)

, as has been proposedfor animal-PLC $delta$ and $gamma$ (Wahl et al., 1992

; Cifuentes et al., 1993

;Rebecchi et al., 1993

). The activity was examined using the three-casekinetic analysis described in detail in "Materials and Methods,"in which bulk and surface PIP₂ concentrations were varied independentlyand concurrently as established for phospholipase A (Hendricksonand Dennis, 1984

). Enzyme activity was measured using PIP₂-deoxycholatemixed micelles as substrate. Under the conditions used, deoxycholatebehaved as a neutral diluent for PIP₂. To investigate whetherPLC activity involves multiple binding events (a previous differentbinding site from the catalytic site) due to interactions withthe bulk lipid interface and subsequent substrate binding withinthe interface, the bulk concentration and mole fraction of PIP₂were increased simultaneously and the IP₃ production was measuredwith assays using a single concentration of deoxycholate and increasingconcentrations of PIP₂. The relationship between PLC activityand bulk and surface concentrations of substrate is presentedin Figure 3. Interesting, it did not follow a sigmoidal relationshipas described for mammalian PLC $beta$ (James et al., 1995

). In ourmodel, the behavior of the enzyme was Michaelian, giving a Hillcoefficient of 0.968, and thus indicating a single binding site.

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Figure 3. PIP₂ hydrolysis by PLC from C. roseus as a function of both bulk concentration and the mole fraction of substrate. The concentration of deoxycholate was held constant at 1.92 mM, and the bulk PIP₂ concentration was increased up to 400 µM. Assays were as stated in ``Materials and Methods''. Data are representative of four experiments with similar results.

The K_s for interface binding by PLC was determined by assaying PIP₂ hydrolysis as a function of bulk concentration at a fixedmole fraction of PIP₂ (0.052). This was achieved by varying bothbulk PIP₂ and deoxycholate concentrations proportionately, whilemaintaining the mole fraction constant. PLC showed a hyperbolicrelationship with PIP₂ bulk concentration (Fig. 4).

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Figure 4. PLC activity toward PIP₂-deoxycholate mixed micelles as a function of bulk PIP₂ concentration. The PIP₂ mole fraction was held constant 0.052 and bulk PIP₂ plus deoxycholate concentrations varied proportionally. Assays were performed as described in ``Materials and Methods''. Data are representative of four experiments.

PLC catalytic activity was also measured at a constant bulk concentration of PIP₂ and varied mole fraction. This was achievedby varying the concentration of deoxycholate alone. Experimentswere performed at a bulk PIP₂ concentration of 100 µM. The relationshipbetween enzyme velocity and substrate mole fraction appeared sigmoidalbetween 0 and 0.08 (Fig. 5). The constants calculated from thiskinetic analysis are: K_s, 45.5 µM, interfacial K_m, 0.05, and V_max,137.2 pmol/min.

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Figure 5. PLC activity toward PIP₂-deoxycholate mixed micelles as a function of PIP₂ surface concentration. Bulk PIP₂ concentration was held constant at 100 µM with various deoxycholate concentrations to vary PIP₂ mole fraction. Other indications are as in Figures 3 and 4.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

We previously reported that PLC activity is present in C. roseus transformed roots (De Los Santos-Briones et al., 1997). Wereport here a kinetic study of the partially purified, membrane-associatedenzyme using different approaches. Few reports regarding the biochemicalcharacterization of plant PLC are available (Tate et al., 1989;Melin et al., 1992; Pical et al., 1992; Yotsushima et al., 1992,1993; Hirayama et al., 1995; Huang et al., 1995; Shi et al., 1995;Kopka et al., 1998). To our knowledge, this is the first reportin which different assays were used to characterize this enzymein plants. It is not known if plant PLCs follow a similar mechanismof activation as that reported for PLC from other sources (Hendricksonand Dennis, 1984; Rebecchi et al., 1992, 1993; Wahl et al., 1992;James et al., 1994, 1995, 1997). Most of the PLC enzymatic activityfrom plant sources is found in the cytosol, but since the substrateof the enzyme is membrane associated, there is the possibilitythat the cytosolic enzyme under certain physiological circumstancesmay suffer a redistribution from the cytosol to the membrane.

