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Plastidial Fatty Acid Signaling Modulates Salicylic Acid– and Jasmonic Acid–Mediated Defense Pathways in the Arabidopsis ssi2 Mutant

^a Department of Plant Pathology, University of Kentucky, Lexington, Kentucky 40546
^b Department of Agronomy, University of Kentucky, Lexington, Kentucky 40546
^c Boyce Thompson Institute, Tower Road, Ithaca, New York 14853

¹ To whom correspondence should be addressed. E-mail pk62{at}uky.edu; fax 859-323-1961

	ABSTRACT

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
A mutation in the Arabidopsis gene ssi2/fab2, which encodes stearoyl–acyl carrier protein desaturase (S-ACP-DES), results in the reduction of oleic acid (18:1) levels in the mutant plants and also leads to the constitutive activation of NPR1-dependent and -independent defense responses. By contrast, ssi2 plants are compromised in the induction of the jasmonic acid (JA)–responsive gene PDF1.2 and in resistance to the necrotrophic pathogen Botrytis cinerea. Although S-ACP-DES catalyzes the initial desaturation step required for JA biosynthesis, a mutation in ssi2 does not alter the levels of the JA precursor linolenic acid (18:3), the perception of JA or ethylene, or the induced endogenous levels of JA. This finding led us to postulate that the S-ACP-DES–derived fatty acid (FA) 18:1 or its derivative is required for the activation of certain JA-mediated responses and the repression of the salicylic acid (SA) signaling pathway. Here, we report that alteration of the prokaryotic FA signaling pathway in plastids, leading to increased levels of 18:1, is required for the rescue of ssi2-triggered phenotypes. 18:1 levels in ssi2 plants were increased by performing epistatic analyses between ssi2 and several mutants in FA pathways that cause an increase in the levels of 18:1 in specific compartments of the cell. A loss-of-function mutation in the soluble chloroplastic enzyme glycerol-3-phosphate acyltransferase (ACT1) completely reverses SA- and JA-mediated phenotypes in ssi2. In contrast to the act1 mutation, a loss-of-function mutation in the endoplasmic reticulum–localized 6 oleate desaturase (FAD2) does not alter SA- or JA-related phenotypes of ssi2. However, a mutation in the plastidial membrane–localized 6 desaturase (FAD6) mediates a partial rescue of ssi2-mediated phenotypes. Although ssi2 fad6 plants are rescued in their morphological phenotypes, including larger size, absence of visible lesions, and straight leaves, these plants continue to exhibit microscopic cell death and express the PR-1 gene constitutively. In addition, these plants are unable to induce the expression of PDF1.2 in response to the exogenous application of JA. Because the act1 mutation rescues all of these phenotypes in ssi2 fad6 act1 triple-mutant plants, act1-mediated reversion may be mediated largely by an increase in the free 18:1 content within the chloroplasts. The reversion of JA responsiveness in ssi2 act1 plants is abolished in the ssi2 act1 coi1 triple-mutant background, suggesting that both JA- and act1-generated signals are required for the expression of the JA-inducible PDF1.2 gene. Our conclusion that FA signaling in plastids plays an essential role in the regulation of SSI2-mediated defense signaling is further substantiated by the fact that overexpression of the N-terminal–deleted SSI2, which lacks the putative plastid-localizing transit peptide, is unable to rescue ssi2-triggered phenotypes, as opposed to overexpression of the full-length protein.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Plants resist pathogen infection by inducing a defense response that is targeted specifically to combat invasion by the pathogen (Keen, 1990; Van der Hoorn et al., 2002). In many cases, the induction of these responses is accompanied by localized cell death at the site of pathogen entry, which often is able to restrict the spread of pathogen to cells within and immediately surrounding the lesions. This phenomenon, known as the hypersensitive response, is one of the earliest visible manifestations of induced defense response and resembles programmed cell death in animals (Flor, 1971; Greenberg et al., 1994; Dangl et al., 1996; Hammond-Kosack and Jones, 1996; Jabs et al., 1996; Gray, 2002). Concurrent with hypersensitive response development, defense reactions are triggered locally and in parts distant from the site of primary infection. This phenomenon, known as systemic acquired resistance, is one of the most studied induced defense responses and is accompanied by a local and systemic increase in endogenous salicylic acid (SA) and a concomitant upregulation of a large set of defense genes, including genes that encode pathogenesis-related (PR) proteins (Ward et al., 1991; Gaffney et al., 1993; Uknes et al., 1993; Dong, 2001).

A substantial body of evidence has demonstrated that SA plays an important signaling role in the activation of PR gene expression and resistance to certain pathogens (Delaney et al., 1994; Dempsey et al., 1999; Feys and Parker, 2000; Dong, 2001; Thomma et al., 2001; Kunkel and Brooks, 2002; Shah, 2003). In addition to SA, jasmonic acid (JA) and ethylene are two other important signal molecules in plant defense against pathogens. The role of JA in defense signaling was proven conclusively by creating the fad3 fad7 fad8 triple mutant, which is unable to accumulate JA and highly susceptible to infection by Pythium spp (Vijayan et al., 1998). Similarly, the JA-insensitive coi1 and jar1 mutants show enhanced susceptibility to fungal pathogens (Penninckx et al., 1996; Staswick et al., 1998; Thomma et al., 1998; Kachroo et al., 2001) and suppress the expression of the JA-inducible defense genes PDF1.2 and THI2.1 (Epple et al., 1995; Penninckx et al., 1998; Kachroo et al., 2001). A defect in ethylene signaling also impairs the expression of PDF1.2 and renders plants susceptible to infection by Alternaria brassicicola (Thomma et al., 1999).

