Gene Expression Patterns during Light and Dark Infection of Prochlorococcus by Cyanophage.

Luke R Thompson,Sallie W Chisholm,Qinglu Zeng,Douglas Andrew Campbell

doi:10.1371/journal.pone.0165375

Luke R Thompson, Sallie W Chisholm + Show 2 more

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https://doi.org/10.1371/journal.pone.0165375

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Journal: PloS one	Publication Date: Oct 27, 2016
Citations: 38	License type: CC BY 4.0

Affiliation: Massachusetts Institute of Technology

Abstract

Cyanophage infecting the marine cyanobacteria Prochlorococcus and Synechococcus require light and host photosystem activity for optimal reproduction. Many cyanophages encode multiple photosynthetic electron transport (PET) proteins, which are presumed to maintain electron flow and produce ATP and NADPH for nucleotide biosynthesis and phage genome replication. However, evidence suggests phage augment NADPH production via the pentose phosphate pathway (PPP), thus calling into question the need for NADPH production by PET. Genes implicated in cyclic PET have since been identified in cyanophage genomes. It remains an open question which mode of PET, cyclic or linear, predominates in infected cyanobacteria, and thus whether the balance is towards producing ATP or NADPH. We sequenced transcriptomes of a cyanophage (P-HM2) and its host (Prochlorococcus MED4) throughout infection in the light or in the dark, and analyzed these data in the context of phage replication and metabolite measurements. Infection was robust in the light, but phage were not produced in the dark. Host gene transcripts encoding high-light inducible proteins and two terminal oxidases (plastoquinol terminal oxidase and cytochrome c oxidase)—implicated in protecting the photosynthetic membrane from light stress—were the most enriched in light but not dark infection. Among the most diminished transcripts in both light and dark infection was ferredoxin–NADP+ reductase (FNR), which uses the electron acceptor NADP+ to generate NADPH in linear photosynthesis. The phage gene for CP12, which putatively inhibits the Calvin cycle enzyme that receives NADPH from FNR, was highly expressed in light infection. Therefore, both PET production of NADPH and its consumption by carbon fixation are putatively repressed during phage infection in light. Transcriptomic evidence is thus consistent with cyclic photophosphorylation using oxygen as the terminal electron acceptor as the dominant mode of PET under infection, with ATP from PET and NADPH from the PPP producing the energy and reducing equivalents for phage nucleotide biosynthesis and replication.

Highlights

Cyanophage are viruses that infect cyanobacteria [1], including the numerically dominant marine picocyanobacteria Prochlorococcus and Synechococcus [2]
As evidenced by the functions of proteins encoded by auxiliary metabolic genes’ (AMGs)—and by the high demand for nucleotides for phage replication—nucleotide biosynthesis is a key product of cyanophageinfected host metabolism; nucleotide biosynthesis genes are common in cyanophage genomes [6, 9]
NADPH is not consumed by carbon fixation, which is inhibited under phage infection [26], and instead the pentose phosphate pathway is the primary source of NADPH [4]

Summary

Introduction

Cyanophage are viruses that infect cyanobacteria [1], including the numerically dominant marine picocyanobacteria Prochlorococcus and Synechococcus [2]. Cyanophage genomes contain various ‘auxiliary metabolic genes’ (AMGs), which are not universal but evolutionarily conserved and are thought to boost and redirect host metabolism during infection [3, 4]. AMGs are more abundant in the larger T4-like cyanomyophage genomes (the subject of this study) [5], they are found in T7-like cyanopodophages [6, 7], and host homologs of AMGs are induced by cyanosiphophages [8], suggesting a common infection strategy across all three cyanophage families. As evidenced by the functions of proteins encoded by AMGs—and by the high demand for nucleotides for phage replication—nucleotide biosynthesis is a key product of cyanophageinfected host metabolism; nucleotide biosynthesis genes are common in cyanophage genomes [6, 9]. The synthesis of deoxynucleoside triphosphates (shortened to ‘nucleotides’ here) requires phosphate—potentially accounting for the presence of phosphateacquisition genes in some cyanophages [6, 10, 11]—but is energy-intensive, requiring large amounts of ATP (energy) and NADPH (reducing equivalents)

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