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Related Concept Videos

Induced Pluripotent Stem Cells01:06

Induced Pluripotent Stem Cells

Stem cells are undifferentiated cells that divide and produce different cell types. Ordinarily, cells that have differentiated into a specific cell type are terminally differentiated; however, scientists have found a way to reprogram these mature cells so that they dedifferentiate and return to an unspecialized, proliferative state. These cells are pluripotent like embryonic stem cells—able to produce all cell types—and are called induced pluripotent stem cells (iPSCs).
Somatic cells are...
Induced Pluripotent Stem Cells01:13

Induced Pluripotent Stem Cells

Stem cells are undifferentiated cells that divide and produce different types of cells. Ordinarily, cells that have differentiated into a specific cell type are post-mitotic—that is, they no longer divide. However, scientists have found a way to reprogram these mature cells so that they “de-differentiate” and return to an unspecialized, proliferative state. These cells are also pluripotent like embryonic stem cells—able to produce all cell types—and are therefore called induced pluripotent stem...
Induced Pluripotent Stem Cells01:13

Induced Pluripotent Stem Cells

Stem cells are undifferentiated cells that divide and produce different types of cells. Ordinarily, cells that have differentiated into a specific cell type are post-mitotic—that is, they no longer divide. However, scientists have found a way to reprogram these mature cells so that they “de-differentiate” and return to an unspecialized, proliferative state. These cells are also pluripotent like embryonic stem cells—able to produce all cell types—and are therefore called induced pluripotent stem...
Maintenance of the ES Cell State01:14

Maintenance of the ES Cell State

The cells of the blastocyst inner cell mass only remain pluripotent for a short time. This state of pluripotency and self-renewal can be maintained in embryonic stem (ES) cell culture by adding specific chemicals or growth factors to ensure the cells can continue dividing and later differentiate into different cell types. In some cases, the cells are grown on a feeder layer of differentiated cells, which provides the growth factors and extracellular matrix components necessary for stem cell...
Somatic to iPS Cell Reprogramming01:29

Somatic to iPS Cell Reprogramming

Reprogramming alters the gene expression in somatic cells, transforming them into induced pluripotent stem (iPS) cells over several generations. Scientists can reprogram cells by introducing genes for four transcription factors—Oct4, Sox2, Klf4, and c-Myc (OSKM) by viral or non-viral methods. These factors are also known as Yamanaka factors after Shinya Yamanaka, who first generated iPS cells using mouse skin cells. Yamanaka was awarded the Nobel Prize in Physiology or Medicine in 2012 for this...
Methods of Nuclear Reprogramming01:24

Methods of Nuclear Reprogramming

Nuclear reprogramming is a process of transforming one cell type into an unrelated cell type by epigenetic changes that alter the cell’s original gene expression pattern. Such epigenetic changes force cells to express a different set of genes, which play a significant role in inducing transformation into other cell types. Nuclear reprogramming offers applications in reproductive cloning for livestock propagation and regenerative medicine — developing patient-specific cells for injury repair.

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Updated: Jun 13, 2026

Reprogramming Mouse Embryonic Fibroblasts with Transcription Factors to Induce a Hemogenic Program
11:00

Reprogramming Mouse Embryonic Fibroblasts with Transcription Factors to Induce a Hemogenic Program

Published on: December 16, 2016

Stem cell plasticity: recapping the decade, mapping the future.

Neil D Theise1

  • 1Departments of Pathology and Medicine, Beth Israel Medical Center, Albert Einstein College of Medicine, New York, NY 10003, USA. neiltheise@chpnet.org

Experimental Hematology
|May 5, 2010
PubMed
Summary
This summary is machine-generated.

Postnatal cells, even terminally differentiated ones, exhibit significant stem cell plasticity, challenging previous assumptions. This plasticity opens avenues for therapeutic and industrial applications, requiring a shift towards "tissue biology" approaches.

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Kinetic Measurement and Real Time Visualization of Somatic Reprogramming
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Kinetic Measurement and Real Time Visualization of Somatic Reprogramming

Published on: July 30, 2016

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Last Updated: Jun 13, 2026

Reprogramming Mouse Embryonic Fibroblasts with Transcription Factors to Induce a Hemogenic Program
11:00

Reprogramming Mouse Embryonic Fibroblasts with Transcription Factors to Induce a Hemogenic Program

Published on: December 16, 2016

Kinetic Measurement and Real Time Visualization of Somatic Reprogramming
08:56

Kinetic Measurement and Real Time Visualization of Somatic Reprogramming

Published on: July 30, 2016

Area of Science:

  • Cellular Biology
  • Developmental Biology
  • Regenerative Medicine

Background:

  • Over a decade of research indicates significant stem cell plasticity.
  • 24 peer-reviewed articles demonstrate plasticity across lineages, with only one negative result.
  • Reversibility of gene restrictions further supports cell plasticity.

Purpose of the Study:

  • To review known pathways and principles of cell plasticity.
  • To relate plasticity data to experimental design and discourse.
  • To explore future therapeutic and industrial applications of cell plasticity.

Main Methods:

  • Literature review of stem cell plasticity research.
  • Analysis of "plasticity principles": Genomic Completeness, Cellular Uncertainty, Stochasticity of Cell Origin and Fate.
  • Discussion of experimental design and discourse in plasticity research.

Main Results:

  • Evidence strongly supports stem cell plasticity in postnatal cells.
  • Four pathways and key principles of plasticity have been identified.
  • Plasticity phenomena are considered ripe for therapeutic and industrial exploration.

Conclusions:

  • Stem cell plasticity is more prevalent than previously understood.
  • Future research must integrate cell and molecular data into a "tissue biology" framework.
  • Interdisciplinary collaboration and computational modeling are crucial for advancing stem cell biology.