ORF138 causes abnormal lipid metabolism in the tapetum leading to Ogu cytoplasmic male sterility in Brassica napus

Abstract

Plant cytoplasmic male sterility is caused by mutations and rearrangements of mitochondrial genes. It serves as a significant way to utilize hybrid vigor to enhance crop yield. Ogu CMS is a natural cytoplasmic male sterility type discovered in radishes, being successfully transferred to rapeseed and cruciferous vegetables. However, current studies lack depth in exploring the molecular mechanisms of its male sterility. In this study, we confirmed orf138 is the causal gene for Ogu CMS through genetic transformation in Arabidopsis. Transcriptome analysis of aborted anthers in different stages suggested differentially expressed genes (DEGs) are mainly enriched in pathways such as glycerophospholipid metabolism and arginine and proline metabolism. It reveals that key genes involved in lipid metabolism pathways are significantly down-regulated in the sterile line (OguA), including BnaGPAT1, localized within the tapetum mitochondrial and endoplasmic reticulum. This could lead to changes in the metabolism of substances like acylglycerols within the tapetum, causing disruptions in lipid metabolism. This is consistent with morphological and subcellular structural changes in the tapetum and microspore cells as observed in the transmission electron microscopy. This abnormal lipid metabolism may trigger specific ROS accumulation in an oxidative stress response, ultimately leading to aborted microspore. Our study based on transcriptome has deepened our understanding of the molecular mechanisms in Ogu CMS.