De novogenome assembly and transcriptome analysis for the drought and salt resistantSolanum sitiens

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This study presents a high-quality 1,245 Mbp <i>de novo</i> genome assembly and transcriptome analysis for the drought and salt-resistant wild tomato relative <i>Solanum sitiens</i>, identifying genetic variations and unique genes associated with stress resistance.

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Abstract

Solanum sitiens is a self-incompatible wild relative of tomato, characterised by salt and drought resistance traits, with the potential to contribute to crop improvement in cultivated tomato. This species has a distinct morphology, classification and ecotype compared to other stress resistant wild tomato relatives such as S. pennellii and S. chilense . Therefore, the availability of a high-quality reference genome for S. sitiens will facilitate the genetic and molecular understanding of salt and drought resistance. Here, we present a de novo genome and transcriptome assembly for S. sitiens (Accession LA1974). A hybrid assembly strategy was followed using Illumina short reads (∼159X coverage) and PacBio long reads (∼44X coverage), generating a total of ∼262 Gbp of DNA sequence; in addition, ∼2,670 Gbp of BioNano data was obtained. A reference genome of 1,245 Mbp, arranged in 1,481 scaffolds with a N50 of 1,826 Mbp was generated. Genome completeness was estimated at 95% using the Benchmarking Universal Single-Copy Orthologs (BUSCO) and the K-mer Analysis Tool (KAT); this is within the range of current high-quality reference genomes for other tomato wild relatives. Additionally, we identified three large inversions compared to S. lycopersicum , containing several drought resistance related genes, such as beta-amylase 1 and YUCCA7 . In addition, ∼63 Gbp of RNA-Seq were generated to support the prediction of 31,164 genes from the assembly, and perform a de novo transcriptome. Some of the protein clusters unique to S. sitiens were associated with genes involved in drought and salt resistance, including GLO1 and FQR1 . This first reference genome for S. sitiens will provide a valuable resource to progress QTL studies to the gene level, and will assist molecular breeding to improve crop production in water-limited environments.

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europepmc
last seen: 2026-05-19T01:45:01.086888+00:00
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License: CC-BY-4.0