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Ian J. Campbell and Jose L. Olmos and Weijun Xu and Dimithree Kahanda and Joshua T. Atkinson and Othneil N. Sparks and Mitchell D. Miller and George N. Phillips and George N. Bennett and Jonathan J. Silberg

Campbell, I.J. et al., 2020. Prochlorococcusphage ferredoxin: structural characterization and electron transfer to cyanobacterial sulfite reductases. Available at: http://dx.doi.org/10.1101/2020.02.07.937771.

AbstractMarine cyanobacteria are infected by phage whose genomes encode ferredoxin (Fd) electron carriers. While these Fds are thought to redirect the energy harvested from light to phage-encoded oxidoreductases that enhance viral fitness, it is not clear how the biophysical properties and partner specificities of phage Fds relate to those in photosynthetic organisms. Bioinformatic analysis using a sequence similarity network revealed that phage Fds are most closely related to cyanobacterial Fds that transfer electrons from photosystems to oxidoreductases involved in nutrient assimilation. Structural analysis of myovirus P-SSM2 Fd (pssm2-Fd), which infectsProchlorococcus marinus, revealed high similarity to cyanobacterial Fds (≤0.5 Å RMSD). Additionally, pssm2-Fd exhibits a low midpoint reduction potential (−336 mV vs. SHE) similar to other photosynthetic Fds, albeit lower thermostability (Tm= 28°C) than many Fds. When expressed in anEscherichia colistrain with a sulfite assimilation defect, pssm2-Fd complemented growth when coexpressed with aProchlorococcus marinussulfite reductase, revealing that pssm2-Fd can transfer electrons to a host protein involved in nutrient assimilation. The high structural similarity with cyanobacterial Fds and reactivity with a host sulfite reductase suggest that phage Fds evolved to transfer electrons to cyanobacterial-encoded oxidoreductases.

http://dx.doi.org/10.1101/2020.02.07.937771

NSF-STC Biology with X-ray Lasers (NSF-1231306)