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Related Concept Videos

Heterochromatin02:38

Heterochromatin

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The extent of chromatin compaction can be studied by staining chromatin using specific DNA binding dyes. Under the microscope, the dense-compacted regions that take up more dye are called heterochromatin. Heterochromatin is further classified into two forms – constitutive heterochromatin and facultative heterochromatin.
Constitutive heterochromatin: It is a highly compact region of chromatin that is mostly concentrated in the centromere and telomere. Unlike euchromatin, the amino acid at...
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Euchromatin01:01

Euchromatin

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The extent of chromatin compaction can be studied by staining chromatin using specific DNA binding dyes. Under the microscope, the dense-compacted regions take up more dye, appearing darker, while the less-compact areas take up less dye and appear lighter. Based on the compaction level, chromatins are classified into two primary forms – euchromatin and heterochromatin.
Euchromatin is the less dense region of the chromatin and stains lighter. Euchromatin contains histone H3 extensively...
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Chromatin Immunoprecipitation- ChIP02:36

Chromatin Immunoprecipitation- ChIP

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Chromatin immunoprecipitation, or ChIP, is an antibody-based technique used to identify sites on DNA that bind to transcription factors of interest or histone proteins. It also helps determine the type of histone modifications such as acetylation, phosphorylation, or methylation.
Types of ChIP
ChIP can be divided into two types - X-ChIP and N-ChIP. X-ChIP involves in vivo cross-linking of histones and regulatory proteins to DNA, fragmenting the DNA by sonication, and isolating the protein-DNA...
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Chromatin Modification in iPS Cells01:32

Chromatin Modification in iPS Cells

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Chromatin modification alters gene expression; therefore, scientists can add histone-modifying enzymes, histone variants, and chromatin remodeling complexes to somatic cells to aid reprogramming into pluripotent stem (iPS) cells.
Compact chromatin makes reprogramming difficult. Enzymes, such as histone demethylases and acetyltransferases, are often added during reprogramming to loosen the chromatin, making the DNA more accessible to transcription factors. Molecules that inhibit histone...
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Spreading of Chromatin Modifications02:25

Spreading of Chromatin Modifications

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The histone proteins in the nucleosomes are post-translationally modified (PTM) to increase or decrease access to DNA. The commonly observed PTMs are methylation, acetylation, phosphorylation, and ubiquitination of lysine amino acids in the histone H3 tail region. These histone modifications have specific meaning for the cell. Hence, they are called "histone code". The protein complex involved in histone modification is termed as "reader-writer" complex.
Writers
The writer...
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Updated: Jun 15, 2025

Mapping Genome-wide Accessible Chromatin in Primary Human T Lymphocytes by ATAC-Seq
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MINGLE: a mutual information-based interpretable framework for automatic cell type annotation in single-cell

Siyu Li1, Yifan Huang1, Shengquan Chen2

  • 1School of Mathematical Sciences and LPMC, Nankai University, Tianjin, 300071, China.

Genome Biology
|June 11, 2025
PubMed
Summary
This summary is machine-generated.

MINGLE enhances single-cell chromatin accessibility sequencing (scCAS) analysis by accurately annotating cell types using cellular similarities and topology. This interpretable framework also identifies novel cell types, offering valuable biological insights.

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Area of Science:

  • Genomics
  • Computational Biology
  • Epigenetics

Background:

  • Single-cell chromatin accessibility sequencing (scCAS) is crucial for understanding epigenomic heterogeneity.
  • Existing methods face challenges in accurately annotating diverse cell types, especially rare or novel ones.

Purpose of the Study:

  • To introduce MINGLE, an interpretable framework for accurate cell type annotation of scCAS data.
  • To develop a novel strategy for identifying previously undiscovered cell types within scCAS datasets.
  • To enhance the biological insights derived from scCAS data analysis.

Main Methods:

  • Developed MINGLE, a mutual information-based framework leveraging cellular similarities and topological structures.
  • Implemented a convex hull-based strategy for novel cell type identification.
  • Conducted extensive experiments to evaluate MINGLE's performance against existing methods.

Main Results:

  • MINGLE demonstrates superior cell type annotation accuracy, particularly for rare and novel cell types.
  • The framework provides valuable biological insights, outperforming current annotation tools.
  • MINGLE exhibits robustness and versatility across cross-batch, cross-tissue, and cross-species datasets, handling data imbalance and size variations effectively.

Conclusions:

  • MINGLE offers a versatile and accurate solution for complex cell type annotation tasks in scCAS data.
  • The framework's ability to identify novel cell types opens new avenues for biological discovery.
  • MINGLE's performance across diverse data scenarios underscores its broad applicability in epigenomic research.