Filtering by
- Creators: Barrett, The Honors College
- Creators: Scotch, Matthew
Our bodies are constantly fighting off viral pathogens both with our external barriers such as skin as well as internally through the immune system. Mucin genes specifically Muc5AC and Muc5B help assist in this process by activating both bacterial and mucus pathogenesis. Their gene expression is correlated with temperature meaning that in warmer temperatures they have decreased expression. Developing a better understanding of their functionality as well as their expression can help species that are in danger of becoming extinct.
Oxymonas is a genus of Oxymonad protist found in the hindgut of drywood termites (family Kalotermitidae). Many genera of drywood termites are invasive pests globally. The hindgut microbiome of Cryptotermes brevis, the West Indian drywood termite, has not been described in detail, and only one published sequence exists of Oxymonas from C. brevis. This study aims to analyze Oxymonas sequences in C. brevis from whole gut genetic material, as well as to dissect its place in phylogenetic trees of Oxymonas and how it fits into specific and evolutionary patterns. To amplify the 18S rRNA gene Oxymonas from C. brevis, the MasterPure DNA extraction kit was used, followed by PCR amplification, followed by agarose gel electrophoresis, followed by purification of the resulting gel bands, followed by ligation/transformation on to an LB agar plate, followed by cloning the resulting bacterial colonies, and topped off by colony screening. The colony screening PCR products were then sequenced in the Genomics Core, assembled in Geneious, aligned and trimmed into a phylogenetic tree, along with several long-read amplicon sequences from Oxymonas in other drywood termites. All whole gut sequences and one amplicon from C. brevis formed a single clade, sharing an ancestor with a sister clade of Oxymonas sp. from C. cavifrons and Procryptotermes leewardensis, but the other long-read fell into its own clade in a different spot on the tree. It can be conjectured that the latter sequence was contaminated and that the C. brevis clones are a monophyletic group, a notion further corroborated by a distantly related clade featuring sequences from Cryptotermes dudleyi, which in turn has a sister taxon of Oxymonas clones from C. cavifrons and P. leewardensis, pointing toward a different kind of co-diversification of the hosts and symbionts rather than cospeciation.
The symbiosis between termites and their parabasalid hindgut protists centers around the wood digestion that is needed for both species to acquire the nutrients from wood. One of the important carbohydrate-active proteins required for the wood breakdown are glycoside hydrolase (GH) families. Previous studies have looked at the phylogeny of some of these protein families from a termite whole gut transcriptome or in a different context than lignocellulose digestion. In this study, we attempt to understand the function and evolution of these GH families in the context of protist evolution by using protist single cell transcriptomes. 14 families of interest were chosen to create phylogenetic trees: GH2, GH3, GH5, GH7, GH8, GH9, GH10, GH11, GH26, GH43, GH45, GH55, GH67, GH95 for their interesting expressions across different protists such as being present in all protists or being present in only termite-associated protists. The dbCAN2 (automated Carbohydrate-active enzyme ANnotation) program was used to find GH families in each of the protist single cell transcriptomes and additional characterized sequences registered on the National Center for Biotechnology Information to create phylogenetic trees for each of the GH families of interest. Results show that many of the GH families expressed in protists were acquired through horizontal gene transfer from fungi and bacteria. Additionally, comparison to the parabasalid phylogeny indicates most GH families evolved independently from the protists. Based on the pattern of expression of these GH families throughout different protist orders, conclusions can be made about whether the specific family was vertically or horizontally acquired in the termite symbionts.
Cells have mechanisms in place to maintain the specific lipid composition of distinct organelles including vesicular transport by the endomembrane system and non-vesicular lipid transport by lipid transport proteins. Oxysterol Binding Proteins (OSBPs) are a family of lipid transport proteins that transfer lipids at various membrane contact sites (MCSs). OSBPs have been extensively investigated in human and yeast cells where twelve have been identified in Homo sapiens and seven in Saccharomyces cerevisiae. The evolutionary relationship between these well-characterized OSBPs is still unclear. Reconstructed OSBP phylogenies revealed that the ancestral Saccharomycotinan had four OSBPs, the ancestral Holomycotan had five OSBPs, the ancestral Holozoan had six OSBPs, the ancestral Opisthokont had three OSBPs, and the ancestral Eukaroyte had three OSBPs. Our analysis identified three clades of ancient OSBPs not present in animals or fungi.