The New Zealand Institute for Plant & Food Research Limited, Auckland, New Zealand; School of Biological Sciences, University of Auckland, Auckland, New Zealand.
The New Zealand Institute for Plant & Food Research Limited, Auckland, New Zealand.
J Biol Chem. 2020 Mar 27;295(13):4181-4193. doi: 10.1074/jbc.RA119.011509. Epub 2020 Feb 17.
Strigolactones (SLs) are terpenoid-derived plant hormones that regulate various developmental processes, particularly shoot branching, root development, and leaf senescence. The SL receptor has an unusual mode of action. Upon binding SL, it hydrolyzes the hormone, and then covalently binds one of the hydrolytic products. These initial events enable the SL receptor DAD2 (in petunia) to interact with the F-box protein PhMAX2A of the Skp-Cullin-F-box (SCF) complex and/or a repressor of SL signaling, PhD53A. However, it remains unclear how binding and hydrolysis structurally alters the SL receptor to enable its engagement with signaling partners. Here, we used mutagenesis to alter DAD2 and affect SL hydrolysis or DAD2's ability to interact with its signaling partners. We identified three DAD2 variants whose hydrolytic activity had been separated from the receptor's interactions with PhMAX2A or PhD53A. Two variants, DAD2 and DAD2, having substitutions in the core α/β hydrolase-fold domain and the hairpin, exhibited hormone-independent interactions with PhMAX2A and PhD53A, respectively. Conversely, the DAD2 variant could not interact with PhMAX2A in the presence of SL, but its interaction with PhD53A remained unaffected. Structural analyses of DAD2 and DAD2 revealed only small differences compared with the structure of the WT receptor. Results of molecular dynamics simulations of the DAD2 structure suggested that increased flexibility is a likely cause for its SL-independent interaction with PhMAX2A. Our results suggest that PhMAX2A and PhD53A have distinct binding sites on the SL receptor and that its flexibility is a major determinant of its interactions with these two downstream regulators.
独脚金内酯(SLs)是一种萜类衍生的植物激素,调节各种发育过程,特别是芽分枝、根系发育和叶片衰老。SL 受体具有不寻常的作用模式。在结合 SL 后,它水解激素,然后共价结合水解产物之一。这些初始事件使 SL 受体 DAD2(在矮牵牛中)能够与 Skp-Cullin-F-box(SCF)复合物的 F-box 蛋白 PhMAX2A 和/或 SL 信号转导的抑制剂 PhD53A 相互作用。然而,目前尚不清楚结合和水解如何在结构上改变 SL 受体,使其能够与信号伙伴结合。在这里,我们使用诱变来改变 DAD2 并影响 SL 水解或 DAD2 与信号伙伴相互作用的能力。我们鉴定了三个 DAD2 变体,其水解活性已从受体与 PhMAX2A 或 PhD53A 的相互作用中分离出来。两个变体 DAD2 和 DAD2 在核心α/β水解酶折叠结构域和发夹中有取代,分别表现出激素非依赖性与 PhMAX2A 和 PhD53A 的相互作用。相反,在 SL 存在下,DAD2 变体不能与 PhMAX2A 相互作用,但与 PhD53A 的相互作用不受影响。与 WT 受体的结构相比,DAD2 和 DAD2 的结构分析仅显示出微小的差异。DAD2 结构的分子动力学模拟结果表明,增加的灵活性可能是其与 PhMAX2A 非激素依赖性相互作用的原因。我们的结果表明,PhMAX2A 和 PhD53A 在 SL 受体上具有不同的结合位点,其灵活性是其与这两个下游调节剂相互作用的主要决定因素。
