Light-regulated Arabidopsis ACBP4 and ACBP5 encode cytosolic acyl-CoA-binding proteins that bind phosphatidylcholine and oleoyl-CoA ester

In Arabidopsis thaliana, six genes encode acyl-CoA-binding proteins (ACBPs) that show conservation of an acyl-CoA-binding domain. These ACBPs display varying affinities for acyl-CoA esters, suggesting of different cellular roles. We have recently reported that three members (ACBP4, ACBP5 and ACBP6) are subcellularly localized to the cytosol by biochemical fractionation, confocal microscopy of transgenic Arabidopsis expressing autofluorescence-tagged fusions and immuno-electron microscopy using ACBP-specific antibodies. In this study, we observed by Northern blot analysis that ACBP4 and ACBP5 mRNAs in rosettes were up-regulated by light and dampened-off in darkness, mimicking FAD7 which encodes omega-3-fatty acid desaturase, an enzyme involved in plastidial lipid metabolism. Results from in vitro binding assays indicate that recombinant ACBP4 and ACBP5 proteins bind [¹⁴C]oleoyl-CoA esters better than recombinant ACBP6, suggesting that light-regulated ACBP4 and ACBP5 encode cytosolic ACBPs that are potential candidates for the intracellular transport of oleoyl-CoA ester exported from the chloroplast to the endoplasmic reticulum for the biosynthesis of non-plastidial membrane lipids. Nonetheless, His-tagged ACBP4 and ACBP5 resemble ACBP6 in their ability to bind phosphatidylcholine suggesting that all three ACBPs are available for the intracellular transfer of phosphatidylcholine.     

Arabidopsis acyl-CoA-binding proteins ACBP4 and ACBP5 are subcellularly localized to the cytosol and ACBP4 depletion affects membrane lipid composition

In Arabidopsis thaliana, acyl-CoA-binding proteins (ACBPs) are encoded by six genes, and they display varying affinities for acyl-CoA esters. Recombinant ACBP4 and ACBP5 have been shown to bind oleoyl-CoA esters in vitro. In this study, the subcellular localizations of ACBP4 and ACBP5 were determined by biochemical fractionation followed by western blot analyses using anti-ACBP4 and anti-ACBP5 antibodies and immuno-electron microscopy. Confocal microscopy of autofluorescence-tagged ACBP4 and ACBP5, expressed transiently in onion epidermal cells and in transgenic Arabidopsis, confirmed their expression in the cytosol. Taken together, ACBP4 and ACBP5 are available in the cytosol to bind and transfer cytosolic oleoyl-CoA esters. Lipid profile analysis further revealed that an acbp4 knockout mutant showed decreases in membrane lipids (digalactosyldiacylglycerol, monogalactosyldiacylglycerol, phosphatidylcholine, phosphatidylethanolamine and phosphatidylinositol) while acbp4-complemented lines attained levels similar to wild type, suggesting that ACBP4 plays a role in the biosynthesis of membrane lipids including galactolipids and phospholipids.     

New roles for acyl-CoA-binding proteins (ACBPs) in plant development, stress responses and lipid metabolism

ACBPs are implicated in acyl-CoA trafficking in many eukaryotes and some prokaryotes. Six genes encode proteins designated as AtACBP1-AtACBP6 in the Arabidopsis thaliana ACBP family. These ACBPs are conserved in the acyl-CoA-binding domain, but vary in size from 92 amino acids (10.4 kDa) to 668 amino acids (73.1 kDa), and are subcellularly localised to different compartments in plant cells. Results from in vitro binding assays show that their corresponding recombinant proteins exhibit differential binding affinities to acyl-CoA esters and phospholipids, implying that these ACBPs may have non-redundant biological functions in vivo. By using knockout/downregulated and overexpression lines of Arabidopsis ACBPs, recent investigations have revealed that in addition to their proposed roles in phospholipid metabolism, these ACBPs can influence plant development including early embryogenesis and leaf senescence, as well as plant stress responses including heavy metal resistance, oxidative stress, freezing tolerance and pathogen resistance. In this review, recent progress on the biochemical and functional analyses of Arabidopsis ACBPs, their links to metabolic/signalling pathways, and their potential applications in development of stress tolerance are discussed.     

