Molecular Phylogeny and Evolution of Morphology in the Social Amoebas

Pauline Schaap; Thomas Winckler; Michaela Nelson; Elisa Alvarez‐Curto; Barrie Elgie; Hiromitsu Hagiwara; James C. Cavender; Alicia Milano-Curto; Daniel E. Rozen; Theo Dingermann; Rupert Mutzel; Sandra L. Baldauf

doi:10.1126/science.1130670

Molecular Phylogeny and Evolution of Morphology in the Social Amoebas

Pauline Schaap(University of Dundee), Thomas Winckler(University of Dundee), Michaela Nelson(University of Dundee), Elisa Alvarez‐Curto(University of Dundee), Barrie Elgie(University of Dundee), Hiromitsu Hagiwara(University of Dundee), James C. Cavender(University of Dundee), Alicia Milano-Curto(University of Dundee), Daniel E. Rozen(University of Dundee), Theo Dingermann(University of Dundee), Rupert Mutzel(University of Dundee), Sandra L. Baldauf(University of Dundee)

Science

October 26, 2006

10.1126/science.1130670

Cited by 282Open Access

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Abstract

The social amoebas (Dictyostelia) display conditional multicellularity in a wide variety of forms. Despite widespread interest in Dictyostelium discoideum as a model system, almost no molecular data exist from the rest of the group. We constructed the first molecular phylogeny of the Dictyostelia with parallel small subunit ribosomal RNA and a-tubulin data sets, and we found that dictyostelid taxonomy requires complete revision. A mapping of characters onto the phylogeny shows that the dominant trend in dictyostelid evolution is increased size and cell type specialization of fruiting structures, with some complex morphologies evolving several times independently. Thus, the latter may be controlled by only a few genes, making their underlying mechanisms relatively easy to unravel.

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