Phospholipase D antagonist 1-butanol inhibited the mobilization of triacylglycerol during seed germination in Arabidopsis

Storage oil breakdown plays an important role in the life cycle of many plants by providing the carbon skeletons that support seedling growth immediately following germination. 1-Butanol, a specific inhibitor of phospholipase D (PLD)-dependent production of the signalling molecule phosphatidic acid (PA), inhibited Arabidopsis seed germination. N-Acylethanolamines (NAEs), which have been shown to inhibits PLDα1 activity, have no effect on seed germination. However, mobilization profile of triacylglycerols (TAG) that induced by each compound has not been reported. To gain deeper insights into the mode of mobilization of TAG during NAE 12:0 or 1-butanol treatment, we conducted a detailed comparative analysis of the effect of NAE 12:0, DMSO, 1-butanol and tert-butanol on Arabidopsis seed germination and fatty acid composition, tert-butanol and DMSO served as the corresponding controls treatment respectively. Our data show that 1-butanol, but not the inactive tert-butanol isomer, inhibited Arabidopsis seed germination, which is accompanied by a with retardation of the mobilization of triacylglycerols (TAG). In contrast, NAE 12:0 did not affect mobilization of TAG, nor did it significantly delay seed germination as monitored by radicle and cotyledon emergence. 1-Butanol induced RNA degradation in seeds and seedlings. We speculate that the large-scale degradation of RNA under the induction of 1-butanol may lead to abnormal gene expression in genes necessary for seed germination, including the genes needed for the mobilization of oil bodies, and thus cause a delay of seed germination. To the best of our knowledge, we report for the first time that 1-butanol delays the mobilization of TAG.     

Phospholipase D signaling regulates microtubule organization in the fucoid alga Silvetia compressa

Recent studies in higher plants or animals have shown that phospholipase D (PLD) signaling regulates many aspects of development, including organization of microtubules (MTs), actin and the endomembrane system. PLD hydrolyzes structural phospholipids to form the second messenger phosphatidic acid (PA). To begin to understand the signaling pathways and molecules that regulate cytoskeletal and endomembrane arrays during early development in the brown alga, Silvetia compressa, we altered PLD activity by applying butyl alcohols to zygotes. 1-Butanol activates PLD and is a preferred substrate, primarily forming phosphatidyl butanol (P-butanol), which is not a signaling molecule. Treatment with 1-butanol inhibited cell division and cytokinesis but not photopolarization or germination, suggesting an MT-based effect. Immunolabeling revealed that 1-butanol treatment rapidly disrupted MT arrays and caused zygotes to arrest in metaphase. MT arrays recovered rapidly following butanol washout, but subsequent development depended on the timing of the treatment regime. Additionally, treatment with 1-butanol early in development disrupted endomembrane organization, known to require functional MTs. Interestingly, treatment with higher concentrations of 2-butanol, which also activates PLD, mimicked the effects of 1-butanol. In contrast, the control t-butanol had no effect on MTs or development. These results indicate that S. compressa zygotes utilize PLD signaling to regulate MT arrays. In contrast, PLD signaling does not appear to regulate actin arrays or endomembrane trafficking directly. This is the first report describing the signaling pathways that regulate cytoskeletal organization in the stramenopile (heterokont) lineage.     

Lipoxygenase-mediated oxidation of polyunsaturated N-acylethanolamines in Arabidopsis