Several lines of evidence suggest the existence of an intricate signaling network involving SA, JA, and ethylene, which leads to fine tuning of defense responses. Although SA and JA activate distinct signaling pathways, there is a growing body of literature that shows that these pathways do not function entirely independently. Rather, they are involved in a complex signaling network that influences the magnitude or amplitude of various signals derived from these pathways (Kunkel and Brooks, 2002). One of the major roles postulated for JA is its antagonistic action on SA-dependent signaling pathways (Creelman and Mullet, 1997; Seo et al., 1997). Similarly, various pharmacological and genetic experiments have shown that SA is a potent suppressor of the JA signaling pathway (Pena-Cortes et al., 1993; Doares et al., 1995; Harms et al., 1995; Niki et al., 1998; Gupta et al., 2000; Spoel et al., 2003).

The mechanism of crosstalk between SA and JA signaling pathways in the plant defense response remains to be elucidated. Results from several laboratories suggest that NPR1, a positive regulator of systemic acquired resistance, also may play a role in crosstalk and modulate the expression of the JA-inducible gene PDF1.2 (Shah et al., 1999; Devadas et al., 2002; Spoel et al., 2003). Recently, Spoel et al. (2003) showed that the NPR1-interacting protein TGA2 also can bind to a TGACG motif in the PDF1.2 promoter. Although the TGACG motif does not appear to be required for NPR1-dependent crosstalk, these results indicate that SA- and JA-mediated pathways are likely to share common components that may have a regulatory role.

Although NPR1 is a key transducer of SA signal (Cao et al., 1997; Ryals et al., 1997), several NPR1-independent pathways also have been identified that regulate PR gene expression and/or resistance to certain bacterial and fungal pathogens (Bowling et al., 1997; Clarke et al., 1998; Rate et al., 1999; Shah et al., 1999, 2001; Kachroo et al., 2000; Shirano et al., 2002). The ssi2 mutant represents one such component of the NPR1-independent signaling pathway. The recessive ssi2 mutation confers constitutive PR gene expression, spontaneous lesion formation, and enhanced resistance to both bacteria and oomycete pathogens (Shah et al., 2001). By contrast, a subset of defense responses regulated by the JA signaling pathway, including expression of the defensin gene PDF1.2 and resistance to Botrytis cinerea, are impaired in ssi2 plants (Kachroo et al., 2001). SSI2 encodes a stearoyl–acyl carrier protein desaturase (S-ACP-DES), which is an archetype member of a family of soluble fatty acid (FA) desaturases; these enzymes play an important role in regulating the overall level of desaturated FAs in the cell. The activity of the mutant S-ACP-DES enzyme was reduced 10-fold, resulting in an increase of the stearic acid (18:0) content in ssi2 plants (Kachroo et al., 2001). Because reduced S-ACP-DES activity leads to the induction of certain defense responses and the inhibition of others, we proposed that a FA-derived signal modulates crosstalk between different defense signaling pathways.

In plants, FAs have started to emerge as important molecules that participate in diverse biological processes (Lee et al., 1997; Ryu and Wang, 1998; Shanklin and Cahoon, 1998; Piffanelli and Murphy, 1999; Kachroo et al., 2001, 2003; Laxalt and Munnik, 2002; Maldonado et al., 2002; Weber, 2002; Li et al., 2003). Interestingly, FA signaling in plants and animals show several intriguing parallels. For example, both JA and its structural equivalent in animals, prostaglandins, are derived from similar enzymatic reactions starting with the hydrolysis of polyunsaturated FAs (Straus and Glass, 2001). Furthermore, the stearoyl desaturase–catalyzed enzymatic step that leads to the synthesis of JA and prostaglandin precursors, linolenic acid and arachidonic acid, respectively, also is conserved between plants and animals (Shanklin and Somerville, 1991). In animals, altered stearoyl-CoA desaturase activity has been implicated in the regulation of cell growth, differentiation, and signal transduction (Kates et al., 1984; Gyorfy et al., 1997, Kim et al., 1999; Kumar et al., 1999). Additionally, altered activity of this enzyme is correlated with apoptosis (de Vries et al., 1997) and neoplasia (Li et al., 1994); these phenomena are similar to the cell death and altered defense signaling phenotypes associated with the ssi2 mutation. Thus, although the mechanism(s) by which a mutation in S-ACP-DES affects defense response activation in plants is unclear, the discovery that a defect in FA desaturation can modulate defense responses opens novel approaches in the study of pathways that lead to disease resistance. Here, we show that a loss-of-function mutation in the chloroplastic enzymes glycerol-3-phosphate acyltransferase and 6 desaturase can reverse various ssi2-triggered phenotypes. We also show that alteration of the prokaryotic FA signaling pathway in plastids, leading to increased levels of 18:1, can rescue ssi2-triggered phenotypes. Our analysis suggests that FA signaling plays an important role in modulating the defense response against pathogens.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
ssi2 Plants Are Not Altered in the Perception or Biosynthesis of JA
SSI2-encoded S-ACP-DES preferentially desaturates stearic acid (18:0) between carbons 9 and 10 to yield 18:1. Compared with wild-type S-ACP-DES, the activity of the mutant protein is reduced 10-fold, which causes an increase in 18:0 levels and a reduction in 18:1 levels in ssi2 plants (Table 1). The inability of the ssi2 mutant plants to induce PDF1.2 expression upon JA treatment could be attributable to any of the following causes: (1) ssi2 plants are insensitive to JA and therefore unable to respond to exogenous treatment; (2) ssi2 plants are impaired in the JA biosynthetic pathway and therefore unable to accumulate endogenous JA; or (3) ssi2 plants lack a JA-coactivating signal, which is derived from S-ACP-DES. To assess these possibilities, we first determined the ability of ssi2 plants to perceive JA by conducting a root-growth bioassay (Staswick et al., 1998). Approximately 30 to 40 seeds each of SSI2, jar1-1, and ssi2 were grown on plates containing either 25 µM JA or an equal proportion of alcohol and allowed to grow vertically. Mean root length was measured 14 days later. As expected, JA inhibited root growth of the wild-type plants, whereas root growth in the JA-insensitive mutant jar1-1 remained largely unaffected (Figure 1A). ssi2 plants behaved like the wild-type plants and showed inhibition of root growth on JA-containing medium. These results suggest that ssi2 plants perceive JA in a manner similar to that of wild-type plants.

