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Beer and bratwurst are great but I'd shove Germans in a false shower over the smell of sauerkraut. That **** isn't cool, dude.
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Although it doesn't go into the many conflicts that exist in anthills, and maybe more so in colonies consisting of many families, it still was a very good documentary, I thought. I have also taken a quick look at some of Wilson's ideas which don't quite seem as radical as my first impression was, though still enough to cause noise among evolutionary theorists. I won't comment too much on it yet as I've written enough to digest. As a closing comment for now, I do have the impression that super colonies may be made possible by the ants pheromone system. It is key to how they interact and it is also how they create infrastructure (scent highways), another arena where they could benefit from cooperation. The pheromone system is also something that sets them apart from other social hymenoptera like honey bees who do not form super colonies. At the same time, ants are kinda dumb with pheromones, like how they'll be easily fooled by anything that smells right. |
Can I wear an ant cologne and be accepted in their colony?
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*a scant
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They should make a cake the size of a building. Then dig an intricate series of tunnels in the ground. Then you take a hundred people and just have them get in a line and just go grab pieces of the cake and take it into the human hill and then go back out for more until the cake is gone. I'd do that ****.
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It does seem like ants can tell nestmates apart from non-nestmates (from another colony) based on smell, but it is unclear to me whether they are able to sniff out kin from non-kin.. which should be an important factor in how interactions evolve. Edit: Might seem so simple it's really dumb, but perhaps a combination of being unable to recognize kin coupled with some kind of constraint that inhibits the evolution of this ability is all ants need to evolve these weidly altruistic supercolonies. |
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Fanta is disgusting. ****ing antI-semites.
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There was a documentary I saw years ago by national geographic which highlighted the ways in which colonies exist along a certain sort of spectrum of eusociality. It was the same documentary I mentioned earlier which showed one of the workers in a colony start to try to go into the process of laying eggs and she was physically restrained and prevented from doing so by her sisters. This was in a long legged ant colony, where the difference in morphology between the queen and the workers was not as drastically pronounced. The workers weren't infertile, they just tended not to reproduce. In other colonies, however, the workers are born sterile and cannot reproduce. Their only reproductive outlet is through the queen which in essence means they are intrinsically tied to the well being of the colony. That is how it is suggested that traits can be selected for on the basis of making the colony more efficient. To my mind it's not much different than traits being selected for that make your body more equipped to survive to reproduction. If the genes of the colony flow strictly through the queen, then it seems like conceptualizing the colony as a sort of "body" with the queen as its reproductive organ is not all that different from the picture Dawkins paints of how genes eventually started coding to build robots (organisms) to carry the genes around and propagate them. Maybe there is something I'm missing but I don't quite see the conflict there. Since it's genes that are being selected for, not individuals, why must we insist the individuals necessarily be self interested?. If a colony of individuals which are born into specific castes to work for the purpose of facilitating the queens reproduction is a more effective way of spreading said genes than allowing for more individualism then why wouldn't natural selection favor it? BTW I read the selfish gene years ago... Could probably use a refresher but I'm familiar with it and as I noted above I don't really see a conflict between his thesis and the idea of a superorganism |
Also you asked am I in Wilson's camp... Not at all I'm only vaguely familiar with him tbh. I don't take any hard stances one way or the other but the way he articulates the superorganism seems to make sense to me... But wtf do I know?
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You may be missing something. The gene view / kin selection / inclusive fitness theory predicts normal one family/ monogamous queen ant colonies just fine because the ants are related and have the haplodiploid sex system.
However, the problem is the super colonies for aforementioned reasons. The ants are cooperating with ants to whom they are not (very) related, which seems like it would not evolve and also would be unstable. Reiterating quickly a couple of things:
Wilson, as far as I can tell, says that groups of altruists outcompete groups of selfish individuals. But AFAIK his group selection idea doesn't explain how pressure on groups also turn into pressure on the individual. For example, queens and their genes compete against many other queens with their own genes. It's easy to imagine some of the selection pressure that would come from that. Queens and their genes make and shape colonies. Their everyday conflicts would shape those genes. While altruistic groups may be competitive, I still can't quite see what pressure there is on these genes to evolve 'nicely' on behalf of a largely unrelated group. What's the mechanism? I currently don't feel like group selection is the answer, but I'll admit it's a conundrum. I suspect it's a varied explanation that has a lot to do with ant ecology coupled with possible constraints / limits. Like I wrote, if ants CAN'T tell which ants are kin and which are not (just nestmates from non-nestmates), then something as simple as that should be expected to turn them altruistic. The reason is their ancestral trait is that ALL of an anthill used to be kin. There was no other way, hence they didn't have to recognize kin. If they were friendly to nestmates, then they were nice to kin. Hence, that ancestral ant would be nice to a nestmate whether it was kin or not. So maybe they could have carried such naivety with them from olden days? You wouldn't expect that because in a colony with several queens/families, selection would so favor any new mutation in ants that lets them recognize kin. But possibly, there could be some limiting factor to ants ability to evolve such a trait. That's just my thinking so far and I expect it to change in the near future :) Edit: I'll check out Wilson's lecture when I find the time |
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As for the super colonies, I can't speak generally but say the one in the bbc documentary that was farming aphids on the spruce trees, Attenborough does mention how the cooperation there is serving a practical benefit with regard to being granted access to the resources that can be marshalled by that big of a colony. |
