Shining light on T6SS mode of action and function within single cells and bacterial communities

Bacteria are ubiquitously found in the environment and form the basis for all known ecosystems on our planet. Most bacterial cells reside in complex multi-species bacterial communities, which are often associated with a host, such as the human microbiota. These bacterial communities are shaped by cooperative and competitive interactions amongst their members. Like higher animals, bacteria also compete with their conspecifics for nutrients and space. This evolutionary arms race resulted in a diverse set of strategies for microbial competition. In particular, bacteria residing on solid surfaces can compete with their neighbors through the use of specialized nanomachines, called secretion systems, enabling the direct delivery of toxic effector molecules into by-standing target cells. The most commonly used weapon for contact-dependent antagonism is the bacterial Type VI secretion system (T6SS). The T6SS belongs to the family of contractile injection systems (CISs). All CISs are structurally and functionally related to contractile bacteriophages (e.g. phage T4) and translocate proteins into target cells by means of physical force, which is generated by rapid sheath contraction. This results in the ejection of the inner tube associated with a sharp tip and effector proteins at its end. Effector translocation leads ultimately to target cell death. Importantly, the T6SS is capable translocating effectors across broad ranges of biological membranes making it a powerful weapon in microbial warfare as well as potent virulence mechanism towards eukaryotic host cells. Our current understanding of T6SS mode of action is primarily based on the combination of structural biology and fluorescence live-cell microscopy studies. While in particular cryo-electron microscopy (cryo-EM) revealed the detailed architecture of the T6SS in situ and of isolated subassemblies, fluorescence live-cell microscopy uncovered the remarkable dynamics of T6SS biogenesis. However, a complete understanding of T6SS dynamics is hampered in standard fluorescent microscopy due to: (i) the spatial and temporal resolution limit, (ii) the inability to efficiently label secreted components of the machinery, (iii) the weak signals due to low protein abundance and rapid photobleaching, (iv) the difficulty to perform long-term co-incubation experiments as well as (v) the inability to precisely control spatial and chemical environment. My doctoral thesis aimed to overcome these limitations to allow novel insights into dynamics of the T6SSs of Vibrio cholerae, Pseudomonas aeruginosa and Acinetobacter baylyi. Specifically sheath assembly, initiation of sheath contraction, T6SS mediated protein translocation in to sister cells as well as strategies for prey cell inhibition were studied in this thesis. First, I studied sheath assembly in ampicillin induced V. cholerae spheroplasts. These enlarged cells assemble T6SS sheaths which are up to 10x longer as compared to rod shaped cells. This allowed us to photobleach an assembling sheath structure and demonstrate that new sheath subunits are added to the growing sheath polymer at the distal end opposite the baseplate. Importantly, this was the first direct observation made for any contractile machines studied to date. Moreover, I showed that unlike for all other CISs, T6SS sheath length is not regulated and correlates with cell size. In order to monitor protein translocation into target cells, we developed a T6SS dependent interbacterial protein complementation assay, enabling the indirect detection of translocated T6SS components into the cytosol of recipient cells. This allowed us to demonstrate that secreted T6SS components are exchanged among by-standing sister cells within minutes upon initial cell contact. Importantly, these results were the first experimental indication that T6SS is capable of translocating its components into the cytosol of Gram-negative target cells. Furthermore, we showed that the amount and the composition of the secreted tip influences the number of T6SS assemblies per cell, whereas different concentration of the tube protein influenced sheath length. We also provided evidence that precise aiming of T6SS assemblies through posttranslational regulation in P. aeruginosa increases the efficiency of substrate delivery. In addition, together with two Nanoscience master students we have also been implementing microfluidics in the Basler laboratory. This powerful technology enabled us to control the spatial arrangements of aggressor and prey populations and to follow these populations at single-cell level over time scales of several hours. In collaboration with Prof. Kevin Forster, University of Oxford, we demonstrated that the rate of target cell lysis heavily influences the outcome of contact-dependent T6SS killing and thus drives evolution of lytic effectors. Moreover, microfluidics allows for the dynamic change of the chemical microenvironment during imaging experiments. By following the T6SS dynamics in response to hyperosmotic shocks resulting in a rapid cell volume reduction, we found that physical pressure from the collapsing cell envelope could trigger sheath contraction. This led us to propose a model for sheath contraction under steady-state conditions where continued sheath polymerization against membrane contact site leads to a gradual increase in pressure applied to the assembled sheath. We propose that this could be potentially sensed by the baseplate, which in turn would trigger sheath contraction

Interactions between environmental stressors: the influence of salinity on host-parasite interactions between Daphnia magna and Pasteuria ramosa

