Genome-defence small RNAs exapted for epigenetic mating-type inheritance

Singh, Dalbir; Saudemont, Baptiste; Guglielmi, Gérard; Arnaiz, Olivier; Goût, Jean-François; Prajer, M; Потехин, А. А.; Przyboś, Ewa; Aubusson-Fleury, Anne; Bhullar, Simran; Bouhouche, Khaled; Lhuillier-Akakpo, Maoussi; Tanty, Véronique; Blugeon, Corinne; Alberti, Adriana; Labadie, Karine; Aury, Jean‐Marc; Sperling, Linda; Duharcourt, Sandra; Meyer, Éric

doi:10.1038/nature13318

Cited by 107 publications

(118 citation statements)

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“…Later work provided fundamental insights into major issues in biology, including mutagenesis (Igarashi 1966), molecular and developmental genetics (Sonneborn 1947), symbiosis (Beale et al 1969), mitochondrial genetics (Adoutte and Beisson 1972), aging (Siegel 1967), nuclear differentiation (Berger 1937), and gene regulation (Allen and Gibson 1972). More recently, Paramecium has been used to study maternal inheritance (Nowacki et al 2005), programmed genome rearrangements and transposon domestication (Arnaiz et al 2012), epigenetic inheritance (Singh et al 2014), and whole-genome duplication (Aury et al 2006;Lynn McGrath, Jean-Francois Gout, Parul Johri, Thomas Graeme Doak, and Michael Lynch, unpublished results). Although not as well-studied as the P. aurelia complex of species, P. caudatum also has a long history of research (Calkins 1902;Sonneborn 1933).…”

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confidence: 99%

Insights into Three Whole-Genome Duplications Gleaned from theParamecium caudatumGenome Sequence

et al. 2014

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Paramecium has long been a model eukaryote. The sequence of the Paramecium tetraurelia genome reveals a history of three successive whole-genome duplications (WGDs), and the sequences of P. biaurelia and P. sexaurelia suggest that these WGDs are shared by all members of the aurelia species complex. Here, we present the genome sequence of P. caudatum, a species closely related to the P. aurelia species group. P. caudatum shares only the most ancient of the three WGDs with the aurelia complex. We found that P. caudatum maintains twice as many paralogs from this early event as the P. aurelia species, suggesting that post-WGD gene retention is influenced by subsequent WGDs and supporting the importance of selection for dosage in gene retention. The availability of P. caudatum as an outgroup allows an expanded analysis of the aurelia intermediate and recent WGD events. Both the Guanine+Cytosine (GC) content and the expression level of preduplication genes are significant predictors of duplicate retention. We find widespread asymmetrical evolution among aurelia paralogs, which is likely caused by gradual pseudogenization rather than by neofunctionalization. Finally, cases of divergent resolution of intermediate WGD duplicates between aurelia species implicate this process acts as an ongoing reinforcement mechanism of reproductive isolation long after a WGD event.T HE genus Paramecium has been used as a model unicellular eukaryotic system for over a century, beginning with research by Jennings (1908) and leading to some of the earliest derivations of mathematical population-genetics properties (Jennings 1916(Jennings , 1917. The subsequent discovery of mating types in members of the Paramecium aurelia complex (Sonneborn 1937) permitted the first systematic crossbreeding of different genotypes in any unicellular eukaryote. Later work provided fundamental insights into major issues in biology, including mutagenesis (Igarashi 1966), molecular and developmental genetics (Sonneborn 1947), symbiosis (Beale et al. 1969), mitochondrial genetics (Adoutte and Beisson 1972), aging (Siegel 1967), nuclear differentiation (Berger 1937), and gene regulation (Allen and Gibson 1972). More recently, Paramecium has been used to study maternal inheritance (Nowacki et al. 2005), programmed genome rearrangements and transposon domestication (Arnaiz et al. 2012), epigenetic inheritance (Singh et al. 2014), and whole-genome duplication (Aury et al. 2006; Lynn McGrath, Jean-Francois Gout, Parul Johri, Thomas Graeme Doak, and Michael Lynch, unpublished results). Although not as well-studied as the P. aurelia complex of species, P. caudatum also has a long history of research (Calkins 1902;Sonneborn 1933). Recent studies on P. caudatum involve investigations into quorum sensing (Fellous et al. 2012), thermal adaptation (Krenek et al. 2012), learning (Armus et al. 2006), endosymbiosis and parasite-mediated selection (Duncan et al. 2010(Duncan et al. , 2011, and ecotoxicology (Rao et al. 2007;Kawamoto et al. 2010;Hailong et al. 2011). P...

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confidence: 99%

Insights into Three Whole-Genome Duplications Gleaned from theParamecium caudatumGenome Sequence

et al. 2014

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“…Exaptation (the shift in the function of a trait during evolution, when a trait is co-opted for a different function than the original) may underlie some mechanisms which are involved in homoeostasis but it may also operate within the scenario presented in this book, which is the re-allocation of resources from germ line to soma. Those mechanisms originally developed in order to facilitate resource flow from soma to germ line (such as gene recombination and gamete selection), may (under certain circumstances, such as those discussed above) be exapted and operate in the opposite way: shift the balance of repair from germ line to soma [42]. This may not be a very long process, as it operates through epigenetic mechanisms some of which involve fast microRNA regulation [43].…”

Section: "Maintenance Of Epigenetic Silencing Of Repetitive Elements mentioning

confidence: 99%

Environmental challenges may impact on somatic repair

Kyriazis¹

2015

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During the process of ageing there is canalisation of repair resources which tend to flow from the soma towards the germ line. In the early periods of phylogenetic development there was a time when repair of germ line cells became more efficient compared to the repair of somatic cells. The level of somatic repair became just enough to ensure that the organism reached sexual maturity. It was the biological equivalent of the mathematical bifurcation, when the pathway developed preferentially towards the germ line attractor. We are now looking for evidence that this could be changing, that we may be witnessing a phase transition from effective germ line repair to an effective somatic repair. Here I consider mechanisms of fidelity-preservation which may be present in the germ line, and examine the possibility that these may be made to operate upon somatic cells instead. Mechanisms which safeguard the reliability of germ line repair and ensuring robustness/resilience in the germ line may also (or instead) be applicable upon somatic material (cells and molecules, factors) and ensure a continually effective repair of this somatic material. Thus the ability to continually repair and maintain somatic organic material within biological systems is not lost. Continual challenges from the environment ensure that the flow of information remains active and it persistently stimulates the ability to repair the soma. Apart from germ line cells, some unicellular organisms such as bacteria maintain their ability for ongoing repairs, a fact that indicates that, in principle, senescence is not unavoidable.

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“…Specific molecular mechanisms of cell determination and differentiation for MT in ciliates were revealed later (see, e.g. : Cervantes et al, 2013;Singh et al, 2014;Vallesi et al, 2014). It was of undoubted importance for us to study the case of D. anser in this respect.…”

Section: Mating Types In Dileptus Ansermentioning

confidence: 99%