A molecular and bioinformatic investigation into the phylogenetic relationships and life cycles of amoeboid protists

Tice, Alexander K

07 August 2020

Eukaryotic organisms that cannot be classified as animals, land plants, or fungi are termed protists. Despite the fact that protists represent the majority of eukaryotic diversity, these organisms have received relatively little attention from biological researchers beyond morphological characterization. Reasons that likely contributed to their neglect include their mostly microscopic nature, that only a few lineages are the causative agents of human disease, that laboratory cultivation can be challenging, and that species concepts for the majority of protists was vague in many lineages. Initial attempts to resolve relationships among eukaryotes produced the five kingdoms model. This model suggested protists were an evolutionary assemblage separate from the animals, plants, and fungi. Molecular systematics provided a more accurate view of relationships amongst eukaryotic taxa. Results from molecular phylogenetic studies demonstrated that protists were a polyphyletic group made of many assemblages, and that more complex lineages such as plants and animals were nested within these assemblages. This new evolutionary framework brought increased attention to protists. The application of molecular biology, especially genomic and transcriptomic sequencing to protists has allowed researchers to generate meaningful data on poorly understood lineages rapidly. Applying these techniques to understudied amoeboid protists, I demonstrated the presence of a complex life cycle in a well-studied group of opportunistic pathogens and their close relatives that was not previously known, as well as characterized new diversity within the group. I made methodological advances in the field of molecular systematics through development of a novel ortholog collection algorithm that I have included in a phylogenomic package capable of resolving ancient (>100 million years) divergences in the tree of eukaryotes. I used the algorithm to build the packages accompanying manually curated database of 240 homologs from 304 eukaryotic taxa. Using the newly developed software and manually curated gene set has yielded the most complete and highly resolved tree of eukaryotes to date. Finally, I used developmental transcriptomics to demonstrate the amoeba Copromyxa protea evolved a means of simple cooperative multicellularity independently from other more well studied multicellular lineages.

protistology

evolutionary biology

bioinformatics

multicellular evolution

The genetic basis of cooperative aggregation in the green alga Chlamydomonas reinhardtii

Berger, Christopher Michael

January 1900

Master of Science / Division of Biology / Bradley J. Olson / Unicellular organisms alter their behavior and morphology in response to environmental stresses, particularly in response to immediate threats to their survival. A common tactic of predator avoidance for unicellular green algae is to aggregate to form groups. We have found that the model unicellular green algae Chlamydomonas reinhardtii forms aggregates in response to the presence of the filter feeding zooplanktonic predator, Daphnia magna. Chalmydomonas is a member of the volvocine algae, a morphologically diverse group of closely related green algae that is often used to study multicellular development. We have characterized aggregation in Chlamydomonas reinhardtii and found that it is rapid, transient and induced by signals originating from the Daphnia predators. To understand the genetic basis of cooperative aggregation we used an RNA-seq approach. RNA-seq characterized the transcriptomic response by Chlamydomonas during aggregation, and we identified 131 genes are significantly differentially expressed between predated and unpredated cultures of Chlamydomonas. Several candidate genes were characterized based on existing annotations, evolutionary history and expression profile. Evolutionary relationships between candidate aggregation genes in Chlamydomonas and their orthologs in multicellular Volvocales suggest a possible role of aggregation genes in multicellular development. Our results demonstrate that Chlamydomonas dynamically alters its morphology based on its environment and identify several candidate genes for aggregation and multicellular development.

Chlamydomonas reinhardtii

Daphnia

Cooperative aggregation

Multicellular evolution

Volvocales

Predation