View larger version (31K): [in this window] [in a new window]   Figure 1. Root Growth Bioassay and JA Levels in the Leaves of SSI2 (Wild-Type) and ssi2 Plants after Wounding or Pathogen Infection. (A) Approximately 30 to 40 seeds each of SSI2, jar1-1, and ssi2 plants were sown on Murashige and Skoog (1962) (MS) plates with or without 25 µM JA and allowed to grow vertically for 14 days. Mean root length (mm ± SD) was determined for 30 seeds from each line. (B) Leaves were wounded with a razor blade or inoculated by spraying with A. brassicicola spores at a concentration of 106 spores/mL. Maximum JA levels were observed at 1 h after wounding and 96 h after inoculation and are shown as averages of two to three replicates. FW, fresh weight.

ssi2 Seedlings Are Not Affected in Their Response to Ethylene
Because expression of the PDF1.2 gene requires the concomitant activation of both JA and ethylene signal transduction pathways (Penninckx et al., 1998), it also is possible that ssi2 plants do not induce PDF1.2 expression because they carry a defect in the ethylene signaling pathway. To test this possibility, we compared the seedling responses of ssi2, wild-type, and ethylene-insensitive etr1 plants to the ethylene precursor aminocyclopropane carboxylic acid (ACC) (Guzman and Ecker, 1990; Smalle et al., 1997). Arabidopsis plants grown under continuous light on water-agar plates containing ACC exhibit enhanced elongation of the hypocotyl (Smalle et al., 1997). Compared with etr1, both ssi2 and wild-type seedlings showed elongated hypocotyls on plates containing ACC as opposed to seedlings grown on plates without ACC (Figure 2A). In addition, both ssi2 and wild-type seedlings showed a drastic inhibition of root growth on ACC plates as opposed to only a partial inhibition in etr1 plants (Figure 2B). These data suggest that ssi2 plants are not impaired in their response to ethylene.

View larger version (19K): [in this window] [in a new window]   Figure 2. Effect of ACC Treatments on Seedlings of SSI2, ssi2, and etr1 Plants. (A) Comparison of hypocotyl lengths of SSI2, ssi2, and etr1 seedlings grown on water-agar plates (w) or water-agar plates containing 50 µM ACC (ACC). Approximately 30 to 40 seeds each of SSI2, ssi2, and etr1 were grown on water-agar plates with or without ACC, and the plates were incubated at 22°C in continuous light. Hypocotyl lengths were measured after 10 days of growth. (B) Comparison of root lengths of 10-day-old seedlings from the same plants used in (A).

The Arabidopsis genes FAD2 (Miquel and Browse, 1992) and ACT1 (Kunst et al., 1989) encode enzymes that are localized in extrachloroplast or chloroplast, respectively, and mutations in these genes result in the upregulation of 18:1 levels in the cell. By contrast, the FAE1 gene product is expressed specifically in seeds, and a mutation in this gene causes an increase in 18:1 levels in the seeds (James et al., 1995). To determine if mutations in these genes can upregulate the levels of 18:1 in ssi2 and thereby complement defective crosstalk, we crossed ssi2 with fad2-1, act1-1, and fae1-1 mutants and screened the F2 populations for double-mutant plants. Interestingly, F2 analysis of the ssi2 x act1 cross revealed that a certain proportion of these plants, corresponding to recessive double mutants, had nearly wild-type-like leaf morphology but were slightly pale compared with either parent (Figure 3A). By contrast, the ssi2 fad2 (Figure 3A) and ssi2 fae1 (data not shown) plants showed ssi2-like phenotypes. Because ssi2 act1 plants contained the ssi2 mutation in the homozygous state, we concluded that the presence of the act1 mutant allele had resulted in the reversion of ssi2-conferred phenotypes. To confirm the genotype at the act1 locus, we sequenced the act1 gene and developed a cleaved amplified polymorphic sequence (CAPS) marker, which allowed us to score for the mutant allele. As expected, analysis of the double-mutant plants with the ACT1-CAPS marker showed that these contained the act1 mutation in the homozygous state. Unlike ssi2 plants, ssi2 act1 double-mutant plants did not show spontaneous cell death or constitutively increased levels of PR-1 gene expression (Figures 3B and 3C). To determine if these double mutant plants had regained sensitivity to the exogenous application of JA, we treated SSI2 (wild-type), ssi2, act1, and ssi2 act1 plants with JA or methyl jasmonate. As expected, ssi2 showed no induction of PDF1.2. By contrast, high levels of PDF1.2 expression were induced in wild-type, act1, and ssi2 act1 plants (Figure 3D). These results indicate that the act1 mutation was sufficient to revert ssi2 plants to wild-type-like plants.

