AUTHOR=Legerme Georgio , Pohlschroder Mechthild 

TITLE=Limited Cross-Complementation Between Haloferax volcanii PilB1-C1 and PilB3-C3 Paralogs

JOURNAL=Frontiers in Microbiology

VOLUME=10

YEAR=2019

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2019.00700

DOI=10.3389/fmicb.2019.00700

ISSN=1664-302X

ABSTRACT=<p>Type IV pili are evolutionarily conserved cell surface filaments that promote surface adhesion and cell aggregation providing bacteria and archaea protection from a variety of stress conditions. In fact, prokaryotic genomes frequently contain several copies of the core biosynthesis genes, <italic>pilB</italic> and <italic>pilC</italic>, encoding an ATPase and membrane anchor, respectively. Recent phylogenetic analyses suggest that in haloarchaea, a subset of <italic>pilB-C</italic> paralogs, such as the <italic>Haloferax volcanii pilB1</italic>-<italic>C1</italic>, were gained <italic>via</italic> horizontal transfer from the crenarchaea, while the co-regulated type IV pilus subunits, the pilins, evolved by duplication, followed by diversification of the ancestral euryarchaeal pilins. Here, we report the identification of an <italic>H. volcanii pilB1</italic> transposon mutant that exhibits an adhesion defect in defined media. A similar defect observed in an <italic>H. volcanii</italic> ∆<italic>pilB1-C1</italic> strain can be rescued by expressing <italic>pilB1-C1 in trans</italic>. However, these proteins cannot rescue the severe adhesion defect of a previously reported ∆<italic>pilB3-C3</italic> strain. Conversely, <italic>pilB3-C3,</italic> which are not predicted to have been laterally transferred, expressed <italic>in trans</italic> can rescue the adhesion defect of a ∆<italic>pilB1-C1</italic> strain. This cross-complementation supports the proposed hybrid origin of the operon containing <italic>pilB1-C1</italic> and shows that at least certain euryarchaeal PilB paralogs can work with different pilin sets. Efficient recognition of the euryarchaeal pilins by the crenarchaeal PilB1-C1 may have required some degree of pilin modification, but perhaps the modifications were minor enough that PilB3 recognition of these pilins was not precluded, resulting in modular evolution and an extensive combinatorial diversity that allows for adaptation to a variety of stress conditions and attachment to varied surfaces.</p>