Not so fast with the evolutionary fantasies. If they can breed and produce fertile offspring, are they really different species? Maybe we've got the definitions wrong somewhere.
Evolution would be a change in the genetic foundation of that whole framework that makes an individual thrive in the environment. A change so big that it would ultimately lead to speciation.
Adaptation is done using existing mechanisms, with no new genetic changes besides the usual background noise. It never leads to speciation.
Biologists often ignore the traditional "breed with fertile offspring" definition when it doesn't fit the facts on the ground. For example, the Smew[1] can hybridize with the Common Goldeneye. Not only are they different species, but they are different genus!
> If they can breed and produce fertile offspring, are they really different species?
Species are defined more-or-less arbitrarily. It's essentially impossible to come up with a meaningful definition of "species" because of the nature of biology.
Imagine a gigantic tree, beginning with the first organism billions of years ago, with every living thing that ever existed as a node. Now, for the sake of the thought experiment, imagine that none of the lines ever died out.
There's no way to really consistently draw a line between one node and another and say "these are two different species." We pretty arbitrarily decide "well, these two sets are sufficiently different so let's call them two difference species." Like sibling commenters noted, sometimes hugely different species can interbreed and produce fertile offspring. Sometimes extremely similar (and related!) species can't breed. Or sometimes they can but never will except under laboratory conditions.
We make this classification, so we can adjust the rules until our model fits reality at an acceptable level. So let's define species as groups of individual of a similar genotype. We were not able to define and measure genetic distances in the past, but now with the ability to read whole genomes, we can do just that.
> sometimes hugely different species can interbreed and produce fertile offspring
Then they are obviously not hugely different. Were we just comparing phenotypes when we decided to classify them as different species? Let's improve on that.
> So let's define species as groups of individual of a similar genotype. We were not able to define and measure genetic distances in the past, but now with the ability to read whole genomes, we can do just that.
How similar?
Consider the following: imagine that you assembled a gathering of all your ancestors in the male line for say, the past two million years. Let's say, for illustrative purposes, that the gap between each generation is twenty years. So you'd have 5 people to represent a century - you, your father, your grandfather, your great-grandfather, and your great-great grandfather. That makes 50 people per millennium, 500 people per ten thousand years, 5,000 people per hundred thousand years, and 50,000 people per million years. So two million years of ancestry gets you 100,000 people, the size of a small city, or about enough people to fit in the Rose Bowl stadium.
So really, not that many people in the grand scheme of things. Now line all those people up in order going all the way back to the first guy, who we'll just call Adam. The difference between Adam N and Adam N+1 is very small. There's no point at which you can say "Adam N is this species and Adam N+1 is that other species." But there's a hell of difference between you and Adam.
The same logic applies to life in general, the tree is just a lot bigger and messier and we're talking about distant cousins rather than ancestors, and some lines are extinct.
But going back to your proposed definition - similar genotype - we can have all kinds of bizarre situations. Say we require the genotype to be 99% similar. By this definition, we conclude that Adam M and N are the same species. We also come to the conclusion that Adam N and Adam O are the same species. But wait! Adam M and O are only 98% similar! What do we do - assign multiple species labels to the same individuals?
Species has proven a necessary and useful abstraction, but it nevertheless doesn't hold up well under scrutiny. That's fine, as long as we recognize its limitations.
> Then they are obviously not hugely different. Were we just comparing phenotypes when we decided to classify them as different species? Let's improve on that.
Genotypes certainly provide useful information, but they can also muddy the waters.
Assume that we take the definition of "any two organisms that can interbreed and produce fertile offspring are the same species" as our preferred definition. (This has its own problems: for example, did you know mules sometimes are fertile, just not usually? Did you know it's conceivable that humans and chimpanzees can interbreed?) It is entirely possible for A and B to be distantly related genetically, yet able to interbreed, while A and C are closely related and unable to interbreed. "Can interbreed" is not necessarily a proxy for genetic distance.
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