N-acylethanolamines (NAEs) are bioactive fatty acid derivatives that occur in all eukaryotes. In plants, NAEs have potent negative growth-regulating properties, and fatty acid amide hydrolase (FAAH)-mediated hydrolysis is a primary catabolic pathway that operates during seedling establishment to deplete these compounds. Alternatively, polyunsaturated (PU)-NAEs may serve as substrates for lipid oxidation. In Arabidopsis, PU-NAEs (NAE 18:2 and NAE 18:3) were the most abundant NAE species in seeds, and their levels were depleted during seedling growth even in FAAH tDNA knock-out plants. Therefore, we hypothesized that lipoxygenase (LOX) participated in the metabolism of PU-NAEs through the formation of NAE-oxylipins. Comprehensive chromatographic and mass spectrometric methods were developed to identify NAE hydroperoxides and -hydroxides. Recombinant Arabidopsis LOX enzymes expressed in Escherichia coli utilized NAE 18:2 and NAE 18:3 as substrates with AtLOX1 and AtLOX5 exhibiting 9-LOX activity and AtLOX2, AtLOX3, AtLOX4, and AtLOX6 showing predominantly 13-LOX activity. Feeding experiments with exogenous PU-NAEs showed they were converted to hydroxide metabolites indicating that indeed Arabidopsis seedlings had the capacity for LOX-mediated metabolism of PU-NAEs in planta. Detectable levels of endogenous NAE-oxylipin metabolites were identified in FAAH fatty acid amide hydrolase seedlings but not in wild-type or FAAH overexpressors, suggesting that NAE hydroxide pools normally do not accumulate unless flux through hydrolysis is substantially reduced. These data suggest that Arabidopsis LOXs indeed compete with FAAH to metabolize PU-NAEs during seedling establishment. Identification of endogenous amide-conjugated oxylipins suggests potential significance of these metabolites in vivo, and FAAH mutants may offer opportunities to address this in the future.     

The N-acylethanolamine-mediated regulatory pathway in plants

While cannabinoids are secondary metabolites synthesized by just a few plant species, N-acylethanolamines (NAEs) are distributed widely in the plant kingdom, and are recovered in measurable, bioactive quantities in many plant-derived products. NAEs in higher plants are ethanolamides of fatty acids with acyl-chain lenghts of C12-C(18) and zero to three C=C bonds. Generally, the most-abundant NAEs found in plants and vertebrates are similar, including NAE 16 : 0, 18 : 1, 18 : 2, and 18 : 3. Like in animal systems, NAEs are formed in plants from N-acylphosphatidylethanolamines (NAPEs), and they are hydrolyzed by an amidase to yield ethanolamine and free fatty acids (FFA). Recently, a homologue of the mammalian fatty acid amide hydrolase (FAAH-1) was identified in Arabidopsis thaliana and several other plant species. Overexpression of Arabidopsis FAAH (AtFAAH) resulted in plants that grew faster, but were more sensitive to biotic and abiotic insults, suggesting that the metabolism of NAEs in plants resides at the balance between growth and responses to environmental stresses. Similar to animal systems, exogenously applied NAEs have potent and varied effects on plant cells. Recent pharmacological approaches combined with molecular-genetic experiments revealed that NAEs may act in certain plant tissues via specific membrane-associated proteins or by interacting with phospholipase D-alpha, although other, direct targets for NAE action in plants are likely to be discovered. Polyunsaturated NAEs can be oxidized via the lipoxygenase pathway in plants, producing an array of oxylipin products that have received little attention so far. Overall, the conservation of NAE occurrence and metabolic machinery in plants, coupled with the profound physiological effects of elevating NAE content or perturbing endogenous NAE metabolism, suggest that an NAE-mediated regulatory pathway, sharing similarities with the mammalian endocannabinoid pathway, indeed exists.     

Elevated levels of N-lauroylethanolamine,an endogenous constituent of desiccated seeds,disrupt normal root development in Arabidopsis thaliana seedlings

N-Acylethanolamines (NAEs) are prevalent in desiccated seeds of various plant species, and their levels decline substantially during seed imbibition and germination. Here, seeds of Arabidopsis thaliana (L.) Heynh. were germinated in, and seedlings maintained on, micromolar concentrations of N-lauroylethanolamine (NAE 12:0). NAE 12:0 inhibited root elongation, increased radial swelling of root tips, and reduced root hair numbers in a highly selective and concentration-dependent manner. These effects were reversible when seedlings were transferred to NAE-free medium. Older seedlings (14 days old) acclimated to exogenous NAE by increased formation of lateral roots, and generally, these lateral roots did not exhibit the severe symptoms observed in primary roots. Cells of NAE-treated primary roots were swollen and irregular in shape, and in many cases showed evidence, at the light- and electron-microscope levels, of improper cell wall formation. Microtubule arrangement was disrupted in severely distorted cells close to the root tip, and endoplasmic reticulum (ER)-localized green fluorescent protein (mGFP5-ER) was more abundant, aggregated and distributed differently in NAE-treated root cells, suggesting disruption of proper cell division, endomembrane organization and vesicle trafficking. These results suggest that NAE 12:0 likely influences normal cell expansion in roots by interfering with intracellular membrane trafficking to and/or from the cell surface. The rapid metabolism of NAEs during seed imbibition/germination may be a mechanism to remove this endogenous class of lipid mediators to allow for synchronized membrane reorganization associated with cell expansion.     

