The Mitochondrial Genomes of a Myxozoan Genus Kudoa Are Extremely Divergent in Metazoa

Takeuchi, Fumihiko; Sekizuka, Tsuyoshi; Ogasawara, Yumiko; Yokoyama, Hiroshi; Kamikawa, Ryoma; Inagaki, Yuji; Nozaki, Tomoyoshi; Sugita-Konishi, Yoshiko; Ohnishi, Takahiro; Kuroda, Makoto

doi:10.1371/journal.pone.0132030

Cited by 33 publications

(51 citation statements)

References 69 publications

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“…Parasitic taxa are likely to have a faster rate of molecular evolution in order to win the “arms race” against their hosts (e.g., Bromham, Cowman, & Lanfear, ; Paterson et al., ). The rate heterogeneity across genes within the Myxozoa can be as high as that between myxozoans and other organisms (Hartigan et al., ; this study), and mitochondrial gene order and organization is highly variable (Takeuchi et al., ; Yahalomi et al., ), indicating a considerably accelerated rate of molecular evolution, possibly the fastest known among eukaryotes. This may well be explained by the extraordinary level of radiation that occurred within this group (Castro, Austin, & Dowton, ; Eo & DeWoody, ).…”

Section: Discussionmentioning

confidence: 60%

The joint evolution of the Myxozoa and their alternate hosts: A cnidarian recipe for success and vast biodiversity

et al. 2018

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The relationships between parasites and their hosts are intimate, dynamic and complex; the evolution of one is inevitably linked to the other. Despite multiple origins of parasitism in the Cnidaria, only parasites belonging to the Myxozoa are characterized by a complex life cycle, alternating between fish and invertebrate hosts, as well as by high species diversity. This inspired us to examine the history of adaptive radiations in myxozoans and their hosts by determining the degree of congruence between their phylogenies and by timing the emergence of myxozoan lineages in relation to their hosts. Recent genomic analyses suggested a common origin of Polypodium hydriforme, a cnidarian parasite of acipenseriform fishes, and the Myxozoa, and proposed fish as original hosts for both sister lineages. We demonstrate that the Myxozoa emerged long before fish populated Earth and that phylogenetic congruence with their invertebrate hosts is evident down to the most basal branches of the tree, indicating bryozoans and annelids as original hosts and challenging previous evolutionary hypotheses. We provide evidence that, following invertebrate invasion, fish hosts were acquired multiple times, leading to parallel cospeciation patterns in all major phylogenetic lineages. We identify the acquisition of vertebrate hosts that facilitate alternative transmission and dispersion strategies as reason for the distinct success of the Myxozoa, and identify massive host specification-linked parasite diversification events. The results of this study transform our understanding of the origins and evolution of parasitism in the most basal metazoan parasites known.

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Section: Discussionmentioning

confidence: 60%

The joint evolution of the Myxozoa and their alternate hosts: A cnidarian recipe for success and vast biodiversity

et al. 2018

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“…The linear mitochondrial genome characteristic among members of Medusozoa appears to be quite variable in Myxozoa. The mitochondrion of species in the myxozoan genus Kudoa are small, and the genes in them are organized into a single circular genome that is evolving more quickly than those in other Medusozoa (Takeuchi et al 2015). The order of genes reported for the mitochondrial genome of Kudoa does not correspond to those published for other Medusozoans (cf.…”

Section: Linearization Homology and Cnidarian Evolutionmentioning

confidence: 95%

“…The order of genes reported for the mitochondrial genome of Kudoa does not correspond to those published for other Medusozoans (cf. Kayal et al 2015;Takeuchi et al 2015). In contrast, in the myxozoan Enteromyxum leei, the mitogenome is organized into eight circular chromosomes (Yahalomi et al 2017).…”

Section: Linearization Homology and Cnidarian Evolutionmentioning

confidence: 99%

Linear Mitochondrial genome in Anthozoa (Cnidaria): A case study in Ceriantharia

Stampar

Broe

Macrander

et al. 2018

Preprint

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Sequences and structural attributes of mitochondrial genomes have played a key role in the clarification of relationships among Cnidaria, a key phylum of early-diverging animals. Among the major lineages of Cnidaria, Ceriantharia ("tube anemones") remains one of the most enigmatic groups in terms of its phylogenetic position. We sequenced the mitochondrial genomes of two ceriantharians to see whether the complete organellar genome would provide more support for the phylogenetic placement of Ceriantharia. For both ceriantharian species studied, the mitochondrial gene sequences could not be assembled into a circular genome. Instead, our analyses suggest both species have fragmented mitochondrial genomes consisting of multiple linear fragments. Linear mitogenomes are characteristic of members of Medusozoa, one of the major lineages of Cnidaria, but are unreported for Anthozoa, which includes the Ceriantharia. The number of fragments and the variation in gene order between species is much greater in Ceriantharia than among Medusozoa. The novelty of the mitogenomic structure in Ceriantharia highlights the distinctiveness of this lineage but, because it appears to be both unique to and diverse within Ceriantharia, it is uninformative about the phylogenetic position of Ceriantharia relative to other anthozoan groups.

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“…In addition, Myxozoa, a large (∼1,300 species) group of oligo-cellular parasites of fish and annelids with previously unknown phylogenetic affinity, is now placed inside Cnidaria (Nesnidal et al 2013; Feng et al 2014; Foox and Siddall 2015; Takeuchi et al 2015). The relationships among nonbilaterian phyla and bilaterian animals remain contentious (Pisani et al 2015; Whelan et al 2015), but are largely irrelevant to the present study.…”

Section: Classification and Phylogeny Of Nonbilaterian Animalsmentioning

confidence: 99%

Animal Mitochondrial DNA as We Do Not Know It: mt-Genome Organization and Evolution in Nonbilaterian Lineages

2016

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Animal mitochondrial DNA (mtDNA) is commonly described as a small, circular molecule that is conserved in size, gene content, and organization. Data collected in the last decade have challenged this view by revealing considerable diversity in animal mitochondrial genome organization. Much of this diversity has been found in nonbilaterian animals (phyla Cnidaria, Ctenophora, Placozoa, and Porifera), which, from a phylogenetic perspective, form the main branches of the animal tree along with Bilateria. Within these groups, mt-genomes are characterized by varying numbers of both linear and circular chromosomes, extra genes (e.g. atp9, polB, tatC), large variation in the number of encoded mitochondrial transfer RNAs (tRNAs) (0–25), at least seven different genetic codes, presence/absence of introns, tRNA and mRNA editing, fragmented ribosomal RNA genes, translational frameshifting, highly variable substitution rates, and a large range of genome sizes. This newly discovered diversity allows a better understanding of the evolutionary plasticity and conservation of animal mtDNA and provides insights into the molecular and evolutionary mechanisms shaping mitochondrial genomes.

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The Mitochondrial Genomes of a Myxozoan Genus Kudoa Are Extremely Divergent in Metazoa

Cited by 33 publications

References 69 publications

The joint evolution of the Myxozoa and their alternate hosts: A cnidarian recipe for success and vast biodiversity

The joint evolution of the Myxozoa and their alternate hosts: A cnidarian recipe for success and vast biodiversity

Linear Mitochondrial genome in Anthozoa (Cnidaria): A case study in Ceriantharia

Animal Mitochondrial DNA as We Do Not Know It: mt-Genome Organization and Evolution in Nonbilaterian Lineages

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