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Histone Modification02:32

Histone Modification

The histone proteins have a flexible N-terminal tail extending out from the nucleosome. These histone tails are often subjected to post-translational modifications such as acetylation, methylation, phosphorylation, and ubiquitination. Particular combinations of these modifications form “histone codes” that influence the chromatin folding and tissue-specific gene expression.
Acetylation
The enzyme histone acetyltransferase adds acetyl group to the histones. Another enzyme, histone deacetylase,...
Histone Modification02:32

Histone Modification

The histone proteins have a flexible N-terminal tail extending out from the nucleosome. These histone tails are often subjected to post-translational modifications such as acetylation, methylation, phosphorylation, and ubiquitination. Particular combinations of these modifications form “histone codes” that influence the chromatin folding and tissue-specific gene expression.
Acetylation
The enzyme histone acetyltransferase adds acetyl group to the histones. Another enzyme, histone deacetylase,...
Spreading of Chromatin Modifications02:25

Spreading of Chromatin Modifications

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 is an enzyme that can...
Covalently Linked Protein Regulators02:04

Covalently Linked Protein Regulators

Proteins can undergo many types of post-translational modifications, often in response to changes in their environment. These modifications play an important role in the function and stability of these proteins. Covalently linked molecules include functional groups, such as methyl, acetyl, and phosphate groups, and also small proteins, such as ubiquitin. There are around 200 different types of covalent regulators that have been identified.
These groups modify specific amino acids in a protein.
The Nucleosome Core Particle01:12

The Nucleosome Core Particle

Nucleosomes are the DNA-histone complex, where the DNA strand is wound around the histone core. The histone core is an octamer containing two copies of H2A, H2B, H3, and H4 histone proteins.
Nucleosomes, paradoxically, perform two opposite functions simultaneously. On the one hand, their primary aim is to protect the delicate DNA strands from physical damage and help achieve a higher compaction ratio. On the other hand, they must allow polymerase enzymes to access histone-bound DNA during...
The Nucleosome Core Particle02:10

The Nucleosome Core Particle

Nucleosomes are the DNA-histone complex, where the DNA strand is wound around the histone core. The histone core is an octamer containing two copies of H2A, H2B, H3, and H4 histone proteins.
The paradox
Nucleosomes, paradoxically, perform two opposite functions simultaneously. On the one hand, their main responsibility is to protect the delicate DNA strands from physical damage and help achieve a higher compaction ratio. While on the other hand, they must allow polymerase enzymes to access DNA...

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Related Experiment Video

Updated: Jun 25, 2026

Purification of H3 and H4 Histone Proteins and the Quantification of Acetylated Histone Marks in Cells and Brain Tissue
09:43

Purification of H3 and H4 Histone Proteins and the Quantification of Acetylated Histone Marks in Cells and Brain Tissue

Published on: November 30, 2018

Histone acetylation: truth of consequences?

Jennifer K Choi1, Leann J Howe

  • 1Department of Biochemistry and Molecular Biology, University of British Columbia, 2350 Health Sciences Mall, Vancouver, BCV6T1Z3, Canada.

Biochemistry and Cell Biology = Biochimie Et Biologie Cellulaire
|February 24, 2009
PubMed
Summary

Histone acetylation, a key epigenetic modification, influences gene transcription by altering chromatin structure or recruiting protein complexes. Further research is needed to fully understand its biochemical mechanisms and downstream effects.

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Purification of H3 and H4 Histone Proteins and the Quantification of Acetylated Histone Marks in Cells and Brain Tissue
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Area of Science:

  • Epigenetics
  • Molecular Biology
  • Biochemistry

Background:

  • Eukaryotic DNA is organized into chromatin, a dynamic nucleoprotein structure.
  • Histone modifications, particularly acetylation, are crucial for regulating chromatin architecture and gene transcription.
  • Histone acetylation has been known since 1964 but its precise biochemical mechanisms remain unclear.

Purpose of the Study:

  • To review current research on the proposed roles of histone acetylation.
  • To clarify the known functions of histone acetylation in gene regulation.
  • To elucidate the biochemical mechanisms underlying histone acetylation's effects.

Main Methods:

  • Literature review of recent research on histone acetylation.
  • Analysis of proposed mechanisms of histone acetylation.
  • Synthesis of current knowledge on histone acetylation's function.

Main Results:

  • Histone acetylation is proposed to function in two ways: altering chromatin structure directly or serving as a tag for recruiting other complexes.
  • Evidence suggests histone acetylation plays a significant role in transcription.
  • The exact biochemical mechanisms of histone acetylation's downstream effects require further investigation.

Conclusions:

  • Histone acetylation is a vital epigenetic mechanism influencing chromatin dynamics and gene expression.
  • Two primary models explain histone acetylation's function: direct structural changes and recruitment of effector proteins.
  • Further research is essential to fully elucidate the biochemical underpinnings of histone acetylation's role in cellular processes.