Ppd-1Remodels Spike Architecture by Regulating Floral Development in wheat

AbstractThe determination of spike architecture is critical to grain yield in wheat (Triticum aestivum), yet the underlying mechanisms remain largely unknown. Here, we measured 51 traits associated with spike architecture and floral development in 197 wheat accessions with photoperiod sensitive and insensitive alleles. We included five distinct allele combinations at thePhotoperiod-1(Ppd-1) loci. A systematic dissection of all recorded phenotypes revealed connections between floral development, spike architecture and grain yield. Modifying the durations of spikelet primordia initiation did not necessarily affect spikelet number. In addition,Ppd-1loci clearly influenced rachis dry weight, pointing to the rachis vascular system as a potential target for higher yield.Ppd-1displayed opposite effects on the durations of pre and post-anthesis phases.Ppd-1controlled carpel size, but not anther size. Finally, the photoperiod-insensitive alleles ofPpd-1triggered floral degeneration. In parallel, we profiled the spike transcriptome at six stages and four positions in threePpd-1genotypes which consists of 234 samples. Integrating phenotypic and expression data suggested that loss of function inPpd-1loci delayed floral degeneration by regulating autophagy and extended floret development by regulating genes in different families. Therefore, we concluded thatPpd-1remodels spike architecture by regulating floral development in wheat.