No, cancer cells fail to do their proper cell cycle checks and thus continue to replicate even though there are errors present. A normal cell would sense the errors, stop to repair them or go into perminant senescense.sontag said:
You first have to establish whether in cancer cells are under heat stress, you haven't shown any evidence for that yet.sontag said:
That is just an image, not an article. The following has nothing to do with heat per se, but in cancer cells you can expect that there is a very large proportion of incorrectly folded proteins: just because it has to synthesize proteins very fast.
Why does a fast speed result in more errors.And why do dATP and dTTP havemonique said:
Would there be a higher density of DRiPs expressed on the cell surfacemonique said:
I was talking about protein folding, folding is a difficult process molecularly. In the ER this protein folding takes place in the accompaniment of chaparones, correct folding is checked by certain proteins. If the protein production is really fast, there is more room for error and there are not enough chaparones or error-read proteins to check the process.sontag said:
If more DRiPS are produced, their representation will be increased relative to the presentation of other cellular proteins. This higher density of presentation of DRiPS by MHCI (immune presentation) will give immune cells information about what is going on inside that particular cell. If the cell all of a sudden starts to present a lot of misfolded melanin (in case of melanoma), the cell will recognize this protein as foreign (since the body is not used to seeing melanin), natural killer cells will be attracted by the presented melanin, which subsequently will kill the cell.
Monique said:Sontag, you can quote someone either by hitting the quote button (bottom right of every post) or by putting the text between the following code:
(quote) (/quote)
or
(quote=monique) (/quote)
where instead of these brackets () you use these []
Exposure to extreme temperatures can cause damage to chromosomes, which are the structures that carry genetic information in our cells. High temperatures can lead to denaturation or breakage of the DNA strands, while low temperatures can cause the DNA to become more rigid and prone to breakage.
Damage to chromosomes can have a range of effects on an organism, depending on the severity and location of the damage. It can lead to mutations, which can result in changes to physical traits or even diseases. In severe cases, it can cause cell death or disrupt vital cellular processes.
Yes, cells have mechanisms in place to repair damage to chromosomes. This includes enzymes that can repair breaks in the DNA strands or remove and replace damaged nucleotides. However, if the damage is too extensive or the repair mechanisms are not functioning properly, it can lead to permanent changes in the genetic code.
No, different organisms have varying levels of tolerance to temperature changes and different ways of coping with potential damage. Some have specialized proteins that protect DNA from high temperatures, while others have evolved to thrive in extreme temperatures. Additionally, factors such as age, health, and exposure time can also affect an organism's susceptibility to temperature-related damage.
While it is impossible to completely prevent all damage to chromosomes, there are steps that can be taken to minimize the risk. This includes avoiding exposure to extreme temperatures, maintaining a healthy lifestyle, and protecting against harmful environmental factors such as radiation. Additionally, prompt and proper treatment of any injuries or illnesses can also help prevent potential damage to chromosomes.