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Farnesylcysteine Lyase Regulation of Abscisic Arabidopsis is Involved in Negative Acid Signaling in

Farnesylcysteine Lyase Regulation of Abscisic Arabidopsis is Involved in Negative Acid Signaling in
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摘要 The Arabidopsis FCLY gene encodes a specific farnesylcysteine (FC) lyase, which is responsible for the oxidative metabolism of FC to farnesal and cysteine. In addition, fcly mutants with quantitative decreases in FC lyase activity exhibit an enhanced response to ABA. However, the enzymological properties of the FCLY-encoded enzyme and its precise role in ABA signaling remain unclear. Here, we show that recombinant Arabidopsis FC lyase expressed in insect cells exhib- its high selectivity for FC as a substrate and requires FAD and molecular oxygen for activity. Arabidopsis FC lyase is also shown to undergo post-translational N-glycosylation. FC, which is a competitive inhibitor of isoprenylcysteine methyltransferase (ICMT), accumulates in fcly mutants. Moreover, the enhanced response of fcly mutants to ABA is reversed by ICMToverexpression. These observations support the hypothesis that the ABA hypersensitive phenotype of fcly plants is the result of FC accumulation and inhibition of ICMT. The Arabidopsis FCLY gene encodes a specific farnesylcysteine (FC) lyase, which is responsible for the oxidative metabolism of FC to farnesal and cysteine. In addition, fcly mutants with quantitative decreases in FC lyase activity exhibit an enhanced response to ABA. However, the enzymological properties of the FCLY-encoded enzyme and its precise role in ABA signaling remain unclear. Here, we show that recombinant Arabidopsis FC lyase expressed in insect cells exhib- its high selectivity for FC as a substrate and requires FAD and molecular oxygen for activity. Arabidopsis FC lyase is also shown to undergo post-translational N-glycosylation. FC, which is a competitive inhibitor of isoprenylcysteine methyltransferase (ICMT), accumulates in fcly mutants. Moreover, the enhanced response of fcly mutants to ABA is reversed by ICMToverexpression. These observations support the hypothesis that the ABA hypersensitive phenotype of fcly plants is the result of FC accumulation and inhibition of ICMT.
作者 David H. Huizinga Ryan Denton Kelly G. Koehler Ashley Tomasello Lyndsay Wood Stephanie E. Sen Dring N. Crowell
机构地区 Department of Biology Department of Chemistry Department of Chemistry Department of Biological Sciences
出处 《Molecular Plant》 SCIE CAS CSCD 2010年第1期143-155,共13页 分子植物(英文版)
关键词 Hormone biology primary metabolism seed biology STOMATA membrane proteins Arabidopsis. Hormone biology primary metabolism seed biology stomata membrane proteins Arabidopsis.
分类号 Q943 [生物学—植物学] TS143.32 [轻工技术与工程—纺织材料与纺织品设计]
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Molecular Plant
2010年 第1期

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