N-Acylated phospholipid metabolism and seedling growth: Insights from lipidomics studies in Arabidopsis

N-Acylphosphatidylethanolamines (NAPEs) are precursors of endogenous bioactive lipids, N-acylethanolamines (NAEs). NAPEs, which occur as a minor membrane lipid, are hydrolyzed in a single enzymatic step catalyzed by a type of phospholipase D (PLD) to generate fatty acid ethanolamides. Although, the occurrence of NAPE is widespread in the plant kingdom, the physiological roles remain under appreciated due to the lack of sensitive tools to quantify the pathway metabolites. In Kilaru et al. (2012, Planta, DOI 10.1007/s00425-012-1669-z), comprehensive mass spectrometry (MS)-based methods were developed to gain a clearer understanding of the complex network of metabolites that participate in NAE metabolic pathway. This targeted lipidomics approach allowed insights to be drawn into the implications of altered NAE levels on NAPE content and composition, and the overall regulation of PLD-mediated hydrolysis in Arabidopsis. Based on these results, we point out here the important need for the identification of the precise isoform(s) of PLD in plants that is (are) involved in the regulated hydrolysis of NAPE and formation of NAE lipid mediators in vivo.     

The effects of the phospholipase D-antagonist 1-butanol on seedling development and microtubule organisation in Arabidopsis

The organisation of plant microtubules into distinct arrays during the cell cycle requires interactions with partner proteins. Having recently identified a 90-kDa phospholipase D (PLD) that associates with microtubules and the plasma membrane [Gardiner et al. (2001) Plant Cell 13: 2143], we exposed seeds and young seedlings of Arabidopsis to 1-butanol, a specific inhibitor of PLD-dependent production of the signalling molecule phosphatidic acid (PA). When added to agar growth media, 0.2% 1-butanol strongly inhibited the emergence of the radicle and cotyledons, while 0.4% 1-butanol effectively blocked germination. When normal seedlings were transferred onto media containing 0.2% and 0.4% 1-butanol, the inhibitor retarded root growth by about 40% and 90%, respectively, by reducing cell elongation. Inhibited plants showed significant swelling in the root elongation zone, bulbous or branched root hairs, and modified cotyledon morphology. Confocal immunofluorescence microscopy of root tips revealed that 1-butanol disrupted the organisation of interphase cortical microtubules. Butanol isomers that do not inhibit PLD-dependent PA production, 2- and 3-butanol, had no effect on seed germination, seedling growth, or microtubule organisation. We propose that production of PA by PLD may be required for normal microtubule organisation and hence normal growth in Arabidopsis.     

Lipidomic analysis of N-acylphosphatidylethanolamine molecular species in Arabidopsis suggests feedback regulation by N-acylethanolamines

N-Acylphosphatidylethanolamine (NAPE) and its hydrolysis product, N-acylethanolamine (NAE), are minor but ubiquitous lipids in multicellular eukaryotes. Various physiological processes are severely affected by altering the expression of fatty acid amide hydrolase (FAAH), an NAE-hydrolyzing enzyme. To determine the effect of altered FAAH activity on NAPE molecular species composition, NAE metabolism, and general membrane lipid metabolism, quantitative profiles of NAPEs, NAEs, galactolipids, and major and minor phospholipids for FAAH mutants of Arabidopsis were determined. The NAPE molecular species content was dramatically affected by reduced FAAH activity and elevated NAE content in faah knockouts, increasing by as much as 36-fold, far more than the NAE content, suggesting negative feedback regulation of phospholipase D-mediated NAPE hydrolysis by NAE. The N-acyl composition of NAPE remained similar to that of NAE, suggesting that the NAPE precursor pool largely determines NAE composition. Exogenous NAE 12:0 treatment elevated endogenous polyunsaturated NAE and NAPE levels in seedlings; NAE levels were increased more in faah knockouts than in wild-type or FAAH overexpressors. Treated seedlings with elevated NAE and NAPE levels showed impaired growth and reduced galactolipid synthesis by the "prokaryotic" (i.e., plastidic), but not the "eukaryotic" (i.e., extraplastidic), pathway. Overall, our data provide new insights into the regulation of NAPE-NAE metabolism and coordination of membrane lipid metabolism and seedling development.     

