Biology Asked on August 22, 2021
Fisher’s principle explains why sex ratios in most sexually reproducing species is approximately $1:1$. However, given that in humans and many other animals, males and females differ genetically, it seems that this should cause issues for Fisher’s principle.
Say that the Y-chromosome of an animal had a mutation that increased the ratios of males to females produced by the animal. At the extreme, we could imagine a mutation such that the sperm of the animal only carried Y-chromosomes. Although, by the Fisher principle, this would be bad for the overall number of offspring produces by the animal, it seems it would be good for the Y-chromosome itself, since it will now be present in all descendants of the animal (since they are all male), rather than only half the descendants. I would therefore expect that such a mutation would spread, skewing the sex ratios away from $1:1$.
Have scenarios like the one I outlined above actually occurred in species? If not, why not?
This sort of thing absolutely happens; useful search terms are "sex ratio distortion", "segregation distortion" (i.e. modifying the ratios with which different chromosomes segregate), and "meiotic drive" (a specific form of segregation distortion).
Your scenario (Y-chromosome genes forcing all offspring to be male) is much less common than the reverse (X-chromosome genes, or other genomic elements, forcing all offspring to be female), because it's easy for an all-female lineage to maintain itself by parthenogenesis. Lyttle (1991) says:
Strong Y drive is of necessity transitory, since drive suppression must either evolve very quickly or the population will be pushed to extinction. This may explain why few Y drive systems have been observed in nature.
However, Lyttle goes on to describe
Jaenike (2001) says
Although several species exhibit Y drive, X drive is far more common.
Table 1 in that paper lists Y-drive examples in houseflies, mosquitoes, medflies, lemmings, and field mice. (I would include an image, but the table extends over 4 pages ...)
As for your final question,
I would therefore expect that such a mutation would spread, skewing the sex ratios away from 1:1 ... Have scenarios like the one I outlined above actually occurred in species? If not, why not?
I haven't dug through all the original literature that Jaenike (2001) cites, to see if there are populations in nature that are male-skewed due to selfish Y chromosomes. The point that Lyttle makes is that, even if you can find evidence of the existence of selfish Y chromosomes hiding in the population, it's very unlikely that these will persist in natural populations for very long, because of the strong selection against them at the population level (and from the rest of the genome); either the population will go extinct, or moderators will evolve that suppress the driving effect of the Y chromosome.
Jaenike, John. “Sex Chromosome Meiotic Drive.” Annual Review of Ecology and Systematics 32, no. 1 (2001): 25–49. https://doi.org/10.1146/annurev.ecolsys.32.081501.113958.
Lyttle, Terrence W. “Segregation Distorters.” Annual Review of Genetics 25, no. 1 (1991): 511–81. https://doi.org/10.1146/annurev.ge.25.120191.002455.
Correct answer by Ben Bolker on August 22, 2021
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