Incorporating Molecular Data in the Taxonomic Study of Diatoms: An Example Using Two Wellknown Genera, Frustulia and Navicula S.S. (Bacillariophyceae, Naviculales)

• Main Author: Bouchard, Andréanne
• Other Authors: Starr, Julian
• Format: Others
• Language: en
• Published: Université d'Ottawa / University of Ottawa 2021
• Subjects: Systematics; Diatom; Navicula; Frustulia; rbcL; atpB; 18S
• Online Access: http://hdl.handle.net/10393/42387; http://dx.doi.org/10.20381/ruor-26609

Diatoms are crucially important to the global ecosystem due to their role in regulating the world’s carbon and silicon cycles, and their production of large amounts of organic material in aquatic environments. They are thought to comprise ca. 100,000 species, although some estimates suggest that there could be over a million. Despite their importance and high species diversity, little is known about their phylogeny due to technical issues that hinder the reconstruction of their relationships. However, owing to a new technique that allows for DNA to be amplified from a single isolated cell, it is possible to explore diatom relationships with extensive taxonomic sampling. This thesis aims to demonstrate that the integration of molecular data and morphological characters can provide a new paradigm for future phylogenetic and taxonomic studies of diatoms, especially among closely related and taxonomically complex groups. To achieve this, I examined common species from two naviculoid diatom genera, Frustulia and Navicula using sequence data from three molecular markers (rbcL, atpB, 18S), traditional and fine-scale morphological characters, and frustule shape. The molecular markers rbcL and atpB evolved at a similar rate and performed well at reconstructing species-level phylogenies, whereas 18S was more conserved and best used for resolving relationships at higher taxonomic levels. Hidden diversity was uncovered in what have traditionally been thought as well-circumscribed taxa, and three new species were described. The methods used here show promise for the future of diatom systematics.