叶绿体
生物
生物化学
运输机
拟南芥
氨基酸
生物物理学
拟南芥
结合位点
基质(水族馆)
转运蛋白
底物特异性
机制(生物学)
构象变化
系统发育学
膜
蛋白质结构
膜转运
膜转运蛋白
系统发育树
线粒体膜转运蛋白
血浆蛋白结合
柠檬酸合酶
功能分歧
活动站点
氨基酸取代
类囊体
作者
Zhao Yang,Xue Zhang,Jingtao Zheng,Shunhao Zhou,Ming‐Ju Amy Lyu,Minjie Ma,Xin-Guang Zhu,Fang Yu,Peng Zhang
出处
期刊:The Plant Cell
[Oxford University Press]
日期:2026-02-20
卷期号:38 (3)
标识
DOI:10.1093/plcell/koag041
摘要
Dicarboxylate transporters (DiTs) mediate the exchange of dicarboxylates across the chloroplast inner membrane, playing critical roles in C/N coupling, photorespiration, chloroplast redox homeostasis, and C4 photosynthesis. DiT1 and DiT2 are Na⁺-independent exchangers of the solute carrier 13 (SLC13) family, and exhibit overlapping yet distinct substrate specificities: DiT1 transports 2-oxoglutarate, malate, and oxaloacetate, while DiT2 additionally transports glutamate and aspartate. However, the structural determinants of their substrate specificity and transport mechanism remain unclear. Here, we determined cryo-electron microscopy structures of Arabidopsis thaliana DiT1 and DiT2.1 bound to diverse substrates in dual conformational states. Structural analyses revealed that AtDiT1 possesses a singular dicarboxylate-binding site that is electrostatically incompatible with amino acid substrates, whereas AtDiT2.1 has 2 distinct sites to accommodate C4- and C5-dicarboxylates, thus allowing amino acids to bind without electrostatic repulsion. Phylogenetic analysis identified an A226S substitution in the substrate-binding site of DiT1, emerging during evolution in the charophyte ancestor of land plants. This substitution enhances oxaloacetate binding affinity in DiT1, which may have improved adaptation to terrestrial environments. Additionally, 2 conserved positively charged residues in DiTs functionally mimic Na⁺ used by SLC13 co-transporters, thereby enabling a Na⁺-independent elevator-type transport mechanism. These findings provide critical structural and mechanistic insights into the functional divergence of plant DiTs.
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