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The highly reduced genome of an enslaved algal nucleus

Author

Listed:
  • Susan Douglas

    (National Research Council of Canada Institute for Marine Biosciences and Program in Evolutionary Biology, Canadian Institute of Advanced Research)

  • Stefan Zauner

    (Cell Biology and Applied Botany, Philipps-University Marburg)

  • Martin Fraunholz

    (Cell Biology and Applied Botany, Philipps-University Marburg
    University of Philadelphia)

  • Margaret Beaton

    (Program in Evolutionary Biology, Canadian Institute of Advanced Research, University of British Columbia
    Mount Allison University)

  • Susanne Penny

    (National Research Council of Canada Institute for Marine Biosciences and Program in Evolutionary Biology, Canadian Institute of Advanced Research)

  • Lang-Tuo Deng

    (Program in Evolutionary Biology, Canadian Institute of Advanced Research, University of British Columbia)

  • Xiaonan Wu

    (Program in Evolutionary Biology, Canadian Institute of Advanced Research, University of British Columbia)

  • Michael Reith

    (National Research Council of Canada Institute for Marine Biosciences and Program in Evolutionary Biology, Canadian Institute of Advanced Research)

  • Thomas Cavalier-Smith

    (Program in Evolutionary Biology, Canadian Institute of Advanced Research, University of British Columbia
    University of Oxford)

  • Uwe-G Maier

    (Cell Biology and Applied Botany, Philipps-University Marburg)

Abstract

Chromophyte algae differ fundamentally from plants in possessing chloroplasts that contain chlorophyll c and that have a more complex bounding-membrane topology1. Although chromophytes are known to be evolutionary chimaeras of a red alga and a non-photosynthetic host1, which gave rise to their exceptional membrane complexity, their cell biology is poorly understood. Cryptomonads are the only chromophytes that still retain the enslaved red algal nucleus as a minute nucleomorph2,3,4. Here we report complete sequences for all three nucleomorph chromosomes from the cryptomonad Guillardia theta. This tiny 551-kilobase eukaryotic genome is the most gene-dense known, with only 17 diminutive spliceosomal introns and 44 overlapping genes. Marked evolutionary compaction hundreds of millions of years ago1,4,5 eliminated nearly all the nucleomorph genes for metabolic functions, but left 30 for chloroplast-located proteins. To allow expression of these proteins, nucleomorphs retain hundreds of genetic-housekeeping genes5. Nucleomorph DNA replication and periplastid protein synthesis require the import of many nuclear gene products across endoplasmic reticulum and periplastid membranes. The chromosomes have centromeres, but possibly only one loop domain, offering a means for studying eukaryotic chromosome replication, segregation and evolution.

Suggested Citation

  • Susan Douglas & Stefan Zauner & Martin Fraunholz & Margaret Beaton & Susanne Penny & Lang-Tuo Deng & Xiaonan Wu & Michael Reith & Thomas Cavalier-Smith & Uwe-G Maier, 2001. "The highly reduced genome of an enslaved algal nucleus," Nature, Nature, vol. 410(6832), pages 1091-1096, April.
    • Handle: RePEc:nat:nature:v:410:y:2001:i:6832:d:10.1038_35074092
    DOI: 10.1038/35074092
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