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The objective of this study is to create a spectrophotometric assay that can measure quinone reduction in the HbRC. The key techniques used in the project consisted of a PCR, a pseudo golden gate, a transformation into E. coli, a conjugation into Heliomicrobium modesticaldum, a growth study, a HbRC prep, and absorbance spectroscopy. PCR was crucial for amplifying the Cyt c553-PshX gene for the pseudo golden gate. The pseudo golden gate ligated Cyt c553-PshX into the plasmid pMTL86251 in order to transform the plasmid with the desired gene into the E. coli strain S17-1. This E. coli strain allows for conjugation into H. modesticaldum. H. modesticaldum cannot uptake DNA by itself, so the E. coli creates a pilus to transfer the desired plasmid to H. modesticaldum. The growth study was crucial for determining if H. modesitcaldum could be induced using xylose without killing the cells or inhibiting the growth in such a way that the project could not be continued. The HbRC prep was used to isolate and purify the Cyt c553-PshX protein. Absorbance spectroscopy and JTS kinetic assay was used to characterize and confirm that the protein eluted from the affinity column was Cyt c553-PshX. The results of the absorbance spectra and JTS kinetic assay confirmed that Cyt c553-PshX was not made. The study is currently being continued using a new system that utilizes SpyCatcher SpyTag covalent linkages in order to attach cytochrome to reduce P800 to the HbRC.
A mutation rate refers to the frequency at which DNA mutations occur in an organism over time. In organisms, mutations are the ultimate source of genetic variation on which selection may act. However, a large number of mutations over time can be detrimental to the cell. Mutation rates are the frequency at which these new mutations arise over time. This can give great insight into DNA repair mechanisms abilities as well as the mutagenic abilities of selected factors. CRISPR-Cas9 is a powerful tool for genome editing, but its off-target effects are not yet fully understood and studied. With its increasing implementation in science and medicine, it is crucial to understand the mutagenic potential of the tool. S. cerevisiae is a model organism for studying genetics due to its fast growth rate and eukaryotic nature. By integrating CRISPR-Cas9 systems into S. cerevisiae, the mutational burden of the technology can be measured and quantified using fluctuation assays. In this experiment, a fluctuation assay using canavanine selective plates was conducted to determine the mutational burden of CRISPR-Cas9 in S. cerevisiae. Multiple trials revealed that various strains of CRISPR-Cas9 had a mutation rate up to 3-fold higher than that of wild-type S. cerevisiae. This information is essential in improving the precision and safety of CRISPR-Cas9 editing in various applications, including gene therapy and biotechnology.
The purpose of the project is to create a survey that will be sent out to thousands of members of the Global Alliance for Genomics and Health (GA4GH) to update GA4GH's Catalogue of Genomic Data Initiatives online. GA4GH's Catalogue of Genomic Data Initiatives has not been updated in several years, leading to outdated and incorrect information. The survey will be used to gather information from genetic groups worldwide to update and increase the amount of data in the Catalogue on the GA4GH website. The questions were created in collaboration with GA4GH and the Human Pangenome Reference Consortium (HPRC). The actual survey was designed on Qualtrics.