Listen, I am a physicist and an engineer and not a bioscientist. If I misued the work mutation then forgive me my ignorance.
If ageing were programmed then over the thousands of years and billions of lives then there should be cases of the normal programming going awry and leading to increased healthspan and increased lifespan. There should be at least 1 case... a handful of cases... There are exactly ZERO cases of programming going awry and giving rise to a 175 year old human being who lived in relatively good health.
Whenever "programming" goes awry it leads to shortend lifespan and decreased healthspan. Progeria is the one that comes to mind because its the easiest to make a point of it.
Probability dictates that if there are genes and combinations of genes that can be activated that will lead to slowed ageing, increased healthspan, increased lifespan, that there should be cases thoughout the history of billions of lives.
There are EXACTLY zero cases throughout all of history. Not one case. Not even among non-humans. Ever seen a 150 year old person? A 75 year old german shepard? No. And you never will. These genes do not exist.
Whenever "programming" goes awry you get less life and less health. Never the opposite.
That should speak volumes about the programmed theory of ageing.
Apparently according to the believers, faulty programming can only shorten life and we have simply yet to see a case where it does the opposite. Really? with billions of data points, and not one case? Hmmm. Sounds like the hypothesis is incorrect.
There are few misconceptions in your view.
first. re "There are EXACTLY zero cases throughout all of history. Not one case. Not even among non-humans."
This is not true . There are animals that do not age -- as in don't age at all, not even 'negligibly'. This is a good read: Diversity of ageing across the tree of life, 2014
second, re genes and programming
Don't know if you're familiar with programming, but most programs consists of instructions (code) and data array. The code part is what commonly is called the 'program'. That's the most important part. The data array is something the code uses when the program is executed.
Genes are the data array. In human DNA, they make up 1% to 2%, and the rest is... something else. Presumably, somewhere in that 98%-99% portion of the DNA, lies the instructions code, or the 'program' itself. What exactly the code consists of and how it is executed, to my knowledge, no one knows (and if anyone knows of a hypothesis posted somewhere, I'd love to read it).
When we say that the development is programmed (and no one denies this) we just state what is apparent, but we do not know how it works. We can only describe what's going on, i.e. we trace the 'pathways' and list the participating molecules and try to discern their role by impeding or augmenting their action.
On the example of the C. elegans paper above, they traced the 'trigger', a molecular signal that originated in the germline stem cells, which, via a specific pathway, caused the gene that encodes for a protein essential for stress response to be available only 30-40% of the time (compared to the baseline that they recorded before the animal reached reproductive maturity).
It is a developmental program, because it happens not randomly or in response to some external stimuli, but 'within a 4h window' after the animal reached the most important stage in its development. In this study, they specifically focused on the heat shock response, but they also noted that all other stress response pathways became suppressed. Of course, this affected the animal as a whole -- i.e. it began to 'accumulate damage' or age.
According to a study they cite, removal of the germline stem cells "increased the lifespan dramatically" -- i.e. removal of germline stem cells interrupted this pro-aging program. It is pro-aging, because it leads to 'accumulation of damage', which had been repaired while the animal was still developing.
re loss of function gene mutation in progeria
In programming, changes in the data array does not affect the code itself, but naturally it does affect the output, or the result of the program. When a gene is mutated, this usually results in the loss of function of the resulting protein and the pathway(s) in which it participates. Even though it's incorrect to draw direct parallels, still, one can liken a 'molecular pathway' to a little sub-program or a subroutine, as it's called in programming.
In your example of progeria, the developmental program is unchanged. Instead, one of the proteins that makes up the nuclear envelope is defective, and this leads to 'loss of function' problems that result in the disease that kills the person in the second decade of life. Here an important 'subroutine' is affected, but not the 'main' program itself.
re 'good' mutation that could increase lifespan
There are cases of people having multiple copies of 'good housekeeping' genes and they tend to live longer. This does not affect developmental program, but only mediates the effects of the pro-aging routine which suppresses the housekeeping genes.
So you see? It's not so much genes, though of course they are important, it's how the genes are directed to function by the program.
Edited by xEva, 17 December 2018 - 05:32 AM.
