Archaea-Like Genes for C₁-Transfer EnzymesinPlanctomycetes: Phylogenetic Implications of Their Unexpected Presence in This Phylum.

Bauer, Margarete; Lombardot, Thierry; Teeling, Hanno; Ward, Naomi L.; Amann, Rudolf I.; Glöckner, Frank O.

The unexpected presence of archaea-like genes for tetrahydromethanopterin (H4MPT)-dependent enzymes in the completely sequenced genome of the aerobic marine planctomycetePirellulasp. strain 1 (“Rhodopirellula baltica”) and in the currently sequenced genome of the aerobic freshwater planctomyceteGemmata obscuriglobusstrain UQM2246 revives the discussion on the origin of these genes in the bacterial domain. We compared the genomic arrangement of these genes inPlanctomycetesand methylotrophic proteobacteria and performed a phylogenetic analysis of the encoded protein sequences to address the question whether the genes have been present in the common ancestor ofBacteriaandArchaeaor were transferred laterally from the archaeal to the bacterial domain and therein. Although this question could not be solved using the data presented here, some constraints on the evolution of the genes involved in archaeal and bacterial H4MPT-dependent C1-transfer may be proposed: (i) lateral gene transfer (LGT) fromArchaeato a common ancestor ofProteobacteriaandPlanctomycetesseems more likely than the presence of the genes in the common ancestor ofBacteriaandArchaea; (ii) a single event of interdomain LGT can be favored over two independent events; and (iii) the archaeal donor of the genes might have been a representative of theMethanosarcinales. In the bacterial domain, the acquired genes evolved according to distinct environmental and metabolic constraints, reflected by specific rearrangements of gene order, gene recruitment, and gene duplication, with subsequent functional specialization. During the course of evolution, genes were lost from some planctomycete genomes or replaced by orthologous genes from proteobacterial lineages.

ARCHAEBACTERIA; PHYLOGENY; BIOLOGY; MOLECULAR evolution; ORIGIN of life; EVOLUTIONARY theories; MOLECULAR biology

Journal of Molecular Evolution, 2004, Vol 59, Issue 5, p571

0022-2844

Academic Journal

10.1007/s00239-004-2643-6