One element of gametophytic apomixis is unreduced embryo sac (ES) formation, which often occurs precociously displacing or replacing meiosis and causing apospory or diplospory, respectively. This study evaluated a premise that apomixis may evolve in hybridogenous plants that contain duplicate sets of allelically divergent ovule development heterochrony genes. The duplicate sets of genes would belong to duplicate genomic regions that are recombinationally isolated from each other (no gene flow) by allopolyploidy or paleopolyploidy, and this isolation would genetically stabilize apomixis. For apomixis to evolve, the ancestral donors of the duplicate regions must have differed from each other in timing of megasporogenesis, ES formation and embryony such that epigenetic misexpressions, or competitions in expression, of the duplicate heterochrony genes in hybridogenous derivatives would cause apomixis. Herein, we report substantial heterochrony in onset timing of germline stages among several sexual diploid Tripsacum genotypes, which may have been progenitors of apomictic polyploid Tripsacum. Tripsacum floridanum and Tripsacum zopilotense genotypes entered meiosis early. The former advanced rapidly through ES formation, but the latter entered a lengthy lag phase prior to ES formation. In two Tripsacum dactyloides var. dactyloides genotypes, meiosis occurred late and was followed by a distinct lag phase prior to ES formation. Likewise, the T. dactyloides var. meridonale genotype entered meiosis late, but the lag phase was brief. These differences appear to reflect allelic diversity at loci responsible for onset timing of different germline development stages within and across species and possibly across the recombinationally isolated duplicate chromosome regions in the Tripsacum paleopolyploid haplome (x = 18). Unique combinations of divergent alleles in hybridogenous plants coupled with polyploidy induced gene misexpressions may be required for apomixis to evolve.
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