William Cenens

Engineered Endolysin-Based “Artilysins” To Combat Multidrug-Resistant Gram-Negative Pathogens

ABSTRACT The global threat to public health posed by emerging multidrug-resistant bacteria in the past few years necessitates the development of novel approaches to combat bacterial infections. Endolysins encoded by bacterial viruses (or phages) represent one promising avenue of investigation. These enzyme-based antibacterials efficiently kill Gram-positive bacteria upon contact by specific cell wall hydrolysis. However, a major hurdle in their exploitation as antibacterials against Gram-negative pathogens is the impermeable lipopolysaccharide layer surrounding their cell wall. Therefore, we developed and optimized an approach to engineer these enzymes as outer membrane-penetrating endolysins (Artilysins), rendering them highly bactericidal against Gram-negative pathogens, including Pseudomonas aeruginosa and Acinetobacter baumannii. Artilysins combining a polycationic nonapeptide and a modular endolysin are able to kill these (multidrug-resistant) strains in vitro with a 4 to 5 log reduction within 30 min. We show that the activity of Artilysins can be further enhanced by the presence of a linker of increasing length between the peptide and endolysin or by a combination of both polycationic and hydrophobic/amphipathic peptides. Time-lapse microscopy confirmed the mode of action of polycationic Artilysins, showing that they pass the outer membrane to degrade the peptidoglycan with subsequent cell lysis. Artilysins are effective in vitro (human keratinocytes) and in vivo (Caenorhabditis elegans). IMPORTANCE Bacterial resistance to most commonly used antibiotics is a major challenge of the 21st century. Infections that cannot be treated by first-line antibiotics lead to increasing morbidity and mortality, while millions of dollars are spent each year by health care systems in trying to control antibiotic-resistant bacteria and to prevent cross-transmission of resistance. Endolysins—enzymes derived from bacterial viruses—represent a completely novel, promising class of antibacterials based on cell wall hydrolysis. Specifically, they are active against Gram-positive species, which lack a protective outer membrane and which have a low probability of resistance development. We modified endolysins by protein engineering to create Artilysins that are able to pass the outer membrane and become active against Pseudomonas aeruginosa and Acinetobacter baumannii, two of the most hazardous drug-resistant Gram-negative pathogens. Bacterial resistance to most commonly used antibiotics is a major challenge of the 21st century. Infections that cannot be treated by first-line antibiotics lead to increasing morbidity and mortality, while millions of dollars are spent each year by health care systems in trying to control antibiotic-resistant bacteria and to prevent cross-transmission of resistance. Endolysins—enzymes derived from bacterial viruses—represent a completely novel, promising class of antibacterials based on cell wall hydrolysis. Specifically, they are active against Gram-positive species, which lack a protective outer membrane and which have a low probability of resistance development. We modified endolysins by protein engineering to create Artilysins that are able to pass the outer membrane and become active against Pseudomonas aeruginosa and Acinetobacter baumannii, two of the most hazardous drug-resistant Gram-negative pathogens.

Art-175 Is a Highly Efficient Antibacterial against Multidrug-Resistant Strains and Persisters of Pseudomonas aeruginosa

ABSTRACT Artilysins constitute a novel class of efficient enzyme-based antibacterials. Specifically, they covalently combine a bacteriophage-encoded endolysin, which degrades the peptidoglycan, with a targeting peptide that transports the endolysin through the outer membrane of Gram-negative bacteria. Art-085, as well as Art-175, its optimized homolog with increased thermostability, are each composed of the sheep myeloid 29-amino acid (SMAP-29) peptide fused to the KZ144 endolysin. In contrast to KZ144, Art-085 and Art-175 pass the outer membrane and kill Pseudomonas aeruginosa, including multidrug-resistant strains, in a rapid and efficient (∼5 log units) manner. Time-lapse microscopy confirms that Art-175 punctures the peptidoglycan layer within 1 min, inducing a bulging membrane and complete lysis. Art-175 is highly refractory to resistance development by naturally occurring mutations. In addition, the resistance mechanisms against 21 therapeutically used antibiotics do not show cross-resistance to Art-175. Since Art-175 does not require an active metabolism for its activity, it has a superior bactericidal effect against P. aeruginosa persisters (up to >4 log units compared to that of the untreated controls). In summary, Art-175 is a novel antibacterial that is well suited for a broad range of applications in hygiene and veterinary and human medicine, with a unique potential to target persister-driven chronic infections.

