Phylogenetic Analysis of Nitrite, Nitric Oxide, and Nitrous Oxide Respiratory Enzymes Reveal a Complex Evolutionary History for Denitrification

Denitrification is a facultative respiratory pathway in which nitrite (NO2 −), nitric oxide (NO), and nitrous oxide (N2O) are successively reduced to nitrogen gas (N2), effectively closing the nitrogen cycle. The ability to denitrify is widely dispersed among prokaryotes, and this polyphyletic distr...

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Bibliographic Details
Published in:Molecular biology and evolution 2008-09, Vol.25 (9), p.1955-1966
Main Authors: Jones, Christopher M., Stres, Bla, Rosenquist, Magnus, Hallin, Sara
Format: Article
Language:English
Subjects:
Archaea - enzymology
Archaea - genetics
Bacteria
Chromosome Mapping
Denitrification
Enzymes
Enzymes - genetics
Enzymes - metabolism
Evolution, Molecular
Evolutionary biology
Gene Transfer, Horizontal
Genetic Variation
Genetics
Genome, Bacterial
Likelihood Functions
MEDICIN
MEDICINE
Metabolic Networks and Pathways - genetics
Molecular biology
nirK
nirS
Nitric oxide
Nitric Oxide - metabolism
Nitrites - metabolism
Nitrogen cycle
Nitrous oxide
Nitrous Oxide - metabolism
norB
nosZ
Phylogeny
Proteobacteria - enzymology
Proteobacteria - genetics
RNA, Ribosomal, 16S - genetics
Sequence Alignment
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Summary:Denitrification is a facultative respiratory pathway in which nitrite (NO2 −), nitric oxide (NO), and nitrous oxide (N2O) are successively reduced to nitrogen gas (N2), effectively closing the nitrogen cycle. The ability to denitrify is widely dispersed among prokaryotes, and this polyphyletic distribution has raised the possibility of horizontal gene transfer (HGT) having a substantial role in the evolution of denitrification. Comparisons of 16S rRNA and denitrification gene phylogenies in recent studies support this possibility; however, these results remain speculative as they are based on visual comparisons of phylogenies from partial sequences. We reanalyzed publicly available nirS, nirK, norB, and nosZ partial sequences using Bayesian and maximum likelihood phylogenetic inference. Concomitant analysis of denitrification genes with 16S rRNA sequences from the same organisms showed substantial differences between the trees, which were supported by examining the posterior probability of monophyletic constraints at different taxonomic levels. Although these differences suggest HGT of denitrification genes, the presence of structural variants for nirK, norB, and nosZ makes it difficult to determine HGT from other evolutionary events. Additional analysis using phylogenetic networks and likelihood ratio tests of phylogenies based on full-length sequences retrieved from genomes also revealed significant differences in tree topologies among denitrification and 16S rRNA gene phylogenies, with the exception of the nosZ gene phylogeny within the data set of the nirK-harboring genomes. However, inspection of codon usage and G + C content plots from complete genomes gave no evidence for recent HGT. Instead, the close proximity of denitrification gene copies in the genomes of several denitrifying bacteria suggests duplication. Although HGT cannot be ruled out as a factor in the evolution of denitrification genes, our analysis suggests that other phenomena, such gene duplication/divergence and lineage sorting, may have differently influenced the evolution of each denitrification gene.
ISSN:0737-4038
1537-1719
1537-1719
DOI:10.1093/molbev/msn146