The unexpected provenance of components in eukaryotic nucleotide-excision-repair and kinetoplast DNA-dynamics from bacterial mobile elements

Abstract

BackgroundProtein ‘weaponry’ deployed in biological conflicts between selfish elements and their hosts are increasingly recognized as being re-purposed for diverse molecular adaptations in the evolution of several uniquely eukaryotic systems. The anti-restriction protein ArdC, transmitted along with the DNA during invasion, is one such factor deployed by plasmids and conjugative transposons against their bacterial hosts.ResultsUsing sensitive computational methods we unify the N-terminal single-stranded DNA-binding domain of ArdC (ArdC-N) with the DNA-binding domains of the nucleotide excision repair (NER) XPC/Rad4 protein and Trypanosoma Tc-38 (p38) protein implicated in kinetoplast(k) DNA replication and dynamics. We show that the ArdC-N domain was independently acquired twice by eukaryotes from bacterial mobile elements. One gave rise to the ‘beta-hairpin domains’ of XPC/Rad4 and the other to the Tc-38-like proteins in the stem kinetoplastid. Eukaryotic ArdC-N domains underwent tandem duplications to form an extensive DNA-binding interface. In XPC/Rad4, the ArdC-N domain combined with the inactive transglutaminase domain of a peptide-N-glycanase originally derived from an active archaeal version, often incorporated in systems countering invasive DNA. We also show that parallel acquisitions from conjugative elements and bacteriophages gave rise to the Topoisomerase IA, DNA polymerases IB-Ds, and DNA ligases involved in kDNA dynamics.ConclusionsWe resolve two outstanding questions in eukaryote-biology: 1) origin of the unique DNA lesion-recognition component of NER; 2) origin of the unusual, plasmid-like features of kDNA. These represent a more general trend in the origin of distinctive components of systems involved in DNA dynamics and their links to the ubiquitin system.