Mini ReviewGenomic GC level, optimal growth temperature, and genome size in prokaryotes
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Cited by (113)
Genome size and GC content of myxomycetes
2023, European Journal of ProtistologyComparative genomics of Photobacterium species from terrestrial and marine habitats
2021, Current Research in Microbial SciencesCitation Excerpt :This findings are in accordance to the results of our analysis for the three species. According to (Musto et al., 2004, 2005, 2006), the GC content of the genome has a direct correlation to the optimum growth temperature of the species. The significant differences on the GC content of the genomes of all three of the species are in accordance with the higher optimum temperatures at which P. phosphoreum and P. iliopiscarium are able to grow (15 - 25 °C, ∼39% GC) in comparison to P. carnosum (10 – 15 °C, ∼38% GC) (Hilgarth et al., 2018b).
Biohydrometallurgy of Chalcopyrite
2021, Biohydrometallurgy of ChalcopyritePeculiar genomic traits in the stress-adapted cryptoendolithic Antarctic fungus Friedmanniomyces endolithicus
2020, Fungal BiologyCitation Excerpt :The genomes of H. werneckii and Friedmanniomyces spp. strains were larger in size than the average size in black fungi; black yeasts’ genomes ranged from 20 up to 50 Mbp; in Chaetothyriales (Eurotiomycetes) ranging from 25.8 Mb in Capronia coronata to 43 Mb in Cladophialophora immunda (Teixeira et al., 2017; Moreno et al., 2019), while H. werneckii genome assembly (̴ 50 Mbp) is the largest in Dothideomycetes. All black yeasts genomes have, on average, high GC content (49–56.5 %) (Teixeira et al., 2017; this study); these data could be peculiar of the extremes-associated ecology of black fungi; indeed, high GC content was already found as a common feature in extremophilic prokaryotes as it helps to stabilize after DNA damage (Gregory et al., 2007; Musto et al., 2006). A large number of predicted proteins was found in two other Antarctic cryptoendolithic black fungi genomes which each contained around 18,000 genes (Coleine et al., 2017).