Background <p><i> WUSCHEL</i>-related homeobox (<i>WOX</i>) transcription factors play pivotal roles in plant development and evolutionary innovation. However, their functions remain largely unexplored in the basal angiosperm <i>Annona atemoya</i>, an economically significant species. This study aimed to elucidate the role of the WOX gene family in growth and regeneration in <i>atemoya</i> using genome-wide identification and functional characterization.</p> Results <p>In the <i>atemoya</i> genome, 11 <i>WOX</i> genes were identified and phylogenetically classified into three distinct clades: Ancient, Intermediate, and Modern. This classification was confirmed by their conserved gene structures and motif compositions. A comparative genomic analysis revealed conserved synteny and purifying selection (Ka/Ks &lt; 1) among <i>WOX</i> orthologs of <i>atemoya</i>, <i>Amborella</i>, and <i>Arabidopsis</i>, highlighting evolutionary constraints and essential functional roles. Analysis of promoters in <i>cis</i>-elements showed the enrichment of development- and hormone-responsive motifs, indicating that <i>AaWOX</i> genes are integrated in conserved regulatory networks. Tissue-specific expression profiling revealed divergent spatiotemporal patterns. <i>AaWOX1</i> and <i>AaWOX3</i> were highly expressed in shoot tissues and during shoot regeneration. <i>AaWOX11/12</i> and <i>AaWOX5/7</i> were preferentially expressed in roots, but only <i>AaWOX11/12</i> was significantly upregulated during root regeneration. Notably, <i>AaWUS</i> was almost undetectable in normal roots but became strongly induced upon callus formation, implying a role in de-differentiation and cellular reprogramming.</p> Conclusions <p>Our study provides a comprehensive genome-wide analysis of the <i>AaWOX</i> family in <i>atemoya</i>, revealing its clade-specific evolutionary conservation and putative functional divergence during organ development and regeneration. These findings highlight the pivotal roles of <i>WOX</i> transcription factors in coordinating regenerative responses in a basal angiosperm and establish a critical foundation for the genetic improvement and biotechnology applications in <i>Annona atemoya</i>.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Evolutionary history and functional diversification of WOX genes in Annona Atemoya

  • Xueyu Zhang,
  • Xiaohong Dai,
  • Minmin Jing,
  • Shuailei Gu,
  • Zhihui Chen,
  • Jingjing Chen

摘要

Background

WUSCHEL-related homeobox (WOX) transcription factors play pivotal roles in plant development and evolutionary innovation. However, their functions remain largely unexplored in the basal angiosperm Annona atemoya, an economically significant species. This study aimed to elucidate the role of the WOX gene family in growth and regeneration in atemoya using genome-wide identification and functional characterization.

Results

In the atemoya genome, 11 WOX genes were identified and phylogenetically classified into three distinct clades: Ancient, Intermediate, and Modern. This classification was confirmed by their conserved gene structures and motif compositions. A comparative genomic analysis revealed conserved synteny and purifying selection (Ka/Ks < 1) among WOX orthologs of atemoya, Amborella, and Arabidopsis, highlighting evolutionary constraints and essential functional roles. Analysis of promoters in cis-elements showed the enrichment of development- and hormone-responsive motifs, indicating that AaWOX genes are integrated in conserved regulatory networks. Tissue-specific expression profiling revealed divergent spatiotemporal patterns. AaWOX1 and AaWOX3 were highly expressed in shoot tissues and during shoot regeneration. AaWOX11/12 and AaWOX5/7 were preferentially expressed in roots, but only AaWOX11/12 was significantly upregulated during root regeneration. Notably, AaWUS was almost undetectable in normal roots but became strongly induced upon callus formation, implying a role in de-differentiation and cellular reprogramming.

Conclusions

Our study provides a comprehensive genome-wide analysis of the AaWOX family in atemoya, revealing its clade-specific evolutionary conservation and putative functional divergence during organ development and regeneration. These findings highlight the pivotal roles of WOX transcription factors in coordinating regenerative responses in a basal angiosperm and establish a critical foundation for the genetic improvement and biotechnology applications in Annona atemoya.