Evolution Is Still Happening: Beneficial Mutations in Humans
Tetrachromatic vision. Most mammals have poor color vision because they have only two kinds of cones, the retinal cells that discriminate different colors of light. Humans, like other primates, have three kinds, the legacy of a past where good color vision for finding ripe, brightly colored fruit was a survival advantage.
The gene for one kind of cone, which responds most strongly to blue, is found on chromosome 7. The two other kinds, which are sensitive to red and green, are both on the X chromosome. Since men have only one X, a mutation which disables either the red or the green gene will produce red-green colorblindness, while women have a backup copy. This explains why this is almost exclusively a male condition.
But here’s a question: What happens if a mutation to the red or the green gene, rather than disabling it, shifts the range of colors to which it responds? (The red and green genes arose in just this way, from duplication and divergence of a single ancestral cone gene.)
To a man, this would make no real difference. He’d still have three color receptors, just a different set than the rest of us. But if this happened to one of a woman’s cone genes, she’d have the blue, the red and the green on one X chromosome, and a mutated fourth one on the other… which means she’d have four different color receptors. She would be, like birds and turtles, a natural “tetrachromat”, theoretically capable of discriminating shades of color the rest of us can’t tell apart. (Does this mean she’d see brand-new colors the rest of us could never experience? That’s an open question.)
And we have evidence that just this has happened on rare occasions. In one study of color discrimination, at least one woman showed exactly the results we would expect from a true tetrachromat.
(via instaflan)
