Thoughts on Chloroplasts and Mitochodria

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Chloroplasts and mitochondria possess their own DNA due to the endosymbiont theory, which suggests they originated as independent single-celled organisms that entered into a symbiotic relationship with other cells. This theory is widely accepted for mitochondria and is also considered for chloroplasts, though some debate exists regarding its acceptance among researchers. The discussion touches on the challenges of proving evolutionary theories and the complexities of genetic research, including the difficulties in establishing mutation rates and isotopic half-lives. Participants express skepticism about the linearity of mutation rates and the reliability of dating methods in genetics. Overall, the conversation highlights the intricacies of evolutionary biology and the limitations of current scientific methods in proving historical biological events.
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I was looking into why chloroplasts and mitochondria have their own DNA separate from the cells DNA.

I found an interesting theory; Chloroplasts and Mitochodria were once single celled organisms. Another single celled organism consumes the mitocodria/chloroplast, but they continue to function.
The cells work in symbiosis together, after millions of years the relationship has now become standard!

Why do you think chloroplasts and mitochodria have their own DNA?
 
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The endosymbiont theory (the one you outlined above) is the currently accepted theory of the origin of Mitochondria (AFAIK).
 
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Is the theory accepted for chloroplasts aswell?
Are there any other widely accepted theories or is this the only one?
 
Lynn Margulis certainly thinks so; but I am not sure if other researchers accept her idea with regard to chloroplasts.
 
Fair enough.

The horrible thing about genetics and evolution is never really being able to prove anything.
 
I'm not very well educated in biology, so do mitochondria do anything else except aerobic respiration?
Do chloroplasts do anything else except photosynthesis?
If not why would such organisms have independently evolved?
 
Just to clarify. There is a massive amount of evidence in favor for evolution and genetics, both mathematical and experimental.
 
I wasn't trying to put down genetics or evolution, it's just very difficult to actually prove any theories.

It's not like we can travel back in time and actually say this evolved from that due to a mutation caused by natural selection.
We can say such things with a certain degree of acuracy, but the fact remains there is no hard proof.

Also some of the mathematics seems a bit odd to me e.g. The rate of mutation being recognised as linear.

How do you prove that an isotope has a half-life of 5700years from 50years research(at most)?

These points and more are why genetic research needs to be excelled.
 
How do you prove that an isotope has a half-life of 5700years from 50years research?

Quite simple:
The relative rate of decay is a CONSTANT.
All you need to know in order to determine the half-life of the substance is the amount of stuff at two different instant.
 
  • #10
Yes I know, but if its really that simple why does such a small half-life (in terms of dating fossils) have a +/- 40 years? What kind of discrepenses can we expect for things such as Potassium with a half-life of 1.25billion years?

Now can you explain why we would think the rate of mutation to be linear?
 
  • #11
Back on topic now.
Why would mitochodria/chloroplasts have independently evolved?
Can they store the products of their reactions by themselves?
 
  • #13
Thankyou for the links.
In the first though there is constant reference of billion years!
The universe is only 6000MYA not 1*10^12, anyone know why this is?
 
  • #14
Just been reading the endosymbiotic theory link and I'd like to point out;

"We will never be able to turn back the clocks, thus we will never be absolutely sure of the correct answer."
 
  • #15
arildno said:
How do you prove that an isotope has a half-life of 5700years from 50years research?

Quite simple:
The relative rate of decay is a CONSTANT.
All you need to know in order to determine the half-life of the substance is the amount of stuff at two different instant.

Aye, but there's the rub:

1) Relative rate of decay is not constant [though current experiments have only shown it varies by a bit]
2) (More relevant) you said you have to know the "amount of stuff at two different instances," but of course that just gets us back to the original issue... one of those instances (the present) we can do...the other instant (the origin of the substance we care about) we obviously cannot do...because we cannot go back in time.
 

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