Arabidopsis cytosolic acyl-CoA-binding proteins ACBP4, ACBP5 and ACBP6 have overlapping but distinct roles in seed development

Eukaryotic cytosolic ACBPs (acyl-CoA-binding proteins) bind acyl-CoA esters and maintain a cytosolic acyl-CoA pool, but the thermodynamics of their protein–lipid interactions and physiological relevance in plants are not well understood. Arabidopsis has three cytosolic ACBPs which have been identified as AtACBP4, AtACBP5 and AtACBP6, and microarray data indicated that all of them are expressed in seeds; AtACBP4 is expressed in early embryogenesis, whereas AtACBP5 is expressed later. ITC (isothermal titration calorimetry) in combination with transgenic Arabidopsis lines were used to investigate the roles of these three ACBPs from Arabidopsis thaliana. The dissociation constants, stoichiometry and enthalpy change of AtACBP interactions with various acyl-CoA esters were determined using ITC. Strong binding of recombinant (r) AtACBP6 with long-chain acyl-CoA (C16- to C18-CoA) esters was observed with dissociation constants in the nanomolar range. However, the affinity of rAtACBP4 and rAtACBP5 to these acyl-CoA esters was much weaker (dissociation constants in the micromolar range), suggesting that they interact with acyl-CoA esters differently from rAtACBP6. When transgenic Arabidopsis expressing AtACBP6pro::GUS was generated, strong GUS (β-glucuronidase) expression in cotyledonary-staged embryos and seedlings prompted us to measure the acyl-CoA contents of the acbp6 mutant. This mutant accumulated higher levels of C18:1-CoA and C18:1- and C18:2-CoAs in cotyledonary-staged embryos and seedlings, respectively, in comparison with the wild type. The acbp4acbp5acbp6 mutant showed the lightest seed weight and highest sensitivity to abscisic acid during germination, suggesting their physiological functions in seeds.     

Involvement of low molecular mass soluble acyl-CoA-binding protein in seed oil biosynthesis

Acyl-CoA-binding protein (ACBP), a low molecular mass (m) (～ 10 kDa) soluble protein ubiquitous in eukaryotes, plays an important housekeeping role in lipid metabolism by maintaining the intracellular acyl-CoA pool. ACBP is involved in lipid biosynthesis and transport, gene expression, and membrane biogenesis. In plants, low m ACBP and high m ACBPs participate in response mechanisms to biotic and abiotic factors, acyl-CoA transport in phloem, and biosynthesis of structural and storage lipids. In light of current research on the modification of seed oil, insight into mechanisms of substrate trafficking within lipid biosynthetic pathways is crucial for developing rational strategies for the production of specialty oils with the desired alterations in fatty acid composition. In this review, we summarize our knowledge of plant ACBPs with emphasis on the role of low m ACBP in seed oil biosynthesis, based on in vitro studies and analyses of transgenic plants. Future prospects and possible applications of low m ACBP in seed oil modification are discussed.     

Overexpression of Arabidopsis Acyl-CoA Binding Protein ACBP3 Promotes Starvation-Induced and Age-Dependent Leaf Senescence

In Arabidopsis thaliana, a family of six genes (ACBP1 to ACBP6) encodes acyl-CoA binding proteins (ACBPs). Investigations on ACBP3 reported here show its upregulation upon dark treatment and in senescing rosettes. Transgenic Arabidopsis overexpressing ACBP3 (ACBP3-OEs) displayed accelerated leaf senescence, whereas an acbp3 T-DNA insertional mutant and ACBP3 RNA interference transgenic Arabidopsis lines were delayed in dark-induced leaf senescence. Acyl-CoA and lipid profiling revealed that the overexpression of ACBP3 led to an increase in acyl-CoA and phosphatidylethanolamine (PE) levels, whereas ACBP3 downregulation reduced PE content. Moreover, significant losses in phosphatidylcholine (PC) and phosphatidylinositol, and gains in phosphatidic acid (PA), lysophospholipids, and oxylipin-containing galactolipids (arabidopsides) were evident in 3-week-old dark-treated and 6-week-old premature senescing ACBP3-OEs. Such accumulation of PA and arabidopsides (A, B, D, E, and G) resulting from lipid peroxidation in ACBP3-OEs likely promoted leaf senescence. The N-terminal signal sequence/transmembrane domain in ACBP3 was shown to be essential in ACBP3-green fluorescent protein targeting and in promoting senescence. Observations that recombinant ACBP3 binds PC, PE, and unsaturated acyl-CoAs in vitro and that ACBP3 overexpression enhances degradation of the autophagy (ATG)-related protein ATG8 and disrupts autophagosome formation suggest a role for ACBP3 as a phospholipid binding protein involved in the regulation of leaf senescence by modulating membrane phospholipid metabolism and ATG8 stability in Arabidopsis. Accelerated senescence in ACBP3-OEs is dependent on salicylic acid but not jasmonic acid signaling.     

