BACKGROUND AND AIMS: Plant nuclear genomes vary tremendously in DNA content, mostly due to differences in ancestral ploidy and variation in the degree of transposon amplification. These processes can increase genome size, but little is known about mechanisms of genome shrinkage and the degree to which these can attenuate or reverse genome expansion. This research focuses on characterizing DNA removal from the rice and Arabidopsis genomes, and discusses whether loss of DNA has effectively competed with amplification in these species. METHODS: Retrotransposons were analyzed for sequence variation within several element families in rice and Arabidopsis. Nucleotide sequence changes in the two termini of individual retrotransposons were used to date their time of insertion. KEY RESULTS: An accumulation of small deletions was found in both species, caused by unequal homologous recombination and illegitimate recombination. The relative contribution of unequal homologous recombination compared to illegitimate recombination was higher in rice than in Arabidopsis. However, retrotransposons are rapidly removed in both species, as evidenced by the similar apparent ages of intact elements (most less than 3 million years old) in these two plants and all other investigated plant species. CONCLUSIONS: Differences in the activity of mechanisms for retrotransposon regulation or deletion generation between species could explain current genome size variation without any requirement for natural selection to act on this trait, although the results do not preclude selection as a contributing factor. The simplest model suggests that significant genome size variation is generated by lineage-specific differences in the molecular mechanisms of DNA amplification and removal, creating major variation in nuclear DNA content that can then serve as the substrate for fitness-based selection.
BACKGROUND AND AIMS: Plant nuclear genomes vary tremendously in DNA content, mostly due to differences in ancestral ploidy and variation in the degree of transposon amplification. These processes can increase genome size, but little is known about mechanisms of genome shrinkage and the degree to which these can attenuate or reverse genome expansion. This research focuses on characterizing DNA removal from the rice and Arabidopsis genomes, and discusses whether loss of DNA has effectively competed with amplification in these species. METHODS: Retrotransposons were analyzed for sequence variation within several element families in rice and Arabidopsis. Nucleotide sequence changes in the two termini of individual retrotransposons were used to date their time of insertion. KEY RESULTS: An accumulation of small deletions was found in both species, caused by unequal homologous recombination and illegitimate recombination. The relative contribution of unequal homologous recombination compared to illegitimate recombination was higher in rice than in Arabidopsis. However, retrotransposons are rapidly removed in both species, as evidenced by the similar apparent ages of intact elements (most less than 3 million years old) in these two plants and all other investigated plant species. CONCLUSIONS: Differences in the activity of mechanisms for retrotransposon regulation or deletion generation between species could explain current genome size variation without any requirement for natural selection to act on this trait, although the results do not preclude selection as a contributing factor. The simplest model suggests that significant genome size variation is generated by lineage-specific differences in the molecular mechanisms of DNA amplification and removal, creating major variation in nuclear DNA content that can then serve as the substrate for fitness-based selection.
Authors: Stephan Nielen; Bruna S Vidigal; Soraya C M Leal-Bertioli; Milind Ratnaparkhe; Andrew H Paterson; Olivier Garsmeur; Angélique D'Hont; Patricia M Guimarães; David J Bertioli Journal: Mol Genet Genomics Date: 2011-11-27 Impact factor: 3.291
Authors: J G Hodgson; M Sharafi; A Jalili; S Díaz; G Montserrat-Martí; C Palmer; B Cerabolini; S Pierce; B Hamzehee; Y Asri; Z Jamzad; P Wilson; J A Raven; S R Band; S Basconcelo; A Bogard; G Carter; M Charles; P Castro-Díez; J H C Cornelissen; G Funes; G Jones; M Khoshnevis; N Pérez-Harguindeguy; M C Pérez-Rontomé; F A Shirvany; F Vendramini; S Yazdani; R Abbas-Azimi; S Boustani; M Dehghan; J Guerrero-Campo; A Hynd; E Kowsary; F Kazemi-Saeed; B Siavash; P Villar-Salvador; R Craigie; A Naqinezhad; A Romo-Díez; L de Torres Espuny; E Simmons Journal: Ann Bot Date: 2010-04 Impact factor: 4.357
Authors: Mathieu Piednoël; Andre J Aberer; Gerald M Schneeweiss; Jiri Macas; Petr Novak; Heidrun Gundlach; Eva M Temsch; Susanne S Renner Journal: Mol Biol Evol Date: 2012-06-21 Impact factor: 16.240
Authors: Adam Wawrzynski; Tom Ashfield; Nicolas W G Chen; Jafar Mammadov; Ashley Nguyen; Ram Podicheti; Steven B Cannon; Vincent Thareau; Carine Ameline-Torregrosa; Ethalinda Cannon; Ben Chacko; Arnaud Couloux; Anita Dalwani; Roxanne Denny; Shweta Deshpande; Ashley N Egan; Natasha Glover; Stacy Howell; Dan Ilut; Hongshing Lai; Sara Martin Del Campo; Michelle Metcalf; Majesta O'Bleness; Bernard E Pfeil; Milind B Ratnaparkhe; Sylvie Samain; Iryna Sanders; Béatrice Ségurens; Mireille Sévignac; Sue Sherman-Broyles; Dominic M Tucker; Jing Yi; Jeff J Doyle; Valérie Geffroy; Bruce A Roe; M A Saghai Maroof; Nevin D Young; Roger W Innes Journal: Plant Physiol Date: 2008-10-24 Impact factor: 8.340
Authors: Jianchang Du; Zhixi Tian; Nathan J Bowen; Jeremy Schmutz; Randy C Shoemaker; Jianxin Ma Journal: Plant Cell Date: 2010-01-15 Impact factor: 11.277