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Cancer Resistant Mouse Provides Possible Cure
Evoluder writes to tell us that scientists at Wake Forest University have found a "cancer resistant mouse" and bred it to make a small army of cancer resistant mice. When transplanting blood from one of these mice to a normal non-resistant mouse they are able to provide "lifetime cancer protection". From the article: "The cancer-resistant mice all stem from a single mouse discovered in 1999. "The cancer resistance trait so far has been passed to more than 2,000 descendants in 14 generations," said Cui, associate professor of pathology. It also has been bred into three additional mouse strains. About 40 percent of each generation inherits the protection from cancer."
How good is this really?
(Assuming this is true, it is a wonderful step.)
"If you cure cancer, you get laid."
If a guy was somehow determined to be "cancer-resistant", imagine how many women would want to procreate with him so that their children would be immune to cancer. The guys that could be declared "cancer-resistant" could have women lining up down the street waiting for the guys to knock them up!
Ninjas don't carry tic tacs
As exciting as this sounds, it's probably not going to lead to a pancea for cancer in humans. We've cured cancer in mice several times over since the 70s. The problem is that mice are a short-lived species that has very little innate resistance to cancer. After all evolution is not going to have an organism waste lots of energy repairing DNA damage and having pools of immune cells constantly checking for mutant cells if the organism is just going to get eaten by a cat in an average of a few months after birth.
By contrast, humans are a very long-lived animal species. Our bodies already have a large number of cancer-prevention mechanisms that simply aren't present in mice. Take for example telomeres. The telomere ends of chromosomes shorten with each cell replication other than gamete formation. All your cells have what is known as the 'Hayflick limit' where the telomeres get too short, the chromosomes become unstable and the cell dies. Although this mechanism is probably one of the contributors to human aging, it also does a very good job of eliminating many tumors. Most of your tumors hit the Hayflick limit and simply die off before they can present a threat to you. Virtually all human cancers either mutate so as to find a way to reactivate the telomerase that re-lengthens the telomeres or manages to find a way to preserve their telomere ends through chromosomal recombination. Mouse cells, by way of contrast, have huge telomeres which never get short enough to act as this sort of cancer-prevention mechanism.
As a result human tumors are much 'tougher' than mouse tumors. The average mouse tumor wouldn't stand a chance in a human. Any tumor that manages to thrive in a human has had to jump a host of hurdles and checkpoints that no mouse tumor does in order to simply survive.
The problem is that many of these cancer cures in mice already exist in humans naturally. Some of these cures (such as this one, most likely) are simply reactivation of vestigial anti-cancer systems in the mice that have atrophied for the above-mentioned reasons. Others are cancer treatments that attack weaknesses in mouse tumors that are simply irrelevant in human ones. I suspect that this super mouse is simply being more human with regards to cancer and that the end result is that we'll rediscover something our bodies already do.
We may actually be doing the experiment and not looking at the results.
The article states that if an immune mouse gives white blood cells to a mouse with cancer the second mouse gets better.
If we assume the same mutation exists in humans, we just need to do a statistical analysis of humans who have had spontaneous permanent cancer remissions after receiving a blood donation.
A few more tests and we could cure a lot of cancer.