Draft genome sequences of two wide-host-range phages of from food processing environments in the United States.

is notorious for persistence in food facilities. Phages can significantly impact the ecology of , but there is a dearth of genome sequence data for phages from food processing ecosystems. We report the genome sequences of two phages from turkey processing facilities in the USA.

Engineered reporter phages for detection of Escherichia coli, Enterococcus, and Klebsiella in urine.

The rapid detection and species-level differentiation of bacterial pathogens facilitates antibiotic stewardship and improves disease management. Here, we develop a rapid bacteriophage-based diagnostic assay to detect the most prevalent pathogens causing urinary tract infections: Escherichia coli, Enterococcus spp., and Klebsiella spp.

Enhancing bacteriophage therapeutics through in situ production and release of heterologous antimicrobial effectors.

Bacteriophages operate via pathogen-specific mechanisms of action distinct from conventional, broad-spectrum antibiotics and are emerging as promising alternative antimicrobials. However, phage-mediated killing is often limited by bacterial resistance development. Here, we engineer phages for target-specific effector gene delivery and host-dependent production of colicin-like bacteriocins and cell wall hydrolases.

L-form conversion in Gram-positive bacteria enables escape from phage infection.

At the end of a lytic bacteriophage replication cycle in Gram-positive bacteria, peptidoglycan-degrading endolysins that cause explosive cell lysis of the host can also attack non-infected bystander cells. Here we show that in osmotically stabilized environments, Listeria monocytogenes can evade phage predation by transient conversion to a cell wall-deficient L-form state. This L-form escape is triggered by endolysins disintegrating the cell wall from without, leading to turgor-driven extrusion of wall-deficient, yet viable L-form cells.

Enhancing phage therapy through synthetic biology and genome engineering.

The antimicrobial and therapeutic efficacy of bacteriophages is currently limited, mostly due to rapid emergence of phage-resistance and the inability of most phage isolates to bind and infect a broad range of clinical strains. Here, we discuss how phage therapy can be improved through recent advances in genetic engineering. First, we outline how receptor-binding proteins and their relevant structural domains are engineered to redirect phage specificity and to avoid resistance.

Reporter Phage-Based Detection of Bacterial Pathogens: Design Guidelines and Recent Developments.

Fast and reliable detection of bacterial pathogens in clinical samples, contaminated food products, and water supplies can drastically improve clinical outcomes and reduce the socio-economic impact of disease. As natural predators of bacteria, bacteriophages (phages) have evolved to bind their hosts with unparalleled specificity and to rapidly deliver and replicate their viral genome. Not surprisingly, phages and phage-encoded proteins have been used to develop a vast repertoire of diagnostic assays, many of which outperform conventional culture-based and molecular detection methods.

Critical Anti-CRISPR Locus Repression by a Bi-functional Cas9 Inhibitor.

Bacteriophages must rapidly deploy anti-CRISPR proteins (Acrs) to inactivate the RNA-guided nucleases that enforce CRISPR-Cas adaptive immunity in their bacterial hosts. Listeria monocytogenes temperate phages encode up to three anti-Cas9 proteins, with acrIIA1 always present. AcrIIA1 binds and inhibits Cas9 with its C-terminal domain; however, the function of its highly conserved N-terminal domain (NTD) is unknown.

Listeria Phages Induce Cas9 Degradation to Protect Lysogenic Genomes.

Bacterial CRISPR-Cas systems employ RNA-guided nucleases to destroy phage (viral) DNA. Phages, in turn, have evolved diverse "anti-CRISPR" proteins (Acrs) to counteract acquired immunity. In Listeria monocytogenes, prophages encode two to three distinct anti-Cas9 proteins, with acrIIA1 always present.

Engineered Reporter Phages for Rapid Bioluminescence-Based Detection and Differentiation of Viable Cells.

The pathogen causes listeriosis, a severe foodborne disease associated with high mortality. Rapid and sensitive methods are required for specific detection of this pathogen during food production. Bioluminescence-based reporter bacteriophages are genetically engineered viruses that infect their host cells with high specificity and transduce a heterologous luciferase gene whose activity can be detected with high sensitivity to indicate the presence of viable target cells.

Reprogramming Bacteriophage Host Range through Structure-Guided Design of Chimeric Receptor Binding Proteins.

Bacteriophages provide excellent tools for diagnostics, remediation, and targeted microbiome manipulation, yet isolating viruses with suitable host specificity remains challenging. Using Listeria phage PSA, we present a synthetic biology blueprint for host-range engineering through targeted modification of serovar-specific receptor binding proteins (RBPs). We identify Gp15 as the PSA RBP and construct a synthetic phage library featuring sequence-randomized RBPs, from which host range mutants are isolated and subsequently integrated into a synthetic, polyvalent phage with extended host range.

Phage resistance at the cost of virulence: Listeria monocytogenes serovar 4b requires galactosylated teichoic acids for InlB-mediated invasion.

The intracellular pathogen Listeria monocytogenes is distinguished by its ability to invade and replicate within mammalian cells. Remarkably, of the 15 serovars within the genus, strains belonging to serovar 4b cause the majority of listeriosis clinical cases and outbreaks. The Listeria O-antigens are defined by subtle structural differences amongst the peptidoglycan-associated wall-teichoic acids (WTAs), and their specific glycosylation patterns.

