tRNA functional signatures classify plastids as late-branching cyanobacteria

Autor:	Wesley D Swingley, Katherine Ch Amrine, Travis J Lawrence, David H. Ardell
Rok vydání:	2019
Předmět:	0106 biological sciences 0301 basic medicine Cyanobacteria Symbiogenesis Evolution Biology 010603 evolutionary biology 01 natural sciences Genome Models Biological 03 medical and health sciences RNA Transfer Models Phylogenomics Machine learning Genetics QH359-425 Plastids Plastid Photosynthesis Clade Symbiosis Ecology Evolution Behavior and Systematics Phylogeny Evolutionary Biology Endosymbiosis Phylogenetic tree Primary endosymbiosis Eukaryota biology.organism_classification Biological Biological Evolution tRNAs Transfer 030104 developmental biology Evolutionary biology RNA Research Article
Zdroj:	BMC Evolutionary Biology BMC Evolutionary Biology, Vol 19, Iss 1, Pp 1-13 (2019) BMC evolutionary biology, vol 19, iss 1
ISSN:	1471-2148
Popis:	Background Eukaryotes acquired the trait of oxygenic photosynthesis through endosymbiosis of the cyanobacterial progenitor of plastid organelles. Despite recent advances in the phylogenomics of Cyanobacteria, the phylogenetic root of plastids remains controversial. Although a single origin of plastids by endosymbiosis is broadly supported, recent phylogenomic studies are contradictory on whether plastids branch early or late within Cyanobacteria. One underlying cause may be poor fit of evolutionary models to complex phylogenomic data. Results Using Posterior Predictive Analysis, we show that recently applied evolutionary models poorly fit three phylogenomic datasets curated from cyanobacteria and plastid genomes because of heterogeneities in both substitution processes across sites and of compositions across lineages. To circumvent these sources of bias, we developed CYANO-MLP, a machine learning algorithm that consistently and accurately phylogenetically classifies (“phyloclassifies”) cyanobacterial genomes to their clade of origin based on bioinformatically predicted function-informative features in tRNA gene complements. Classification of cyanobacterial genomes with CYANO-MLP is accurate and robust to deletion of clades, unbalanced sampling, and compositional heterogeneity in input tRNA data. CYANO-MLP consistently classifies plastid genomes into a late-branching cyanobacterial sub-clade containing single-cell, starch-producing, nitrogen-fixing ecotypes, consistent with metabolic and gene transfer data. Conclusions Phylogenomic data of cyanobacteria and plastids exhibit both site-process heterogeneities and compositional heterogeneities across lineages. These aspects of the data require careful modeling to avoid bias in phylogenomic estimation. Furthermore, we show that amino acid recoding strategies may be insufficient to mitigate bias from compositional heterogeneities. However, the combination of our novel tRNA-specific strategy with machine learning in CYANO-MLP appears robust to these sources of bias with high accuracy in phyloclassification of cyanobacterial genomes. CYANO-MLP consistently classifies plastids as late-branching Cyanobacteria, consistent with independent evidence from signature-based approaches and some previous phylogenetic studies.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::b0c0f1ae0b2c029fdc86a20f53307a86 https://pubmed.ncbi.nlm.nih.gov/31818253 Zobrazit plný text záznamu Plný text ve formátu PDF Plný text ve formátu HTML
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