ProACO4-GUS expression and RT-PCR analysis revealed that ACO4 is predominantly expressed in shoots of Arabidopsis seedlings under light conditions. ACO4-overexpressed mutant 35S-ACO4 produced more ethylene relative to the wild-type, which resulted in reduced growth of Arabidopsis seedlings. The abnormal growth of seedlings recurred after the application of Co 2+ ions, suggesting that ACO4 is a functional ACO necessary to regulate the growth and development of Arabidopsis seedlings. Exogenously-applied brassinosteroids (BRs) inhibited the expression of ACO4, and an enhanced ACO4 expression was found in det2, a BR-deficient mutant. Additionally, expression of ACO4 was decreased in bzr1-D (a BZR1-dominant mutant), implying that BR signaling negatively regulates ACO4 expression via BZR1 in Arabidopsis. In the intergenic region of ACO4, four E-boxes and a BR regulatory element (BRRE) are found. Electrophoretic mobility shift and chromatin immunoprecipitation assays showed that BZR1 binds directly to the BRRE in the putative promoter region of ACO4. By binding of BZR1 to BRRE, less ethylene was produced, which seems to regulate the growth and development of Arabidopsis seedlings.
Gas chromatography–mass
spectrometry
(GC–MS) analysis revealed that castasterone and its biosynthetic
precursors are found in Brachypodium distachyon. In vitro conversion experiments with crude enzyme solutions prepared
from B. distachyon demonstrated the
presence of the following biosynthetic sequences: campesterol →
campesta-4-en-3-one → campesta-3-one → campestanol →
6-deoxocathasterone → 6-deoxoteasterone → teasterone
↔ 3-dehydroteasterone ↔ typhasterol → castasterone.
campesterol → 22-hydroxycampesterol → 22-hydroxy-campesta-4-en-3-one
→ 22-hydroxy-campesta-3-one → 6-deoxo-3-dehydroteasterone
→ 3-dehydroteasterone. 6-deoxoteasterone ↔ 6-deoxo-3-dehydroteasterone
↔ 6-deoxotyphasterol → 6-deoxocastasterone →
castasterone. This shows that there are campestanol-dependent and
campestanol-independent pathway in B. distachyon that synthesize 24-methylated brassinosteroids (BRs). Biochemical
analysis of BRs biosynthetic enzymes confirmed that BdDET2, BdCYP90B1, BdCYP90A1, BdCYP90D2, and BdCYP85A1 are orthologous
to BR 5α-reductase, BR C-22 hydroxylase, BR C-3 oxidase, BR
C-23 hydroxylase, and BR C-6 oxidase, respectively. Brassinolide was
not identified in B. distachyon. Additionally, B. distachyon crude enzyme solutions could not catalyze
the conversion of castasterone to brassinolide, and the gene encoding
an ortholog of CYP85A2 (a brassinolide synthase) was not found in B. distachyon. These results strongly suggest that
the end product for brassinosteroid biosynthesis which controls the
growth and development of B. distachyon is not brassinolide but rather castasterone.
Brassinosteroids (BRs) are known to be endogenous regulators of ethylene production, suggesting that some BR activity in plant growth and development is associated with ethylene. Here, we demonstrated that ethylene production in Arabidopsis thaliana roots is increased by BR signaling via the ethylene biosynthetic gene for ACC oxidase 1 (ACO1). Electrophoretic mobility shift and chromatin immuneprecipitation assays showed that the BR transcription factor BES1 directly binds to two E-box sequences located in the intergenic region of ACO1. GUS expression using site mutations of the E-box sequences verified that ACO1 is normally expressed only when BES1 binds to the E-boxes in the putative promoter of ACO1, indicating that this binding is essential for ACO1 expression and the subsequent production of ethylene in A. thaliana roots. BR exogenously applied to A. thaliana roots enhanced the gravitropic response. Additionally, bes1-D exhibited a greater gravitropic response than did the wild-type specimens, proving that BR is a positive regulator of the gravitropic response in A. thaliana roots. The knockdown mutant aco1-1 showed a slightly lower gravitropic response than did the wild-type specimens, while bes1-D X aco1-1 exhibited a lower gravitropic response than did bes1-D. Therefore, ACO1 is a direct downstream target for BR transcription factor BES1, which controls ethylene production for gravitropism in A. thaliana roots.
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