One of the most characteristic and intriguing features of lipolytic enzymes is their activation by interfaces. To explainthe pathways of lipolysis, several investigators have proposeda reversible enzyme adsorption to, or penetration into, the interfaces(Hendrickson and Dennis, 1984; Rebecchi et al., 1993; James etal., 1997). However, such a mechanism has not been demonstratedfor plant PLCs. To address this question, we describe the activityof PLC using lipid substrates dispersed in phospholipid vesicles,phospholipid-detergent mixed micelles, and phospholipid monolayersspread at an air-water interface.

We used ³³P-labeled substrates to measure PLC activity directly, which showed that the rate and extent of PIP₂ hydrolysis ina PC-PS composite monolayer are surface pressure dependent. Althoughincreasing phospholipid mass in the monolayer increased surfacepressure, this was not accompanied by a simple increase in enzymeactivity throughout the pressure range investigated (Fig. 1B).The reduction in PLC activity, as initial monolayer pressureswere increased above the optimum pressure (20 mN/m,; Fig. 1B),was presumably a result of a decrease in the ability of the enzymeto bind the substrate, since this phenomenon has to be very specificand is probably regulated by the PIP₂ concentration or anotherunknown mechanism. However, there were no pressure-induced changesin the rate of catalysis during the course of the experiments(Fig. 1A), which indicates that it was the initial surface pressurethat was crucial in determining the subsequent penetration ofPLC into the monolayers. It also indicates that the changes inactivity were not due to changes in the PIP₂ composition of themonolayer after PLC started catalysis. The lower rate of catalysisof lipids at a lower initial surface pressure, which would beexpected to permit relatively easy penetration of PLC, may bedue to enzyme denaturation by unfolding at the monolayer.

PLC activity may be affected by the composition of the subphase in these assays. The subphase buffer was design to be a simplifiedintracellular-type buffer solution composed of KCl and NaH₂PO₄.The resultant free Ca²⁺ concentration was determined in part by the ionic strength andthe ionic composition of the solution, which was characterizedin previous experiments in which the Ca²⁺ requirements of the enzyme were studied (De Los Santos-Brioneset al., 1997). The pressure-activity relationship (low activityat pressure below 20 mN/m, reaching a maximum at 20 mN/m, anddecreasing above 20 mN/m) for PLC activity against PIP₂-containingmonolayers presented here (see Fig. 1B) contrasts with that previouslyreported for PLC $delta$ (Rebecchi et al., 1992, 1993).

Our results (Fig. 1B) resemble those of PLC $beta$ (James et al., 1995, 1997), which is surprising since all of the genes clonedto date for plant PLC are of the $delta$ type. For the $delta$ isoform (Rebecchiet al., 1992), it was shown that PLC activity decreased linearlywith increasing monolayer surface pressure, with maximum activitybeing observed at the lowest pressures investigated (15 mN/m).The basis for the differences between PLC from C. roseus and PLC $delta$ activity in monolayers is not clear, but it establishes thephenomenon that different isoforms are affected differently bythe quality of the interfaces with which they interact. The datapresented here with plant PLC, as well as data from other studies(Rebecchi et al., 1992, 1993; James et al., 1995, 1997), clearlyshow that PIP₂ hydrolysis in monolayers is surface pressure dependent,which is consistent with some element of penetration of lipidinterfaces by this family of enzymes.

Our results, together with previous studies using monolayer substrates in which PLC activity was inhibited as the surfacepressure increased, suggest that PLCs must penetrate lipid aggregatesin order to bind and hydrolyze their substrates. Such a modelmay seem unnecessary given that the phosphodiester bond in PIP₂is likely to be exposed in the aqueous environment at the surfaceof the membrane. We propose that this mode of action may facilitatecatalysis by restricting diffusion of PLCs into the two-dimensionalmembrane. Indeed, this may be why a dual substrate mechanism isapparently conserved among a wide range of lipid-metabolizingenzymes.

