PLoS ONE (Jan 2013)

Genomics and physiology of a marine flavobacterium encoding a proteorhodopsin and a xanthorhodopsin-like protein.

  • Thomas Riedel,
  • Laura Gómez-Consarnau,
  • Jürgen Tomasch,
  • Madeleine Martin,
  • Michael Jarek,
  • José M González,
  • Stefan Spring,
  • Meike Rohlfs,
  • Thorsten Brinkhoff,
  • Heribert Cypionka,
  • Markus Göker,
  • Anne Fiebig,
  • Johannes Klein,
  • Alexander Goesmann,
  • Jed A Fuhrman,
  • Irene Wagner-Döbler

DOI
https://doi.org/10.1371/journal.pone.0057487
Journal volume & issue
Vol. 8, no. 3
p. e57487

Abstract

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Proteorhodopsin (PR) photoheterotrophy in the marine flavobacterium Dokdonia sp. PRO95 has previously been investigated, showing no growth stimulation in the light at intermediate carbon concentrations. Here we report the genome sequence of strain PRO95 and compare it to two other PR encoding Dokdonia genomes: that of strain 4H-3-7-5 which shows the most similar genome, and that of strain MED134 which grows better in the light under oligotrophic conditions. Our genome analysis revealed that the PRO95 genome as well as the 4H-3-7-5 genome encode a protein related to xanthorhodopsins. The genomic environment and phylogenetic distribution of this gene suggest that it may have frequently been recruited by lateral gene transfer. Expression analyses by RT-PCR and direct mRNA-sequencing showed that both rhodopsins and the complete β-carotene pathway necessary for retinal production are transcribed in PRO95. Proton translocation measurements showed enhanced proton pump activity in response to light, supporting that one or both rhodopsins are functional. Genomic information and carbon source respiration data were used to develop a defined cultivation medium for PRO95, but reproducible growth always required small amounts of yeast extract. Although PRO95 contains and expresses two rhodopsin genes, light did not stimulate its growth as determined by cell numbers in a nutrient poor seawater medium that mimics its natural environment, confirming previous experiments at intermediate carbon concentrations. Starvation or stress conditions might be needed to observe the physiological effect of light induced energy acquisition.