Prediction of the most favorable configuration in the ACBP-membrane interaction based on electrostatic calculations

Acyl-CoA binding proteins (ACBPs) are highly conserved 10 kDa cytosolic proteins that bind medium- and long-chain acyl-CoA esters. They act as intracellular carriers of acyl-CoA and play a role in acyl-CoA metabolism, gene regulation, acyl-CoA-mediated cell signaling, transport-mediated lipid synthesis, membrane trafficking and also, ACBPs were indicated as a possible inhibitor of diazepam binding to the GABA-A receptor. To estimate the importance of the non-specific electrostatic energy in the ACBP-membrane interaction, we computationally modeled the interaction of HgACBP with both anionic and neutral membranes. To compute the Free Electrostatic Energy of Binding (dE), we used the Finite Difference Poisson Boltzmann Equation (FDPB) method as implemented in APBS. In the most energetically favorable orientation, ACBP brings charged residues Lys18 and Lys50 and hydrophobic residues Met46 and Leu47 into membrane surface proximity. This conformation suggests that these four ACBP amino acids are most likely to play a leading role in the ACBP-membrane interaction and ligand intake. Thus, we propose that long range electrostatic forces are the first step in the interaction mechanism between ACBP and membranes.     

Arabidopsis ACBP3 is an extracellularly targeted acyl-CoA-binding protein

Cytosolic 10-kDa acyl-CoA-binding proteins (ACBPs) function in the storage and intracellular transport of acyl-CoA esters in eukaryotes. Fatty acids synthesized de novo in plant chloroplasts are exported as oleoyl-CoA and palmitoyl-CoA esters. In Arabidopsis, other than the 10-kDa ACBP, there exists five larger ACBPs (ACBP1 to ACBP5) of which homologues have not been characterized in other organisms. To investigate the significance of this gene family, we have attempted to subcellularly localize them and compare their acyl-CoA-binding affinities. We have previously shown that Arabidopsis ACBP1 and ACBP2 are membrane-associated proteins while ACBP4 and ACBP5 contain kelch motifs. Here, to localize ACBP3, we have expressed ACBP3-red fluorescent protein (DsRed2) from the CaMV 35S promoter. ACBP3-DsRed was localized extracellularly in transiently expressed tobacco BY-2 cells and onion epidermal cells. The function of the acyl-CoA-binding domain in ACBP3 was investigated by in vitro binding assays using (His)₆-ACBP3, which was observed to bind [¹⁴C]arachidonyl-CoA with high affinity in comparison to [¹⁴C]palmitoyl-CoA and [¹⁴C]oleoyl-CoA. To identify the residues functional in binding, five mutants with single amino acid substitutions in the acyl-CoA-binding domain of (His)₆-ACBP3 and (His)₆-ACBP1 (which also binds [¹⁴C]arachidonyl-CoA) were generated by site-directed mutagenesis. Binding assays with arachidonyl-CoA revealed that replacement of a conserved R residue (R150A in ACBP1 and R284A in ACBP3), disrupted binding. In contrast, other substitutions in ACBP1 (Y126A, K130A, K152A and Y171A) and in ACBP3 (F260A, K264A, K286A and Y305A) did not affect arachidonyl-CoA binding, unlike their equivalents in (His)₆-ACBP2, (His)₆-ACBP4 and (His)₆-ACBP5, which had altered binding to palmitoyl-CoA or oleoyl-CoA.     