View larger version (56K): [in this window] [in a new window]   Figure 3. Morphological and Molecular Phenotypes of SSI2, ssi2, ssi2 act1, and ssi2 fad2 Plants. (A) Comparison of the morphological phenotypes displayed by SSI2, ssi2, and ssi2 act1 plants. Plants were grown on soil and photographed after 3 (SSI2) or 4 (ssi2, ssi2 act1, and ssi2 fad2) weeks. (B) Expression of the PR-1 gene in SSI2, ssi2, ssi2 act1, and ssi2 fad2 plants. RNA gel blot analysis was performed on 5 µg of total RNA extracted from 4-week-old soil-grown plants. Ethidium bromide staining of rRNA was used as a loading control. (C) Microscopy of trypan blue–stained leaves from SSI2, ssi2, and ssi2 act1 plants. Leaves from ssi2 plants contain intensely stained areas of dead cells (arrowhead), whereas ssi2 act1 leaves show a wild-type-like phenotype. (D) Expression of the PDF1.2 gene in SSI2, act1, ssi2 act1, and ssi2 plants in response to 50 µM JA or water treatment. Samples were harvested at 48 h after treatment and examined by RNA gel blot analysis performed on 5 µg of total RNA. Ethidium bromide staining of rRNA was used as a loading control.

View larger version (31K): [in this window] [in a new window]   Figure 4. Resistance Response, Levels of SA and SA Glucoside, and SA Responsiveness. (A) Comparison of necrosis caused by B. cinerea in SSI2 (Col-0 and Nössen [Nö] ecotypes), ssi2, ssi2 act1, and act1 genetic backgrounds. Inoculations were performed on leaves of 4-week-old plants pricked with a needle at two to three well-spaced spots per leaf. The shading of each box indicates the severity of necrosis, and the numbers at right of the sample boxes indicate the number of leaves assayed. (B) Growth of P. parasitica ecotype Emco5. Cotyledons of 7-day-old seedlings from the various plant genotypes listed at left were inoculated by spraying conidiospores at a concentration of 106 spores/mL. There was no difference in the size of cotyledons between wild-type and mutant plants at the time of infection. Pathogen growth was assessed by counting the number of sporangiophores per cotyledon at 8 days after inoculation. The shading of each box indicates the severity of infection, based on the number of sporangiophores per cotyledon (see key at right). Numbers at right of the sample boxes indicate the number of cotyledons assayed. Ler, Landsberg erecta. (C) Endogenous SA and SA glucoside levels in leaves of 4-week-old soil-grown SSI2, ssi2, act1, and ssi2 act1 plants. The values presented are averages of three replicates. FW, fresh weight. (D) SA responsiveness of act1 and ssi2 act1 plants. Wild-type, act1, and ssi2 act1 plants were treated with water or 100 µM benzo(1,2,3)thiadiazole-7-carbothioic acid (BTH) and analyzed for PR-1 gene expression after 48 h. Ethidium bromide staining of rRNA was used as a loading control.

The act1 Mutation Restores Wild-Type-Like SA Levels in ssi2 Plants and Does Not Impair SA Responsiveness
To test if reversion of the enhanced resistance phenotype conferred by the ssi2 mutation also influences the accumulation of increased levels of SA, we determined the levels of SA and SA glucoside (SAG) in wild-type, ssi2, act1, and ssi2 act1 plants (Figure 4C). The ssi2 act1 plants showed a dramatic decrease in the levels of SA/SAG compared with the ssi2 plants, suggesting that the act1 mutation suppresses all of the SA-related phenotypes of the ssi2 mutant. Interestingly, suppression of SA levels alone is not sufficient to abolish any of the ssi2 phenotypes, because ssi2 nahG plants continue to remain stunted, show spontaneous cell death, express PR genes, and show partial resistance to bacterial and oomycete pathogens (Shah et al., 2001).

To determine if the act1 mutation restores various ssi2 phenotypes by impairing SA signaling, we sprayed wild-type, act1, and ssi2 act1 plants with water or benzo(1,2,3)thiadiazole-7-carbothioic acid and analyzed these for the induction of PR-1 gene expression. Both act1 and ssi2 act1 plants showed high levels of PR-1 expression, which was comparable to the induced levels of PR-1 seen in the wild-type plants (Figure 4D). These results suggest that ssi2 act1 plants are SA responsive and that the act1 mutation does not impair SA signaling. Therefore, act1-mediated suppression of the SA signaling pathway in ssi2 act1 plants may involve the generation of a signal that acts as a repressor and shuts off the SA signaling pathway.

The act1 Mutation Causes the Upregulation of 18:1 Levels in ssi2 Plants
ACT1 encodes glycerol-3-phosphate acyltransferase, which functions in the first step of the prokaryotic pathway of glycerolipid biosynthesis (Kunst et al., 1988) (Figure 5). The FAs 16:0 and 18:1 synthesized de novo in the chloroplasts either enter into the "prokaryotic pathway" in the chloroplast envelope or are exported to the endoplasmic reticulum as CoA thioesters, where they are incorporated into lipids via the "eukaryotic pathway." A mutation in act1 effectively converts a 16:3 plant such as Arabidopsis to an 18:3 plant, resulting in the accumulation of 18:1-ACP and the redirection of C-16 chains into the eukaryotic pathway (Kunst et al., 1988, 1989). Therefore, act1 mutant plants are deficient in their levels of 16:3 FA. To determine how act1 influences the FA content of ssi2 plants, levels of the various FAs were determined in leaf tissue of ssi2, act1, ssi2 act1, and wild-type plants (Table 1). As expected, the FA profile of ssi2 act1 plants overlapped with the profiles from single-mutant plants; ssi2 act1 plants contained lower levels of 16:3, similar to act1 plants, and high levels of 18:0, similar to ssi2 plants. However, the 18:1 content in ssi2 act1 plants was 15-fold higher compared with that in ssi2 plants, whereas the levels of all other FAs in general remained similar to those of control plants. These data suggest that the restoration of phenotypes in ssi2 act1 plants is likely to be mediated by increased levels of 18:1 in these plants. Because the act1-mediated increase in 18:1-ACP levels was initiated within chloroplasts, this result also suggests that reversion of the ssi2 phenotype may be linked to chloroplastic 18:1 content. This finding is supported by the fact that ssi2 fad2 plants accumulated an 17-fold increase in 18:1 content but continued to show ssi2-like phenotypes (Table 1).

