Chromosome-level genome assembly of Lilford's wall lizard, Podarcis lilfordi (Gunther, 1874) from the Balearic Islands (Spain)

The Mediterranean lizard Podarcis lilfordi is an emblematic species of the Balearic Islands. The extensive phenotypic diversity among extant isolated populations makes the species a great insular model system for eco-evolutionary studies, as well as a challenging target for conservation management plans. Here we report the first high-quality chromosome-level assembly and annotation of the P. lilfordi genome, along with its mitogenome, based on a mixed sequencing strategy (10X Genomics linked reads, Oxford Nanopore Technologies long reads and Hi-C scaffolding) coupled with extensive transcriptomic data (Illumina and PacBio). The genome assembly (1.5 Gb) is highly contiguous (N50 = 90 Mb) and complete, with 99% of the sequence assigned to candidate chromosomal sequences and >97% gene completeness. We annotated a total of 25,663 protein-coding genes translating into 38,615 proteins. Comparison to the genome of the related species Podarcis muralis revealed substantial similarity in genome size, annotation metrics, repeat content, and a strong collinearity, despite their evolutionary distance (similar to 18-20 MYA). This genome expands the repertoire of available reptilian genomes and will facilitate the exploration of the molecular and evolutionary processes underlying the extraordinary phenotypic diversity of this insular species, while providing a critical resource for conservation genomics.

Automated summary

This study reports the first high-quality assembly and annotation of the P. lilfordi genome, along with its mitogenome, using a mixed sequencing strategy. The genome assembly is highly contiguous and complete, and the annotation reveals a large number of protein-coding genes. Comparison to a related species showed substantial similarity in genome size, annotation metrics, repeat content, and collinearity. This genome provides a critical resource for studying the molecular and evolutionary processes underlying the phenotypic diversity of this insular species, as well as for conservation genomics.