MCB 182 Lecture 10.6 - Topologically associated domains (TADs), A/B compartments
MCB 182 Lecture 10.8 - Choosing 3C assay, genome assembly with Hi-C
MCB 182 Lecture 10.4 - Chromatin conformation capture (Hi-C) assays
MCB 182 Lecture 10.2 - DamID for mapping protein-DNA interactions
MCB 182 Lecture 10.5 - Visualization of Hi-C data, bias in the Hi-C assay
MCB 182 Lecture 10.7 - Chromatin looping, loop extrusion model
MCB 182 Lecture 10.3 - Chromatin conformation capture (3C, 4C) assays
Introduction to Regulatory Genomics and Epigenomics I: Intro to the Biology of Gene Regulation
Aberrant CTCF binding facilitates oncogenic transcriptional dysregulation in cancer
Bioinformatics for the 3D Genome: An Introduction to Analyzing and Interpreting Hi-C Data
Chromosome territories LADs TADs MARs part1
Polycomb Group Complexes Collaborate at Multiple Levels to Repress Transcription
BIO415 Developmental Biology Lec1 Muhammad Shoaib
Molecular Biology Lecture 58 | Chromatin Remodeling Part-6 | Euchromatization | Heterochromatization
DNA Loops Drive Digit Development
Functional organisation of the genome in 3D by Dr Stefan Schoenfelder
CTCF story
Endoluminal Therapies in Bariatric Surgery by Matthew Kroh
Multiscale and integrative single-cell Hi-C analysis
Cryo-Milling TCC-Based Mapping of Genome-Wide Chromatin Contacts