1-Butanol interferes with phospholipase D1 and protein kinase Calpha association and inhibits phospholipase D1 basal activity

1-Butanol is commonly used as a substrate for phospholipase D (PLD) activity measurement. Surprisingly we found that, in the presence of 30 mM 1-butanol (standard PLD assay conditions), PLD1 activity in COS-7 cells was lost after incubation for 2 min. In contrast, in the presence of the protein kinase C (PKC) inhibitor staurosporine or dominant negative PKCalpha D481E, the activity was sustained for at least 30min. The binding between PLD1 and PKCalpha was also lost after 2 min incubation with 30 mM 1-butanol while staurosporine and D481E maintained the binding. 1-Butanol at 2 mM did not inhibit PLD1 basal activity or PLD1 binding to PKCalpha, and staurosporine and PKCalpha D481E produced a constant increase in PLD1 basal activity of 2-fold. These results indicate that 1-butanol is inhibitory to PLD1 activity by reducing its association with PKCalpha, and that the concentration of 1-butanol is an important consideration in assaying basal PLD1 activity.     

Plant fatty acid (ethanol) amide hydrolases

Fatty acid amide hydrolase (FAAH) plays a central role in modulating endogenous N-acylethanolamine (NAE) levels in vertebrates, and, in part, constitutes an "endocannabinoid" signaling pathway that regulates diverse physiological and behavioral processes in animals. Recently, an Arabidopsis FAAH homologue was identified which catalyzed the hydrolysis of NAEs in vitro suggesting a FAAH-mediated pathway exists in plants for the metabolism of endogenous NAEs. Here, we provide evidence to support this concept by identifying candidate FAAH genes in monocots (Oryza sativa) and legumes (Medicago truncatula), which have similar, but not identical, exon-intron organizations. Corresponding M. truncatula and rice cDNAs were isolated and cloned into prokaryotic expression vectors and expressed as recombinant proteins in Escherichia coli. NAE amidohydrolase assays confirmed that these proteins indeed catalyzed the hydrolysis of 14C-labeled NAEs in vitro. Kinetic parameters and inhibition properties of the rice FAAH were similar to those of Arabidopsis and rat FAAH, but not identical. Sequence alignments and motif analysis of plant FAAH enzymes revealed a conserved domain organization for these members of the amidase superfamily. Five amino-acid residues determined to be important for catalysis by rat FAAH were absolutely conserved within the FAAH sequences of six plant species. Homology modeling of the plant FAAH proteins using the rat FAAH crystal structure as a template revealed a conserved protein core that formed the active site of each enzyme. Collectively, these results indicate that plant and mammalian FAAH proteins have similar structure/activity relationships despite limited overall sequence identity. Defining the molecular properties of NAE amidohydrolase enzymes in plants will help to better understand the metabolic regulation of NAE lipid mediators.     

N-acylethanolamines are metabolized by lipoxygenase and amidohydrolase in competing pathways during cottonseed imbibition

Saturated and unsaturated N-acylethanolamines (NAEs) occur in desiccated seeds primarily as 16C and 18C species with N-palmitoylethanolamine and N-linoleoylethanolamine (NAE 18:2) being most abundant. Here, we examined the metabolic fate of NAEs in vitro and in vivo in imbibed cotton (Gossypium hirsutum) seeds. When synthetic [1-(14)C]N-palmitoylethanolamine was used as a substrate, free fatty acids (FFA) were produced by extracts of imbibed cottonseeds. When synthetic [1-(14)C]NAE 18:2 was used as a substrate, FFA and an additional lipid product(s) were formed. On the basis of polarity, we presumed that the unidentified lipid was a product of the lipoxygenase (LOX) pathway and that inclusion of the characteristic LOX inhibitors nordihydroguaiaretic acid and eicosatetraynoic acid reduced its formation in vitro and in vivo. The conversion of NAE 18:2 in imbibed cottonseed extracts to 12-oxo-13-hydroxy-N-(9Z)-octadecanoylethanolamine was confirmed by gas chromatography-mass spectrometry, indicating the presence of 13-LOX and 13-allene oxide synthase, which metabolized NAE 18:2. Cell fractionation studies showed that the NAE amidohydrolase, responsible for FFA production, was associated mostly with microsomes, whereas LOX, responsible for NAE 18:2-oxylipin production, was distributed in cytosol-enriched fractions and microsomes. The highest activity toward NAE by amidohydrolase was observed 4 to 8 h after imbibition and by LOX 8 h after imbibition. Our results collectively indicate that two pathways exist for NAE metabolism during seed imbibition: one to hydrolyze NAEs in a manner similar to the inactivation of endocannabinoid mediators in animal systems and the other to form novel NAE-derived oxylipins. The rapid depletion of NAEs by these pathways continues to point to a role for NAE metabolites in seed germination.     