Arabidopsis cDNA encoding a membrane-associated protein with an acyl-CoA binding domain

Acyl-CoA binding proteins (ACBPs) are small (ca. 10 kDa) highly-conserved cytosolic proteins that bind long-chain acyl-CoAs. A novel cDNA encoding ACBP1, a predicted membrane protein of 24.1 kDa with an acyl-CoA binding protein domain at its carboxy terminus, was cloned from Arabidopsis thaliana. At this domain, ACBP1 showed 47% amino acid identity to Brassica ACBP and 35% to 40% amino acid identity to yeast, Drosophila, bovine and human ACBPs. Recombinant (His)6-ACBP1 fusion protein was expressed in Escherichia coli and was shown to bind 14[C]oleoyl-CoA. A hydrophobic domain, absent in the 10 kDa ACBPs, was located at the amino terminus of ACBP1. Using antipeptide polyclonal antibodies in western blot analysis, ACBP1 was shown to be a membrane-associated glycosylated protein with an apparent molecular mass of 33 kDa. The ACBP1 protein was also shown to accumulate predominantly in siliques and was localized to the seed within the silique. These results suggest that the biological role of ACBP1 is related to lipid metabolism in the seed, presumably in which acyl-CoA esters are involved. Northern blot analysis showed that the 1.4 kb ACBP1 mRNA was expressed in silique, root, stem, leaf and flower. Results from Southern blot analysis of genomic DNA suggest the presence of at least two genes encoding ACBPs in Arabidopsis.     

Deciphering the roles of acyl-CoA-binding proteins in plant cells

Lipid trafficking is vital for metabolite exchange and signal communications between organelles and endomembranes. Acyl-CoA-binding proteins (ACBPs) are involved in the intracellular transport, protection, and pool formation of acyl-CoA esters, which are important intermediates and regulators in lipid metabolism and cellular signaling. In this review, we highlight recent advances in our understanding of plant ACBP families from a cellular and developmental perspective. Plant ACBPs have been extensively studied in Arabidopsis thaliana (a dicot) and to a lesser extent in Oryza sativa (a monocot). Thus far, they have been detected in the plasma membrane, vesicles, endoplasmic reticulum, Golgi apparatus, apoplast, cytosol, nuclear periphery, and peroxisomes. In combination with biochemical and molecular genetic tools, the widespread subcellular distribution of respective ACBP members has been explicitly linked to their functions in lipid metabolism during development and in response to stresses. At the cellular level, strong expression of specific ACBP homologs in specialized cells, such as embryos, stem epidermis, guard cells, male gametophytes, and phloem sap, is of relevance to their corresponding distinct roles in organ development and stress responses. Other interesting patterns in their subcellular localization and spatial expression that prompt new directions in future investigations are discussed.     

Membrane localization of Arabidopsis acyl-CoA binding protein ACBP2

Cytosolic acyl-CoA binding proteins bind long-chain acyl-CoAs and act as intracellular acyl-CoA transporters and pool formers. Recently, we have characterized Arabidopsis thaliana cDNAs encoding novel forms of ACBP, designated ACBP1 and ACBP2, that contain a hydrophobic domain at the N-terminus and show conservation at the acyl-CoA binding domain to cytosolic ACBPs. We have previously demonstrated that ACBP1 is membrane-associated in Arabidopsis. Here, western blot analysis of anti-ACBP2 antibodies on A. thaliana protein showed that ACBP2 is located in the microsome-containing membrane fraction and in the subcellular fraction containing large particles (mitochondria, chloroplasts and peroxisomes), resembling the subcellular localization of ACBP1. To further investigate the subcellular localization of ACBP2, we fused ACBP2 translationally in-frame to GFP. By means of particle gene bombardment, ACBP2-GFP and ACBP1-GFP fusion proteins were observed transiently expressed at the plasma membrane and at the endoplasmic reticulum in onion epidermal cells. GFP fusions with deletion derivatives of ACBP1 or ACBP2 lacking the transmembrane domain were impaired in membrane targeting. Our investigations also showed that when the transmembrane domain of ACBP1 or that of ACBP2 was fused with GFP, the fusion protein was targeted to the plasma membrane, thereby establishing their role in membrane targeting. The localization of ACBP1-GFP is consistent with our previous observations using immunoelectron microscopy whereby ACBP1 was localized to the plasma membrane and vesicles. We conclude that ACBP2, like ACBP1, is a membrane protein that likely functions in membrane-associated acyl-CoA transfer/metabolism.     

