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Telomeres and Telomerase02:41

Telomeres and Telomerase

In eukaryotic DNA replication, a single-stranded DNA fragment remains at the end of a chromosome after the removal of the final primer. This section of DNA cannot be replicated in the same manner as the rest of the strand because there is no 3’ end to which the newly synthesized DNA can attach. This non-replicated fragment results in gradual loss of the chromosomal DNA during each cell duplication. Additionally, it can induce a DNA damage response by enzymes that recognize single-stranded DNA.
Telomeres and Telomerase02:41

Telomeres and Telomerase

In eukaryotic DNA replication, a single-stranded DNA fragment remains at the end of a chromosome after the removal of the final primer. This section of DNA cannot be replicated in the same manner as the rest of the strand because there is no 3’ end to which the newly synthesized DNA can attach. This non-replicated fragment results in gradual loss of the chromosomal DNA during each cell duplication. Additionally, it can induce a DNA damage response by enzymes that recognize single-stranded DNA.
Replicative Cell Senescence02:15

Replicative Cell Senescence

Replicative cell senescence is a property of cells that allows them to divide a finite number of times throughout the organism's lifespan while preventing excessive proliferation. Replicative senescence is associated with the gradual loss of the telomere — short, repetitive DNA sequences found at the end of the chromosomes. Telomeres are bound by a group of proteins to form a protective cap on the ends of chromosomes. Embryonic stem cells express telomerase — an enzyme that adds the telomeric...
Forced Transdifferentiation01:28

Forced Transdifferentiation

Transdifferentiation, also known as lineage reprogramming, was first discovered by Selman and Kafatos in 1974 in silkmoths. They observed that the moths’ cuticle-producing cells transformed into salt-producing cells. Many such cases of natural transdifferentiation occur in organisms. In humans, pancreatic alpha cells can become beta cells. In newts, the loss of the eye’s lens causes the pigmented epithelial cells to transdifferentiate into the lens cells.
Artificial transdifferentiation occurs...

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Related Experiment Video

Updated: Jun 14, 2026

Utilizing Murine Inducible Telomerase Alleles in the Studies of Tissue Degeneration/Regeneration and Cancer
08:34

Utilizing Murine Inducible Telomerase Alleles in the Studies of Tissue Degeneration/Regeneration and Cancer

Published on: April 13, 2015

Does telomerase reverse transcriptase induce functional de-differentiation of human endothelial cells?

Yvonne Baumer1, Dorothee Funk, Burkhard Schlosshauer

  • 1NMI, Natural and Medical Sciences Institute at the University of Tübingen, Reutlingen, Germany.

Cellular and Molecular Life Sciences : CMLS
|March 31, 2010
PubMed
Summary
This summary is machine-generated.

Telomerase reverse transcriptase (hTERT) overexpression immortalizes human endothelial cells. This process maintains their typical characteristics, showing no signs of functional de-differentiation, which is crucial for understanding cell aging and cancer.

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Related Experiment Videos

Last Updated: Jun 14, 2026

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Published on: April 13, 2015

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Directed Differentiation of Hemogenic Endothelial Cells from Human Pluripotent Stem Cells
04:23

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Published on: March 31, 2021

Area of Science:

  • Cell Biology
  • Molecular Biology
  • Gerontology

Background:

  • Telomerase reverse transcriptase (hTERT) counteracts telomere shortening, preventing cellular senescence and age-related death.
  • While embryonic cells have high telomerase activity, it declines with differentiation, but tumor cells often re-express it.

Purpose of the Study:

  • To investigate if telomerase overexpression and subsequent immortalization impact the functional phenotype of human endothelial cells.
  • To resolve controversial data regarding the correlation between cell proliferation and differentiation in the context of telomerase activity.

Main Methods:

  • Comparative analysis of endothelial cell functions, including cell adhesion to ECM proteins using multisubstrate arrays (MSA).
  • Assessment of protein marker expression, DiI-Ac-LDL uptake, inflammatory response (ICAM-1 upregulation), tube formation, and barrier properties in transfilter cultures.

Main Results:

  • Overexpression of hTERT in primary endothelial cells leads to immortalization.
  • Despite immortalization, endothelial cells retained typical endothelial characteristics.
  • No evidence of functional de-differentiation was observed in the immortalized endothelial cells.

Conclusions:

  • Immortalization of human endothelial cells via hTERT overexpression preserves their normal functional phenotype.
  • This finding suggests that telomerase activity can be modulated without compromising endothelial cell identity and function.