Frédéric Marsolais scite author profile

SUMMARYHere we demonstrate that GmMYB176 regulates CHS8 expression and affects isoflavonoid synthesis in soybean. We previously established that CHS8 expression determines the isoflavonoid level in soybean seeds by comparing the transcript profiles of cultivars with different isoflavonoid contents. In the present study, a functional genomic approach was used to identify the factor that regulates CHS8 expression and isoflavonoid synthesis. Candidate genes were cloned, and co-transfection assays were performed in Arabidopsis leaf protoplasts. The results showed that GmMYB176 can trans-activate the CHS8 promoter with maximum activity. Transient expression of GmMYB176 in soybean embryo protoplasts increased endogenous CHS8 transcript levels up to 169-fold after 48 h. GmMYB176 encodes an R1 MYB protein, and is expressed in soybean seed during maturation. Furthermore, GmMYB176 recognizes a 23 bp motif containing a TAGT(T/A)(A/T) sequence within the CHS8 promoter. A subcellular localization study confirmed nuclear localization of GmMYB176. A predicted pST binding site for 14-3-3 protein is required for subcellular localization of GmMYB176. RNAi silencing of GmMYB176 in hairy roots resulted in reduced levels of isoflavonoids, showing that GmMYB176 is necessary for isoflavonoid biosynthesis. However, over-expression of GmMYB176 was not sufficient to increase CHS8 transcript and isoflavonoid levels in hairy roots. We conclude that an R1 MYB transcription factor, GmMYB176, regulates CHS8 expression and isoflavonoid synthesis in soybean.

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Co-occurrence of both l-asparaginase subtypes in Arabidopsis: At3g16150 encodes a K+-dependent l-asparaginase

Bruneau

Chapman

Marsolais

2006

Planta

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L-asparaginases (EC 3.5.1.1) are hypothesized to play an important role in nitrogen supply to sink tissues, especially in legume-developing seeds. Two plant L-asparaginase subtypes were previously identified according to their K(+)-dependence for catalytic activity. An L-asparaginase homologous to Lupinus K(+)-independent enzymes with activity towards beta-aspartyl dipeptides, At5g08100, has been previously characterized as a member of the N-terminal nucleophile amidohydrolase superfamily in Arabidopsis. In this study, a K(+)-dependent L-asparaginase from Arabidopsis, At3g16150, is characterized. The recombinants At3g16150 and At5g08100 share a similar subunit structure and conserved autoproteolytic pentapeptide cleavage site, commencing with the catalytic Thr nucleophile, as determined by ESI-MS. The catalytic activity of At3g16150 was enhanced approximately tenfold in the presence of K(+). At3g16150 was strictly specific for L-Asn, and had no activity towards beta-aspartyl dipeptides. At3g16150 also had an approximately 80-fold higher catalytic efficiency with L-Asn relative to At5g08100. Among the beta-aspartyl dipeptides tested, At5g08100 had a preference for beta-aspartyl-His, with catalytic efficiency comparable to that with L-Asn. The phylogenetic analysis revealed that At3g16150 and At5g08100 belong to two distinct subfamilies. The transcript levels of At3g16150 and At5g08100 were highest in sink tissues, especially in flowers and siliques, early in development, as determined by quantitative RT-PCR. The overlapping spatial patterns of expression argue for a partially redundant function of the enzymes. However, the high catalytic efficiency suggests that the K(+)-dependent enzyme may metabolize L-Asn more efficiently under conditions of high metabolic demand for N.

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Inactivation of Brassinosteroid Biological Activity by a Salicylate-inducible Steroid Sulfotransferase from Brassica napus

Rouleau¹,

Marsolais²,

Richard³

et al. 1999

Journal of Biological Chemistry

122

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Recent discoveries from brassinosteroid-deficient mutants led to the recognition that plants, like animals, use steroids to regulate their growth and development. We describe the characterization of one member of a Brassica napus sulfotransferase gene family coding for an enzyme that catalyzes the O-sulfonation of brassinosteroids and of mammalian estrogenic steroids. The enzyme is specific for the hydroxyl group at position 22 of brassinosteroids with a preference for 24-epicathasterone, an intermediate in the biosynthesis of 24-epibrassinolide. Enzymatic sulfonation of 24-epibrassinolide abolishes its biological activity in the bean second internode bioassay. This mechanism of hormone inactivation by sulfonation is similar to the modulation of estrogen biological activity observed in mammals. Furthermore, the expression of the B. napus steroid sulfotransferase genes was found to be induced by salicylic acid, a signal molecule in the plant defense response. This pattern of expression suggests that, in addition to an increased synthesis of proteins having antimicrobial properties, plants respond to pathogen infection by modulating steroid-dependent growth and developmental processes.Many developmental and physiological processes in organisms ranging from fungi to humans are regulated by a small number of steroid hormones. However, until recently the plant kingdom was almost completely excluded from the field of steroid endocrinology. The recent demonstration that the Arabidopsis de-etiolated2 (det2) and the constitutive photomorphogenesis and dwarfism (cpd) mutants are defective in the synthesis of brassinosteroids (BRs) 1 focused attention toward the physiological function of steroids in plants (1, 2). Since these initial discoveries, several other mutants impaired in BR synthesis or perception have been characterized at the molecular level (3-5).BRs have been shown to elicit a broad spectrum of responses including the promotion of cell elongation and cell division, inhibition of de-etiolation in the dark, repression of light-regulated genes in the dark, and repression of stressregulated genes (2, 6, 7). Brassinolide was the first BR isolated and characterized from plants (Fig.

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Cytosolic acetyl-CoA promotes histone acetylation predominantly at H3K27 in Arabidopsis

Chen

Wang

et al. 2017

Nature Plants

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Acetyl-coenzyme A (acetyl-CoA) is a central metabolite and the acetyl source for protein acetylation, particularly histone acetylation that promotes gene expression. However, the effect of acetyl-CoA levels on histone acetylation status in plants remains unknown. Here, we show that malfunctioned cytosolic acetyl-CoA carboxylase1 (ACC1) in Arabidopsis leads to elevated levels of acetyl-CoA and promotes histone hyperacetylation predominantly at lysine 27 of histone H3 (H3K27). The increase of H3K27 acetylation (H3K27ac) is dependent on adenosine triphosphate (ATP)-citrate lyase which cleaves citrate to acetyl-CoA in the cytoplasm, and requires histone acetyltransferase GCN5. A comprehensive analysis of the transcriptome and metabolome in combination with the genome-wide H3K27ac profiles of acc1 mutants demonstrate the dynamic changes in H3K27ac, gene transcripts and metabolites occurring in the cell by the increased levels of acetyl-CoA. This study suggests that H3K27ac is an important link between cytosolic acetyl-CoA level and gene expression in response to the dynamic metabolic environments in plants.

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