A gap-free tomato genome built from complementary PacBio and Nanopore long DNA sequences reveals extensive linkage drag during breeding

Abstract

The assembly and scaffolding of plant crop genomes facilitates the characterization of genetically diverse cultivated and wild germplasm. The cultivated tomato has been improved through the introgression of genetic material from related wild species, including resistance to pandemic strains of Tobacco Mosaic virus (TMV) from Solanum peruvianum. Here we applied PacBio HiFi and ONT nanopore sequencing to develop independent, highly contiguous and complementary assemblies of an inbred TMV-resistant tomato variety. We merged the HiFi and ONT assemblies to generate a long-read-only assembly where all twelve chromosomes were represented as twelve contiguous sequences (N50=68.5 Mbp). The merged assembly was validated by chromosome conformation capture data and is highly consistent with previous tomato assemblies that made use of genetic maps and HiC for scaffolding. Our long-read-only assembly reveals that a complex series of structural variants linked to the TMV resistance gene likely contributed to linkage drag of a 64.1 Mbp region of the S. peruvianum genome during tomato breeding. We show that this minimal introgression region is present in six cultivated tomato hybrid varieties developed in three commercial breeding programs. Our results suggest that complementary long read technologies can facilitate the rapid generation of near complete genome sequences.