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Literature summary for 1.14.99.39 extracted from

  • Macqueen, D.J.; Gubry-Rangin, C.
    Molecular adaptation of ammonia monooxygenase during independent pH specialization in Thaumarchaeota (2016), Mol. Ecol., 25, 1986-1999 .
    View publication on PubMed

Organism

Organism UniProt Comment Textmining
Candidatus Nitrosotalea
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Nitrosopumilus
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Nitrososphaera
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Synonyms

Synonyms Comment Organism
amoA
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Candidatus Nitrosotalea
amoA
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Nitrosopumilus
amoA
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Nitrososphaera

General Information

General Information Comment Organism
evolution reconstruction of AmoA protein sequence evolution during a major evolutionary transition to acidophily in the C14 lineage of Nitrosotalea, and ancestral reconstruction of sequence changes fixed in the AmoA protein during the evolutionary transition to acidophily in the C11 lineage of Nitrososphaera, AmoA protein evolution during ancestral pH adaptation events, nature of selection associated with AmoA evolution, overview. Three pH-adapted lineages are particularly important in terms of their high abundance in contemporary terrestrial ecosystems, i.e. the phylogenetically-distant acidophilic lineages called C11 (within Nitrososphaera) and C14/C15 (within Nitrosotalea) and the alkalinophilic lineage called C1/2 (within Nitrososphaera) Candidatus Nitrosotalea
evolution reconstruction of AmoA protein sequence evolution during a major evolutionary transition to acidophily in the C14 lineage of Nitrosotalea, and ancestral reconstruction of sequence changes fixed in the AmoA protein during the evolutionary transition to acidophily in the C11 lineage of Nitrososphaera, AmoA protein evolution during ancestral pH adaptation events, nature of selection associated with AmoA evolution, overview. Three pH-adapted lineages are particularly important in terms of their high abundance in contemporary terrestrial ecosystems, i.e. the phylogenetically-distant acidophilic lineages called C11 (within Nitrososphaera) and C14/C15 (within Nitrosotalea) and the alkalinophilic lineage called C1/2 (within Nitrososphaera) Nitrosopumilus
evolution reconstruction of AmoA protein sequence evolution during a major evolutionary transition to acidophily in the C14 lineage of Nitrosotalea, and ancestral reconstruction of sequence changes fixed in the AmoA protein during the evolutionary transition to acidophily in the C11 lineage of Nitrososphaera, AmoA protein evolution during ancestral pH adaptation events, nature of selection associated with AmoA evolution, overview. Three pH-adapted lineages are particularly important in terms of their high abundance in contemporary terrestrial ecosystems, i.e. the phylogenetically-distant acidophilic lineages called C11 (within Nitrososphaera) and C14/C15 (within Nitrosotalea) and the alkalinophilic lineage called C1/2 (within Nitrososphaera) Nitrososphaera
physiological function AmoA function is essential for energy production Candidatus Nitrosotalea
physiological function AmoA function is essential for energy production Nitrosopumilus
physiological function AmoA function is essential for energy production Nitrososphaera