Interactions between environmental stressors play an important role in shaping the health of an organism. This is particularly true in terms of the prevalence and severity of infectious disease, as stressors in combination will not always act to simply decrease the immune function of a host, but may instead interact to compound or even oppose the influence of parasitism on the health of an organism. Here, we explore the impact of environmental stress on host-parasite interactions using the water flea Daphnia magna and it is obligate parasite Pasteuria ramosa. Utilising an ecologically relevant stressor, we focus on the combined effect of salinity and P. ramosa on the fecundity and survival of the host, as well as on patterns of infectivity and the proliferation of the parasite. We show that in the absence of the parasite, host fecundity and survival was highest in the low salinity treatments. Once a parasite was introduced into the environment, however, salinity and parasitism acted antagonistically to influence both host survival and fecundity, and these patterns of disease were unrelated to infection rates or parasite spore loads. By summarising the form of interactions found in the broader Daphnia literature, we highlight how the combined effect of stress and parasitism will vary with the type of stressor, the trait used to describe the health of Daphnia and the host-parasite combination under observation. Our results highlight how the context-dependent nature of interactions between stress and parasitism inevitably complicates the link between environmental factors and the prevalence and severity of diseas

Type VI Secretion System Substrates Are Transferred and Reused among Sister Cells

Bacterial type VI secretion system (T6SS) is a nanomachine that works similarly to a speargun. Rapid contraction of a sling (sheath) drives a long shaft (Hcp) with a sharp tip and associated effectors through the target cell membrane. We show that the amount and composition of the tip regulates initiation of full-length sheath assembly and low amount of available Hcp decreases sheath length. Importantly, we show that both tip and Hcp are exchanged by T6SS among by-standing cells within minutes of initial cell-cell contact. The translocated proteins are reused for new T6SS assemblies suggesting that tip and Hcp reach the cytosol of target cells. The efficiency of protein translocation depends on precise aiming of T6SS at the target cells. This interbacterial protein complementation can support T6SS activity in sister cells with blocked protein synthesis and also allows cooperation between strains to increase their potential to kill competition. VIDEO ABSTRACT

Vaccination with the surface proteins MUL_2232 and MUL_3720 of Mycobacterium ulcerans induces antibodies but fails to provide protection against Buruli ulcer

Buruli ulcer, caused by infection with Mycobacterium ulcerans, is a chronic ulcerative neglected tropical disease of the skin and subcutaneous tissue that is most prevalent in West African countries. M. ulcerans produces a cytotoxic macrolide exotoxin called mycolactone, which causes extensive necrosis of infected subcutaneous tissue and the development of characteristic ulcerative lesions with undermined edges. While cellular immune responses are expected to play a key role against early intracellular stages of M. ulcerans in macrophages, antibody mediated protection might be of major relevance against advanced stages, where bacilli are predominantly found as extracellular clusters.; To assess whether vaccine induced antibodies against surface antigens of M. ulcerans can protect against Buruli ulcer we formulated two surface vaccine candidate antigens, MUL_2232 and MUL_3720, as recombinant proteins with the synthetic Toll-like receptor 4 agonist glucopyranosyl lipid adjuvant-stable emulsion. The candidate vaccines elicited strong antibody responses without a strong bias towards a TH1 type cellular response, as indicated by the IgG2a to IgG1 ratio. Despite the cross-reactivity of the induced antibodies with the native antigens, no significant protection was observed against progression of an experimental M. ulcerans infection in a mouse footpad challenge model.; Even though vaccine-induced antibodies have the potential to opsonise the extracellular bacilli they do not have a protective effect since infiltrating phagocytes might be killed by mycolactone before reaching the bacteria, as indicated by lack of viable infiltrates in the necrotic infection foci

Interactions between environmental stressors: the influence of salinity on host-parasite interactions between Daphnia magna and Pasteuria ramosa

Interactions between environmental stressors play an important role in shaping the health of an organism. This is particularly true in terms of the prevalence and severity of infectious disease, as stressors in combination will not always act to simply decrease the immune function of a host, but may instead interact to compound or even oppose the influence of parasitism on the health of an organism. Here, we explore the impact of environmental stress on host–parasite interactions using the water flea Daphnia magna and it is obligate parasite Pasteuria ramosa. Utilising an ecologically relevant stressor, we focus on the combined effect of salinity and P. ramosa on the fecundity and survival of the host, as well as on patterns of infectivity and the proliferation of the parasite. We show that in the absence of the parasite, host fecundity and survival was highest in the low salinity treatments. Once a parasite was introduced into the environment, however, salinity and parasitism acted antagonistically to influence both host survival and fecundity, and these patterns of disease were unrelated to infection rates or parasite spore loads. By summarising the form of interactions found in the broader Daphnia literature, we highlight how the combined effect of stress and parasitism will vary with the type of stressor, the trait used to describe the health of Daphnia and the host–parasite combination under observation. Our results highlight how the context-dependent nature of interactions between stress and parasitism inevitably complicates the link between environmental factors and the prevalence and severity of disease

The type VI secretion system sheath assembles at the end distal from the membrane anchor