A Multifaceted Study of Pseudomonas aeruginosa Shutdown by Virulent Podovirus LUZ19

ABSTRACT In contrast to the rapidly increasing knowledge on genome content and diversity of bacterial viruses, insights in intracellular phage development and its impact on bacterial physiology are very limited. We present a multifaceted study combining quantitative PCR (qPCR), microarray, RNA-seq, and two-dimensional gel electrophoresis (2D-GE), to obtain a global overview of alterations in DNA, RNA, and protein content in Pseudomonas aeruginosa PAO1 cells upon infection with the strictly lytic phage LUZ19. Viral genome replication occurs in the second half of the phage infection cycle and coincides with degradation of the bacterial genome. At the RNA level, there is a sharp increase in viral mRNAs from 23 to 60% of all transcripts after 5 and 15 min of infection, respectively. Although microarray analysis revealed a complex pattern of bacterial up- and downregulated genes, the accumulation of viral mRNA clearly coincides with a general breakdown of abundant bacterial transcripts. Two-dimensional gel electrophoretic analyses shows no bacterial protein degradation during phage infection, and seven stress-related bacterial proteins appear. Moreover, the two most abundantly expressed early and late-early phage proteins, LUZ19 gene product 13 (Gp13) and Gp21, completely inhibit P. aeruginosa growth when expressed from a single-copy plasmid. Since Gp13 encodes a predicted GNAT acetyltransferase, this observation points at a crucial but yet unexplored level of posttranslational viral control during infection. IMPORTANCE Massive genome sequencing has led to important insights into the enormous genetic diversity of bacterial viruses (bacteriophages). However, for nearly all known phages, information on the impact of the phage infection on host physiology and intracellular phage development is scarce. This aspect of phage research should be revitalized, as phages evolved genes which can shut down or redirect bacterial processes in a very efficient way, which can be exploited towards antibacterial design. In this context, we initiated a study of the human opportunistic pathogen Pseudomonas aeruginosa under attack by one its most common predators, the Phikmvlikevirus. By analyzing various stages of infection at different levels, this study uncovers new features of phage infection, representing a cornerstone for future studies on members of this phage genus. Massive genome sequencing has led to important insights into the enormous genetic diversity of bacterial viruses (bacteriophages). However, for nearly all known phages, information on the impact of the phage infection on host physiology and intracellular phage development is scarce. This aspect of phage research should be revitalized, as phages evolved genes which can shut down or redirect bacterial processes in a very efficient way, which can be exploited towards antibacterial design. In this context, we initiated a study of the human opportunistic pathogen Pseudomonas aeruginosa under attack by one its most common predators, the Phikmvlikevirus. By analyzing various stages of infection at different levels, this study uncovers new features of phage infection, representing a cornerstone for future studies on members of this phage genus.

Expression of a novel P22 ORFan gene reveals the phage carrier state in Salmonella typhimurium.

We discovered a novel interaction between phage P22 and its host Salmonella Typhimurium LT2 that is characterized by a phage mediated and targeted derepression of the host dgo operon. Upon further investigation, this interaction was found to be instigated by an ORFan gene (designated pid for phage P22 encoded instigator of dgo expression) located on a previously unannotated moron locus in the late region of the P22 genome, and encoding an 86 amino acid protein of 9.3 kDa. Surprisingly, the Pid/dgo interaction was not observed during strict lytic or lysogenic proliferation of P22, and expression of pid was instead found to arise in cells that upon infection stably maintained an unintegrated phage chromosome that segregated asymmetrically upon subsequent cell divisions. Interestingly, among the emerging siblings, the feature of pid expression remained tightly linked to the cell inheriting this phage carrier state and became quenched in the other. As such, this study is the first to reveal molecular and genetic markers authenticating pseudolysogenic development, thereby exposing a novel mechanism, timing, and populational distribution in the realm of phage–host interactions.

Systematic Identification of Hypothetical Bacteriophage Proteins Targeting Key Protein Complexes of Pseudomonas aeruginosa

Addressing the functionality of predicted genes remains an enormous challenge in the postgenomic era. A prime example of genes lacking functional assignments are the poorly conserved, early expressed genes of lytic bacteriophages, whose products are involved in the subversion of the host metabolism. In this study, we focused on the composition of important macromolecular complexes of Pseudomonas aeruginosa involved in transcription, DNA replication, fatty acid biosynthesis, RNA regulation, energy metabolism, and cell division during infection with members of seven distinct clades of lytic phages. Using affinity purifications of these host protein complexes coupled to mass spectrometric analyses, 37 host complex-associated phage proteins could be identified. Importantly, eight of these show an inhibitory effect on bacterial growth upon episomal expression, suggesting that these phage proteins are potentially involved in hijacking the host complexes. Using complementary protein-protein interaction assays, we further mapped the inhibitory interaction of gp12 of phage 14-1 to the α subunit of the RNA polymerase. Together, our data demonstrate the powerful use of interactomics to unravel the biological role of hypothetical phage proteins, which constitute an enormous untapped source of novel antibacterial proteins. (Data are available via ProteomeXchange with identifier PXD001199.).

