The interaction between a bacteriophage and its host is mediated by the phage's receptor binding protein (RBP). Despite its fundamental role in governing phage activity and host range, molecular rules of RBP function remain a mystery. Here, we systematically dissect the functional role of every residue in the tip domain of T7 phage RBP (1660 variants) by developing a high-throughput, locus-specific, phage engineering method. This rich dataset allowed us to cross compare functional profiles across hosts to precisely identify regions of functional importance, many which were previously unknown. Substitution patterns showed host-specific differences in position and physicochemical properties of mutations, revealing molecular adaptation to individual hosts. We discovered gain-of-function variants against resistant hosts and host-constricting variants that eliminated certain hosts. To demonstrate therapeutic utility, we engineered highly active T7 variants against urinary tract pathogen. Our approach presents a generalized framework for characterizing sequence-function relationships in many phage-bacterial systems.
Highlights d Thousands of diverse viruses encode genes that manipulate organic sulfur metabolism d Infection in the presence of sulfide increases bacteriophage production d Engineered phage T7 retains cysteine synthase (cysK) over multiple generations d These viruses can influence human gut dysbiosis, microbiomes, and biogeochemistry
SummaryViruses influence the fate of nutrients and human health by killing microorganisms and altering metabolic processes. Organosulfur metabolism and biologically-derived hydrogen sulfide play dynamic roles in manifestation of diseases, infrastructure degradation, and essential biological processes. While microbial organosulfur metabolism is well-studied, the role of viruses in organosulfur metabolism is unknown. Here we report the discovery of 39 gene families involved in organosulfur metabolism encoded by 3,749 viruses from diverse ecosystems, including human microbiomes. The viruses infect organisms from all three domains of life. Six gene families encode for enzymes that degrade organosulfur compounds into sulfide, while others manipulate organosulfur compounds and may influence sulfide production. We show that viral metabolic genes encode key enzymatic domains, are translated into protein, are maintained after recombination, and that sulfide provides a fitness advantage to viruses. Our results reveal viruses as drivers of organosulfur metabolism with important implications for human and environmental health.
Transcriptional repressors play an
important role in regulating
phage life cycle. Here, we examine how synthetic transcription repressors
can be used in bacteriophage T7 to create a dynamic, controllable
infectivity switch. We engineered T7 phage by replacing a large region
of the early phage genome with different combinations of ligand-responsive
promoters and ribosome binding sites (RBS) designed to control the
phage RNA polymerase, gp1. Phages with engineered
infectivity switch are fully viable at levels comparable to wildtype
T7, when not repressed, indicating the phage can be engineered without
loss of fitness. The most effective switch used a TetR-responsive
promoter and an attenuated RBS, resulting in a 2-fold increase in
latent period and a 10-fold decrease in phage titer when repressed.
Phage activity can be further tuned using different inducer concentrations.
Our study provides a proof of concept for how a simple synthetic circuit
introduced into the phage genome enables user control over phage infectivity.
The interaction between a bacteriophage and its host is mediated by the phage’s receptor binding protein (RBP). Despite its fundamental role in governing phage activity and host range, molecular rules of RBP function remain a mystery. Here, we systematically dissect the functional role of every residue in the tip domain of T7 phage RBP using a high-throughput, locus-specific, phage engineering method. We find that function-enhancing mutations are concentrated around outward-facing loops suggesting directionality and orientational-bias in receptor engagement. These mutations are host-specific, indicating adaptation to individual hosts and highlighting a tradeoff between activity and host range. We discover gain-of-function variants effective against resistant strains and host-constricting variants that selectively eliminate certain hosts. We demonstrate therapeutic utility against uropathogenic E. coli by engineering a highly active T7 to avert emergence of spontaneous resistance of the pathogen. Our approach is generalizable to other phages and will enable the design of programmable phages.
Transcriptional repressors play an important role in regulating phage genomes. Here, we examined how synthetic regulation based on repressors can be to create a dynamic, controllable infectivity switch in bacteriophage T7. We engineered T7 by replacing a large region of the early phage genome with combinations of ligand-responsive promoters and ribosome binding sites (RBS) designed to control the phage RNA polymerase. Phages with the engineered switch showed virulence comparable to wildtype when not repressed, indicating the phage can be engineered without a loss of fitness. When repressed, the most effective switch used a TetR promoter and a weak RBS, resulting in a two-fold increase in latent period (time to lyse host) and change in phage titer. Further, phage activity could be tuned by varying inducer concentrations. Our study provides a proof of concept for a simple circuit for user control over phage infectivity.
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