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On Wed, 13 Mar 2024 06:28:17 -0700, John HarshmanThat makes it sound like a purposeful or adaptive process, but maybe it's just random. In fact mitochondria in most taxa have lost most of their crucial genes, and I don't see much difference between the ones they've lost and the ones they've kept. How is cytochrome c different from cytochrome b, for example?
<john.harshman@gmail.com> wrote:
On 3/12/24 10:59 PM, jillery wrote:My understanding is there are likely several causes for geneticOn Tue, 12 Mar 2024 09:04:22 -0700, erik simpson>
<eastside.erik@gmail.com> wrote:
>On 3/12/24 6:44 AM, John Harshman wrote:>On 3/12/24 3:50 AM, Ernest Major wrote:All sorts of seemingly long-separated species (both plant and animal)On 11/03/2024 23:28, John Harshman wrote:Then again, ducks that are thought to be separated by tens of millionsOn 3/11/24 4:17 PM, RonO wrote:>https://www.science.org/content/article/these-gars-are-ultimate-living-fossils>
>
Open access article:
https://academic.oup.com/evolut/advance-article/doi/10.1093/evolut/qpae028/7615529?login=false
>
These researchers looked at Gar, but it also applies to sturgeons.
These two bony fish lineages seem to have a very slow rate of
molecular evolution. The changes in their DNA accumulate so slowly
that two lineages separated for over 100 million years can still
form fertile hybrids. 3 million years is pushing it for species
like lions and tigers that can still form hybrids, but the hybrids
are sterile. Bonobos and chimps are around 3 million years divergent
and can still form fertile hybrids, but the claim is that these fish
evolve orders of magnitude more slowly than mammals.
>
The Science news article claims that mammals accumulate 0.02
mutations per site per million years, while these fish averaged only
0.00009 mutations per million years. For the 1100 coding exons that
they looked at for this study these fish evolve much more slowly
than mammals.
>
The news article notes that other "living fossils" such as
coelacanths (0.0005) evolve faster, but slower than amphibians
(0.007). It sounds like terrestrial animals evolve faster than fish.
If it's repair mechanisms they hypothesize as the cause of slow
evolution, they really should be looking at junk sequences rather
than just 4-fold degenerate sites. I suggest introns. And if the
introns aren't alignable, well, that kills the theory right there.
>
Tree species thought to be separated by tens of millions of years are
known to hybridise. For example Platanus orientalis and Platanus
occidentalis, and also with Tilia, Quercus and Aesculus. In the case
of Tilia I suspect that multiple rounds of introgression has served to
limit the amount of divergence between species. However Tilia does
appear as a short branch in cladograms, supporting the hypothesis that
forest trees have a lower rate of evolution.
>
of years are also known to hybridize, and their rate of evolution isn't
particularly slow.
>
are observed. What determines whether the hybrid offspring are fertile,
infertile or sterile? I found an article on Big Think
https://bigthink.com/the-past/soviet-human-ape-super-warriors-humanzee-ivanov/
describing an unsuccessful attempt to produce a "humanzee". Fortunately
it didn't work. The chromosome count is different in humans and
chimpanzee, but does this imply that it's essentially impossible?
>
My understanding is, the limiting factor is the compatibility of mtDNA
with nuclear DNA. As species evolve, mtDNA mutates faster than
nuclear DNA, but they still need to maintain compatibility with each
other. Organisms where the two are poorly compatible fail to thive or
even to survive. Over time, isolated populations can evolve mtDNA
that are no longer compatible with nuclear DNA from other populations.
ISTM infertility between isolated populations would be a natural
though not necessarily inevitable consequence of having two separate
DNA pools.
>
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Zhang C, Montooth KL, Calvi BR. Incompatibility between mitochondrial
and nuclear genomes during oogenesis results in ovarian failure and
embryonic lethality. Development. 2017 Jul 1;144(13):2490-2503. doi:
10.1242/dev.151951. Epub 2017 Jun 2. PMID: 28576772; PMCID:
PMC5536873.
**********************************
That's one of several possible reasons for incompatibility. Some others
have already been mentioned.
incompatibilities. My impression is chromosome count is among the
least of them. As long as the important genes line up during meiosis,
it doesn't really matter if the chromosomes are in multiple pieces.
That's why for example the chromosome 2 fusion wasn't as big a problem
for our ancestors as some claim.
OTOH mtDNA/nuclear DNA incompatibility is an insurmountable problem.
Since the original endosymbiosis billions of years ago, mitochondria
have transferred much of their DNA into the nucleus, in order to speed
their duplication, while keeping for themselves most crucial genes,
for example to regulate ATP synthesis.
Having two separate pools of DNA with different mutation ratesWould that not be true for any pair of chromosomes whose products must interact, i.e. more or less any pair of chromosomes? I see no reason to elevate that particular reason for genetic isolation over several others.
necessarily means that from time to time some gamete fusions will
combine two incompatible pools. Breeding long-isolated populations
makes that even more likely. And once two populations are
biologically isolated, for any reason, they necessarily evolve
independently of each other.
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