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Reverse evolution in real-time

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  • Reverse evolution in real-time

    http://www.eurekalert.org/pub_releases/2009-01/igd c-rei010609.php


    Public release date: 11-Jan-2009
    Contact: Ana Godinho
    [email protected]
    35-121-440-7959
    Instituto Gulbenkian de Ciencia

    Reverse evolution in real-time

    Instituto Gulbenkian de Ciencia scientists turn back clock on
    evolution in fruit fly to provide key insights into basic mechanisms
    of evolution In his book, Wonderful World, Stephen Jay Gould writes
    about an experiment of 'replaying life's tape', wherein one could go
    back in time, let the tape of life play again and see if 'the
    repetition looks at all like the original'. Evolutionary biology tells
    us that it wouldn't look the same - the outcome of evolution is
    contingent on everything that came before. Now, scientists at the
    Instituto Gulbenkian de Ciência (IGC) in Portugal, New York
    University and the University of California Irvine, provide the first
    quantitative genetic evidence of why this is so.

    In this study, to be published online this week in the journal Nature
    Genetics, Henrique Teotónio and his colleagues recreated natural
    selection in real-time, in the laboratory (rather than based on
    inferences from fossil records or from comparing existing natural
    populations) and provide the first quantitative evidence for natural
    selection on so-called standing genetic variation - a process long
    thought to be operating in natural populations that reproduce sexually
    but which, until now, had never been demonstrated.

    The researchers used laboratory-grown populations of fruit fly
    (Drosophila melanogaster), derived from an original group of flies,
    harvested from the wild back in 1975. These ancestral flies were grown
    in the laboratory, for two decades, under different environmental
    conditions, (such as starvation and longer life-cycles) so that each
    population was selected for specific characteristics. Henrique
    Teotónio and his colleagues placed these populations back in the
    ancestral environment, for 50 generations, to impose reverse evolution
    on the flies, and then looked at the genetic changes in certain areas
    of chromosome 3 of these flies.

    Says Henrique, 'In 2001 we showed that evolution is reversible in as
    far as phenotypes are concerned, but even then, only to a
    point. Indeed, not all the characteristics evolved back to the
    ancestral state. Furthermore, some characteristics reverse-evolved
    rapidly, while others took longer. Reverse evolution seems to stop
    when the populations of flies achieve adaptation to the ancestral
    environment, which may not coincide with the ancestral state. In this
    study, we have shown that underlying these phenomena is the fact that,
    at the genetic level, convergence to the ancestral state is on the
    order of 50%, that is, on average, only half of the gene frequencies
    revert to the ancestral gene frequencies - evolution is contingent
    upon history at the genetic level too'.

    These findings provide further insights into the basic understanding
    of how evolution and diversity are generated and maintained. On the
    one hand, it provides evidence for evolution happening through changes
    in the distribution of alleles in a population (so-called standing
    genetic variation), from generation to generation, rather than the
    appearance of mutations, from one generation to the next. On the other
    hand, as Henrique notes, 'It has implications for the definition of
    biodiversity: some of the 'reversed' flies may be phenotypically
    identical to the ancestral flies, but they are genetically
    different. How then do we define biodiversity?'

    This study was funded by a Fundação para a Ciência e a
    Tecnologia grant awarded to Henrique Teotónio, who joined the IGC
    in 2003 as a group leader and currently heads the Evolutionary
    Genetics group and the in-house PhD Programme in Life Sciences.

    Notes for Editors:

    The Instituto Gulbenkian de Ciência (IGC) is one of the leading
    life science research centres in Portugal. Founded by the Calouste
    Gulbenkian Foundation, the IGC´s mission is to carry out biomedical
    research and training. The IGC currently acts as a host institution to
    international research groups, providing state-of-the-art research
    facilities in a stimulating and autonomous environment. The IGC runs
    several ambitious graduate training programmes and a dedicated
    outreach and public engagement in science programme. More information
    is available at www.igc.gulbenkian.pt.

    Glossary:

    Allele - one member of a pair or series of different forms of a gene.
    Phenotype - any observable characteristic of a living organism, such
    as shape, size, physical features and behaviour. An organism's
    phenotype is a result of the activities of several of its genes, the
    environment or interactions between genes and the environment.
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