View larger version (23K): [in this window] [in a new window]   Figure 5. Condensed Scheme for Lipid Biosynthesis in the Chloroplasts of Arabidopsis Leaves. De novo FA biosynthesis from acetyl-CoA occurs exclusively in the plastids of all cells (represented by the oval). Acetyl-CoA carboxylase (ACCase) and fatty acid synthase (FAS) complex are key enzymes involved in the biosynthesis of C16:0 FA. Upon elongation to C18:0, this FA undergoes desaturation to C18:1. This step is catalyzed by the SSI2-encoded S-ACP-DES. The product of this reaction (C18:1-ACP) either enters the prokaryotic pathway of lipid biosynthesis through the acylation of glycerol-3-phosphate (G3P) or is exported out of the plastids as a CoA thioester to enter the eukaryotic pathway. The acylation of G3P is catalyzed by an ACT1-encoded G3P acyltransferase. Desaturation of the C18:1 present on membrane glycerolipids (GL) is catalyzed by FAD2- or FAD6-encoded 6 desaturases that are present on the endoplasmic reticulum (ER) or the plastid envelop, respectively. Esterification of the CoA group is mediated by acyl-CoA synthetase (ACS). Symbols for various components are as follows: ACP, acyl carrier protein; C, carbon; DAG, diacylglycerol; DGDG, digalactosyldiacylglycerol; Lyso-PA, 1-acyl-G3P; MGDG, monogalactosyldiacylglycerol; PA, phosphatidic acid; PG, phosphatidylglycerol; SL, sulfolipid.

Partial Reversion of ssi2 Phenotypes by a Mutation in Plastidial 6 Oleate Desaturase

View larger version (33K): [in this window] [in a new window]   Figure 6. Morphological and Molecular Phenotypes of ssi2, ssi2 fad6, and ssi2 fad6 act1 Plants. (A) Comparison of the morphological phenotypes displayed by the ssi2, ssi2 fad6, and ssi2 fad6 act1 plants. Plants were grown on soil and photographed after 4 weeks. (B) Microscopy of trypan blue–stained leaves from SSI2, ssi2, ssi2 fad6, and ssi2 fad6 act1 plants. More than 90% of the ssi2 fad6 leaf samples showed prominent cell death (shown as I), whereas the remaining samples showed a marked reduction in the cell-death phenotype (shown as II). (C) Expression of PR-1 in ssi2, fad6, ssi2 fad6, and ssi2 fad6 act1 plants. For ssi2 fad6 plants, PR-1 gene expression was analyzed for three different sets of leaves. The lanes marked I and II represent RNA extracted from ssi2 fad6 leaves that showed high and low numbers of dead cells (shown in [B]), respectively. The lane marked III represents RNA extracted from leaves of one individual ssi2 fad6 plant in which a few leaves showed no cell death. RNA gel blot analysis was performed on 5 µg of total RNA extracted from 4-week-old soil-grown plants. Ethidium bromide staining of rRNA was used as a loading control. (D) Expression of PDF1.2 in SSI2, fad6, ssi2 fad6, and ssi2 fad6 act1 plants in response to 50 µM JA. Lanes marked I and II represent RNA extracted from ssi2 fad6 plants that showed high and low numbers of dead cells, respectively. Samples were harvested at 48 h after treatment and examined by RNA gel blot analysis performed on 5 µg of total RNA. Ethidium bromide staining of rRNA was used as a loading control.

We next determined the FA profiles of fad6 and ssi2 fad6 plants and found that both fad6 and ssi2 fad6 plants contained reduced levels of 16:3 and 18:3 and increased levels of 16:1 and 18:1, compared with wild-type plants (Table 1). Compared with ssi2 plants, ssi2 fad6 plants accumulated 24-fold greater levels of 18:1; these levels were 10-fold higher than those in ssi2 act1 plants. This finding suggests that an increase in the 18:1 content of chloroplastic membrane lipids is not sufficient to completely revert the altered defense signaling in ssi2 plants.

The act1 Mutation Mediates a Complete Rescue of ssi2 fad6 Plants
A partial recovery of ssi2 phenotypes by the fad6 mutation suggests that a simple increase in membranous 18:1 levels may not be enough to restore defective signaling in ssi2 plants. On the other hand, a complete reversal of ssi2 phenotypes by the act1 mutation suggests that the act1 mutation may generate free 18:1 in addition to channelizing 18:1 into chloroplastic membrane lipids. If these assumptions were correct, then we would expect the act1 mutation to completely restore all ssi2-related phenotypes in ssi2 fad6 plants. We generated ssi2 fad6 act1 triple-mutant plants by crossing ssi2 act1 with fad6 and identified triple mutants plants by CAPS and derived CAPS analysis of act1, fad6, and ssi2. The triple-mutant plants were morphologically similar to ssi2 act1 plants and showed no visible or microscopic cell death in their leaves (Figures 6A and 6B). These plants showed basal levels of PR-1 gene expression (Figure 6C) and high levels of the JA-inducible PDF1.2 gene (Figure 6D). Together, these results suggest that the act1 mutation is epistatic to the fad6 mutation and can completely suppress the ssi2-related phenotypes in ssi2 fad6 plants.

