Evolution of Linear Mitochondrial Genomes in Medusozoan Cnidarians

Kayal, Ehsan; Bentlage, Bastian; Collins, Allen G.; Kayal, Mohsen; Pirro, Stacy; Lavrov, Dennis V.

doi:10.1093/gbe/evr123

Cited by 138 publications

(216 citation statements)

References 58 publications

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“…Medusozoa (Cnidaria excluding Anthozoa) feature linear chromosomes that are split into two or more different molecules (Voigt et al, 2008;Kayal et al, 2012). hjoismäki and Goffart, 2011, and references therein).…”

Section: Aberrant Genome Structuresmentioning

confidence: 99%

“…Only the basal Anthozoa harbour circular mitochondrial genomes with a size of up to 21kb (Medina et al, 2006), while the other cnidarian classes display linear chromosomes. In Hydrozoa and Cubozoa they are in addition fragmented into several pieces (Voigt et al, 2008;Kayal et al, 2012). The largest number so far, eight chromosomes, has been found in the the cubozoan Alatina moseri.…”

Section: Aberrant Genome Structuresmentioning

confidence: 99%

“…Putative genomic regions involved in replication have been identified for Hydra, although several plausible mechanisms known for other genetic systems have been ruled out for this species (Voigt et al, 2008), see also (Kayal et al, 2012). It seems to be promising to evaluate alternative mechanisms for mitogenome replication known for nonmetazoans with linear or multipartite mitogenomes (see e.g.…”

Section: Model(s) Of Replicationmentioning

confidence: 99%

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Genetic aspects of mitochondrial genome evolution

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et al. 2013

Molecular Phylogenetics and Evolution

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Section: Aberrant Genome Structuresmentioning

confidence: 99%

Section: Aberrant Genome Structuresmentioning

confidence: 99%

Section: Model(s) Of Replicationmentioning

confidence: 99%

See 1 more Smart Citation

Genetic aspects of mitochondrial genome evolution

Bernt

Braband

Schierwater

et al. 2013

Molecular Phylogenetics and Evolution

227

148

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“…Митогеном многоклеточных животных, за исключением представи телей типа Knidaria, в большинстве случаев содержит 37 генов: 13 белоккодирующих генов, 22 гена тРНК и два гена рибосомальной РНК (Castellana et al, 2011;Kayal et al, 2012).…”

Section: филогенетикаunclassified

The mitochondrial gene order and CYTB gene evolution in insects

Sharko¹,

Nedoluzhko²,

Расторгуев³

et al. 2017

Vestn. VOGiS

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over millions of years of evolution, the genomes of modern insects have accumulated a significant num ber of mutations, which often can lead up a blind alley when carrying out phylogenetic research. genomic differences between some representatives belonging to the same family or group are often so great that they demand using nonconventional methods of the phylogenetic analysis. it is known that mole cular evo lution goes by the way of not only single nucleotide substitutions, but also by larger genomic reorganiza tions, such as insertion or deletion of large genome fragments, and even changing the order of genes. Mitochondrial Dna genes (mtDna) are quite often used as markers for phylogenetic research into many organisms including arthropods, because mtDna is multicopied, is inherited maternally, does not undergo recombination and accumulates mutations quickly enough (relative to the nuclear genome). to date, a large number of full nucleotide sequences of mitoge nomes (thousands of organisms) has been deposited in public databases; however, their phylogenetic ana lysis has obstacles, especially for representatives of the insects (insecta), whose evolution takes a consider able part of geological time. in this work we describe the application and a comparison of two ways of the phylogenetic analysis for different groups of insects. the first method uses the variability of the nucleotide sequence of mtDna, and the second one analyses the order of genes in full mitochondrial genomes of insects that can be used as an additional marker in phylogenetic research into representatives of the order Hymenoptera.Key words: gene order; mitochondrial Dna; insects; Hymenoptera; mitoSpider; cYtB; phylogeny.За миллионы лет эволюции геномы современных насекомых нако пили значительное количество мутаций. геномные различия неко торых представителей класса insecta, принадлежащих одному се мейству или отряду, настолько велики, что могут завести в тупик при проведении филогенетических исследований и требуют использования нетрадиционных методов анализа. известно, что молекулярная эволюция идет не только путем единичных нуклео тидных замен, но и включает в себя более крупные геномные пере стройки, такие как изменение порядка генов. гены митохондри альной днК (мтднК) достаточно часто используются в качестве маркера для филогенетических исследований у многих организ мов, в том числе членистоногих, поскольку мтднК многокопийна, наследуется по материнской линии, не подвержена рекомбинации и достаточно быстро (относительно ядерного генома) накапливает мутации. К настоящему времени в общедоступных базах данных собрано большое количество полных нуклеотидных последова тельностей митогеномов (тысячи организмов), однако их филоге нетический анализ имеет свои сложности, особенно для пред ставителей класса насекомые (insecta), чья эволюция занимает значи тельный отрезок геологического времени. Целью данного иссле дования была оценка возможности использования новых методи ческих приемов филогенетического анализа насекомых. срав ни ваются два способ...

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“…Os problemas classificatórios em Cnidaria têm atraído o interesse de zoólogos (Werner 1973a) e são diversos os trabalhos que apresentam teorias e hipóteses filogenéticas tentativas para classificar o grupo. As principais divergências concernem na problemática sobre: a diversificação dos ciclos de vida e qual dos dois estágios ou formas corporais (pólipo ou medusa) seria o mais basal (Werner 1973a;Werner 1973b;Bridge et al 1992;Schuchert 1993;Bridge et al 1995;Odorico and Miller 1997); na relação entre as quatro das atuais classes de Medusozoa (Hydrozoa, Scyphozoa, Cubozoa e Staurozoa); e entre os subgrupos de Hydrozoa e ordens de Scyphozoa (Marques and Collins 2004;Dawson 2004;Collins et al 2006;Daly et al 2007;Kayal et al 2012;Kayal et al 2013;Zapata et al 2015). Kayal et al (2013) ampliaram a amostragem dos genomas mitocondriais já apresentados para Cnidaria a fim de reavaliar as relações filogenéticas dentro do filo.…”

Section: Introdução Geralunclassified

Conformação gonadal, caracterização histoquímica e ultraestrutural da gônada masculina e espermatozoides em espécies de águas-vivas (Cubozoa e Scyphozoa, Medusozoa, Cnidaria)

Tiseo¹

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Evolution of Linear Mitochondrial Genomes in Medusozoan Cnidarians

Cited by 138 publications

References 58 publications

Genetic aspects of mitochondrial genome evolution

Genetic aspects of mitochondrial genome evolution

The mitochondrial gene order and CYTB gene evolution in insects

Conformação gonadal, caracterização histoquímica e ultraestrutural da gônada masculina e espermatozoides em espécies de águas-vivas (Cubozoa e Scyphozoa, Medusozoa, Cnidaria)

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