The lack of recombination drives the fixation of transposable elements on the fourth chromosome of Drosophila melanogaster

CAROLINA BARTOLOMÉ; XULIO MASIDE

doi:10.1017/S0016672304006755

Abstract

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In regions of suppressed recombination, where selection is expected to be less efficient in removing slightly deleterious mutations, transposable element (TE) insertions should be more likely to drift to higher frequencies, and even to reach fixation. In the absence of excision events, once a TE is fixed it cannot be eliminated from the population, and accumulation of elements thus should become an irreversible process. In the long term, this can drive the degeneration of large non-recombining fractions of the genomes. Chromosome 4 of Drosophila melanogaster has very low levels of recombination, if any, and this could be causing its degeneration. Here we report the results of a PCR-based analysis of the population frequencies of TE insertions in a sample from three African natural populations. We investigated 27 insertions from 12 TE families, located in regions of either suppressed or free recombination. Our results suggest that TE insertions tend to be fixed in the non-recombining regions, particularly on the fourth chromosome. We have also found that this involves all types of elements, and that fixed insertions are significantly shorter and more divergent from the canonical sequence than those segregating in the sample (28·1% vs. 86·3% of the canonical length, and average nucleotide divergence (DXY)=0·082 vs. 0·008, respectively). Finally, DNA-based elements seem to show a greater tendency to reach fixation than retrotransposons. Implications of these findings for the population dynamics of TEs, and the evolutionary forces that shape the patterns of genetic variation in regions of reduced recombination, are discussed.

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Neafsey, Daniel E. Blumenstiel, Justin P. and Hartl, Daniel L. 2004. Different Regulatory Mechanisms Underlie Similar Transposable Element Profiles in Pufferfish and Fruitflies. Molecular Biology and Evolution, Vol. 21, Issue. 12, p. 2310.

Lipatov, Mikhail Lenkov, Kapa Petrov, Dmitri A and Bergman, Casey M 2005. Paucity of chimeric gene-transposable element transcripts in the Drosophila melanogaster genome. BMC Biology, Vol. 3, Issue. 1,

Casals, Ferran Cáceres, Mario Manfrin, Maura Helena González, Josefa and Ruiz, Alfredo 2005. Molecular Characterization and Chromosomal Distribution of Galileo, Kepler and Newton, Three Foldback Transposable Elements of the Drosophila buzzatii Species ComplexSequence data from this article have been deposited in the EMBL/GenBank Data Libraries under accession nos. AY756161, AY756162, AY756163, AY756164, AY756165, AY756166, AY756167, AY756168, AY756169, AY756170.. Genetics, Vol. 169, Issue. 4, p. 2047.

Abe, H. Seki, M. Ohbayashi, F. Tanaka, N. Yamashita, J. Fujii, T. Yokoyama, T. Takahashi, M. Banno, Y. Sahara, K. Yoshido, A. Ihara, J. Yasukochi, Y. Mita, K. Ajimura, M. Suzuki, M. G. Oshiki, T. and Shimada, T. 2005. Partial deletions of the W chromosome due to reciprocal translocation in the silkworm Bombyx mori. Insect Molecular Biology, Vol. 14, Issue. 4, p. 339.

Charlesworth, D Charlesworth, B and Marais, G 2005. Steps in the evolution of heteromorphic sex chromosomes. Heredity, Vol. 95, Issue. 2, p. 118.

Steinemann, Sigrid and Steinemann, Manfred 2005. Y chromosomes: born to be destroyed. BioEssays, Vol. 27, Issue. 10, p. 1076.

Samant, Sadhana A. Ogunkua, Olugbemiga O. Hui, Ling Lu, Jing Han, Yibing Orth, Joanne M. and Pilder, Stephen H. 2005. The mouse t complex distorter/sterility candidate, Dnahc8, expresses a γ-type axonemal dynein heavy chain isoform confined to the principal piece of the sperm tail. Developmental Biology, Vol. 285, Issue. 1, p. 57.

