Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution

Méheust, Raphaël; Watson, Andrew K.; Lapointe, François‐Joseph; Papke, R. Thane; Lopez, Philippe; Bapteste, Éric

doi:10.1186/s13059-018-1454-9

Cited by 40 publications

(30 citation statements)

References 49 publications

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“…Specific patterns of satellites have emerged in some individual species. This scenario highlights the genome plasticity of prokaryotes, where exchange of genome sequences is widespread [21, 22]. The emergence of a few species with non-coding satellite families suggests that these species have acquired a specific mechanism of satellite transposition.…”

Section: Discussionmentioning

confidence: 99%

Satellites in the prokaryote world

Subirana

Messeguer

2019

BMC Evol Biol

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Background Satellites or tandem repeats are very abundant in many eukaryotic genomes. Occasionally they have been reported to be present in some prokaryotes, but to our knowledge there is no general comparative study on their occurrence. For this reason we present here an overview of the distribution and properties of satellites in a set of representative species. Our results provide novel insights into the evolutionary relationship between eukaryotes, Archaea and Bacteria. Results We have searched all possible satellites present in the NCBI reference group of genomes in Archaea (142 species) and in Bacteria (119 species), detecting 2735 satellites in Archaea and 1067 in Bacteria. We have found that the distribution of satellites is very variable in different organisms. The archaeal Methanosarcina class stands out for the large amount of satellites in their genomes. Satellites from a few species have similar characteristics to those in eukaryotes, but most species have very few satellites: only 21 species in Archaea and 18 in Bacteria have more than 4 satellites/Mb. The distribution of satellites in these species is reminiscent of what is found in eukaryotes, but we find two significant differences: most satellites have a short length and many of them correspond to segments of genes coding for amino acid repeats. Transposition of non-coding satellites throughout the genome occurs rarely: only in the bacteria Leptospira interrogans and the archaea Methanocella conradii we have detected satellite families of transposed satellites with long repeats. Conclusions Our results demonstrate that the presence of satellites in the genome is not an exclusive feature of eukaryotes. We have described a few prokaryotes which do contain satellites. We present a discussion on their eventual evolutionary significance.

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Section: Discussionmentioning

confidence: 99%

Satellites in the prokaryote world

Subirana

Messeguer

2019

BMC Evol Biol

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“…An assumption of ALE is that all residues of a protein share the same phylogenetic history. However, it has been suggested that Haloarchaea encode relatively large numbers of composite/chimeric proteins where different regions (or components) of the protein are the result of (partly) independent phylogenetic histories 79 . We identified 307 clusters with 7776 putative fusion proteins that based on the eggNOG mapper annotations were associated with two or more COG/NOG clusters.…”

Section: Methanocellalesmentioning

confidence: 99%

Hikarchaeia demonstrate an intermediate stage in the methanogen-to-halophile transition

et al. 2020

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Halobacteria (henceforth: Haloarchaea) are predominantly aerobic halophiles that are thought to have evolved from anaerobic methanogens. This remarkable transformation most likely involved an extensive influx of bacterial genes. Whether it entailed a single massive transfer event or a gradual stream of transfers remains a matter of debate. To address this, genomes that descend from methanogen-to-halophile intermediates are necessary. Here, we present five such near-complete genomes of Marine Group IV archaea (Hikarchaeia), the closest known relatives of Haloarchaea. Their inclusion in gene tree-aware ancestral reconstructions reveals an intermediate stage that had already lost a large number of genes, including nearly all of those involved in methanogenesis and the Wood-Ljungdahl pathway. In contrast, the last Haloarchaea common ancestor gained a large number of genes and expanded its aerobic respiration and salt/UV resistance gene repertoire. Our results suggest that complex and gradual patterns of gain and loss shaped the methanogen-to-halophile transition.

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“…Another factor concerns gene fusions. Genes tend to undergo fusion and fission during evolution [ 137 , 138 ]. In clustering procedures, gene fusions tend to slightly reduce the number of clusters because when they occur, they can bring two fused genes into one alignment, and the weaker phylogenetic signal in the fusion is obscured [ 23 ].…”

Section: Introductionmentioning

confidence: 99%

The last universal common ancestor between ancient Earth chemistry and the onset of genetics

et al. 2018

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All known life forms trace back to a last universal common ancestor (LUCA) that witnessed the onset of Darwinian evolution. One can ask questions about LUCA in various ways, the most common way being to look for traits that are common to all cells, like ribosomes or the genetic code. With the availability of genomes, we can, however, also ask what genes are ancient by virtue of their phylogeny rather than by virtue of being universal. That approach, undertaken recently, leads to a different view of LUCA than we have had in the past, one that fits well with the harsh geochemical setting of early Earth and resembles the biology of prokaryotes that today inhabit the Earth's crust.

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Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution

Cited by 40 publications

References 49 publications

Satellites in the prokaryote world

Satellites in the prokaryote world

Hikarchaeia demonstrate an intermediate stage in the methanogen-to-halophile transition

The last universal common ancestor between ancient Earth chemistry and the onset of genetics

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