Induction of PDF1.2 in ssi2 act1 Plants Requires a Functional JA Pathway
Because the JA-induced expression of PDF1.2 requires the COI1 gene (Xie et al., 1998), we further assessed if the rescue of JA responsiveness in ssi2 act1 plants requires a fully functional JA pathway. To obtain triple-mutant plants, ssi2 act1 plants were crossed with coi1 plants and the F2 population was scored for plants homozygous for the ssi2 and act1 loci. Because tight linkage between the ssi2 and coi1 loci did not allow us to obtain ssi2 act1 plants that were homozygous for the coi1 locus, we isolated ssi2 act1 homozygous plants that were heterozygous at the coi1 locus. Three such plants were isolated after screening 460 F2 plants, and these were selfed to isolate ssi2 act1 coi1 triple-mutant plants. Genotypes at the coi1, act1, and ssi2 loci were determined by CAPS or derived CAPS marker analysis. The triple-mutant plants were morphologically similar to ssi2 act1 plants. Single-, double-, and triple-mutant plants between ssi2, act1, and coi1 were sprayed with water or JA, and the RNA isolated from these plants was analyzed for the expression of PDF1.2 after 48 h of treatment (Figure 7). As observed previously, ssi2 plants failed to induce any expression of PDF1.2, as opposed to the high levels seen in ssi2 act1 and ssi2 act1 COI1/- plants. By contrast, ssi2 act1 coi1 plants behaved like coi1 and ssi2 single-mutant plants and did not allow any JA-mediated induction of PDF1.2. These results suggest that COI1 is required for the induction of PDF1.2 in ssi2 act1 plants and that the act1-mediated rescue of JA responsiveness in ssi2 plants involves a step upstream of the COI1 gene in the JA pathway. However, it is likely that the act1 mutation regenerates a putative signal that in combination with JA is required for the induction of PDF1.2. In such a situation, blocking either the step leading to the generation of this putative signal or the JA signaling pathway will block the expression of the PDF1.2 gene. This notion is supported by our observation that exogenous application of both JA and 18:1 are required for the rescue of PDF1.2 expression in ssi2 plants (Kachroo et al., 2001).

View larger version (36K): [in this window] [in a new window]   Figure 7. JA Responsiveness in ssi2 act1 coi1 Triple-Mutant Plants. Expression of PDF1.2 in SSI2, ssi2, coi1, ssi2 act1, ssi2 act1 COI1/-, and ssi2 act1 coi1 plants in response to 50 µM JA or water treatment. Samples were harvested at 48 h after treatment and examined by RNA gel blot analysis performed on 5 µg of total RNA. Ethidium bromide staining of rRNA was used as a loading control.

View larger version (59K): [in this window] [in a new window]   Figure 8. Complementation of ssi2 Plants with Full-Length and N-Terminal Truncated SSI2 cDNAs. (A) Morphological phenotypes displayed by the transgenic plants overexpressing SSI2 or SSI2 N-t cDNA. Plants were grown on soil and photographed after 4 weeks. (B) Expression of the SSI2 and PR-1 genes in transgenic plants overexpressing SSI2 or SSI2 N-t cDNA. The band marked by the arrow represents endogenous SSI2 transcript. RNA gel blot analysis was performed on 5 µg of total RNA extracted from 4-week-old soil-grown plants. Ethidium bromide staining of rRNA was used as a loading control.

	DISCUSSION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

There are two possible ways that a mutation in act1 can rescue various ssi2-mediated phenotypes. First, because act1 suppresses SA/SAG levels in ssi2, it is likely that the act1 mutation renders plants defective in the SA signaling pathway, thereby shutting off constitutive SA signaling conferred by the ssi2 mutation. However, removal of SA by expressing the NahG transgene in ssi2 plants does not abolish any of its phenotypes (Shah et al., 2001). Furthermore, act1 plants are able to respond to the exogenous application of SA and are not altered in their resistance response to virulent or avirulent pathogens (Figures 4B and 4D). These results suggest that ACT1 may not participate in the SA signaling pathway and that reducing SA levels is not sufficient to cure the defect in JA-mediated responses in ssi2 plants. The second and most plausible explanation is that the act1 mutation acts indirectly by increasing the levels of 18:1 FA, and this increase leads to the restoration of ssi2-mediated signaling. This notion is supported by the observations that the injection of 18:1 rescues the responsiveness of ssi2 to JA (Kachroo et al., 2001) and that ssi2 act1 plants accumulate 15-fold higher levels of 18:1 compared with ssi2 plants, whereas levels of other FAs remain similar to those in control plants.

The mechanism underlying the wild-type-like reversion of ssi2 by a mutation in act1 is likely to involve FA signaling and to be mediated by 18:1 or its derivative. However, it also is possible that the signaling between various defense pathways is regulated by the ratios of saturated versus unsaturated FAs. This notion is supported by the observation that unsaturated FAs can stimulate or inhibit the activities of various regulatory enzymes (Klumpp et al., 1998; Baudouin et al., 1999). Furthermore, in animal systems, the ratio of saturated to unsaturated FAs is thought to control many cellular functions, including cell growth, differentiation, and apoptosis (Kates et al., 1984; Ntambi, 1995). Therefore it is likely that the act1 mutation mediates its effect by increasing the proportion of unsaturated 18:1 and balancing the ratio between 18:0 and 18:1. Interestingly, the ratios of 18:0 to 18:1 were more similar in wild-type and ssi2 act1 plants than in ssi2 plants, in which 18:0/18:1 ratios were 10-fold or more higher.

