Abstract

The emergence of new viruses impacting human health represents an important threat, with HIV, SARS and Ebola as recent examples. New viruses do not spontaneously generate, but arise from the extant viral population by acquisition of preferences for new hosts. However, the mechanisms by which this occurs remain poorly understood, and changes in the host preferences of viruses are not readily predictable. Bacteriophages represent a powerful model system for addressing questions of viral host range evolution. The phage population is vast, dynamic, and old, and they play key roles in environmental carbon turnover and bacterial pathogenicity. Phage studies provide a multitude of benefits, ranging biotechnology tools, diagnostics for bacterial infections, phage therapy, synthetic biology, microbial computers, and microbial batteries. The great genetic diversity of the phage population, the ease with which novel phages can be isolated, their host range manipulated, and their phage genes analyzed, presents a tractable experimental system. Phage genomes are typically small compared to their bacterial hosts, and yet the definition of phage genome sequences lags far behind that of their larger host genomes. Moreover, the abundance of novel genes within phage genomes shows they represent the largest unexplored reservoir of sequences in the biosphere, which we have been slow to tap. The diversity of phage genomes and genes is likely driven by 3-4 billion years of warfare between the hosts and their infecting viruses, with constant pressure for resistant hosts, and phage co- evolution to access new hosts. Thus, understanding the role of host preferences and the demands for specific genes to growth in specific hosts, will provide critical clues as to how new viruses emerge, and a context to interpreting both phage and bacterial genomes. A large collection of 800 completely sequenced phage genomes infecting a common host strain, Mycobacterium smegmatis mc2155 shows them to be highly diverse. Not only are there many types of unrelated genomes, but great variation among related genomes, and the GC% ranges from 50-70%. We propose that this diversity is generated by the availability of a diverse range of possible bacterial hosts, together with the ability of the phages to switch host preferences, and we predict that phages of other hosts that are isolated from similar environments will show similar degrees of diversity. To explore the dynamics of viral host range evolution we will characterize the phages of hosts within the Order Actinomycetales. Individual phages will be isolated and sequenced, and the genome diversity of these phages explored more broadly using targeted metagenomic strategies. The host ranges of these phages will be determined and host range variants evolved across several hosts. The genetic requirements for viral growth in different bacterial hosts will be established, and bioinformatic analyses will characterize genes under positive selection, recombination rates, the barriers to genetic exchange, and the contributions of host preferences.

Public Health Relevance

Elucidating the dynamics of viral host range evolution will provide insights into the origins of ne viruses and illuminate the roles of bacteriophages in bacterial pathogenesis. The discovery of viruses of closely related hosts and variants accessing new hosts will reveal the mechanisms of evolution and genetic variation.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM116884-02
Application #
9145719
Study Section
Prokaryotic Cell and Molecular Biology Study Section (PCMB)
Program Officer
Reddy, Michael K
Project Start
2015-09-17
Project End
2019-06-30
Budget Start
2016-07-01
Budget End
2017-06-30
Support Year
2
Fiscal Year
2016
Total Cost
Indirect Cost

  Institution

Name
University of Pittsburgh
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213

  Publications

Ko, Ching-Chung; Hatfull, Graham F (2018) Mycobacteriophage Fruitloop gp52 inactivates Wag31 (DivIVA) to prevent heterotypic superinfection. Mol Microbiol 108:443-460
Hatfull, Graham F (2018) Mycobacteriophages. Microbiol Spectr 6:
Pope, Welkin H; Montgomery, Matthew T; Bonilla, J Alfred et al. (2017) Complete Genome Sequences of 38 Gordonia sp. Bacteriophages. Genome Announc 5:
Russell, Daniel A; Hatfull, Graham F (2017) PhagesDB: the actinobacteriophage database. Bioinformatics 33:784-786
Dedrick, Rebekah M; Jacobs-Sera, Deborah; Bustamante, Carlos A Guerrero et al. (2017) Prophage-mediated defence against viral attack and viral counter-defence. Nat Microbiol 2:16251
Dedrick, Rebekah M; Mavrich, Travis N; Ng, Wei L et al. (2017) Expression and evolutionary patterns of mycobacteriophage D29 and its temperate close relatives. BMC Microbiol 17:225
Pope, Welkin H; Mavrich, Travis N; Garlena, Rebecca A et al. (2017) Bacteriophages of Gordonia spp. Display a Spectrum of Diversity and Genetic Relationships. MBio 8:
Klyczek, Karen K; Bonilla, J Alfred; Jacobs-Sera, Deborah et al. (2017) Tales of diversity: Genomic and morphological characteristics of forty-six Arthrobacter phages. PLoS One 12:e0180517
Jacobs-Sera, Deborah; Catinas, Oana; Fernandez-Martinez, Mariceli et al. (2017) Genome Sequences of Mycobacteriophages Kerberos, Pomar16, and StarStuff. Genome Announc 5:
Mavrich, Travis N; Hatfull, Graham F (2017) Bacteriophage evolution differs by host, lifestyle and genome. Nat Microbiol 2:17112

Showing the most recent 10 out of 15 publications