Abstract
Salix, an economically and ecologically multifunctional tree species widely distributed in China, encompasses five ornamental species sequenced in this study, which are highly beneficial for plant phytoremediation due to their ability to absorb heavy metals. This research utilized high-throughput sequencing to acquire chloroplast genome sequences of Salix, analyzing their gene composition and structural characteristics, identifying potential molecular markers, and laying a foundation for Salix identification and resource classification. Chloroplast DNA was extracted from the leaves of Salix argyracea, Salix dasyclados, Salix eriocephala, Salix integra 'Hakuro Nishiki', and Salix suchowensis using an optimized CTAB method. Sequencing was conducted on the Illumina NovaSeq PE150 platform, and bioinformatics tools were employed to compare the structural features and variations within the chloroplast genomes of the Salix. Analysis revealed high similarity among the chloroplast genome sequences of the five Salix species, with a subsequent examination identifying 276, 269, 270, 273, and 273 SSR loci, respectively, along with unique simple repeat sequences in each variety. Comparison of chloroplast genomes across 22 Salix highlighted variations in regions such as matK-trnQ, ndhC-trnV, psbE-petL, rpl36-rps8, and ndhB-rps7, which may serve as valuable molecular markers for willow resource classification studies. In this study, chloroplast genome sequencing and structural analysis of Salix not only enhances the genetic resources of Salix but also forms a critical basis for the development of molecular markers and the exploration of interspecific phylogeny in the genus.