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【Plant Communications】The GATA5–GhFBA1_At–KNAT7 module regulates fruit branch angle and high-density yield by controlling cell expansion and cell wall thickness in cotton
来源: 时间:2026-06-15

Zhiyong Xu, Chao Fu, Yu Le, Meilin Chen, Yuanxue Li, Ningyu Yang, Liuyang Hui, Xianlong Zhang, Yang Yang*, Zhongxu Lin*

Plant Communications, Online now, 101960, June 08, 2026

Abstract

Enhancing cotton yield remains a paramount breeding objective. Given limited arable land, increasing planting density is an effective strategy to boost cotton yield. However, the genetic basis of plant architecture suitable for high-density planting, particularly the molecular mechanism controlling fruit branch angle (FBA), remains largely unknown. This study identified qFBA-A11, a major QTL regulating FBA, using a Gossypium hirsutum × G. mustelinum introgression lines population. Map-based cloning revealed that GhFBA1_At was the major gene positively regulating FBA. GhFBA1_At encodes a protein with no known functional domains. Further investigations identified that GATA5, a light-responsive transcription factor, is a positive regulator of GhFBA1_At expression. The GhFBA1_At protein inhibited KNAT7 accumulation through direct protein-protein interaction and downregulated the expression of cell wall biosynthesis-related genes. This process promoted cell expansion while reducing cell wall thickness, ultimately weakening the mechanical strength of the cell wall and leading to a loose plant architecture. A structural variation (SV) at the GhFBA1_At locus in G. mustelinum caused complete gene loss, resulting in a compact plant architecture. Phylogenetic analysis showed that this SV was unique to G. mustelinum. CRISPR-Cas9 editing of GhFBA1_At generated a compact plant architecture and enhanced cotton yield under high-density planting. Our findings established GhFBA1_At as a crucial regulator of FBA, elucidated its molecular mechanism, and provided valuable germplasm resources for ideal plant architecture breeding in cotton.

论文链接:https://www.cell.com/plant-communications/fulltext/S2590-3462(26)00268-3