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Why Mexican cavefish turned blind
Several populations of cavefish have constantly and independently, lost their eyesight and pigmentation.
Washington: Several populations of cavefish have constantly and independently, lost their eyesight and pigmentation, which is a remarkable example of convergent evolution, researchers say.
The blind Mexican cavefish (Astyanax mexicanus) have not only lost their sight but have adapted to perpetual darkness by also losing their pigment (albinism) and having altered sleep patterns.
The blind cavefish and the surface dwelling Mexican tetra, despite appearances, are the same species and can interbreed. The cavefish are simply a variant of the Mexican tetra, albeit one adapted to living in complete darkness. A team of researchers from Portugal, America, and Mexico studied the DNA from 11 populations of cavefish (from three geographic regions) and 10 populations of their surface dwelling cousins to help understand the evolutionary origin of the physical difference between them.
While results from the genotyping showed that the surface populations were genetically very similar, the story for the cave populations was very different.
The cave forms had a much lower genetic diversity, probably as a result of limited space and food. Not surprisingly the cave populations with the most influx from the surface had the highest diversity. In fact there seemed to be a great deal of migration in both directions.
It has been thought that historically at least two groups of fish lived in the rivers of Sierra de El Abra, Mexico. One group originally colonized the caves, but became extinct on the surface. A different population then restocked the rivers and also invaded the caves. “We were fortunate in being able to use A. mexicanus as a kind of ‘natural’ experiment where nature has already provided the crosses and isolation events between populations for us. Our genotyping results have provided evidence that the cave variant had at least five separate evolutionary origins from these two ancestral stocks,” Prof Richard Borowsky, from the Cave Biology Group at New York University said.
“Despite interbreeding and gene flow from the surface populations the eyeless ‘cave phenotype’ has been maintained in the caves. This indicates that there must be strong selection pressure against eyes in the cave environment,” Dr Martina Bradic who lead the research continued.
“Whatever the advantage of the eyeless condition, it may explain why different populations of A. mexicanus cave fish have independently evolved the same eyeless condition, a striking example of convergent evolution,” Dr Bradic added. The study has been published in BioMed Central’s open access journal BMC Evolutionary Biology.
ANI
The blind Mexican cavefish (Astyanax mexicanus) have not only lost their sight but have adapted to perpetual darkness by also losing their pigment (albinism) and having altered sleep patterns.
The blind cavefish and the surface dwelling Mexican tetra, despite appearances, are the same species and can interbreed. The cavefish are simply a variant of the Mexican tetra, albeit one adapted to living in complete darkness. A team of researchers from Portugal, America, and Mexico studied the DNA from 11 populations of cavefish (from three geographic regions) and 10 populations of their surface dwelling cousins to help understand the evolutionary origin of the physical difference between them.
While results from the genotyping showed that the surface populations were genetically very similar, the story for the cave populations was very different.
The cave forms had a much lower genetic diversity, probably as a result of limited space and food. Not surprisingly the cave populations with the most influx from the surface had the highest diversity. In fact there seemed to be a great deal of migration in both directions.
It has been thought that historically at least two groups of fish lived in the rivers of Sierra de El Abra, Mexico. One group originally colonized the caves, but became extinct on the surface. A different population then restocked the rivers and also invaded the caves. “We were fortunate in being able to use A. mexicanus as a kind of ‘natural’ experiment where nature has already provided the crosses and isolation events between populations for us. Our genotyping results have provided evidence that the cave variant had at least five separate evolutionary origins from these two ancestral stocks,” Prof Richard Borowsky, from the Cave Biology Group at New York University said.
“Despite interbreeding and gene flow from the surface populations the eyeless ‘cave phenotype’ has been maintained in the caves. This indicates that there must be strong selection pressure against eyes in the cave environment,” Dr Martina Bradic who lead the research continued.
“Whatever the advantage of the eyeless condition, it may explain why different populations of A. mexicanus cave fish have independently evolved the same eyeless condition, a striking example of convergent evolution,” Dr Bradic added. The study has been published in BioMed Central’s open access journal BMC Evolutionary Biology.
ANI