The data regarding the vesicle binding assay imply association of plant PLC with membrane interfaces through the substrate,PIP₂ (Fig. 2). For efficient PLC-catalyzed production of secondmessengers, PLC may bind to membrane interfaces in a PIP₂-specificnoncatalytic manner, and subsequent bindings or rearrangementsoccur within the interface that may help to form a stable anchorageof PLC at the membrane surface. This mechanism may also lead toa series of catalysis reactions whereby PLC could hydrolyze multiplePIP₂ molecules before detaching from the interface. The bindingof a PIP₂ molecule to at least one site in PLC other than theactive site is inherent in the above proposal. When PLC from C.roseus was incubated with Suc-loaded PC-PS vesicles lacking PIP₂,no measurable binding of the enzyme to the vesicles was exhibited(data not shown). These data strongly support a multisubstratemechanism in which binding at the interface is a specific processrequiring the presence of lipid substrate.

Another unexpected result is shown in Figure 3, in which the kinetic data were analyzed to see if there were multiple bindingsites onto the interface and a subsequent binding to the lipidsubstrate inside the interface. Surprisingly, the curve was notsigmoidal as reported for most mammalian PLCs (Wahl et al., 1992;Rebecchi et al., 1993; James et al., 1995); instead, the curvefollowed a Michaelis-Menten curve with a Hill coefficient closeto 1, probably due to a single binding site. This suggests thatplants are regulated in a completely different way from animals.The pleckstrin homology domain, which is found in a broad arrayof signaling proteins (including all animal PLC isoenzymes), hasbeen suggested to be a sequence that associates proteins withmembranes to function (Musacchio et al., 1993), based on evidencefor the interaction of PLC $delta$ -pleckstrin homology domains withPIP₂. In animal PLC $delta$ enzyme, the amino-terminal region containingthe pleckstrin homology domain was necessary for binding to phospholipidvesicles containing PIP₂ (Cifuentes et al., 1993). These resultssuggest that PIP₂ might be important for localizing proteins containingpleckstrin homology domains at the membrane surface. However,the pleckstrin homology domain has not to our knowledge been reportedin the gene products cloned to date for plant PLC. Perhaps plantPLC first has to bind noncatalytically to PIP₂ at the same sitewhere catalysis occurs.

PLCs, which are involved in signal transduction responses to cellular stimuli, are members of a diverse family of enzymeswhose mode of interaction with lipid substrates is complex andonly partly defined. In summary, we have described the establishmentof a controlled monolayer system for studying the family of PLCs,which will permit further investigations into different aspectsof the interaction of plant PLCs with their substrates and theirregulation. In this study, we have examined the kinetic characteristicsof PIP₂ hydrolysis by partially purified plant PLC in the absenceof their physiological activators. Although it has been proposedthat Ca²⁺ may act as a regulator for plant PLCs, this has never been demonstrated.The data presented here help to establish a basic understandingof how this enzyme behaves toward lipid-water interfaces fromwhich physiologically relevant mechanisms of regulation may eventuallybe discernible.

	FOOTNOTES

¹ This work was supported by grants from Consejo Nacional de Ciencia y Tecnológia (no. 4119P-N9609) and International Foundationfor Science (no. C/2236-2), the interchange program between theRoyal Society of London and the Scientific Research Academy ofMéxico, and a Consejo Nacional de Ciencia y Tecnología fellowshipto C.D.L.S.-B. (no. 88202).
^* Corresponding author; e-mail ths{at}cicy.mx; fax 99-81-3900.

Received March 26, 1999; accepted May 12, 1999.

ABBREVIATIONS

Abbreviations: IP₃, inositol 1,4,5-trisphosphate. PC, dioleoylphosphatidylcholine. PIP, phosphatidylinositol monophosphate. PIP₂, phosphatidylinositol 4,5-bisphosphate. PLC, phospholipase C. PS, phosphatidylserine.

	ACKNOWLEDGMENTS

We thank Dr. Peter Downes (Biochemistry Department, Dundee University, Scotland) for the facilities provided in his laboratoryfor the monolayer assays, as well as his generous assistance withreagents, and Dr. Brian Maust (Unidad de Biotecnología, Centrode Investigación Científica de Yucatán) for revision of theEnglish version of the manuscript.

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Top Abstract Introduction Methods Results Discussion References

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Kinetic Analysis of Phospholipase C from Catharanthus roseus Transformed Roots Using Different Assays¹

Copyright Clearance Center: 0032-0889/99/120//08

© 1999 American Society of Plant Physiologists