RNAi-Mediated Depletion of Poxvirus Proteins.

RNA interference (RNAi) allows for transient, targeted depletion of cellular or viral proteins. Previously, small interfering RNA (siRNA) screens targeting cellular factors successfully identified several host genes that are required for VACV infection, and other viruses such as HIV. In this chapter, we outline how RNAi can be adapted to unravel the functions of poxvirus genes, using a 96-well format.

Vaccinia virus hijacks EGFR signalling to enhance virus spread through rapid and directed infected cell motility.

Cell motility is essential for viral dissemination. Vaccinia virus (VACV), a close relative of smallpox virus, is thought to exploit cell motility as a means to enhance the spread of infection. A single viral protein, F11L, contributes to this by blocking RhoA signalling to facilitate cell retraction.

Engineering Bacteriophages as Versatile Biologics.

Viruses of bacteria (bacteriophages or phages) are highly evolved nanomachines that recognize bacterial cell walls, deliver genetic information, and kill or transform their targets with unparalleled specificity. For a long time, the use of genetically modified phages was limited to phage display approaches and fundamental research. This is mostly because phage engineering has been a complex and time-consuming task, applicable for only a few well characterized model phages.

A functional type II-A CRISPR-Cas system from Listeria enables efficient genome editing of large non-integrating bacteriophage.

CRISPR-Cas systems provide bacteria with adaptive immunity against invading DNA elements including bacteriophages and plasmids. While CRISPR technology has revolutionized eukaryotic genome engineering, its application to prokaryotes and their viruses remains less well established. Here we report the first functional CRISPR-Cas system from the genus Listeria and demonstrate its native role in phage defense.

Proteotype profiling unmasks a viral signalling network essential for poxvirus assembly and transcriptional competence.

To orchestrate context-dependent signalling programmes, poxviruses encode two dual-specificity enzymes, the F10 kinase and the H1 phosphatase. These signalling mediators are essential for poxvirus production, yet their substrate profiles and systems-level functions remain enigmatic. Using a phosphoproteomic screen of cells infected with wild-type, F10 and H1 mutant vaccinia viruses, we systematically defined the viral signalling network controlled by these enzymes.

Cross-genus rebooting of custom-made, synthetic bacteriophage genomes in L-form bacteria.

Engineered bacteriophages provide powerful tools for biotechnology, diagnostics, pathogen control, and therapy. However, current techniques for phage editing are experimentally challenging and limited to few phages and host organisms. Viruses that target Gram-positive bacteria are particularly difficult to modify.

3D printing of bacteria into functional complex materials.

Despite recent advances to control the spatial composition and dynamic functionalities of bacteria embedded in materials, bacterial localization into complex three-dimensional (3D) geometries remains a major challenge. We demonstrate a 3D printing approach to create bacteria-derived functional materials by combining the natural diverse metabolism of bacteria with the shape design freedom of additive manufacturing. To achieve this, we embedded bacteria in a biocompatible and functionalized 3D printing ink and printed two types of "living materials" capable of degrading pollutants and of producing medically relevant bacterial cellulose.

Vaccinia Virus Infection Requires Maturation of Macropinosomes.

The prototypic poxvirus, vaccinia virus (VACV), occurs in two infectious forms, mature virions (MVs) and extracellular virions (EVs). Both enter HeLa cells by inducing macropinocytic uptake. Using confocal microscopy, live-cell imaging, targeted RNAi screening and perturbants of endosome maturation, we analyzed the properties and maturation pathway of the macropinocytic vacuoles containing VACV MVs in HeLa cells.

DNA virus uncoating.

Virus genomes are condensed and packaged inside stable proteinaceous capsids that serve to protect them during transit from one cell or host organism, to the next. During virus entry, capsid shells are primed and disassembled in a complex, tightly-regulated, multi-step process termed uncoating. Here we compare the uncoating-programs of DNA viruses of the pox-, herpes-, adeno-, polyoma-, and papillomavirus families.

Next generation approaches to study virus entry and infection.

As obligate intracellular parasites viruses rely on host cell factors and functions for all stages of infection, from entry to spread. Characterization of these cellular components is critical to advance our understanding of the infection process and develop novel means to combat viral pathogens. To this end, the recent application of next generation approaches including compound screening, cell-targeting RNA interference, gene knockouts, and several proteomics approaches has served to expand our understanding of virus-host interactions, and facilitated the discovery of potential anti-viral targets.

siRNA screen of early poxvirus genes identifies the AAA+ ATPase D5 as the virus genome-uncoating factor.

Poxvirus genome uncoating is a two-step process. First, cytoplasmic viral cores are activated and early viral genes are expressed. Next, cores are disassembled and the genomes released.

Tracking viral genomes in host cells at single-molecule resolution.

Viral DNA trafficking in cells has large impacts on physiology and disease development. Current methods lack the resolution and accuracy to visualize and quantify viral DNA trafficking at single-molecule resolution. We developed a noninvasive protocol for accurate quantification of viral DNA-genome (vDNA) trafficking in single cells.