The bacterial Type VI secretion system (T6SS) delivers proteins into target cells using fast contraction of a long sheath anchored to the cell envelope and wrapped around an inner Hcp tube associated with the secreted proteins. Mechanisms of sheath assembly and length regulation are unclear. Here we study these processes using spheroplasts formed from ampicillin-treated Vibrio cholerae. We show that spheroplasts secrete Hcp and deliver T6SS substrates into neighbouring cells. Imaging of sheath dynamics shows that the sheath length correlates with the diameter of spheroplasts and may reach up to several micrometres. Analysis of sheath assembly after partial photobleaching shows that subunits are exclusively added to the sheath at the end that is distal from the baseplate and cell envelope attachment. We suggest that this mode of assembly is likely common for all phage-like contractile nanomachines, because of the conservation of the structures and connectivity of sheath subunits

DNA Uptake upon T6SS-Dependent Prey Cell Lysis Induces SOS Response and Reduces Fitness of Acinetobacter baylyi

Certain Gram-negative bacteria use the type VI secretion system (T6SS) to kill and lyse competing bacteria. Here, we show that the T6SS-dependent lysis of prey cells by the naturally competent Acinetobacter baylyi results in the extensive filamentation of a subpopulation of A. baylyi cells. Filamentation is dependent on the release of DNA from the prey and its uptake by the competence system. The analysis of A. baylyi transcriptome and the response of transcriptional reporters suggest that the uptake of DNA results in the upregulation of the SOS response, which often leads to cell-division arrest. Long-term competition between competent and non-competent strains shows that the strain lacking the DNA uptake machinery outcompetes the parental strain only in the presence of the T6SS-dependent lysis of prey cells. Our data suggest that the cost of the induced SOS response may drive the selection of tight regulation or the loss of DNA uptake in bacteria capable of lysing their competitors

A Transgenic MMTV-Flippase Mouse Line for Molecular Engineering in Mammary Gland and Breast Cancer Mouse Models.

Genetically engineered mouse models have become an indispensable tool for breast cancer research. Combination of multiple site-specific recombination systems such as Cre/loxP and Flippase (Flp)/Frt allows for engineering of sophisticated, multi-layered conditional mouse models. Here, we report the generation and characterization of a novel transgenic mouse line expressing a mouse codon-optimized Flp under the control of the mouse mammary tumor virus (MMTV) promoter. These mice show robust Flp-mediated recombination in luminal mammary gland and breast cancer cells but no Flp activity in non-mammary tissues, with the exception of limited activity in salivary glands. These mice provide a unique tool for studying mammary gland biology and carcinogenesis in mice

Subcellular localization of Type VI secretion system assembly in response to cell-cell contact

Bacteria require a number of systems, including the type VI secretion system (T6SS), for interbacterial competition and pathogenesis. The T6SS is a large nanomachine that can deliver toxins directly across membranes of proximal target cells. Since major reassembly of T6SS is necessary after each secretion event, accurate timing and localization of T6SS assembly can lower the cost of protein translocation. Although critically important, mechanisms underlying spatiotemporal regulation of T6SS assembly remain poorly understood. Here, we used super-resolution live-cell imaging to show that while Acinetobacter and Burkholderia thailandensis can assemble T6SS at any site, a significant subset of T6SS assemblies localizes precisely to the site of contact between neighboring bacteria. We identified a class of diverse, previously uncharacterized, periplasmic proteins required for this dynamic localization of T6SS to cell–cell contact (TslA). This precise localization is also dependent on the outer membrane porin OmpA. Our analysis links transmembrane communication to accurate timing and localization of T6SS assembly as well as uncovers a pathway allowing bacterial cells to respond to cell–cell contact during interbacterial competition

The evolution of the type VI secretion system as a disintegration weapon

The type VI secretion system (T6SS) is a nanomachine used by many bacteria to drive a toxin-laden needle into other bacterial cells. Although the potential to influence bacterial competition is clear, the fitness impacts of wielding a T6SS are not well understood. Here we present a new agent-based model that enables detailed study of the evolutionary costs and benefits of T6SS weaponry during competition with other bacteria. Our model identifies a key problem with the T6SS. Because of its short range, T6SS activity becomes self-limiting, as dead cells accumulate in its way, forming "corpse barriers" that block further attacks. However, further exploration with the model presented a solution to this problem: if injected toxins can quickly lyse target cells in addition to killing them, the T6SS becomes a more effective weapon. We tested this prediction with single-cell analysis of combat between T6SS-wielding Acinetobacter baylyi and T6SS-sensitive Escherichia coli. As predicted, delivery of lytic toxins is highly effective, whereas nonlytic toxins leave large patches of E. coli alive. We then analyzed hundreds of bacterial species using published genomic data, which suggest that the great majority of T6SS-wielding species do indeed use lytic toxins, indicative of a general principle underlying weapon evolution. Our work suggests that, in the T6SS, bacteria have evolved a disintegration weapon whose effectiveness often rests upon the ability to break up competitors. Understanding the evolutionary function of bacterial weapons can help in the design of probiotics that can both establish well and eliminate problem species