Informational Gene Phylogenies Do Not Support a Fourth Domain of Life for Nucleocytoplasmic Large DNA Viruses

Williams, Tom A.; Embley, T. Martin; Heinz, Eva

doi:10.1371/journal.pone.0021080

Cited by 73 publications

(69 citation statements)

References 50 publications

(82 reference statements)

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“…For example, a viral fourth domain sister to the eukaryotes has been proposed based on the phylogeny of clamp loader proteins [66] and of the RNA polymerase II (RNAP2), transcription factor II beta, flap endonuclease and proliferating cell nuclear antigen [28]. As in the previous cases, subsequent analyses of those datasets using more robust methods and sequence evolution models as well as more comprehensive taxonomic samplings demonstrated once again that the giant virus sequences were misplaced in the original analyses because of their high evolutionary rate and/or compositional bias and that, actually, these genes had most likely been acquired by the viruses from eukaryotic donors [67,68]. In §5, we revisit one of these examples in more detail.…”

Section: Giant Viruses Horizontal Gene Transfer and Long Branch Attrmentioning

confidence: 83%

“…2 in [28]). In a detailed reanalysis of this marker, Williams et al [68] demonstrated that the RNAP2 sequence dataset contained a substantial amount of non-phylogenetic signal, mainly owing to the high evolutionary rate and compositional bias of the viral sequences. They also showed the very poor fit between the sequence data and the JTT model and verified that more complex models exhibited significantly better fit.…”

Section: Giant Viruses Caught In the Felsenstein's Trapmentioning

confidence: 99%

“…Whereas Williams et al [68] focused mostly on the impact of using unfit models, we have further investigated other aspects of this sequence dataset as a case study showing the difficulties that the highly divergent viral sequences may generate in phylogenetic analyses. Our first objective was assessing to what extent the RNAP2 viral sequences were divergent and could be affected by LBA.…”

Section: Giant Viruses Caught In the Felsenstein's Trapmentioning

confidence: 99%

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Evolution of viruses and cells: do we need a fourth domain of life to explain the origin of eukaryotes?

Moreira¹,

López‐García²

2015

Phil. Trans. R. Soc. B

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The recent discovery of diverse very large viruses, such as the mimivirus, has fostered a profusion of hypotheses positing that these viruses define a new domain of life together with the three cellular ones (Archaea, Bacteria and Eucarya). It has also been speculated that they have played a key role in the origin of eukaryotes as donors of important genes or even as the structures at the origin of the nucleus. Thanks to the increasing availability of genome sequences for these giant viruses, those hypotheses are amenable to testing via comparative genomic and phylogenetic analyses. This task is made very difficult by the high evolutionary rate of viruses, which induces phylogenetic artefacts, such as long branch attraction, when inadequate methods are applied. It can be demonstrated that phylogenetic trees supporting viruses as a fourth domain of life are artefactual. In most cases, the presence of homologues of cellular genes in viruses is best explained by recurrent horizontal gene transfer from cellular hosts to their infecting viruses and not the opposite. Today, there is no solid evidence for the existence of a viral domain of life or for a significant implication of viruses in the origin of the cellular domains.

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Section: Giant Viruses Horizontal Gene Transfer and Long Branch Attrmentioning

confidence: 83%

Section: Giant Viruses Caught In the Felsenstein's Trapmentioning

confidence: 99%

Section: Giant Viruses Caught In the Felsenstein's Trapmentioning

confidence: 99%

See 1 more Smart Citation

Evolution of viruses and cells: do we need a fourth domain of life to explain the origin of eukaryotes?

Moreira¹,

López‐García²

2015

Phil. Trans. R. Soc. B

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“…As we will see, while some of these ideas fall under the two rival views on the nature and origin of life (metabolism versus genetic information) and cannot be properly tested, others can be tested by using appropriate molecular phylogenetic analyses and, in most cases, refuted (López-García and Moreira 2009; Moreira 2000; Moreira and López-García 2009; Williams et al 2011). At any rate, these different heterogeneous models have stimulated virocentric debates, which can be classed as two types.…”

