Videoaula 01 Senescência e Morte Celular

Edgar Bione

5 Oct 202010:37

Summary

TLDRThis video lecture delves into the concepts of cellular senescence and cell death, focusing on the biological processes of aging. It explains how cells undergo irreversible changes over time, including telomere shortening, DNA damage accumulation, and the role of the INK4A gene in regulating the cell cycle. The transcript compares the cellular characteristics of newborns, adults, and elderly individuals, highlighting the increasing susceptibility to senescence with age. It also touches on the possibility of cancer development at any stage, though more common in older individuals. The session concludes by introducing the concept of cell death, which will be discussed in the next lesson.

Takeaways

😀 Senescence refers to the aging process of cells, characterized by reduced physiological functions, increased susceptibility to diseases, and decreased resistance to stress.
😀 The aging of cells can be caused by environmental factors, such as infections or damage from toxins, leading to cellular responses like apoptosis, necrosis, or cell cycle arrest.
😀 Telomeres, the protective ends of chromosomes, shorten with each cell division, which eventually halts cell division and results in cellular senescence.
😀 As cells age, DNA damage accumulates, further impairing the cell’s ability to function and divide properly, contributing to senescence.
😀 The INK4A gene family produces proteins that inhibit cyclin-dependent kinases (CDKs), thus controlling the cell cycle and promoting senescence when necessary.
😀 Telomeres are longer in newborns, which means they have fewer senescent cells and their bodies exhibit smoother, more youthful skin.
😀 In adults, telomeres are moderately shortened, leading to some senescence, and DNA damage begins to accumulate, but the body still maintains a relatively youthful appearance.
😀 In elderly individuals, telomeres are much shorter, DNA damage is significant, and the expression of senescence-related genes (INK4A) is high, leading to more senescent cells.
😀 While senescence helps protect against tumor formation by halting cell division, some cancer cells may evade senescence and continue dividing, potentially leading to malignancy.
😀 The process of cellular senescence and the shortening of telomeres serve as biological markers of aging, impacting not just individual cells but the overall aging of the organism.

Q & A

What is cellular senescence and how does it relate to aging?
-Cellular senescence refers to the process where a cell permanently stops dividing. It is closely related to aging as cells undergo this process due to factors like telomere shortening, DNA damage, and stress, which accumulate over time and limit the cell's ability to proliferate.
What are the three main characteristics of cellular senescence?
-The three main characteristics of cellular senescence are: 1) Reduction of physiological functions, 2) Increased susceptibility to diseases, and 3) Decreased resistance to stress.
How does stress affect cellular senescence?
-Stress, whether from internal biochemical changes or external factors like bacteria and viruses, can cause cellular damage. This stress may lead the cell to undergo apoptosis (programmed cell death), necrosis, or simply enter a state of senescence where it halts division.
What is the role of telomeres in cellular senescence?
-Telomeres are protective caps at the ends of chromosomes that shorten with each cell division. As telomeres shorten over time, they signal to the cell that it has reached its division limit, leading to cellular senescence or apoptosis to prevent genomic instability.
What is the significance of the Ink4a gene in cellular senescence?
-The Ink4a gene produces proteins that inhibit cyclin-dependent kinases (CDKs), which are necessary for the cell cycle to progress. The activation of this gene leads to cell cycle arrest, contributing to the cessation of cellular division, a hallmark of senescence.
How do the changes in telomeres and Ink4a expression relate to aging?
-As we age, telomeres shorten and the expression of Ink4a increases, leading to a higher rate of cellular senescence. This accumulation of senescent cells contributes to aging and a decrease in tissue regeneration.
What is the relationship between cellular senescence and DNA damage accumulation?
-DNA damage accumulates over time, and this damage can trigger senescence. Damaged DNA prevents normal cell division and can lead to the activation of pathways that halt the cell cycle, causing the cell to enter senescence or die through apoptosis.
Why does cellular senescence increase susceptibility to diseases?
-As cells become senescent, they lose their ability to divide and regenerate. This impairs tissue repair and immune response, leading to a weakened system that is more vulnerable to diseases, including cancer and degenerative conditions.
Can cellular senescence lead to cancer formation?
-While senescent cells typically stop dividing to prevent tumor formation, some cells can escape senescence or undergo changes that allow them to continue proliferating. This can contribute to cancer formation, especially in older individuals, who have a higher accumulation of senescent cells.
How do telomere shortening and the accumulation of DNA damage relate to the aging process?
-Telomere shortening and the accumulation of DNA damage are two major contributors to aging. Shortened telomeres prevent further cell division, while DNA damage impairs the function and integrity of cells. Together, these factors limit cellular function, leading to the aging of tissues and organs.