The GRAS transcription factor CsTL regulates tendril formation in cucumber

Junjun Shen, Yanxin Jiang, Jian Pan, Linhan Sun, Qingqing Li, Wenjing He, Piaoyun Sun, Bosi Zhao, Hongjiao Zhao, Xubo Ke, Yalu Guo, Tongwen Yang, Zheng Li
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Abstract

Cucumber (Cucumis sativus, Cs) tendrils are slender vegetative organs that typically require manual removal to ensure orderly growth during greenhouse cultivation. Here, we identified cucumber tendril-less (tl), a Tnt1 retrotransposon-induced insertion mutant lacking tendrils. Map-based cloning identified the mutated gene, CsaV3_3G003590, which we designated as CsTL, which is homologous to Arabidopsis thaliana LATERAL SUPPRESSOR (AtLAS). Knocking out CsTL repressed tendril formation but did not affect branch initiation, whereas overexpression of CsTL resulted in the formation of two or more tendrils in one leaf axil. Although expression of two cucumber genes regulating tendril formation, Tendril (CsTEN) and Unusual Floral Organs (CsUFO), was significantly decreased in CsTL knockout lines, these two genes were not direct downstream targets of CsTL. Instead, CsTL physically interacted with CsTEN, an interaction that further enhanced CsTEN-mediated expression of CsUFO. In Arabidopsis, the CsTL homolog AtLAS acts upstream of REVOLUTA (REV) to regulate branch initiation. Knocking out cucumber CsREV inhibited branch formation without affecting tendril initiation. Furthermore, genomic regions containing CsTL and AtLAS were not syntenic between the cucumber and Arabidopsis genomes, whereas REV orthologs were found on a shared syntenic block. Our results revealed not only that cucumber CsTL possesses a divergent function in promoting tendril formation but also that CsREV retains its conserved function in shoot branching.
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GRAS转录因子CsTL调控黄瓜卷须的形成
黄瓜(Cucumis sativus,Cs)卷须是细长的无性生殖器官,在温室栽培过程中通常需要人工去除以确保有序生长。在这里,我们发现了黄瓜无卷须突变体(tl),这是一种 Tnt1 反转座子诱导的插入突变体,缺乏卷须。基于图谱的克隆确定了突变基因CsaV3_3G003590,我们将其命名为CsTL,它与拟南芥LATERAL SUPPRESSOR(ATLAS)同源。敲除 CsTL 会抑制卷须的形成,但不会影响分枝的萌发,而过表达 CsTL 则会导致在一个叶腋中形成两个或更多的卷须。虽然两个调控卷须形成的黄瓜基因--卷须(CsTEN)和不寻常花器官(CsUFO)--的表达量在CsTL基因敲除株系中显著下降,但这两个基因并不是CsTL的直接下游靶标。相反,CsTL 与 CsTEN 发生了物理作用,这种作用进一步增强了 CsTEN 介导的 CsUFO 的表达。在拟南芥中,CsTL同源物ATLAS作用于REVOLUTA(REV)的上游,以调节分枝的启动。敲除黄瓜 CsREV 可抑制分枝的形成,但不影响卷须的萌发。此外,在黄瓜和拟南芥基因组中,含有 CsTL 和 AtLAS 的基因组区域不具有同源性,而 REV 的同源物却存在于共享的同源区块中。我们的研究结果不仅揭示了黄瓜 CsTL 在促进卷须形成方面具有不同的功能,而且还揭示了 CsREV 在芽分枝方面保留了其保守的功能。
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