Diversity-generating retroelements: natural variation, classification and evolution inferred from a large-scale genomic survey

A comprehensive phylogenetic analysis was conducted of non-long-terminal-repeat (non-LTR) retrotransposons based on an extended sequence alignment of their reverse transcriptase (RT) domain. The 440 amino acid positions used included a region proposed to be similar to the "thumb" of the right-handed RT structure found in retroviruses. All identified non-LTR elements could be grouped into 11 distinct clades. Using the rates of sequence change derived from studies of the vertical inheritance of R1 and R2 elements in arthropods as a comparison, we found no evidence for the horizontal transmission of non-LTR elements. Assuming vertical descent, the phylogeny suggested that non-LTR elements are as old as eukaryotes, with each of the 11 clades dating back to the Precambrian era. The analysis enabled us to propose a simple chronology for the acquisition of different enzymatic domains in the evolution of the non-LTR class of retrotransposons. The first non-LTR elements were sequence specific by virtue of a restriction-enzyme-like endonuclease located downstream of the RT domain. Evolving from this original group were elements (eight clades) that acquired an apurinic-apyrimidic endonuclease-like domain upstream of the RT domain. Finally, four of these clades have inherited an RNase H domain downstream of the RT domain. The phylogenies of the AP endonuclease and RNase H domains were also determined for this report and are consistent with the monophyletic acquisition of these domains. These studies represent the most comprehensive effort to date to trace the evolution of a major class of transposable elements.

Host-pathogen interactions are often driven by mechanisms that promote genetic variability. We have identified a group of temperate bacteriophages that generate diversity in a gene, designated mtd (major tropism determinant), which specifies tropism for receptor molecules on host Bordetella species. Tropism switching is the result of a template-dependent, reverse transcriptase-mediated process that introduces nucleotide substitutions at defined locations within mtd. This cassette-based mechanism is capable of providing a vast repertoire of potential ligand-receptor interactions.

Background The classical Bordetella subspecies are phylogenetically closely related, yet differ in some of the most interesting and important characteristics of pathogens, such as host range, virulence and persistence. The compelling picture from previous comparisons of the three sequenced genomes was of genome degradation, with substantial loss of genome content (up to 24%) associated with adaptation to humans. Results For a more comprehensive picture of lineage evolution, we employed comparative genomic and phylogenomic analyses using seven additional diverse, newly sequenced Bordetella isolates. Genome-wide single nucleotide polymorphism (SNP) analysis supports a reevaluation of the phylogenetic relationships between the classical Bordetella subspecies, and suggests a closer link between ovine and human B. parapertussis lineages than has been previously proposed. Comparative analyses of genome content revealed that only 50% of the pan-genome is conserved in all strains, reflecting substantial diversity of genome content in these closely related pathogens that may relate to their different host ranges, virulence and persistence characteristics. Strikingly, these analyses suggest possible horizontal gene transfer (HGT) events in multiple loci encoding virulence factors, including O-antigen and pertussis toxin (Ptx). Segments of the pertussis toxin locus (ptx) and its secretion system locus (ptl) appear to have been acquired by the classical Bordetella subspecies and are divergent in different lineages, suggesting functional divergence in the classical Bordetellae. Conclusions Together, these observations, especially in key virulence factors, reveal that multiple mechanisms, such as point mutations, gain or loss of genes, as well as HGTs, contribute to the substantial phenotypic diversity of these versatile subspecies in various hosts.