JOINTLESS Maintains Inflorescence Meristem Identity in Tomato

Plant & Cell Physiology Pub Date : 2024-04-17 DOI:10.1093/pcp/pcae046

Samuel Huerga-Fernández, Nathalie Detry, Beata Orman-Ligeza, Frédéric Bouché, Marc Hanikenne, Claire Périlleux

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Abstract

JOINTLESS (J) was isolated in tomato (Solanum lycopersicum) from mutants lacking a flower pedicel abscission zone (AZ), and encodes a MADS-box protein of the SVP/AGL24 sub-family. The loss of J function also causes the return to leaf initiation in the inflorescences, indicating a pivotal role in inflorescence meristem identity. Here, we compared j mutants in different accessions that exhibit either an indeterminate shoot growth, producing regular sympodial segments, or a determinate shoot growth, due to the reduction of sympodial segments and causal mutation of the SELF PRUNING (SP) gene. We observed that the inflorescence phenotype of j mutants is stronger in indeterminate (SP) accessions such as Ailsa Craig (AC), than in determinate (sp) ones, such as Heinz (Hz). Moreover, RNA-seq analysis revealed that the return to vegetative fate in j mutants is accompanied by expression of SP, which supports conversion of the inflorescence meristem to sympodial shoot meristem in j inflorescences. Other markers of vegetative meristems such as APETALA2c, and branching genes such as BRANCHED 1 (BRC1a/b) were differentially expressed in the inflorescences of j(AC) mutants. We also found in the indeterminate AC accession that J represses homeotic genes of B- and C-classes, and that its overexpression causes an oversized leafy calyx phenotype and has a dominant negative effect on AZ formation. A model is therefore proposed where J, by repressing shoot fate and influencing reproductive organ formation, acts as a key determinant of inflorescence meristems.

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JOINTLESS 可保持番茄花序分生组织的特性

在番茄（Solanum lycopersicum）中，JOINTLESS（J）是从缺乏花梗脱落区（AZ）的突变体中分离出来的，它编码 SVP/AGL24 亚家族的 MADS-box 蛋白。J 功能的缺失也会导致花序中叶的萌发，表明其在花序分生组织特征中起着关键作用。在这里，我们比较了不同品种中的 j 突变体，这些突变体要么表现出不确定的嫩枝生长，产生规则的合生节片，要么表现出确定的嫩枝生长，这是由于合生节片的减少和自剪枝（SP）基因的因果突变造成的。我们观察到，j 突变体的花序表型在艾尔莎-克雷格（Ailsa Craig，AC）等不定型（SP）品种中比在海因茨（Heinz，Hz）等定型（SP）品种中更强。此外，RNA-seq分析表明，j突变体恢复到无性系的命运伴随着SP的表达，这支持了j花序中花序分生组织向交感芽分生组织的转化。无性分生组织的其他标记（如 APETALA2c）和分枝基因（如 BRANCHED 1 (BRC1a/b)）在 j（AC）突变体的花序中表达不同。我们还发现，在不定型 AC 子代中，J 能抑制 B 类和 C 类的同源基因，其过量表达会导致过大的叶萼表型，并对 AZ 的形成产生显性负效应。因此提出了一个模型，即 J 通过抑制芽的命运和影响生殖器官的形成，成为花序分生组织的关键决定因素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Plant & Cell Physiology

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