It is interesting that ssi2 plants continue to make low levels of 18:1 even though they are defective in the step leading to the formation of 18:1 (Figure 5). Similarly, fab2, which contains a null mutation in the SSI2 gene, also accumulates low levels of 18:1 (Lightner et al., 1994), indicating that trace amounts of 18:1 in ssi2 plants are not contributed by the residual activity of the mutant enzyme. This finding indicates that in addition to SSI2, several other isozymes of S-ACP-DES contribute to the generation of 18:1, although SSI2 appears to be the major enzyme regulating 18:1 levels in the chloroplast. Chloroplasts have been shown to harbor signaling components for both the SA and JA pathways, and a close proximity of various intermediates from these pathways would not only favor crosstalk but provide tighter control over their regulation (Schmid and Amrhein, 1995; Verberne et al., 2000; Weber, 2002). This also would explain why other mutations, including fad2, which upregulates 18:1 levels in the extrachloroplast membranes, are unable to complement a defect in ssi2 plants.

One important difference between the cellular locations of ACT1 and FAD2 is that although the former is a soluble chloroplastic enzyme, the later is a membrane-bound extrachloroplastic enzyme. These membrane-bound desaturases increase the unsaturated levels of membrane lipids and are less likely to cause an increase in the free FA pool in the cell. By contrast, a mutation in act1 is more likely to increase the free 18:1-ACP levels in the cell (Figure 5). This leads to the possibility that the reversion of phenotypes in ssi2 act1 plants may be attributable to the free chloroplastic 18:1-ACP pool rather than to the increased 18:1 content in the chloroplastic membrane lipids. However, the partial reversion of the morphological phenotype seen in ssi2 fad6 plants suggests that increases in both the free pool of 18:1-ACP and the 18:1 content of chloroplastic membrane lipids may be required for the restoration of ssi2 phenotypes. These results also suggest that act1 may generate certain factor(s) in addition to channelizing 18:1 into chloroplastic membrane lipids. This appears to be the case, because the act1 mutation is epistatic to the fad6 mutation and restores all of the ssi2-triggered phenotypes in ssi2 fad6 plants. Because SSI2 must be targeted to the chloroplast to be able to complement the ssi2 phenotypes (Figure 8), signaling within chloroplasts appears to account for the altered defense signaling in ssi2. Thus, it may be reasonable to assume that free 18:1 levels within the chloroplasts are able to balance the high levels of 18:0 generated as a result of the ssi2 mutation. Alternatively, the free 18:1 generated within the chloroplasts may generate a signal that participates in the modulation of defense signaling between the SA and JA pathways.

Several studies in both plants and animals have suggested a role for 18:1 in various cellular processes. In parsley cells, 18:1 levels have been shown to be upregulated in a biphasic manner at 2 h after treatment with an elicitor from Phytophthora sojae (Kirsch et al., 1997). By contrast, the levels of 18:2 declined and the levels of 18:3 increased steadily and doubled at 12 h after treatment. These findings indicate that the pathway from 18:1 to 18:3 is not linear and that 18:1 could play other roles besides serving as a precursor for 18:2. Studies in mammalian systems have shown that 18:1 can induce the translocation of protein kinase C from the cytosol toward the membranes via a direct or indirect process (Diaz-Guerra et al., 1991). Interestingly, in a recent study by Spoel et al. (2003), nucleocytoplasmic localization of NPR1 was suggested to regulate the crosstalk between the SA and JA pathways. Therefore, it is conceivable that 18:1 levels in plants regulate crosstalk by inducing the translocation of regulators of defense gene expression.

In addition to increasing the levels of 18:1 in ssi2 plants, the act1 and fad6 mutations also decrease 16:3 levels in the double-mutant plants. Thus, it is possible that the lower levels of 16:3 may play a role in restoring various phenotypes in ssi2 act1 and ssi2 fad6 plants. It is equally probable that the reduction in 16:3 levels is merely coincidental, because both act1 and fad6 affect the prokaryotic pathway of glycerolipid biosynthesis. Several results support this view. First, we have isolated several suppressor mutants in the ssi2 background that restore all of the ssi2-triggered phenotypes but contain normal levels of 16:3 (Kachroo et al., 2003). Second, ssi2 plants themselves show slight reductions in 16:3 levels compared with wild-type plants. Third, 35S:SSI2 transgenic plants show increased levels of 16:3 similar to wild-type plants. Fourth, although both ssi2 act1 and ssi2 fad6 plants have reduced 16:3 levels, only ssi2 act1 plants are completely rescued for all the ssi2-triggered phenotypes. Fifth, a mutation in fad5, which also decreased the levels of 16:3, did not restore wild-type-like phenotypes in ssi2 plants (A. Kachroo and P. Kachroo, unpublished results).

Our results also show that in addition to JA and ethylene, expression of the PDF1.2 gene is dependent on normal levels of FAs. The lack of induction of PDF1.2 in ssi2 plants does not appear to involve the JA or ethylene pathway, because ssi2 plants are responsive to both of these hormones (Figures 1 and 2). Furthermore, the restoration of JA responsiveness in ssi2 act1 plants can be abolished by the coi1 mutation, which indicates that functional FA and JA signaling pathways are required for the expression of PDF1.2.

In conclusion, our results clearly demonstrate the importance of FAs in modulating signaling between SA- and JA-dependent defense pathways. Further analysis of the FA signaling pathway should provide useful insights into the complex networking of these pathways and their regulation.