The ACBP gene family in Rhodnius prolixus: Expression,characterization and function of RpACBP-1

The acyl-CoA-binding proteins (ACBP) constitute a family of conserved proteins that bind acyl-CoA with high affinity and protect it from hydrolysis. Thus, ACBPs may have essential roles in basal cellular lipid metabolism. The genome of the insect Rhodnius prolixus encodes five ACBP genes similar to those described for other insect species. The qPCR analysis revealed that these genes have characteristic expression profiles in insect organs, suggesting that they have specific roles in insect physiology. Recombinant RpACBP-1 was able to bind acyl-CoA in an in vitro gel-shift assay. Moreover, heterologous RpACBP-1 expression in acb1Δ mutant yeast rescued the multi-lobed vacuole phenotype, indicating that RpACBP-1 acts as a bona fide acyl-CoA-binding protein. RpACBP-1 knockdown using RNAi caused triacylglycerol accumulation in the insect posterior midgut and a reduction in the number of deposited eggs. The amount of stored triacylglycerol was reduced in flight muscle, and the incorporation of fatty acids in cholesteryl esters was increased in the fat body. These results showed that RpACBP-1 participates in several lipid metabolism steps in R. prolixus.     

Overexpression of membrane-associated acyl-CoA-binding protein ACBP1 enhances lead tolerance in Arabidopsis

In Arabidopsis thaliana , a family of six genes encodes acyl-CoA-binding proteins (ACBPs) that show conservation at the acyl-CoA-binding domain. They are the membrane-associated ACBP1 and ACBP2, extracellularly targeted ACBP3, kelch-motif-containing ACBP4 and ACBP5, and 10-kDa ACBP6. The acyl-CoA domain in each of ACBP1 to ACBP6 binds long-chain acyl-CoA esters in vitro , suggestive of possible roles in plant lipid metabolism. We addressed here the use of Arabidopsis ACBPs in conferring lead [Pb(II)] tolerance in transgenic plants because the 10-kDa human ACBP has been identified as a molecular target for Pb(II) in vivo . We investigated the effect of Pb(II) stress on the expression of genes encoding Arabidopsis ACBP1, ACBP2 and ACBP6. We showed that the expression of ACBP1 and ACBP2 , but not ACBP6 , in root is induced by Pb(II) nitrate treatment. In vitro Pb(II)-binding assays indicated that ACBP1 binds Pb(II) comparatively better, and ACBP1 was therefore selected for further investigations. When grown on Pb(II)-containing medium, transgenic Arabidopsis lines overexpressing ACBP1 were more tolerant to Pb(II)-induced stress than the wild type. Accumulation of Pb(II) in shoots of the ACBP1 -overepxressing plants was significantly higher than wild type. The acbp1 mutant showed enhanced sensitivity to Pb(II) when germinated and grown in the presence of Pb(II) nitrate and tolerance was restored upon complementation using an ACBP1 cDNA. Our results suggest that ACBP1 is involved in mediating Pb(II) tolerance in Arabidopsis with accumulation of Pb(II) in shoots. Such observations of Pb(II) accumulation, rather than Pb(II) extrusion, in the ACBP1 -overexpressing plants implicate possible use of ACBP1 in Pb(II) phytoremediation.     

Computational Prediction of acyl-coA Binding Proteins Structure in Brassica napus

Acyl-coA binding proteins could transport acyl-coA esters from plastid to endoplasmic reticulum, prior to fatty acid biosynthesis, leading to the formation of triacylglycerol. The structure and the subcellular localization of acyl-coA binding proteins (ACBP) in Brassica napus were computationally predicted in this study. Earlier, the structure analysis of ACBPs was limited to the small ACBPs, the current study focused on all four classes of ACBPs. Physicochemical parameters including the size and the length, the intron-exon structure, the isoelectric point, the hydrophobicity, and the amino acid composition were studied. Furthermore, identification of conserved residues and conserved domains were carried out. Secondary structure and tertiary structure of ACBPs were also studied. Finally, subcellular localization of ACBPs was predicted. The findings indicated that the physicochemical parameters and subcellular localizations of ACBPs in Brassica napus were identical to Arabidopsis thaliana. Conserved domain analysis indicated that ACBPs contain two or three kelch domains that belong to different families. Identical residues in acyl-coA binding domains corresponded to eight amino acid residues in all ACBPs of B. napus. However, conserved residues of common ACBPs in all species of animal, plant, bacteria and fungi were only inclusive in small ACBPs. Alpha-helixes were displayed and conserved in all the acyl-coA binding domains, representing almost the half of the protein structure. The findings confirm high similarities in ACBPs between A. thaliana and B. napus, they might share the same functions but loss or gain might be possible.     