Biosynthesis and turnover of anandamide and other N-acylethanolamines in peritoneal macrophages.

Polyunsaturated N-acylethanolamines (NAEs), including anandamide (20:4n-6 NAE), elicit a variety of biological effects through cannabinoid receptors, whereas saturated and monounsaturated NAEs are inactive. Arachidonic acid mobilization induced by treatment of intact mouse peritoneal macrophages with Ca2+ ionophore A23187 had no effect on the production of NAE or its precursor N-acylphosphatidylethanolamine (N-acyl PE). Addition of exogenous ethanolamine resulted in enhanced NAE synthesis by its N-acylation with endogenous fatty acids, but this pathway was not selective for arachidonic acid. Incorporation of (18)O from H2 (18)O-containing media into the amide carbonyls of both NAE and N-acyl PE demonstrated a rapid, constitutive turnover of both lipids.     

Involvement of acid ceramidase in the degradation of bioactive N-acylethanolamines

Bioactive N-acylethanolamines (NAEs) include palmitoylethanolamide, oleoylethanolamide, and anandamide, which exert anti-inflammatory, anorexic, and cannabimimetic actions, respectively. The degradation of NAEs has been attributed to two hydrolases, fatty acid amide hydrolase and NAE acid amidase (NAAA). Acid ceramidase (AC) is a lysosomal enzyme that hydrolyzes ceramide (N-acylsphingosine), which resembles NAAA in structure and function. In the present study, we examined the role of AC in the degradation of NAEs. First, we demonstrated that purified recombinant human AC can hydrolyze various NAEs with lauroylethanolamide (C12:0-NAE) as the most reactive NAE substrate. We then used HEK293 cells metabolically labeled with [¹⁴C]ethanolamine, and revealed that overexpressed AC lowered the levels of ¹⁴C-labeled NAE. As analyzed with liquid chromatography-tandem mass spectrometry, AC overexpression decreased the amounts of different NAE species. Furthermore, suppression of endogenous AC in LNCaP prostate cells by siRNA increased the levels of various NAEs. Lastly, tissue homogenates from mice genetically lacking saposin D, a presumable activator protein of AC, showed much lower hydrolyzing activity for NAE as well as ceramide than the homogenates from wild-type mice. These results demonstrate the ability of AC to hydrolyze NAEs and suggest its physiological role as a third NAE hydrolase.     

Endogenous unsaturated C18 N-acylethanolamines are vanilloid receptor (TRPV1) agonists

The endogenous C18 N-acylethanolamines (NAEs) N-linolenoylethanolamine (18:3 NAE), N-linoleoylethanolamine (18:2 NAE), N-oleoylethanolamine (18:1 NAE), and N-stearoylethanolamine (18:0 NAE) are structurally related to the endocannabinoid anandamide (20:4 NAE), but these lipids are poor ligands at cannabinoid CB(1) receptors. Anandamide is also an activator of the transient receptor potential (TRP) vanilloid 1 (TRPV(1)) on primary sensory neurons. Here we show that C18 NAEs are present in rat sensory ganglia and vascular tissue. With the exception of 18:3 NAE in rat sensory ganglia, the levels of C18 NAEs are equal to or substantially exceed those of anandamide. At submicromolar concentrations, 18:3 NAE, 18:2 NAE, and 18:1 NAE, but not 18:0 NAE and oleic acid, activate native rTRPV(1) on perivascular sensory nerves. 18:1 NAE does not activate these nerves in TRPV(1) gene knock-out mice. Only the unsaturated C18 NAEs elicit whole cell currents and fluorometric calcium responses in HEK293 cells expressing hTRPV(1). Molecular modeling revealed a low energy cluster of U-shaped unsaturated NAE conformers, sharing several pharmacophoric elements with capsaicin. Furthermore, one of the two major low energy conformational families of anandamide also overlaps with the cannabinoid CB(1) receptor ligand HU210, which is in line with anandamide being a dual activator of TRPV(1) and the cannabinoid CB(1) receptor. This study shows that several endogenous non-cannabinoid NAEs, many of which are more abundant than anandamide in rat tissues, activate TRPV(1) and thus may play a role as endogenous TRPV(1) modulators.     

