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Related Concept Videos

Telomeres and Telomerase02:41

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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...
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In eukaryotic cells, DNA replication is highly conserved and tightly regulated. Multiple linear chromosomes must be duplicated with high fidelity before cell division, so there are many proteins that fulfill specialized roles in the replication process. Replication occurs in three phases: initiation, elongation, and termination, and ends with two complete sets of chromosomes in the nucleus.
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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...
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lncRNA - Long Non-coding RNAs02:39

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In humans, more than 80% of the genome gets transcribed. However, only around 2% of the genome codes for proteins. The remaining part produces non-coding RNAs which includes ribosomal RNAs, transfer RNAs, telomerase RNAs, and regulatory RNAs, among other types. A large number of regulatory non-coding RNAs have been classified into two groups depending upon their length – small non-coding RNAs, such as microRNA, which are less than 200 nucleotides in length, and long non-coding RNA...
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Updated: Sep 7, 2025

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

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[Telomeres and lung].

C Guérin1, B Crestani2, C Dupin2

  • 1Service de Pneumologie A, Centre de compétences maladies pulmonaires rares, AP-HP, Hôpital Bichat, Paris, France..

Revue Des Maladies Respiratoires
|June 17, 2022
PubMed
Summary
This summary is machine-generated.

Genetic mutations in telomere-related genes (TRGs) are found in 30% of familial interstitial lung disease (ILD) cases, often presenting with additional health issues and impacting disease progression. Genetic counseling and testing are recommended for affected families.

Keywords:
Fibrose pulmonaireGeneticGénétiqueHepato-pulmonary syndromeInterstitial lung diseaseMyelodysplasiaMyélodysplasiePneumopathie interstitielle diffusePulmonary fibrosisSyndrome hepato-pulmonaireTransplantation

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Area of Science:

  • Genetics
  • Pulmonology
  • Immunology

Background:

  • Familial interstitial lung disease (ILD) is a significant clinical challenge.
  • Genetic factors play a crucial role in the pathogenesis of ILD.
  • Telomere-related gene (TRG) mutations have been identified as a cause of familial ILD.

Purpose of the Study:

  • To investigate the prevalence and clinical implications of TRG mutations in familial ILD.
  • To explore the association of TRG mutations with extra-pulmonary manifestations and disease prognosis.
  • To highlight the importance of genetic counseling and testing in managing familial ILD.

Main Methods:

  • Genetic analysis of familial ILD cohorts.
  • Clinical data collection on ILD patients with and without TRG mutations.
  • Assessment of extra-pulmonary manifestations and lung function decline.

Main Results:

  • TRG mutations (TERT, TERC, RTEL1, PARN, DKC1, TINF2, NAF1, NOP10, NHP2, ACD, ZCCH8) identified in approximately 30% of familial ILD cases.
  • Patients with TRG mutations exhibit extra-pulmonary manifestations (immune-hematological, hepatic, mucosal-cutaneous).
  • TRG mutations are linked to both idiopathic pulmonary fibrosis (IPF) and non-IPF ILDs, including hypersensitivity pneumonitis (HP), and are associated with accelerated forced vital capacity (FVC) decline and poorer lung transplant outcomes.

Conclusions:

  • TRG mutations are a significant genetic cause of familial ILD, associated with diverse clinical phenotypes.
  • Early identification through genetic counseling and pre-symptomatic testing can aid in personalized management and risk assessment.
  • Environmental exposure reduction and genetic counseling are crucial for patients and families affected by TRG-related ILD.