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Epigenomics: Technologies and Applications.

Kevin C Wang1, Howard Y Chang2,3

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Summary
This summary is machine-generated.

High-throughput epigenome mapping and multiomics reveal cellular heterogeneity and molecular connections. These advancements enhance understanding of cell fate, identity, and function in health and disease.

Keywords:
chromatinepigenomicsgenomicshumans

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Area of Science:

  • Genomics and Molecular Biology
  • Epigenetics and Chromatin Biology

Background:

  • High-throughput epigenome mapping technologies enable multiomics data generation.
  • Multiomics integration allows for detailed analysis of genomic output layers.
  • Understanding the epigenome is crucial for deciphering cellular complexity.

Purpose of the Study:

  • To provide a perspective on the progress and applications in the field of epigenomics.
  • To highlight the role of multiomics in understanding cellular heterogeneity and molecular connectivity.
  • To anticipate future revolutions in human epigenome research.

Main Methods:

  • Utilizing high-throughput epigenome mapping technologies.
  • Integrating multiomics measurements of various epigenome components.
  • Mapping chromatin accessibility dynamics and higher-order chromatin structure.

Main Results:

  • Delineation and recording of different layers of genomic output.
  • Interrogation of cellular heterogeneity through multiomics integration.
  • Discovery of molecular connectivity maps between the genome and its functional output.
  • New insights into cell fate decisions, identity, and function.

Conclusions:

  • Epigenomics and multiomics have revolutionized the understanding of cellular processes.
  • Mapping chromatin dynamics provides critical insights into normal development and disease.
  • Future advancements promise a deeper understanding of the human epigenome.