The N-acylation-phosphodiesterase pathway and cell signalling

Long-chain N-acylethanolamines (NAEs) elicit a variety of biological and pharmacological effects, Anandamide (20:4n-6 NAE) and other polyunsaturated NAEs bind to the cannabinoid receptor and may thus serve as highly specific lipid mediators of cell signalling. NAEs can be formed by phospholipase D-catalyzed hydrolysis of N-acylethanolamine phospholipids or by direct condensation of ethanolamine and fatty acid, So far, most of the latter biosynthetic activity has been shown to be the reverse reaction of the NAE amidohydrolase that catalyzes NAE degradation. Thus, increasing evidence supports the hypothesis that the N-acylation-phosphodiesterase pathway yields not only saturated-monounsaturated NAEs, but polyunsaturated ones, including anandamide, as well.     

High-throughput lipidomic analysis of fatty acid derived eicosanoids and N-acylethanolamines

Fatty acid-derived eicosanoids and N-acylethanolamines (NAE) are important bioactive lipid mediators involved in numerous biological processes including cell signaling and disease progression. To facilitate research on these lipid mediators, we have developed a targeted high-throughput mass spectrometric based methodology to monitor and quantitate both eicosanoids and NAEs, and can be analyzed separately or together in series. Each methodology utilizes scheduled multiple reaction monitoring (sMRM) pairs in conjunction with a 25 min reverse-phase HPLC separation. The eicosanoid methodology monitors 141 unique metabolites and quantitative amounts can be determined for over 100 of these metabolites against standards. The analysis covers eicosanoids generated from cycloxygenase, lipoxygenase, cytochrome P450 enzymes, and those generated from non-enzymatic pathways. The NAE analysis monitors 36 metabolites and quantitative amounts can be determined for 33 of these metabolites against standards. The NAE method contains metabolites derived from saturated fatty acids, unsaturated fatty acids, and eicosanoids. The lower limit of detection for eicosanoids ranges from 0.1pg to 1pg, while NAEs ranges from 0.1pg to 1000pg. The rationale and design of the methodology is discussed.     

Discovery and Characterization of an Arabidopsis thaliana N-Acylphosphatidylethanolamine Synthase