Section: Novel Virocentric Hypothesesmentioning

confidence: 99%

“…It is therefore essential to include sequences from the virus' hosts or host family to see whether or not the viral sequence places close to them. Using better taxon sampling and adequate models of sequence evolution, it can be shown that the vast majority of homologues to cellular genes present in giant viruses correspond to transfers from the host (or from bacteria co-infecting the same host) to its virus; and that NCLDV genes do not form a monophyletic group at the base of eukaryotes, but appear dispersed within the eukaryotic tree close to their respective hosts Moreira 2000;Moreira and Brochier-Armanet 2008;Moreira and Lopez-Garcia 2005;Moreira and López-García 2009;Williams et al 2011). Therefore, the hypothesis that NCLDV giant viruses form a fourth domain of life that can be placed in an organismal tree of life (Boyer et al 2010;Raoult et al 2004) can be refuted.…”

Section: Do Some Giant Viruses Form a Fourth Domain Of Life?mentioning

confidence: 99%

Viruses in Biology

López‐García

Moreira

2012

Evo Edu Outreach

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During the first half of the twentieth century, many scientists considered viruses the smallest living entities and primitive life forms somehow placed between the inert world and highly evolved cells. The development of molecular biology in the second half of the century showed that viruses are strict molecular parasites of cells, putting an end to previous virocentric debates that gave viruses a primeval role in the origin of life. Recent advances in comparative genomics and metagenomics have uncovered a vast viral diversity and have shown that viruses are active regulators of cell populations and that they can influence cell evolution by acting as vectors for gene transfer among cells. They have also fostered a revival of old virocentric ideas. These ideas are heterogeneous, extending from proposals that consider viruses functionally as living beings and/or as descendants of viral lineages that preceded cell evolution to other claims that consider viruses and/or some viral families a fourth domain of life. In this article, we revisit these virocentric ideas and analyze the place of viruses in biology in light of the long-standing dichotomic debate between metabolist and geneticist views which hold, respectively, that self-maintenance (metabolism) or self-replication and evolution are the primeval features of life. We argue that whereas the epistemological discussion about whether viruses are alive or not and whether some virus-like replicators precede the first cells is a matter of debate that can be understood within the metabolism-versus-genes dialectic; the claim that viruses form a fourth domain in the tree of life can be solidly refuted by proper molecular phylogenetic analyses and needs to be removed from this debate.

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Nucleo‐cytoplasmic Large DNA Viruses ( NCLDV ) of Eukaryotes

Koonin

Yutin

2012

Encyclopedia of Life Sciences

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A group of diverse viruses with large deoxyribonucleic acid (DNA) genomes that replicate in the cytoplasm and in some cases partly in the nucleus of eukaryotic cells share a set of conserved genes and probably have evolved from a common ancestral virus. Known as nucleo‐cytoplasmic large DNA viruses (NCLDV), this class of viruses encompasses seven families: Poxviridae, Asfarviridae, Iridoviridae, Ascoviridae, Phycodnaviridae, Mimiviridae , and a probable new family represented by Marseillevirus and Lausannevirus. The family Mimiviridae includes giant viruses that possess genomes of a million or more basepairs that are comparable in size and complexity with some bacterial genomes. Phylogenetic analysis of the conserved genes of the NCLDV and mapping of the resulting phylogeny of the NCLDV onto the phylogeny of their eukaryotic hosts suggest an early origin and primary radiation of the NCLDV, possibly concomitant with the primary radiation of eukaryotes. Key Concepts: Seven families of viruses with large double‐stranded DNA genomes together constitute a monophyletic class of viruses known as Nucleo‐Cytoplasmic Large DNA Viruses (NCLDV). All NCLDV share several genes that encode essential proteins involved in viral genome replication and virion formation. An evolutionary reconstruction using a maximum‐likelihood model assigns approximately 50 genes coding for most of the key virus functions to the common ancestor of all extant NCLDV. Some of the NCLDV families infect many diverse eukaryotes whereas many groups of eukaryotes are infected by diverse NCLDV suggesting that the major radiation of the NCLDV occurred at an early stage of evolution, perhaps concomitantly with eukaryogenesis. The NCLDV includes the largest known viruses: Mimiviruses which encode over 1000 genes and are comparable to bacteria in size and complexity.

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Informational Gene Phylogenies Do Not Support a Fourth Domain of Life for Nucleocytoplasmic Large DNA Viruses

Cited by 73 publications

References 50 publications

Evolution of viruses and cells: do we need a fourth domain of life to explain the origin of eukaryotes?

Evolution of viruses and cells: do we need a fourth domain of life to explain the origin of eukaryotes?

Viruses in Biology

Nucleo‐cytoplasmic Large DNA Viruses ( NCLDV ) of Eukaryotes

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