Almost since the creation of the genus Euglena (Ehrenberg), the taxa assigned to it have been separated, split apart, and reorganized into new genera based on morphological relationships, resulting in the creation of the genera Phacus (Dujardin), Lepocinclis (Perty), Astasia (Pringsheim), and Khawkinea ( Jahn and McKibben) based on intuitive methods. In an effort to assess the validity of these genera, we have used small subunit (SSU) rDNA data to generate a phylogenetic framework for these genera, with particular attention to the genus Euglena. Using the conserved sequence areas, we performed a phylogenetic analysis using parsimony, maximum likelihood, and distance methods. These different criteria have resulted in trees of the same topology. The euglenoid clade was composed of phagotrophic euglenoids at the base, which gave rise to phototrophs that in turn gave rise to osmotrophs. Among the photosynthetic taxa, the biflagellate form diverged prior to the uniflagellate form. Additionally, the need for a revision in the taxonomy of some of these genera was demonstrated. Currently, taxa from the photosynthetic genera Euglena, Phacus, and Lepocinclis do not form monophyletic clades, but are intermixed with each other as well as with the osmotrophic taxa, Astasia and Khawkinea.
Small subunit rDNA sequences of 42 taxa belonging to 10 genera were used to infer phylogenetic relationships among euglenoids. Members of the phototrophic genera Euglena, Phacus, Lepocinclis, Colacium, Trachelomonas, and Strombomonas plus the osmotrophs Astasia longa, Khawkinea quartana, and Hyalophacus ocellatus were included. Six major clades were found in most trees using multiple methods. The utility of Bayesian analyses in resolving these clades is demonstrated. The genus Phacus was polyphyletic with taxa sorting into two main clades. The two clades correlated with overall morphology and corresponded in large part to the previously defined sections, Pleur‐ aspis Pochmann and Proterophacus Pochmann. Euglena was also polyphyletic and split into two clades. In Bayesian analyses species with less plastic pellicles and small disk‐like chloroplasts diverged at the base of the tree. They grouped into a single clade which included the two Lepocinclis spp., which also are rigid and bear similar chloroplasts. The metabolic Euglena species with larger plastids bearing pyrenoids and paramylon caps arose near the top of the tree. The loricates Strombomonas and Trachelomonas formed two well‐ supported, but paraphyletic, clades. The strong support for the individual clades confirmed the value of using lorica features as taxonomic criteria. The separation of the osmotrophic species A. longa, K. quartana, and H. ocellatus into different clades suggested that the loss of the photosynthetic ability has occurred multiple times.
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