Evolution of Dinoflagellate Unigenic Minicircles and the Partially Concerted Divergence of Their Putative Replicon Origins

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Molecular Biology and Evolution 19:489-500 (2002)
© 2002 Society for Molecular Biology and Evolution

Evolution of Dinoflagellate Unigenic Minicircles and the Partially Concerted Divergence of Their Putative Replicon Origins

Zhaoduo Zhang¹, Thomas Cavalier-Smith² and Beverley R. Green

Department of Botany, University of British Columbia

Dinoflagellate chloroplast genes are unique in that each geneis on a separate minicircular chromosome. To understand theorigin and evolution of this exceptional genomic organizationwe completely sequenced chloroplast psbA and 23S rRNA gene minicirclesfrom four dinoflagellates: three closely related Heterocapsaspecies (H. pygmaea, H. rotundata, and H. niei) and the verydistantly related Amphidinium carterae. We also completely sequenceda Protoceratium reticulatum minicircle with a 23S rRNA geneof novel structure. Comparison of these minicircles with thosepreviously sequenced from H. triquetra and A. operculatum showsthat in addition to the single gene all have noncoding regionsof approximately a kilobase, which are likely to include a replicationorigin, promoter, and perhaps segregation sequences. The noncodingregions always have a high potential for folding into hairpinsand loops. In all six dinoflagellate strains for which multipleminicircles are fully sequenced, parts of the noncoding regions,designated cores, are almost identical between the psbA and23S rRNA minicircles, but the remainder is very different. Thereare two, three, or four cores per circle, sometimes highly relatedin sequence, but no sequence identity is detectable betweencores of different species, even within one genus. This contrastbetween very high core conservation within a species, but noneamong species, indicates that cores are diverging relativelyrapidly in a concerted manner. This is the first well-establishedcase of concerted evolution of noncoding regions on numerousseparate chromosomes. It differs from concerted evolution amongtandemly repeated spacers between rRNA genes, and that of invertedrepeats in plant chloroplast genomes, in involving only thenoncoding DNA cores. We present two models for the origin ofchloroplast gene minicircles in dinoflagellates from a typicalancestral multigenic chloroplast genome. Both involve substantialgenomic reduction and gene transfer to the nucleus. One assumesdifferential gene deletion within a multicopy population ofthe resulting oligogenic circles. The other postulates activetransposition of putative replicon origins and formation ofminicircles by homologous recombination between them.

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