Abstract
Perennialism is common among the higher plants, yet we know little about its inheritance. To address this, six hybrids were made by reciprocally crossing perennial Zea diploperennis Iltis, Doebley & R. Guzman with three varieties/inbred lines of annual maize (Z. mays L. spp. mays). We specifically focused on the plant’s ability to regrow after flowering and senescence. All the F1 plants demonstrated senescence and regrowth for several cycles, indicating a dominant effect of the Z. diploperennis alleles. The regrowth ability was stably transmitted to progeny of the hybrids in segregation ratios that suggested the trait was controlled by two dominant, complementary loci. Genome-wide screening with genotyping-by-sequencing (GBS) identified two major regrowth loci reg1 and reg2 on chromosomes 2 and 7, respectively. GBS results were validated using a larger F2 population and PCR markers derived from the single nucleotide polymorphisms within the locus intervals. These markers will be employed to select near-isogenic lines for the two loci and to identify candidate genes in the loci in Z. diploperennis.
Significance Statement Our study contributes to our general understanding of inheritance of perennialism in the higher plants. Previous genetic studies of the perennialism in Zea have yielded contradictory results. We take a reductionist approach by specifically focusing on the plant’s ability to regenerate new shoots after senescence without regard to associated traits, such as rhizome formation, tillering or environmental impacts. Using this criterion, inheritance of perennialism in Zea appears to be dominantly and qualitatively inherited. Importantly, our data indicate that there is no major barrier to transferring this trait into maize or other grass crops for perennial crop development, which enhances sustainability of grain crop production in an environmentally friendly way.