	METHODS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Plant Growth Conditions and Genetic Analysis
Plants were grown in MTPS 144 Conviron walk-in-chambers (Winnipeg, Manitoba, Canada) at 22°C with 65% RH and 14-h photoperiods. Crosses were performed by pollinating flowers of ssi2 or wild-type Nössen plants with pollen from fad2, act1, fad6, or fae1 plants. The ssi2 act1 coi1 triple-mutant plants were obtained by pollinating flowers from coi1 with pollen from ssi2 act1. The ssi2 fad6 act1 triple-mutant plants were obtained by pollinating ssi2 act1 flowers with pollen from fad6.

The genotype at the ssi2 locus was determined by derived cleaved amplified polymorphic sequence (CAPS) analysis (Kachroo et al., 2001). The genotype at the act1-1 locus was determined by identifying the mutant base, amplifying a 0.5-kb region flanking the mutant base, and digesting the amplified product with BsmFI. Primers used to amplify act1-specific CAPS were 5'-GCCATCAAGTGTTCATCTACT-3' and 5'-GGAAGTCATACAAGGTTGCTA-3'. The genotype at the coi1 locus was determined as described previously (Xie et al., 1998). The genotype at the fad6 locus was identified by CAPS analysis. Sequence analysis of the fad6-1 gene revealed a mutation from G to A at bp 478 in fad6 cDNA, which abolishes the restriction enzyme site for AlwNI in the fad6 amplified DNA. Primers used for FAD6-CAPS were 5'-GGATACACTTCCCAAAGAGGTG-3' and 5'-AGTTCACCCAGTGAGCTATGG-3'. The genotype at the fad2 locus was determined by sequence analysis. The fad2-1 mutation was determined by sequence analysis of the mutant gene and found to contain A instead of G at 310 bp in the cDNA. The genotype at the fae1 locus was determined indirectly by scoring for plants that segregated like ecotype Columbia for markers on the lower arm of chromosome 4.

RNA Extraction and RNA Gel Blot Analysis
Small-scale extraction of RNA from one or two leaves was performed with the TRIzol reagent (Gibco BRL, Gaithersburg, MD) according to the manufacturer's instructions. RNA gel blot analysis and the synthesis of randomly primed probes for PR-1 and PDF1.2 were performed as described (Kachroo et al., 2001).

Generation of Transgenic Plants Overexpressing SSI2 and SSI2 N-t cDNAs
The putative transit peptide region of SSI2 was predicted by aligning it with the protein sequence from castor bean S-ACP-DES. SSI2 N-t cDNA was amplified such that it lacked 34 amino acids of the putative signal peptide and the 35th amino acid was converted to Met. Both full-length and N-terminal truncated cDNAs were amplified as NcoI-XbaI–linked PCR products and cloned downstream of the double 35S promoter in pRTL2.GUS (-glucuronidase) vector. For transformation of Arabidopsis thaliana, the fragment containing promoter, SSI2 cDNA, and terminator was removed from the pRTL2-SSI2 or pRTL2-SSI2 N-t vectors and cloned into the HindIII site of the binary vectors pBAR1 and pVK18. Transgenic seeds containing pBAR1-derived vector were selected on soil sprayed with BASTA, and transgenic seeds containing pVK18 were selected on Murashige and Skoog (1962) medium containing hygromycin.

Trypan Blue Staining
Leaf samples were taken from 2-week-old plants grown on soil. Trypan blue staining was performed as described previously (Bowling et al., 1997).

Salicylic Acid, Jasmonic Acid, and Fatty Acid Analysis
Salicylic acid and salicylic acid glucoside were extracted and measured from 0.4 g (fresh weight) of leaf tissue as described previously (Bowling et al., 1994). Jasmonic acid and fatty acid analysis were performed as described previously (Dahmer et al., 1989; He et al., 2002). Endogenous levels of jasmonic acid were induced by spray inoculating Alternaria brassicicola spores at a concentration of 10⁶ spores/mL or by wounding leaf tissue with a razor blade.

Pathogen Infection
Infection with Peronospora parasitica Emco5 was performed by spraying or applying a single drop of asexual inoculum suspension as described previously (Kachroo et al., 2001). Infection with Botrytis cinerea was performed by spraying the spores at a concentration of 10⁷/mL on plants that were wounded by needle pricks. Plants were covered with a transparent plastic dome and kept in a plexiglass container to create maximum humidity conditions. Necrosis and fungal growth were scored at 8 to 10 days after inoculation. Necrosis was quantified by estimating the percentage of leaf tissue showing decay and was confirmed microscopically by determining fungal spread and the extent of sporulation.

Upon request, materials integral to the findings presented in this publication will be made available in a timely manner to all investigators on similar terms for noncommercial research purposes. To obtain materials, please contact Pradeep Kachroo, pk62{at}uky.edu.

	Acknowledgments

 
We thank Maelor Davies for allowing us to use the research facilities at the Kentucky Tobacco Research and Development Center and Baochun Li and David Zaitlin for sharing their laboratory space. We also thank John Shanklin and John Browse for useful discussions and John Browse for providing act1 fab2 seeds. We thank David Smith for useful suggestions. We thank William Broekaert and Bart Thomma for providing a culture of Botrytis, and we thank the ABRC for providing seeds for act1, fad6, fad2, and fae1 mutants. This work was supported by University of Kentucky research support funds to P.K., by Grants MCB 9723952 and MCB 0110404 from the National Science Foundation to D.K., and by U.S. Department of Agriculture National Research Initiative Grant 2002-01661 and Kentucky Science and Engineering Foundation Grant 200110151401 to D.H. and H.F. This study is publication 03-12-133 of the Kentucky Agricultural Experiment Station.

	Footnotes

 
Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.017301.

Received September 11, 2003; accepted October 6, 2003.

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