Phage–host interactions during pseudolysogeny: Lessons from the Pid/dgo interaction

Although the study of phage infection has a long history and catalyzed much of our current understanding in bacterial genetics, molecular biology, evolution and ecology, it seems that microbiologists have only just begun to explore the intricacy of phage–host interactions. In a recent manuscript by Cenens et al. we found molecular and genetic support for pseudolysogenic development in the Salmonella Typhimurium–phage P22 model system. More specifically, we observed the existence of phage carrier cells harboring an episomal P22 element that segregated asymmetrically upon subsequent divisions. Moreover, a newly discovered P22 ORFan protein (Pid) able to derepress a metabolic operon of the host (dgo) proved to be specifically expressed in these phage carrier cells. In this addendum we expand on our view regarding pseudolysogeny and its effects on bacterial and phage biology.

Functional elucidation of antibacterial phage ORFans targeting Pseudomonas aeruginosa

Immediately after infection, virulent bacteriophages hijack the molecular machinery of their bacterial host to create an optimal climate for phage propagation. For the vast majority of known phages, it is completely unknown which bacterial functions are inhibited or coopted. Early expressed phage genome regions are rarely identified, and often filled with small genes with no homology in databases (so‐called ORFans). In this work, we first analysed the temporal transcription pattern of the N4‐like Pseudomonas‐infecting phages and selected 26 unknown, early phage ORFans. By expressing their encoded proteins individually in the host bacterium Pseudomonas aeruginosa, we identified and further characterized six antibacterial early phage proteins using time‐lapse microscopy, radioactive labelling and pull‐down experiments. Yeast two‐hybrid analysis gaveclues to their possible role in phage infection. Specifically, we show that the inhibitory proteins may interact with transcriptional regulator PA0120, the replicative DNA helicase DnaB, the riboflavin metabolism key enzyme RibB, the ATPase PA0657and the spermidine acetyltransferase PA4114. The dependency of phage infection on spermidine was shown in a final experiment. In the future, knowledge of how phages shut down their hosts as well ass novel phage–host interaction partners could be very valuable in the identification of novel antibacterial targets.

Viral Transmission Dynamics at Single-Cell Resolution Reveal Transiently Immune Subpopulations Caused by a Carrier State Association

Monitoring the complex transmission dynamics of a bacterial virus (temperate phage P22) throughout a population of its host (Salmonella Typhimurium) at single cell resolution revealed the unexpected existence of a transiently immune subpopulation of host cells that emerged from peculiarities preceding the process of lysogenization. More specifically, an infection event ultimately leading to a lysogen first yielded a phage carrier cell harboring a polarly tethered P22 episome. Upon subsequent division, the daughter cell inheriting this episome became lysogenized by an integration event yielding a prophage, while the other daughter cell became P22-free. However, since the phage carrier cell was shown to overproduce immunity factors that are cytoplasmically inherited by the P22-free daughter cell and further passed down to its siblings, a transiently resistant subpopulation was generated that upon dilution of these immunity factors again became susceptible to P22 infection. The iterative emergence and infection of transiently resistant subpopulations suggests a new bet-hedging strategy by which viruses could manage to sustain both vertical and horizontal transmission routes throughout an infected population without compromising a stable co-existence with their host.

Antibacterial phage ORFans of Pseudomonas aeruginosa phage LUZ24 reveal a novel MvaT inhibiting protein

The functional elucidation of small unknown phage proteins (‘ORFans’) presents itself as one of the major challenges of bacteriophage molecular biology. In this work, we mined the Pseudomonas aeruginosa-infecting phage LUZ24 proteome for antibacterial and antibiofilm proteins against its host. Subsequently, their putative host target was identified. In one example, we observed an interaction between LUZ24 gp4 and the host transcriptional regulator MvaT. The polymerization of MvaT across AT-rich DNA strands permits gene silencing of foreign DNA, thereby limiting any potentially adverse effects of such DNA. Gel shift assays proved the inhibitory effect of LUZ24 gp4 on MvaT DNA binding activity. Therefore, we termed this gene product as Mip, the MvaT inhibiting protein. We hypothesize Mip prevents the AT-rich LUZ24 DNA from being physically blocked by MvaT oligomers right after its injection in the host cell, thereby allowing phage transcription and thus completion of the phage infection cycle.

An overview of the domestication and impact of the Salmonella mobilome

Abstract Salmonella spp. are accountable for a large fraction of the global infectious disease burden, with most of their infections being food- or water-borne. The phenotypic features and adaptive potential of Salmonella spp. appear to be driven to a large extent by mobile or laterally acquired genetic elements. A better understanding of the conduct and diversification of these important pathogens consequently requires a more profound insight into the different mechanisms by which these pivotal elements establish themselves in the cell and affect its behavior. This review, therefore, provides an overview of the physiological impact and domestication of the Salmonella mobilome.