NUPTs in Sequenced Eukaryotes and Their Genomic Organization in Relation to NUMTs

doi:10.1093/molbev/msh210

MBE Advance Access originally published online on July 14, 2004
Molecular Biology and Evolution 2004 21(10):1972-1980; doi:10.1093/molbev/msh210

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Molecular Biology and Evolution vol. 21 no. 10 © Society for Molecular Biology and Evolution 2004; all rights reserved.

Research Article

NUPTs in Sequenced Eukaryotes and Their Genomic Organization in Relation to NUMTs

Erik Richly and Dario Leister

Abteilung für Pflanzenzüchtung und Ertragsphysiologie, and Abteilung für Pflanzenzüchtung und Genetik; Max-Planck-Institut für Züchtungsforschung, Köln, Germany

E-mail: leister{at}mpiz-koeln.mpg.de.

NUPTs (nuclear plastid DNA) derive from plastid-to-nucleus DNAtransfer and exist in various plant species. Experimental dataimply that the DNA transfer is an ongoing, highly frequent process,but for the interspecific diversity of NUPTs, no clear explanationexists. Here, an inventory of NUPTs in the four sequenced plastid-bearingspecies and their genomic organization is presented. Large genomeswith a predicted low gene density contain more NUPTs. In Chlamydomonasand Plasmodium, DNA transfer occurred but was limited, probablybecause of the presence of only one plastid per cell. In Arabidopsisand rice, NUPTs are frequently organized as clusters. Tightclusters can contain both NUPTs and NUMTs (nuclear mitochondrialDNA), indicating that preNUPTs and preNUMTs might have concatamerizedbefore integration. The composition of such a hypothetical preNUPT-preNUMTpool seems to be variable, as implied by substantially differentNUPTs:NUMTs ratios in different species. Loose clusters canspan several dozens of kbps of nuclear DNA, and they containmarkedly more NUPTs or NUMTs than expected from a random genomicdistribution of nuclear organellar DNA. The level of sequencesimilarity between NUPTs/NUMTs and plastid/mitochondrial DNAcorrelates with the size of the integrant. This implies thatoriginal insertions are large and decay over evolutionary timeinto smaller fragments with diverging sequences. We suggestthat tight and loose clusters represent intermediates of thisdecay process.

Key Words: gene transfer • genome evolution • mitochondrion • NUMT • NUPT • plastid

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