PROJECT SUMMARY/ABSTRACT
Chromosomes are copied by a complex holoenzyme called the replisome. Obstacles are routinely negotiated
by the replisome with auxiliary mechanisms that ensure genomic integrity, aberrance of which can lead to
chromosome instability and a broad range of diseases including cancer. The candidate’s long term goal is to
understand the molecular basis for genetic and epigenetic fidelity, with the potential to improve the treatment
and/or prevention of disease. In this proposal, the candidate will use a fully functional replisome reconstituted
from over 30 pure polypeptides to study how replisomes bypass obstacles that regularly occur in the genome
while enforcing genetic and epigenetic integrity across generations. In the first specific aim the candidate’s
current work on the molecular mechanisms of lesion bypass by the replisome will be elaborated, with a focus
on how checkpoint kinases Mec1 and Rad53 and the Mrc1/Tof1/Csm3 (MTC) complex modify the activity of
the replisome while regulating lesion bypass. Interactions between several key replisome components and the
MTC complex will be probed by microscale thermophoresis (MST) and cross-linking mass spectrometry (XL-
MS). In addition to biochemical experiments, single-molecule approaches will be used to probe the mechanism
of replisome regulation by the MTC complex, resolving replisome components with fluorescence during active
replication on DNA. Single-molecule FRET experiments will be used in the independent phase to probe how
MTC affects the structural dynamics of the replisome. In the second aim, the candidate will investigate
nucleosome bypass by the replisome, focusing on the post-replication fate of histones during the mentored
phase. Using histones enriched for fluorescence, replication-coupled histone deposition will be tracked by a
first-of-its-kind attempt at spatially resolving leading vs. lagging strand products with a combination of optical
trapping, fluorescence, and flow. Along with bead-based biochemical experiments, the results will help
differentiate between models of epigenetic inheritance. In the independent phase, interactions between the
replisome and FACT, a histone chaperone, will be determined with MST and XL-MS. The molecular
mechanisms of various chaperones will be probed using single-molecule FRET experiments monitoring the
spatiokinetics of chromatin remodeling in real time, also determining the role of histone modifications in
remodeling. The mentored phase of the project will be conducted in the laboratories of Dr. Michael O’Donnell
(mentor) and Dr. Shixin Liu (co-mentor) at Rockefeller University, a world-class research environment. The
success of the candidate’s proposed research depends critically on using advanced integrative single-molecule
techniques, as well as XL-MS. Thus, the candidate seeks intensive training with manipulation and detection of
individual molecules in the co-mentor’s state-of-the-art facilities, in addition to XL-MS with Drs. Brian Chait and
Yi Shi (collaborators). The candidate also has also planned activities to improve mentoring, lab management,
scientific communication, and professional skills, enabling a successful transition to an independent career.