A University of Leicester (UK) research team led by Dr Eran Tauber has studied genetic variation in circadian clock genes in wild populations of the fruit fly, Drosophila melanogaster–and has discovered that their genes have developed different genetic variations that are functionally important. The paper was published in PLOS ONE.
The research focuses on examining a protein called Cryptochrome (CRY), a blue light photoreceptor that synchronizes the circadian clock of the fruit fly with the environmental light-dark cycle. CRY is involved in circadian clock functioning in both plants and animals, including humans.
Adaptive variations have resulted in two versions of the CRY protein existing in fruit flies, both with a different amino acid present–these amino acids affect the circadian clock of the fruit fly.
Tauber says in a release: “The fruit-fly has been a major model organism in the study of the circadian clock, and our collection of strains from various wild populations allow us to identify changes in the genes that serve as molecular adaptations of populations to their local environments. We have analysed the sequence of these genes in flies from different European populations and identified many variations. One of these variations involves a single DNA base change resulting in two versions of the protein, each with a different amino acid.”
Bioinformatic analysis of the protein structure was carried out by Dr Ralf Schmid from the University of Leicester’s Department of Biochemistry, and suggests that this single mutation has a profound effect on the protein structure of the fruit fly.
Dr Mirko Pegoraro, a researcher from the University of Leicester, says: “The fact that the two versions of the protein are present in similar proportions in all the fruit fly populations that we sampled suggests that this variation is functionally important in the species and is actively maintained by natural selection.
“We have tested the behaviour of the flies that express the different CRY proteins and found some interesting and significant differences in their activity pattern during the day, and adult emergence from their pupae. The fact that a single amino acid change can result in a different behaviour is an extraordinary discovery.”
The frequency of the genetic variants became similar in a controlled research environment, simulating the frequencies observed in the wild. Using this kind of experimental evolution allowed the team to demonstrate that this variation is actively maintained by the species, although the exact mechanism is yet to be identified.