Dating Alphaproteobacteria evolution with eukaryotic fossils

Wang, Sishuo; Luo, Haiwei

doi:10.1038/s41467-021-23645-4

Cited by 37 publications

(55 citation statements)

References 69 publications

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“…The tree in Figure 1 shows an 'Alphaproteobacteria-sister' to mitochondria topology that is equivalent to that initially reported using 24 concatenated proteins, including NuoL and many marine MAGs [11]. The same clustering has been recently reproduced with different taxonomic samplings of either Alphaproteobacteria or mitochondria [26,33]. However, the most common topology of phylogenetic trees combining Alphaproteobacterial and mitochondrial proteins shows the mitochondrial clade nested within the early branching part of the trees, often in a sister position to the Rickettsiales order [2,4,11,26].…”

Section: A General Survey Of the Phylogeny Of Alphaproteobacteriasupporting

confidence: 71%

“…Then, a series of minor orders of predominantly marine taxa, such as Sneathiellales, separates clade b from clade c, which includes all major lineages of Alphaproteobacteria, from Rhizobiales to Rhodobacterales (Figure 1). An equivalent three-clades sequence can be discerned in the branching order of phylogenetic trees reported earlier, for example in studies on Alphaproteobacteria only [3,5,13], as well as in studies focusing on the Alphaproteobacterial ancestry of mitochondria [11,26,33]. Indeed, clade c fundamentally corresponds to the 'Core alphaproteobacteria' group reported by Martijn et al, 2018 [11].…”

Section: A General Survey Of the Phylogeny Of Alphaproteobacteriamentioning

confidence: 62%

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New Alphaproteobacteria Thrive in the Depths of the Ocean with Oxygen Gradient

Cevallos

Esposti

2022

Microorganisms

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We survey here the Alphaproteobacteria, a large class encompassing physiologically diverse bacteria which are divided in several orders established since 2007. Currently, there is considerable uncertainty regarding the classification of an increasing number of marine metagenome-assembled genomes (MAGs) that remain poorly defined in their taxonomic position within Alphaproteobacteria. The traditional classification of NCBI taxonomy is increasingly complemented by the Genome Taxonomy Database (GTDB), but the two taxonomies differ considerably in the classification of several Alphaproteobacteria, especially from ocean metagenomes. We analyzed the classification of Alphaproteobacteria lineages that are most common in marine environments, using integrated approaches of phylogenomics and functional profiling of metabolic features that define their aerobic metabolism. Using protein markers such as NuoL, the largest membrane subunit of complex I, we have identified new clades of Alphaproteobacteria that are specific to marine niches with steep oxygen gradients (oxycline). These bacteria have relatives among MAGs found in anoxic strata of Lake Tanganyika and together define a lineage that is distinct from either Rhodospirillales or Sneathiellales. We characterized in particular the new ‘oxycline’ clade. Our analysis of Alphaproteobacteria also reveals new clues regarding the ancestry of mitochondria, which likely evolved in oxycline marine environments.

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Section: A General Survey Of the Phylogeny Of Alphaproteobacteriasupporting

confidence: 71%

Section: A General Survey Of the Phylogeny Of Alphaproteobacteriamentioning

confidence: 62%

New Alphaproteobacteria Thrive in the Depths of the Ocean with Oxygen Gradient

Cevallos

Esposti

2022

Microorganisms

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“…With the hypothesis described above, we calculated a phylogenetic tree (Figure 7) using the sequences of the available babb duplicated topologies of archaea and bacteria domains. Notably, we could use the Archaeal, CCA-adding enzyme sequences to obtain a rooted tree (Figure 7), that yields information consistent with the widely accepted taxonomy, like the overall, Gracilicutes vs Terrabacteria division (Coleman et al, 2021), the general Firmicutes phylogeny division of Limnochordales, Halanaerobiales, Negativicutes (Taib et al, 2020), or the placement of Magnetococcales as an Alpha proteobacteria outgroup (Wang & Luo, 2021). It also proposes that Methanopyrus is the closest Archaea related to bacteria (Long et al, 2020); to divide Deltaproteobacteria in four phyla that do not belong to proteobacteria (Waite et al, 2020).…”

Section: Resultsmentioning

confidence: 77%

Bacterial glycyl tRNA synthetase offers glimpses of ancestral protein topologies

Dimas-Torres

Rodríguez-Hernández

Valencia-Sánchez

et al. 2021

Preprint

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Many experimental and predicted observations remain unanswered in the current proposed trees of life (ToL). Also, the current trend in reporting phylogenetic data is based in mixing together the information of dozens of genomes or entire conserved proteins. In this work, we consider the modularity of protein evolution and, using only two domains with duplicated ancestral topologies from a single, universal primordial protein corresponding to the RNA binding regions of contemporary bacterial glycyl tRNA synthetase (bacGlyRS), archaeal CCA adding enzyme (arch-CCAadd) and eukaryotic rRNA processing enzyme (euk-rRNA), we propose a rooted bacterial ToL that agrees with several previous observations unaccounted by the available trees.

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“…In an evolutionary context, Alpha-and Delta-proteobacteria like R. palustris and G. sulfurreducens, respectively, probably did not arise on Earth until well after (<2-3 GYA; Marin et al, 2017;Wang and Luo, 2021) Gale crater was formed in the Late Noachian (Fig. 1C).…”

Section: Discussionmentioning

confidence: 99%

Microbial habitability of early Mars lacustrine environments sustained by iron redox cycling

Moore

Carr

2021

Preprint

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Several studies have reported new data on the estimated compositions of chemical components at Gale crater; however, there is still a lack of information regarding potential past support of biomass and detectable biomarkers of ancient life. In this study we evaluate microbial habitability of early Mars constrained by the recently reconstructed water chemistry at Gale. The modeled community is based on Fe-metabolizing bacteria with the ability to utilize solid-phase iron oxides (e.g., magnetite) as an electron source or sink. Our results illustrate the plausibility of a sustained community in Gale Lake and provides suggestions for future modeled and laboratory-based studies to further evaluate the past habitability of Mars, biosignatures and their preservation potential, and hidden metabolic potential.One Sentence SummaryThis work provides an existence proof of habitability on early Mars and demonstrates modeling processes by which the habitability of extraterrestrial environments can be explored quantitatively.

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Dating Alphaproteobacteria evolution with eukaryotic fossils

Cited by 37 publications

References 69 publications

New Alphaproteobacteria Thrive in the Depths of the Ocean with Oxygen Gradient

New Alphaproteobacteria Thrive in the Depths of the Ocean with Oxygen Gradient

Bacterial glycyl tRNA synthetase offers glimpses of ancestral protein topologies

Microbial habitability of early Mars lacustrine environments sustained by iron redox cycling

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