Khan, Asis Böhme, Ulrike Kelly, Krystyna A. Adlem, Ellen Brooks, Karen Simmonds, Mark Mungall, Karen Quail, Michael A. Arrowsmith, Claire Chillingworth, Tracey Churcher, Carol Harris, David Collins, Matthew Fosker, Nigel Fraser, Audrey Hance, Zahra Jagels, Kay Moule, Sharon Murphy, Lee O'Neil, Susan Rajandream, Marie-Adele Saunders, David Seeger, Kathy Whitehead, Sally Mayr, Thomas Xuan, Xuenan Watanabe, Junichi Suzuki, Yutaka Wakaguri, Hiroyuki Sugano, Sumio Sugimoto, Chihiro Paulsen, Ian Mackey, Aaron J. Roos, David S. Hall, Neil Berriman, Matthew Barrell, Bart Sibley, L. David and Ajioka, James W. 2006. Common inheritance of chromosome Ia associated with clonal expansion of Toxoplasma gondii. Genome Research, Vol. 16, Issue. 9, p. 1119.

Casals, Ferran González, Josefa and Ruiz, Alfredo 2006. Abundance and chromosomal distribution of six Drosophila buzzatii transposons: BuT1, BuT2, BuT3, BuT4, BuT5, and BuT6. Chromosoma, Vol. 115, Issue. 5, p. 403.

Kuhn, Gustavo C. S. Franco, Fernando F. Manfrin, Maura H. Moreira-Filho, Orlando and Sene, Fabio M. 2007. Low rates of homogenization of the DBC-150 satellite DNA family restricted to a single pair of microchromosomes in species from the Drosophila buzzatii cluster. Chromosome Research, Vol. 15, Issue. 4, p. 457.

García Guerreiro, María Pilar and Fontdevila, Antonio 2007. The Evolutionary History of Drosophila buzzatii. XXXVI. Molecular Structural Analysis of Osvaldo Retrotransposon Insertions in Colonizing Populations Unveils Drift Effects in Founder Events. Genetics, Vol. 175, Issue. 1, p. 301.

Santolamazza, Federica Mancini, Emiliano Simard, Frédéric Qi, Yumin Tu, Zhijian and della Torre, Alessandra 2008. Insertion polymorphisms of SINE200 retrotransposons within speciation islands of Anopheles gambiae molecular forms. Malaria Journal, Vol. 7, Issue. 1,

DOLGIN, ELIE S. CHARLESWORTH, BRIAN and CUTTER, ASHER D. 2008. Population frequencies of transposable elements in selfing and outcrossingCaenorhabditisnematodes. Genetics Research, Vol. 90, Issue. 4, p. 317.

García Guerreiro, María Pilar Chávez-Sandoval, Blanca E Balanyà, Joan Serra, Lluís and Fontdevila, Antonio 2008. Distribution of the transposable elements bilbo and gypsy in original and colonizing populations of Drosophila subobscura. BMC Evolutionary Biology, Vol. 8, Issue. 1,

Reis, Micael Vieira, Cristina P. Morales-Hojas, Ramiro and Vieira, Jorge 2008. An old bilbo-like non-LTR retroelement insertion provides insight into the relationship of species of the virilis group. Gene, Vol. 425, Issue. 1-2, p. 48.

Dolgin, Elie S and Charlesworth, Brian 2008. The Effects of Recombination Rate on the Distribution and Abundance of Transposable Elements. Genetics, Vol. 178, Issue. 4, p. 2169.

Bartolomé, Carolina Bello, Xabier and Maside, Xulio 2009. Widespread evidence for horizontal transfer of transposable elements across Drosophilagenomes. Genome Biology, Vol. 10, Issue. 2,

Sackton, Timothy B. Kulathinal, Rob J. Bergman, Casey M. Quinlan, Aaron R. Dopman, Erik B. Carneiro, Mauricio Marth, Gabor T. Hartl, Daniel L. and Clark, Andrew G. 2009. Population Genomic Inferences from Sparse High-Throughput Sequencing of Two Populations of Drosophila melanogaster. Genome Biology and Evolution, Vol. 1, Issue. , p. 449.

González, Josefa and Petrov, Dmitri A. 2009. The adaptive role of transposable elements in the Drosophila genome. Gene, Vol. 448, Issue. 2, p. 124.

Behura, S. K. Shukle, R. H. and Stuart, J. J. 2010. Assessment of structural variation and molecular mapping of insertion sites of Desmar‐like elements in the Hessian fly genome. Insect Molecular Biology, Vol. 19, Issue. 6, p. 707.

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The lack of recombination drives the fixation of transposable elements on the fourth chromosome of Drosophila melanogaster

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