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関連する概念動画

Chromatin Packaging01:32

Chromatin Packaging

19.8K
Each human somatic cell contains 6 billion base pairs of DNA. Each base pair is 0.34 nm long, meaning each diploid cell contains a staggering 2 meters of DNA. This long DNA strand is packed inside a nucleus measuring only 10-20 microns in diameter with the help of specialized DNA-binding proteins called histones. Together they form a compact DNA-protein complex called chromatin. The chromatin is further compacted into higher-order structures. The highest level of compaction is achieved during...
19.8K
Chromatin Packaging02:21

Chromatin Packaging

22.5K
Each human somatic cell contains 6 billion base-pairs of DNA. Each base-pair is 0.34 nm long, which means that each diploid cell contains a staggering 2 meters of DNA. How is such a long DNA strand packed inside a nucleus measuring only 10 - 20 microns in diameter? 
The chromatin
In combination with specialized DNA binding protein called Histones, the DNA double helix forms a compact DNA: protein complex called chromatin. The chromatin itself is further compacted into higher-order...
22.5K
The Nucleosome Core Particle01:12

The Nucleosome Core Particle

2.5K
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...
2.5K
The Nucleosome Core Particle02:10

The Nucleosome Core Particle

14.7K
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...
14.7K
Nucleosome Remodeling02:54

Nucleosome Remodeling

11.3K
Nucleosomes are the basic units of chromatin compaction. Each nucleosome consists of the DNA bound tightly around a histone core, which makes the DNA inaccessible to DNA binding proteins such as DNA polymerase and RNA polymerase. Hence, the fundamental problem is to ensure access to DNA when appropriate, despite the compact and protective chromatin structure.
Nucleosome remodeling complex
Eukaryotic cells have specialized enzymes called ATP-dependent nucleosome remodeling enzymes. These enzymes...
11.3K
The Nucleosome02:33

The Nucleosome

19.2K
DNA in a human cell is almost 2m long and it is packed inside a tiny nucleus that is only a few microns in diameter. The level of compaction of DNA inside the nucleus is astonishing. It is organized into several sequentially higher levels of compaction to fit into such a tiny space. The most compact form of DNA is a chromosome that can be seen under a microscope in a dividing cell.
DNA is wound twice around a protein complex called histone core, that consist of 8 histone proteins. This complex...
19.2K

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3D Multicolor DNA FISH Tool to Study Nuclear Architecture in Human Primary Cells
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3D Multicolor DNA FISH Tool to Study Nuclear Architecture in Human Primary Cells

Published on: January 25, 2020

11.0K

4Dヌクレオームプロジェクト

Job Dekker1, Andrew S Belmont2, Mitchell Guttman3

  • 1Program in Systems Biology, Department of Biochemistry and Molecular Pharmacology, University of Massachusetts Medical School, Howard Hughes Medical Institute, Worcester, Massachusetts 01605, USA.

Nature
|September 15, 2017
PubMed
まとめ
この要約は機械生成です。

ゲノム構造とダイナミクスを 3次元空間と時間とともにマッピングしています この研究は,核の組織と遺伝子調節におけるその役割に関する機械的洞察を提供します.

さらに関連する動画

Capturing Chromosome Conformation Across Length Scales
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Capturing Chromosome Conformation Across Length Scales

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Mapping Absolute DNA Density in Cell Nuclei using Single-molecule Localization Microscopy
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Mapping Absolute DNA Density in Cell Nuclei using Single-molecule Localization Microscopy

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関連する実験動画

Last Updated: Feb 22, 2026

3D Multicolor DNA FISH Tool to Study Nuclear Architecture in Human Primary Cells
11:25

3D Multicolor DNA FISH Tool to Study Nuclear Architecture in Human Primary Cells

Published on: January 25, 2020

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Capturing Chromosome Conformation Across Length Scales
10:15

Capturing Chromosome Conformation Across Length Scales

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Mapping Absolute DNA Density in Cell Nuclei using Single-molecule Localization Microscopy
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Mapping Absolute DNA Density in Cell Nuclei using Single-molecule Localization Microscopy

Published on: November 11, 2025

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科学分野:

  • ゲノミクス
  • 分子生物学
  • バイオ物理学

背景:

  • ゲノム組織を理解することは 遺伝子調節の解読に不可欠です
  • 原子核の空間と時間の構造は 細胞の機能に影響します
  • 現在の方法は,包括的なマッピングのためにさらに開発する必要があります.

研究 の 目的:

  • ゲノム構造とダイナミクスをマッピングするための新しいアプローチを開発し,適用する.
  • 核の組織と機能に関する機械的洞察を得るために
  • ゲノム組織と遺伝子調節の関係を調査する.

主な方法:

  • 実験・計算技術の開発とベンチマーク
  • ゲノム構造と核組織を測定する
  • 検証済みの技術と 生物物理モデルを組み合わせる

主要な成果:

  • 空間的なゲノム組織の定量モデルを確立する.
  • 様々な生物学的状態におけるゲノム組織を分析する
  • 細胞集団と単細胞に対するアプローチの検証

結論:

  • 4Dヌクレオームネットワークは ゲノム組織に関する理解を深めています
  • 開発された方法は,核の機能を研究するための新しいツールを提供します.
  • この研究は空間的なゲノム組織と 遺伝子調節の洞察を結びつけています