N-Acylethanolamines (NAEs) are lipids involved in several physiological processes in animal and plant cells. In brain, NAEs are ligands of endocannabinoid receptors, which modulate various signaling pathways. In plant, NAEs regulate seed germination and root development, and they are involved in plant defense against pathogen attack. This signaling activity is started by an enzyme called N-acylphosphatidylethanolamine (NAPE) synthase. This catalyzes the N-acylation of phosphatidylethanolamine to form NAPE, which is most likely hydrolyzed by phospholipase D β/γ isoforms to generate NAE. This compound is further catabolized by fatty amide hydrolase. The genes encoding the enzymes involved in NAE metabolism are well characterized except for the NAPE synthase gene(s). By heterologous expression in Escherichia coli and overexpression in plants, we characterized an acyltransferase from Arabidopsis thaliana (At1g78690p) catalyzing the synthesis of lipids identified as NAPEs (two-dimensional TLC, phospholipase D hydrolysis assay, and electrospray ionization-tandem mass spectrometry analyses). The ability of free fatty acid and acyl-CoA to be used as acyl donor was compared in vitro with E. coli membranes and purified enzyme (obtained by immobilized metal ion affinity chromatography). In both cases, NAPE was synthesized only in the presence of acyl-CoA. β-Glucuronidase promoter experiments revealed a strong expression in roots and young tissues of plants. Using yellow fluorescent protein fusion, we showed that the NAPE synthase is located in the plasmalemma of plant cells.N-Acylethanolamines (NAEs)² are bioactive lipids composed of an ethanolamine headgroup amide-linked to an acyl chain varying in length and degree of saturation. In animals, NAEs are involved in different physiological processes, such as neuroprotective action (1), embryo development (2), cell proliferation (3), apoptosis (4), nociception, anxiety, inflammation, appetite/anorexia, learning, and memory (for review, see Ref. 5). Most studies carried out with animal cells/tissues have focused on N-arachidonoylethanolamine (anandamide, NAE20:4), which is synthesized in brain neurons but also, under certain conditions, in macrophage cells (6). NAE20:4 binds CB1 cannabinoid receptors located in brain neurons (7) and also acts as ligand of vanilloid receptors for pain modulation (8). In addition, it has been shown that NAE20:4 also promotes food intake, whereas NAE18:0 and NAE18:1 exert anorexic effects by increasing satiety (9–11). NAE16:0 is accumulated during inflammation and has several anti-inflammatory effects (for a review, see Ref. 12).In plants, NAEs are thought to be involved in various physiological functions. For example, because NAE levels observed in various dry seeds decline rapidly after imbibition, a possible role of these compounds in the regulation of seed germination has been proposed (13). It was further observed that the addition of 25 μm NAE12:0 to growth medium of Arabidopsis thaliana leads to a decrease in the size of the main and lateral roots and in root hair formation. This reduction in growth was associated with a modification of cytoskeletal organization (14). NAE12:0 is also able to delay cut Dianthus caryophyllus (carnation) senescence by decreasing oxidative damage and enhancing antioxidant defense (15), whereas NAE14:0 inhibits the elicitor-induced medium alkalinization and activates phenylalanine ammonia lyase gene expression involved in plant defense against pathogen attack (16).Both in plant and animal cells (for a review, see Ref. 17), NAEs are formed by the hydrolysis (by PLDs) of N-acylphosphatidylethanolamine (NAPE). NAPE is an unusual derivative of phosphatidylethanolamine (PE) with a third fatty acid linked to the amine position of the ethanolamine headgroup. In animals, the formation of NAEs is catalyzed by a PLD with a high specificity toward NAPE (NAPE-PLD). In plants, PLDβ and PLDγ isoforms, but not PLDα, hydrolyzed NAPE into NAE in vitro, and this is thought to operate in response to several biotic and abiotic stresses. Both in animals and in plants, NAEs signaling is terminated by the action of fatty acid amide hydrolases, which hydrolyze NAEs to free fatty acid and ethanolamine. FAAH has been identified and characterized in mammals and plants (for a review, see Ref. 17). In Arabidopsis, FAAH has been shown to modulate NAE content. Moreover, lines overexpressing FAAH displayed enhanced seedling growth as well as increased cell size (18) and were also more susceptible to bacterial pathogens (19).Although the role of NAEs and their catabolism have been extensively investigated, little is known about their precursors, the NAPEs. NAPEs represent a minor phospholipid class but are present in all tissues of plants and animals. The principal function of NAPEs is to serve as a precursor for the production of lipid mediator NAEs, but it has also been suggested that NAPEs could serve as a membrane stabilizer to maintain cellular compartmentalization during tissue damage (20). More recently, N-palmitoyl-PE was proposed to act as an inhibitor of macrophage phagocytosis through inhibition of the activation of Rac1 and Cdc42 (21).In the animal and plant kingdoms, therefore, the signaling events mediated by NAEs appear to be involved in many physiological processes that have been extensively studied. The genes encoding the enzymes involved in the synthesis (from NAPEs) and the degradation of NAEs have been cloned and characterized. By contrast, little is known about the physiological roles of NAPEs or about the first step of this lipid signaling pathway, namely the N-acylation of PE to form NAPEs. In animals, the synthesis of NAPEs is catalyzed by an N-acyltransferase, where the O-linked acyl unit from a phospholipid donor is transferred to the ethanolamine headgroup of PE (22). Recently, a rat LRAT-like protein 1 or RLP1 was shown to display such an activity, but according to the authors, RLP-1 can function as a PE N-acyltransferase, catalytically distinguishable from the known Ca²⁺-dependent N-acyltransferase (23). However, a different situation is observed in plants. NAPE synthase activity was shown to directly acylate PE with free fatty acids (24, 25), but a gene encoding a NAPE synthase activity remained unidentified until now. The present work shows that the A. thaliana acyltransferase At1g78690p catalyzes the synthesis of NAPEs from PE and acyl-CoAs in vitro as well as in vivo when this enzyme is expressed in E. coli and overexpressed in plants.