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In partial fulfillment of the requirements for the degree of
Master of Science in Biology
in the
School of Biological Sciences
Jessica Pfliger
Will defend her thesis
“CHARACTERIZATION OF A CHROMATINIZED HYDROGEN PEROXIDE BIOSENSOR IN CANCER CELLS”
14, February 2022
1:00pm
https://bluejeans.com/126058378
Thesis Advisor:
Dr. Yuhong Fan
School of Biological Sciences
Georgia Institute of Technology
Committee Members:
Dr. Alfred Merrill
School of Biological Sciences
Georgia Institute of Technology
Dr. Hengbin Wang
Department of Biochemistry and Molecular Genetics
School of Medicine
University of Alabama at Birmingham
Abstract:
Hydrogen Peroxide (H2O2) is an important eukaryotic signaling molecule regulating cellular processes. As one of the most abundant reactive oxidative species (ROS), H2O2 can cause oxidative stress and cytotoxicity at elevated concentrations leading to DNA damage and programmed cell death. Despite the recent advancements in modulating ROS responses for potential cancer therapies, little is known about nuclear ROS temporal emergence and dynamics. To investigate the role of nuclear ROS and H2O2 in chromatin, we established a genetically engineered chromatin-targeted biosensor for H2O2, H2B-HyPer, by fusion of HyPer, a specific H2O2 biosensor, with core histone H2B. In this thesis, I utilized fluorescent microscopy and fluorescent recovery after photobleaching (FRAP) to study the H2O2 dynamics within the chromatin of HCT116 colon cancer cells containing genetically integrated H2B-HyPer. I demonstrate that H2B-HyPer is localized in the nucleus of HCT116/H2B-HyPer cells with an average residence time and mobile fraction of 9.14 minutes and 20.59%, respectively, comparable to the core histones in chromatin. I then show that H2B-HyPer is sensitive to changes in H2O2 levels post addition of H2O2 or DTT in culture medium. Further analysis of H2B-HyPer kinetics revealed a rapid increase and recovery of H2B-HyPer signal intensity in HCT116/H2B-HyPer cells upon treatment with and the removal of H2O2. Altogether, these studies establish H2B-HyPer as an effective biosensor for real-time spatio-temporal tracking of chromatin-proximal H2O2 dynamics.
