Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Chromatin Packaging01:32

Chromatin Packaging

16.6K
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...
16.6K
Nucleosome Remodeling02:54

Nucleosome Remodeling

9.0K
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...
9.0K
Duplication of Chromatin Structure02:05

Duplication of Chromatin Structure

5.4K
The process of chromosome duplication during cell division requires genome-wide disruption and re-assembly of chromatin. The chromatin structure must be accurately inherited, reassembled, and maintained in the daughter cells to ensure lineage propagation.
The basic unit of the chromatin is the nucleosome, consisting of DNA wrapped around octameric histone proteins and short stretches of linker DNA separating individual nucleosomes. The histone proteins within the nucleosome have their...
5.4K
Spreading of Chromatin Modifications02:25

Spreading of Chromatin Modifications

8.2K
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...
8.2K
Polytene Chromosomes02:04

Polytene Chromosomes

10.0K
Polytene chromosomes are giant interphase chromosomes with several DNA strands placed side by side. They were discovered in the year 1881 by Balbiani in salivary glands, intestine, muscles, malpighian tubules, and hypoderm of larvae Chironomus plumosus. Hence, these are also called "Salivary gland chromosomes." These are found in insects of the order Diptera and Collembola; in certain organs of mammals; and synergids, antipodes of flowering plants. Polytene chromosomes are also...
10.0K
Inheritance of Chromatin Structures03:17

Inheritance of Chromatin Structures

6.2K
Epigenetics is the study of inherited changes in a cell's phenotype without changing the DNA sequences. It provides a form of memory for the differential gene expression pattern to maintain cell lineage, position-effect variegation, dosage compensation, and maintenance of chromatin structures such as telomeres and centromeres. For example, the structure and location of the centromere on chromosomes are epigenetically inherited. Its functionality is not dictated or ensured by the underlying...
6.2K

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Management of the Axilla for Early-Stage Breast Cancer: A State-Of-The-Art Review.

ANZ journal of surgery·2026
Same author

Operationalizing the Construct of the Internal Saboteur: Development and Psychometric Validation of the Internal Saboteur Scale (ISS).

European journal of investigation in health, psychology and education·2026
Same author

Emergent domain segregation in self-interacting polymers explains chromosome 3D conformations in single human cells.

Physical review. E·2026
Same author

PSMA PET/CT staging in intermediate-risk prostate cancer: Toward risk-adapted implementation.

Seminars in oncology·2026
Same author

Overcoming absolute dysphagia in a thirty-year-old patient with advanced anaplastic lymphoma kinase-positive non-small cell lung cancer: a case report.

Frontiers in oncology·2026
Same author

Physics-Based Modeling of Sparse Single-Cell Hi-C Uncovers Structural and Epigenetic Variability.

International journal of molecular sciences·2026

Related Experiment Video

Updated: Jun 6, 2025

Hi-C: A Method to Study the Three-dimensional Architecture of Genomes.
22:27

Hi-C: A Method to Study the Three-dimensional Architecture of Genomes.

Published on: May 6, 2010

408.8K

A Multiscale Perspective on Chromatin Architecture through Polymer Physics.

Francesca Vercellone1, Andrea M Chiariello2, Andrea Esposito2

  • 1Dipartimento di Ingegneria Chimica dei Materiali e della Produzione Industriale-DICMaPI,11, Università degli Studi di Napoli Federico II and INFN Napoli, Naples, Italy.

Physiology (Bethesda, Md.)
|November 27, 2024
PubMed
Summary
This summary is machine-generated.

Computational models explain how chromatin folding impacts gene expression and disease. These physics-based approaches predict interactions and reveal molecular causes of diseases like SARS-CoV-2 infection.

Keywords:
SARS-CoV-2chromatin architecturemultiscale modelingpolymer physicsstructural variants

More Related Videos

Imaging Replicative Domains in Ultrastructurally Preserved Chromatin by Electron Tomography
14:56

Imaging Replicative Domains in Ultrastructurally Preserved Chromatin by Electron Tomography

Published on: May 20, 2022

3.7K
Author Spotlight: Efficient Nucleosome Reconstitution for Single-Molecule Techniques
05:58

Author Spotlight: Efficient Nucleosome Reconstitution for Single-Molecule Techniques

Published on: September 6, 2024

1.0K

Related Experiment Videos

Last Updated: Jun 6, 2025

Hi-C: A Method to Study the Three-dimensional Architecture of Genomes.
22:27

Hi-C: A Method to Study the Three-dimensional Architecture of Genomes.

Published on: May 6, 2010

408.8K
Imaging Replicative Domains in Ultrastructurally Preserved Chromatin by Electron Tomography
14:56

Imaging Replicative Domains in Ultrastructurally Preserved Chromatin by Electron Tomography

Published on: May 20, 2022

3.7K
Author Spotlight: Efficient Nucleosome Reconstitution for Single-Molecule Techniques
05:58

Author Spotlight: Efficient Nucleosome Reconstitution for Single-Molecule Techniques

Published on: September 6, 2024

1.0K

Area of Science:

  • Molecular Biology
  • Genomics
  • Biophysics

Background:

  • Chromatin's spatial organization is vital for gene expression and cellular function.
  • Disruptions in chromatin structure are linked to various diseases.
  • Advanced techniques like Hi-C and microscopy reveal complex chromatin interactions.

Purpose of the Study:

  • To demonstrate the genomewide application of physics-based computational models for chromatin structure.
  • To highlight the predictive power of these models for chromatin contacts and molecular determinants.
  • To provide a framework for understanding disease-associated alterations in chromosome folding.

Main Methods:

  • Utilizing physics-based computational models, including polymer phase separation and loop-extrusion mechanisms.
  • Applying these models to genomewide data to predict chromatin contacts.
  • Integrating experimental data with computational predictions.

Main Results:

  • Models successfully predict chromatin contacts across multiple scales.
  • The models elucidate underlying molecular determinants of chromatin organization.
  • Demonstrated ability to explain alterations in chromosome folding in disease contexts.

Conclusions:

  • Physics-based models are powerful tools for understanding chromatin architecture.
  • These models offer insights into the molecular basis of diseases linked to chromatin disruption.
  • Computational approaches enhance our understanding of chromatin's role in health and disease.