Does the globally invasive marine angiosperm, Halophila stipulacea, have high genetic diversity or unique mutations?

Seagrasses are important primary producers in many marine ecosystems, and support a wide diversity of marine life. However, invasive seagrasses like Halophila stipulacea can have pronounced negative impacts on an ecosystem by displacing native seagrasses and changing the community composition of the reef. Endemic to the Red Sea, Persian Gulf and Indian Ocean, Halophila stipulacea has become invasive in the Mediterranean and Caribbean Seas, presumably as a result of the opening of the Suez Canal and international ship traffic. However, it is unclear why this marine angiosperm has become invasive in parts of its range and not others. It is hypothesized that invasive forms may have evolved rapidly in response to natural selection in new and novel environments. Alternatively, genetic variation of introduced populations may be uniquely suited to thrive in regions where it is invasive. In this study, we use RAD next-generation sequencing to screen thousands of SNPs to investigate the genetic basis of adaptation in both native and invasive populations. We test whether genes under selection in the native range are the same as in the invasive range, or whether new genes have arisen with the invasion of each marine basin. The comparison of SNP frequencies unique among basins and environmental variables will aid in predicting new areas of invasion, assisting in improved management strategies to combat this invasive seagrass.