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His lecture wasn't very illuminating. To my mind, he suggests that evolution happens at multiple levels. Through evolution at the gene/individual level, you can, by chance, evolve a set of important pre-conditions. Something he mentions is a defensible nest and the trait of not dispersing, but staying put. Wilson's thought is that if "normal" evolution leads to a species/colony attaining all these pre-conditions, they can flip over into an altruistic colony. That colony then has to make it in a competition with other non-altruistic colonies and has to be competitive. If it is, it will be selected for at the group level. It is my impression that he thinks group selection is what keeps these groups altruistic over time, yet he does not go into the supposed mechanisms by which that should work. He does mention that it can be shown in maths which I assume means you can make it work in a model. It's true, you can, but my current impression is that this is possible because the living conditions for organisms in models can become very weird, like they can have no parental investment in their young and possibly become adults once they're born, there may be no cost to simply living, etc. Anyways, something he fails to bring up is whether or not the ants he talks about are kin. He says he distrusts kin selection as an explanation for superorganisms and so, if the individual ants were not kin, he could have capitalized and gotten support for his statement by mentioning that, but he didn't. Hence, I assume the ants in his examples were kin. As mentioned, kin selection theory has no trouble explaining the evolution of a superorganism and actually, solving that mystery was one of kin selection's big selling points in the 60s. Kin selection alone cannot explain a supercolony, but a superorganism is no trouble.. as long as the individuals that make up the superorganism are closely related. There are other ways to evolve cooperation (like reciprocality), but kin selection is expected to lead to higher apparent "altruism" (altruism on the level of individuals, selfishness on the level of genes). The word superorganism isn't one that I myself would use because it kinda hides the fact that ant hills are colonies occasionally marked by conflicts of interests between its inhabitants. Individuals don't always behave altruistic and even if they did, normal evolutionary theory (kin selection / inclusive fitness) can predict when that altruism should break down. The word is a heuristic device good for illustrating a point or to use in sentences like "evolution of the superorganism", but that's about it. He's mostly in the world of ants, but when talking about superorganisms, it would be interesting to go into the world of colony animals, like siphonophores which is the group containing the famous portuguese man o war. https://i.pinimg.com/originals/63/4c...5cfc736d7a.jpg In their specific case, all the zooids (individuals) that make up the man o war are genetically identical and so kin selection would fully explain that. |
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You don't think group selection is a good explaination. But you also don't have any idea what a good explaination would be. Is that more or less where we're at? |
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I have suggested a possible explanation. Ants being unable to recognize kin-nestmates from non-kin-nestmates could (should?) turn them altruistic. Generally, I would expect ants to evolve this ability, but there may be some constraint to its evolution. However, not being an ant expert, I am unsure of how good that suggested explanation is. Perhaps we should just shoot an email to Bert Hölldobler and ask him what he thinks. |
I dunno who that is but if you could get him to comment that's be cool. I appreciate your input anyway.
What you suggested about them not being able to recognize non kin sounds essentially like what they said happened in the one national geographic documentary that first brought this to my attention. They said something about either the ants from different nests stopped recognizing the difference between their scents or that somehow the scents were altered to be the same. Not sure which it was but basically the result is they don't seem to recognize that these ants from neighboring colonies aren't part of their colony. Instead of this being a mutation that hurts the colony and leaves it vulnerable to more "selfish" traditional colonies, it seems like it lead to them spreading from Argentina to Europe and other parts of the globe. It seems to me on the face of it that there is at least some utility/advantage to being able to drastically increase the scale on which colonies can cooperate, but I'm not sure if maybe it ultimately is unstable as you suggested it might be. I guess time will tell |
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So with kin selection sort of stopped in its tracks, at least temporarily, I'll admit there might be some merit to Wilson's group selection arguments. You're also right that this could make it unstable in the long run. It might be a while, though. I may be blabbering on, but there's a concept in evolutionary which illustrates evolutionary constraints in a nice way which is fitness landscapes. They look kinda like this: https://advances.sciencemag.org/cont...1/F1.large.jpg I'm not exactly sure what the landscapes here represent, but if we look at C, we can just make up a silly scenario for illustrative purposes. Lets just say birds and say that the landscape represents different adaptations in beak size. The dips and peaks in the chart represent fitness or how good an adaptation/strategy is (the higher the better). So the little peak to the right could be a small beak. It's good for cracking seeds so it's a good adaptation. However, there is an even more optimal beak size to the left in the landscape, illustrated by the largest peak. This could be a longer beak great for reaching insects hiding in the wood. One might think if it's better to have a longer beak, that would simply evolve, but in this case the stepwise evolutionary path of gradual beak elongation would take the birds into a dip where the beak is a decidedly un-optimal shape. The middle ground adaptation, the in-between beak, has lower fitness than any of the positive strategies. So if some birds just start down that path, natural selection will work against them and push the population back up into the strategy they already have. Natural selection prevents them from evolving into the optimal beak shape strategy. In order to make the "leap", they may have to make it as a single mutation, giving rise to one special bird with a much better beak. This happens for some traits, but it's not likely to happen for something like a bird beak. So I'm not sure what the constraints would be to ants evolving kin-recognition, but constraints are usually present in some shape and it's not unlikely that there could be one or more and that the effect could be considerable. edit: I sent a mail to Hölldobler :) I don't expect an answer, but will of course share one if it comes. |
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