Project description:Purine catabolism is regarded as a housekeeping function that remobilizes nitrogen for plant growth and development. However, emerging evidence suggests that certain purine metabolites might contribute to stress protection of plants. Here, we show that in Arabidopsis, the intermediary metabolite allantoin plays a role in abiotic stress tolerance via activation of abscisic acid (ABA) metabolism. The aln loss-of-function of ALN, encoding allantoinase, results in increased allantoin accumulation, genome-wide up-regulation of stress-related genes, and enhanced tolerance to drought-shock and osmotic stress in aln mutant seedlings. This phenotype is not caused by a general response to purine catabolism inhibition, but rather results from a specific effect of allantoin. Allantoin activates ABA production both through increased transcription of NCED3, encoding a key enzyme in ABA biosynthesis, and through post-translational activation via high-molecular-weight complex formation of BG1, a ß-glucosidase hydrolyzing glucose-conjugated ABA. Exogenous application of allantoin to wild-type plants also activates the two ABA-producing pathways that lead to ABA accumulation and stress-responsive gene expression, but this effect is abrogated in ABA-deficient and BG1-knockout mutants. We propose that purine catabolism functions not only in nitrogen metabolism, but also in stress tolerance by influencing ABA production, which is mediated by the possible regulatory action of allantoin. Compared analysis of the transcriptomes of 2-week-old Arabidopsis seedlings from an allantoin-accumulating mutant genotype versus wild type background Col-0 (2 independent biological replicates per genotype). The allantoin-accumulating mutant in Col-0 background was the aln-1 mutant allele in allantoinase (ALN) (abbreviated as aln).

Project description:Allantoin is a metabolic intermediate of purine catabolism that often accumulates in stressed plants. Recently, using Arabidopsis knockout mutants (aln) of ALLANTOINASE, we showed that this purine metabolite activates ABA production, thereby stimulating stress-related gene expression and enhancing seedling tolerance to abiotic stress. A detailed re-examination of the microarray data of an aln mutant (aln-1) not only confirmed increased expression of ABA-inducible genes, but also revealed altered expression of genes involved in jasmonic acid (JA) responses, likely under the control of MYC2, a master switch in the JA signaling pathway. Consistent with the transcriptome profiles, the aln-1 mutant displayed increased JA levels and enhanced responses to mechanical wounding and exogenous JA. Moreover, aln mutants demonstrated modestly increased susceptibility to hemibiotrophic and necrotrophic pathogens, probably reflecting the antagonistic action of MYC2 on the defense against these bacteria. Exogenously administered allantoin elicited the expression of JA-responsive genes including MYC2 in wild-type plants, supporting that allantoin might be responsible for the observed JA-related aln phenotypes. However, the effect of exogenous allantoin was suppressed by mutations deficient in bioactive JA (jar1-1), insensitive to JA (myc2-3) and deficient in ABA (aba2-1 and bglu18). The suppressive effect of jar1-1 and bglu18 mutations was further confirmed in the aln-1 background (jar1-1/aln-1 and bglu18/aln-1). These results indicate that allantoin can activate the MYC2-regulated JA signaling pathway through ABA production. Overall, this study provides evidence for the possible connection of purine catabolism with stress hormone homeostasis and signaling, and highlights the importance of allantoin in these interactions. Evidence has been presented only recently for the involvement of purine catabolism in stress protection of plants and the mechanism behind this remains obscure. Here we show that in Arabidopsis, the intermediary metabolite allantoin can activate the MYC2-regulated jasmonate signaling pathway via the mechanism involving ABA, providing the link between the metabolism and two interactive signaling pathways of stress hormones that play critical roles in plant adaptation to environmental adversity.

Project description:Allantoin is a metabolic intermediate of purine catabolism that often accumulates in stressed plants. Recently, using Arabidopsis knockout mutants (aln) of ALLANTOINASE, we showed that this purine metabolite activates ABA production, thereby stimulating stress-related gene expression and enhancing seedling tolerance to abiotic stress. A detailed re-examination of the microarray data of an aln mutant (aln-1) not only confirmed increased expression of ABA-inducible genes, but also revealed altered expression of genes involved in jasmonic acid (JA) responses, likely under the control of MYC2, a master switch in the JA signaling pathway. Consistent with the transcriptome profiles, the aln-1 mutant displayed increased JA levels and enhanced responses to mechanical wounding and exogenous JA. Moreover, aln mutants demonstrated modestly increased susceptibility to hemibiotrophic and necrotrophic pathogens, probably reflecting the antagonistic action of MYC2 on the defense against these bacteria. Exogenously administered allantoin elicited the expression of JA-responsive genes including MYC2 in wild-type plants, supporting that allantoin might be responsible for the observed JA-related aln phenotypes. However, the effect of exogenous allantoin was suppressed by mutations deficient in bioactive JA (jar1-1), insensitive to JA (myc2-3) and deficient in ABA (aba2-1 and bglu18). The suppressive effect of jar1-1 and bglu18 mutations was further confirmed in the aln-1 background (jar1-1/aln-1 and bglu18/aln-1). These results indicate that allantoin can activate the MYC2-regulated JA signaling pathway through ABA production. Overall, this study provides evidence for the possible connection of purine catabolism with stress hormone homeostasis and signaling, and highlights the importance of allantoin in these interactions. Evidence has been presented only recently for the involvement of purine catabolism in stress protection of plants and the mechanism behind this remains obscure. Here we show that in Arabidopsis, the intermediary metabolite allantoin can activate the MYC2-regulated jasmonate signaling pathway via the mechanism involving ABA, providing the link between the metabolism and two interactive signaling pathways of stress hormones that play critical roles in plant adaptation to environmental adversity. Two replicates of the mutant were compared with controls. This series is a re-analysis of GSE44922.