Binding site differences revealed by crystal structures of Plasmodium falciparum and bovine acyl-CoA binding protein

Acyl-CoA binding protein (ACBP) maintains a pool of fatty acyl-CoA molecules in the cell and plays a role in fatty acid metabolism. The biochemical properties of Plasmodium falciparum ACBP are described together with the 2.0 A resolution crystal structures of a P. falciparum ACBP-acyl-CoA complex and of bovine ACBP in two crystal forms. Overall, the bovine ACBP crystal structures are similar to the NMR structures published previously; however, the bovine and parasite ACBP structures are less similar. The parasite ACBP is shown to have a different ligand-binding pocket, leading to an acyl-CoA binding specificity different from that of bovine ACBP. Several non-conservative differences in residues that interact with the ligand were identified between the mammalian and parasite ACBPs. These, together with measured binding-specificity differences, suggest that there is a potential for the design of molecules that might selectively block the acyl-CoA binding site.     

Arabidopsis ACBP6 is an acyl-CoA-binding protein associated with phospholipid metabolism

In our recent paper in Plant Physiology, we showed that the Arabidopsis thaliana 10-kD acyl-CoA-binding protein, ACBP6, is subcellularly localized to the cytosol and that the overexpression of ACBP6 in transgenic Arabidopsis enhanced freezing tolerance. ACBP6-conferred freezing tolerance was independent of induced cold-regulated (COLD-RESPONSIVE) gene expression, but was correlated to an enhanced expression of phospholipase Dδ (PLDδ). Lipid analyses on cold-acclimated freezing-treated ACBP6-overexpressors revealed a decline in phosphatidylcholine (PC) and an elevation of phosphatidic acid (PA) in comparison to wild type. Furthermore, the His-tagged ACBP6 recombinant protein was observed using in vitro filter-binding assays to bind PC, but not PA or lysophosphatidylcholine. Taken together, our results implicate roles for ACBP6 in phospholipid metabolism that is related to gene regulation and PC-binding/transfer. This represents the first report demonstrating the in vitro binding of an ACBP to a phospholipid. The effect of ACBP6 on PLDδ expression is reminiscent of yeast 10-kD ACBP function in the regulation of genes associated with stress responses, fatty acid synthesis and phospholipid synthesis. However, the yeast ACBP regulates the expression of genes involved in phospholipid synthesis by donation of acyl-CoA esters and its binding to phospholipids remains to be demonstrated.Key words: acyl-CoA-binding protein, freezing tolerance, phosphatidylcholine-binding, phospholipid transfer     

Syncytium gene expression in Glycine max[PI 88788] roots undergoing a resistant reaction to the parasitic nematode Heterodera glycines

The plant parasitic nematode, Heterodera glycines is the major pathogen of Glycine max (soybean). H. glycines accomplish parasitism by creating a nurse cell known as the syncytium from which it feeds. The syncytium undergoes two developmental phases. The first is a parasitism phase where feeding sites are selected, initiating the development of the syncytium. During this earlier phase (1–4 days post infection), syncytia undergoing resistant and susceptible reactions appear the same. The second phase is when the resistance response becomes evident (between 4 and 6 dpi) and is completed by 9 dpi. Analysis of the resistant reaction of G. max genotype PI 88788 (G. max_{[PI 88788]}) to H. glycines population NL1-RHg/HG-type 7 (H. glycines_{[NL1-RHg/HG-type 7]}) is accomplished by laser microdissection of syncytia at 3, 6 and 9 dpi. Comparative analyses are made to pericycle and their neighboring cells isolated from mock-inoculated roots. These analyses reveal induced levels of the jasmonic acid biosynthesis and 13-lipoxygenase pathways. Direct comparative analyses were also made of syncytia at 6 days post infection to those at 3 dpi (base line). The comparative analyses were done to identify localized gene expression that characterizes the resistance phase of the resistant reaction. The most highly induced pathways include components of jasmonic acid biosynthesis, 13-lipoxygenase pathway, S-adenosyl methionine pathway, phenylpropanoid biosynthesis, suberin biosynthesis, adenosylmethionine biosynthesis, ethylene biosynthesis from methionine, flavonoid biosynthesis and the methionine salvage pathway. In comparative analyses of 9 dpi to 6 dpi (base line), these pathways, along with coumarin biosynthesis, cellulose biosynthesis and homogalacturonan degradation are induced. The experiments presented here strongly implicate the jasmonic acid defense pathway as a factor involved in the localized resistant reaction of G. max_{[PI 88788]} to H. glycines_{[NL1-RHg/HG-type 7]}.