Critical unanswered questions in the field of genome biology are how the dynamics of chromatin folding shape gene expression patterns. Our knowledge of the dynamics of higher-order 3-D folding of chromatin is severely limited, largely due to the lack of technologies to precisely image, engineer and monitor looping in a precise spatiotemporal manner across a population of cells. Here we propose to address these limitations by developing tools to dynamically alter chromatin folding in a synchronous manner across populations of cells as well as individual cells, and measure chromatin looping and its relationship to transcription at high spatial resolution in single cells.
In Specific Aim 1 we will design tools to control looping dynamics. We will modify factors that fold chromatin at various levels, such as Ldb1 and CTCF by fusion to a moiety whose stability can be controlled by diffusible ligands. In combination with hi resolution 5C and single molecule imaging these tools are expected to generate fundamental insights into the relationship of nuclear architecture and gene expression mechanisms.
In Specific Aim 2 we plan to engineer light-inducible systems for the precise control of looping dynamics. Using light activated dimerization domains that can be used in conjunction with designer DNA binding proteins we attempt to engineer factors used to rapidly promote or disrupt chromatin looping at various scales. This technology should enable studies not only in populations but also at the single cell level.
In Specific Aim 3 : we will develp reagents to study the transcriptional dynamics in relation to looping at the single cell level. We will combine RNA FISH with super-resolution imaging to develop a methodology for exploring the spatial and temporal structure of nascent transcription at high resolution. Combined with high-throughput image acquisition, we will discriminate the temporal dynamics of transcription by measuring the relative intensities arising from the different parts of the transcript. We will employ super-resolution imaging (STORM) to measure the spatial structure of transcription sites. These experiments are expected to reveal the impact of forced chromatin looping on distinct stages of the transcription cycle and elucidate the relationship between transcriptional burst kinetics and physical gene structure.

Public Health Relevance

This application seeks to develop new tools that explore the function of higher order chromatin folding in gene regulation. We combine the design of highly dynamically controllable looping factors with high resolution 5C experimentation and single molecule imaging to provide the field with reagents to study the impact of chromatin folding and nuclear compartmentalization on diverse processes, including transcription activation and repression.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project--Cooperative Agreements (U01)
Project #
1U01HL129998-01
Application #
9003449
Study Section
Special Emphasis Panel (ZRG1-CB-D (50))
Program Officer
Postow, Lisa
Project Start
2015-09-15
Project End
2020-07-31
Budget Start
2015-09-15
Budget End
2016-07-31
Support Year
1
Fiscal Year
2015
Total Cost
$754,986
Indirect Cost
$184,161
Name
University of Pennsylvania
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
042250712
City
Philadelphia
State
PA
Country
United States
Zip Code
19104
Norton, Heidi K; Emerson, Daniel J; Huang, Harvey et al. (2018) Detecting hierarchical genome folding with network modularity. Nat Methods 15:119-122
Kim, Ji Hun; Titus, Katelyn R; Gong, Wanfeng et al. (2018) 5C-ID: Increased resolution Chromosome-Conformation-Capture-Carbon-Copy with in situ 3C and double alternating primer design. Methods 142:39-46
Torre, Eduardo; Dueck, Hannah; Shaffer, Sydney et al. (2018) Rare Cell Detection by Single-Cell RNA Sequencing as Guided by Single-Molecule RNA FISH. Cell Syst 6:171-179.e5
Rouhanifard, Sara H; Mellis, Ian A; Dunagin, Margaret et al. (2018) ClampFISH detects individual nucleic acid molecules using click chemistry-based amplification. Nat Biotechnol :
Huang, Mo; Wang, Jingshu; Torre, Eduardo et al. (2018) SAVER: gene expression recovery for single-cell RNA sequencing. Nat Methods 15:539-542
Bartman, Caroline R; Hamagami, Nicole; Keller, Cheryl A et al. (2018) Transcriptional Burst Initiation and Polymerase Pause Release Are Key Control Points of Transcriptional Regulation. Mol Cell :
Sun, James H; Zhou, Linda; Emerson, Daniel J et al. (2018) Disease-Associated Short Tandem Repeats Co-localize with Chromatin Domain Boundaries. Cell 175:224-238.e15
Norton, Heidi K; Phillips-Cremins, Jennifer E (2017) Crossed wires: 3D genome misfolding in human disease. J Cell Biol 216:3441-3452
Huang, Peng; Keller, Cheryl A; Giardine, Belinda et al. (2017) Comparative analysis of three-dimensional chromosomal architecture identifies a novel fetal hemoglobin regulatory element. Genes Dev 31:1704-1713
Ko, Jina; Bhagwat, Neha; Yee, Stephanie S et al. (2017) A magnetic micropore chip for rapid (<1 hour) unbiased circulating tumor cell isolation and in situ RNA analysis. Lab Chip 17:3086-3096

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