Extensive Novel Genomic Variations in Mutant European Pear Individuals Revealed by Mapping to a Pangenome Reference

European pear (Pyrus communis) is the most widely cultivated Pyrus species outside of Asia; however, production has been declining in Europe, Oceania, and North America. Most European pear cultivars are over 100 years old and face pressure from disease, a changing climate, and challenging postharvest characteristics, while demand for increased production efficiency rises. To generate germplasm with desirable characteristics to address these concerns, a mutation breeding approach was chosen, with crosses made between four economically significant cultivars ( Bartlett, dAnjou, Abbe Fetel, and Comice) using gamma-irradiated pollen. This resulted in 49 viable offspring, of which 37 have survived at least 10 years. Nanopore whole-genome sequencing was used to test the success of this approach and screen for variants of interest. Sequence reads were mapped to both a lightweight, purpose-built pangenome derived from assemblies of parental haplotypes and a linear reference genome, enabling the high-quality discovery of variants of all sizes, ranging from single-base substitutions to megabase-scale deletions, with the overwhelming majority being small variants. The overall rate of mutation was 153 novel small variants and 0.228 novel structural variants per Gray of absorbed gamma radiation. Alternate ploidy levels were detected in four lines, which included three triploids and one tetraploid. While the resulting individuals appear incapable of floral development, they may be of utility as rootstock cultivars and a valuable genetic resource for understanding the underlying basis of structural traits.