5 Must Know Facts For Your Next Test

1. Telomeres consist of repeating units of the DNA sequence 'TTAGGG' in humans, which helps prevent chromosome end degradation.
2. During DNA replication, the lagging strand cannot fully replicate the end of the chromosome, leading to gradual shortening of telomeres with each cell division.
3. Certain types of stem cells and cancer cells express telomerase, allowing them to maintain longer telomeres and avoid senescence, contributing to their ability to divide indefinitely.
4. Shortened telomeres are associated with aging and increased risk of age-related diseases, including cancer and cardiovascular diseases.
5. Research into telomere biology has potential therapeutic implications, such as developing drugs that target telomerase for cancer treatment or strategies to enhance telomere maintenance in aging cells.

Review Questions

• How do telomeres contribute to cellular aging, and what implications does this have for organismal lifespan?
  • Telomeres contribute to cellular aging by gradually shortening with each cell division, eventually leading to cellular senescence when they become critically short. This process limits the number of times a cell can divide, which has direct implications for organismal lifespan since tissues rely on cellular proliferation for maintenance and repair. When telomeres are too short, it can impair tissue regeneration and increase vulnerability to age-related diseases.
• Discuss the role of telomerase in cellular function and its significance in cancer biology.
  • Telomerase is an enzyme that helps maintain the length of telomeres by adding repetitive nucleotide sequences back to the ends of chromosomes. In most somatic cells, telomerase is not active, leading to gradual telomere shortening. However, many cancer cells activate telomerase, allowing them to maintain long telomeres and evade the normal limits on cell division. This gives cancer cells a growth advantage and contributes to tumorigenesis, making telomerase a potential target for cancer therapies.
• Evaluate the potential therapeutic strategies involving telomere biology for treating age-related diseases and cancer.
  • Potential therapeutic strategies involving telomere biology include targeting telomerase activity in cancer cells to induce senescence or apoptosis, thereby slowing tumor growth. Conversely, enhancing telomerase activity in aged or dysfunctional somatic cells may improve tissue regeneration and combat age-related diseases. Both approaches require careful consideration of the balance between promoting normal cell function while preventing unchecked proliferation that can lead to cancer. Research continues to explore these avenues, emphasizing the need for precise regulation of telomere dynamics in therapeutic contexts.

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