Abstract
Diatoms are the largest group of heterokont algae with more than 100,000 species. As one of the single-celled photosynthetic organisms that inhabit marine, aquatic and terrestrial ecosystems, diatoms contribute ~ 45% of global primary production. Despite their ubiquity and environmental significance, very few diatom plastid genomes (plastomes) have been sequenced and studied. This study explored patterns of nucleotide substitution rates of diatom plastids across the entire suite of plastome protein-coding genes for 40 taxa representing the major clades. The highest substitution rate was lineage-specific within the araphid 2 taxon Astrosyne radiata and radial 2 taxon Proboscia sp. Rate heterogeneity was also evident in different functional classes and individual genes. Similar to land plants, proteins genes involved in photosynthetic metabolism have lower synonymous and nonsynonymous substitutions rates than those involved in transcription and translation. Significant positive correlations were identified between substitution rates and measures of genomic rearrangements, including indels and inversions, which is a similar result to what was found in legume plants. This work advances the understanding of the molecular evolution of diatom plastomes and provides a foundation for future studies.
Highlights
Diatoms are the largest group of heterokont algae with more than 100,000 species
The present study explored the patterns of plastid nucleotide substitution rates across the entire suite of 103 shared genes for 40 species of diatoms
Limited studies have been performed using plastome protein-coding sequences from diatoms and not much is known about their molecular evolution
Summary
As one of the single-celled photosynthetic organisms that inhabit marine, aquatic and terrestrial ecosystems, diatoms contribute ~ 45% of global primary production. Despite their ubiquity and environmental significance, very few diatom plastid genomes (plastomes) have been sequenced and studied. Diatoms have since colonized freshwater, marine and terrestrial habitats contributing ~ 45% of global primary production[2,3,4] and as much as 20% of global carbon fixation via photosynthesis[5, 6] Despite their ubiquity and the environmental significance of diatom photosynthesis, very few diatom plastid genomes (plastomes) have been sequenced and studied. Information Technology, Faculty of Computer Science and Information Technology, King Abdul Aziz University, Scientific Reports | (2020) 10:14358
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