ZmMTOPVIB is essential for double-strand break formation and bipolar spindle assembly during maize meiosis

Abstract

AbstractThe programmed formation of DNA double-strand breaks (DSBs) during early meiosis is catalyzed by SPO11, a conserved ortholog to the A subunit of an archaeal topoisomerase VI (TopoVI) which functions as a hetero-tetramer comprising two A and two B subunits. An essential role of the meiotic TopoVI B subunit (TopVIB) in DSB formation has been reported in mouse, Arabidopsis and rice. Very recently, rice MTopVIB was revealed to have an unexpected role in meiotic bipolar spindle assembly, highlighting multiple functions of MTopVIB during rice meiosis. In this work, the meiotic TopVIB in maize (ZmMTOPVIB) was characterized. The ZmmtopVIB mutant plants exhibited normal vegetative growth but male and female sterility. DSB formation is abolished in mutant meiocytes. Despite normal assembly of axial elements, synapsis was severely affected and homologous pairing was disrupted in mutants. Importantly, we showed that bipolar spindle assembly was also affected in ZmmtopVIB, resulting in triad and polyad formation. Overall, our results demonstrate that ZmMTOPVIB plays critical roles in DSB formation and homologous recombination. In addition, the newly-discovered function of MTOPVIB in bipolar spindle assembly is likely conserved across different monocots.One-sentence summaryThe dual roles of MTOPVIB in regulating meiotic DSB formation and bipolar spindle assembly are evolutionarily conserved in monocot plants.