Project description:Purine catabolism is regarded as a housekeeping function that remobilizes nitrogen for plant growth and development. However, emerging evidence suggests that certain purine metabolites might contribute to stress protection of plants. Here, we show that in Arabidopsis, the intermediary metabolite allantoin plays a role in abiotic stress tolerance via activation of abscisic acid (ABA) metabolism. The aln loss-of-function of ALN, encoding allantoinase, results in increased allantoin accumulation, genome-wide up-regulation of stress-related genes, and enhanced tolerance to drought-shock and osmotic stress in aln mutant seedlings. This phenotype is not caused by a general response to purine catabolism inhibition, but rather results from a specific effect of allantoin. Allantoin activates ABA production both through increased transcription of NCED3, encoding a key enzyme in ABA biosynthesis, and through post-translational activation via high-molecular-weight complex formation of BG1, a ß-glucosidase hydrolyzing glucose-conjugated ABA. Exogenous application of allantoin to wild-type plants also activates the two ABA-producing pathways that lead to ABA accumulation and stress-responsive gene expression, but this effect is abrogated in ABA-deficient and BG1-knockout mutants. We propose that purine catabolism functions not only in nitrogen metabolism, but also in stress tolerance by influencing ABA production, which is mediated by the possible regulatory action of allantoin.

Project description:ra07-02_aba2 - maternal/embryonic aba-1 - Identification of genes regulated by maternal and embryonic ABA - Comparison of expression in seeds (15 days after pollination) of aba2-2 mutant to wild type (Col-0), aba2 (female) x Col-0 (male) crossing, and aba2-2 sprayed with ABA (100 micro M, twice a week). Keywords: gene knock out,treated vs untreated comparison

Project description:Although abscisic acid (ABA) and gibberellins (GAs) play pivotal roles in many physiological processes in plants, their interaction in the control of leaf growth remains elusive. In this study, genetic analyses of ABA and GA interplay in leaf growth were performed in Arabidopsis thaliana. The results indicate that for ABA and GA interaction, leaf growth of both the aba2/ga20ox1 and aba2/GA20OX1-OE plants exhibits partially additive effects but is similar to the aba2 mutant. Consistent with this result, transcriptome analysis suggests that a substantial proportion (45-65%) of the gene expression profile of aba2/ga20ox1 and aba2/GA20OX1-OE plants overlaps and shares a similar pattern to the aba2 mutant. Thus, these data support that ABA deficiency dominates leaf growth regardless of GA levels. Moreover, gene ontology (GO) analysis indicates gene enrichment in the categories of hormone response, developmental and metabolic processes, and cell wall organization in these three genotypes. Leaf developmental genes are also involved in ABA-GA interaction. Collectively, these data support that the genetic relationship of ABA and GA interaction involves multiple coordinated pathways rather than a simple linear pathway in the regulation of leaf growth. To better understand the molecular basis of ABA and GA interaction, transcriptome analysis was performed among the genotypes used in this study.

Project description:To characterize the plant molecular response to Pythium irregulare, whole genome transcriptional profiles of infected and non-infected, wild type, jasmonic acid insensitive (coi1-1), ABA biosynthesis mutants (aba2-12), ein2-5 mutant, sid2-1 plants were obtained using “two-color” long-oligonucleotide microarrays.

Project description:ra07-02_aba2 - maternal/embryonic aba-1 - Identification of genes regulated by maternal and embryonic ABA - Comparison of expression in seeds (15 days after pollination) of aba2-2 mutant to wild type (Col-0), aba2 (female) x Col-0 (male) crossing, and aba2-2 sprayed with ABA (100 micro M, twice a week). Keywords: gene knock out,treated vs untreated comparison 6 dye-swap - CATMA arrays

Project description:Our current study showed that the ABA and ethylene signal transduction pathways function in parallel and have antagonistic interaction during seed germination and early seedling growth. To further address the possible mechanism by which these two hormones crosstalk, microarray analysis was performed. By microarray analysis we found that an ACC oxidase (ACO) was significantly up-regulated in the aba2 mutant, whereas the 9-CIS-EPOXYCAROTENOID DIOXYGENASE (NCED3) gene in ein2, and both the ABSCISIC ACID INSENSITIVE1 (ABI1) and cytochrome P450, family 707, subfamily A, polypeptide 2 (CYP707A2) genes in etr1-1 were up- and down-regulated, respectively. These data further suggest that ABA and ethylene may control the hormonal biosynthesis, catabolism or signaling of each other to enhance their antagonistic effects upon seed germination and early seedling growth.

Project description:mRNA sequencing was used to identify genes differentially expressed in Delta1-pyrroline-5-carboxylate synthase1-4 (p5cs1-4) mutants deficient in low water potential-induced proline accumulation and the Abscisic Acid (ABA) deficient mutant aba2-1 compared to Col-0 wild type. Three treatments were analyzed for each genotype: unstressed control, a 96 hour low water potential (-1.2 MPa) treatment and a stress-release treatment where seedlings were removed from the stress treatment and transferred back to control media for 10 hours. Approximately 100 genes were found to be significantly up-regulated in p5cs1-4 compared to wild type in both the control and stress treatments with an equal number down regulated. There was also a substantial transcription response to the stress release treatment which varied between wild type, p5cs1-4 and aba2-1.