TY - JOUR A1 - Broeker, Nina K. A1 - Roske, Yvette A1 - Valleriani, Angelo A1 - Stephan, Mareike Sophia A1 - Andres, Dorothee A1 - Koetz, Joachim A1 - Heinemann, Udo A1 - Barbirz, Stefanie T1 - Time-resolved DNA release from an O-antigen-specific Salmonella bacteriophage with a contractile tail JF - The journal of biological chemistry N2 - Myoviruses, bacteriophages with T4-like architecture, must contract their tails prior to DNA release. However, quantitative kinetic data on myovirus particle opening are lacking, although they are promising tools in bacteriophage-based antimicrobial strategies directed against Gram-negative hosts. For the first time, we show time-resolved DNA ejection from a bacteriophage with a contractile tail, the multi-O-antigen-specific Salmonella myovirus Det7. DNA release from Det7 was triggered by lipopolysaccharide (LPS) O-antigen receptors and notably slower than in noncontractile-tailed siphoviruses. Det7 showed two individual kinetic steps for tail contraction and particle opening. Our in vitro studies showed that highly specialized tailspike proteins (TSPs) are necessary to attach the particle to LPS. A P22-like TSP confers specificity for the Salmonella Typhimurium O-antigen. Moreover, crystal structure analysis at 1.63 angstrom resolution confirmed that Det7 recognized the Salmonella Anatum O-antigen via an E15-like TSP, DettilonTSP. DNA ejection triggered by LPS from either host showed similar velocities, so particle opening is thus a process independent of O-antigen composition and the recognizing TSP. In Det7, at permissive temperatures TSPs mediate O-antigen cleavage and couple cell surface binding with DNA ejection, but no irreversible adsorption occurred at low temperatures. This finding was in contrast to short-tailed Salmonella podoviruses, illustrating that tailed phages use common particle-opening mechanisms but have specialized into different infection niches. KW - bacteriophage KW - lipopolysaccharide (YLPS) KW - structural biology KW - DNA viruses KW - glycobiology KW - fluorescence KW - Salmonella enterica KW - contractile tail KW - DNA ejection KW - O-antigen specificity KW - Salmonella myovirus KW - tailspike protein KW - molecular machine Y1 - 2019 U6 - https://doi.org/10.1074/jbc.RA119.008133 SN - 1083-351X VL - 294 IS - 31 SP - 11751 EP - 11761 PB - American Society for Biochemistry and Molecular Biology CY - Bethesda ER - TY - JOUR A1 - Stephan, Mareike Sophia A1 - Bröker, Nina K. A1 - Saragliadis, Athanasios A1 - Roos, Norbert A1 - Linke, Dirk A1 - Barbirz, Stefanie T1 - In vitro analysis of O-antigen-specific bacteriophage P22 inactivation by Salmonella outer membrane vesicles JF - Frontiers in microbiology N2 - Bacteriophages use a large number of different bacterial cell envelope structures as receptors for surface attachment. As a consequence, bacterial surfaces represent a major control point for the defense against phage attack. One strategy for phage population control is the production of outer membrane vesicles (OMVs). In Gram-negative host bacteria, O-antigen-specific bacteriophages address lipopolysaccharide (LPS) to initiate infection, thus relying on an essential outer membrane glycan building block as receptor that is constantly present also in OMVs. In this work, we have analyzed interactions ofSalmonella(S.) bacteriophage P22 with OMVs. For this, we isolated OMVs that were formed in large amounts during mechanical cell lysis of the P22 S. Typhimurium host.In vitro, these OMVs could efficiently reduce the number of infective phage particles. Fluorescence spectroscopy showed that upon interaction with OMVs, bacteriophage P22 released its DNA into the vesicle lumen. However, only about one third of the phage P22 particles actively ejected their genome. For the larger part, no genome release was observed, albeit the majority of phages in the system had lost infectivity towards their host. With OMVs, P22 ejected its DNA more rapidly and could release more DNA against elevated osmotic pressures compared to DNA release triggered with protein-free LPS aggregates. This emphasizes that OMV composition is a key feature for the regulation of infective bacteriophage particles in the system. KW - bacteriophage KW - bacterial outer membrane vesicles KW - O-antigen KW - bacterial KW - membrane fractionation KW - Salmonella KW - lipopolysaccharide Y1 - 2020 U6 - https://doi.org/10.3389/fmicb.2020.510638 SN - 1664-302X VL - 11 PB - Frontiers Media CY - Lausanne ER - TY - CHAP A1 - Stephan, Mareike Sophia A1 - Barbirz, Stefanie A1 - Robinson, Tom A1 - Yandrapalli, Naresh A1 - Dimova, Rumiana T1 - Bacterial mimetic systems for studying bacterial inactivation and infection BT - Meeting abstract: 65th Annual Meeting of the Biophysical Society (BPS), Feb. 22-26, 2021 T2 - Biophysical journal : BJ / ed. by the Biophysical Society Y1 - 2021 U6 - https://doi.org/10.1016/j.bpj.2020.11.1087 SN - 0006-3495 SN - 1542-0086 VL - 120 IS - 3 SP - 148A EP - 148A PB - Cell Press CY - Cambridge ER - TY - THES A1 - Stephan, Mareike Sophia T1 - A bacterial mimetic system to study bacterial inactivation and infection N2 - The emerging threat of antibiotic-resistant bacteria has become a global challenge in the last decades, leading to a rising demand for alternative treatments for bacterial infections. One approach is to target the bacterial cell envelope, making understanding its biophysical properties crucial. Specifically, bacteriophages use the bacterial envelope as an entry point to initiate infection, and they are considered important building blocks of new antibiotic strategies against drug-resistant bacteria.. Depending on the structure of the cell wall, bacteria are classified as Gram-negative and Gram-positive. Gram-negative bacteria are equipped with a complex cell envelope composed of two lipid membranes enclosing a rigid peptidoglycan layer. The synthesis machinery of the Gram-negative cell envelope is the target of antimicrobial agents, including new physical sanitizing procedures addressing the outer membrane (OM). It is therefore very important to study the biophysical properties of the Gram-negative bacterial cell envelope. The high complexity of the Gram-negative OM sets the demand for a model system in which the contribution of individual components can be evaluated separately. In this respect, giant unilamellar vesicles (GUVs) are promising membrane systems to study membrane properties while controlling parameters such as membrane composition and surrounding medium conditions. The aim of this work was to develop methods and approaches for the preparation and characterization of a GUV-based membrane model that mimics the OM of the Gram-negative cell envelope. A major component of the OM is the lipopolysaccharide (LPS) on the outside of the OM heterobilayer. The vesicle model was designed to contain LPS in the outer leaflet and lipids in the inner leaflet. Furthermore, the interaction of the prepared LPS-GUVs with bacteriophages was tested. LPS containing GUVs were prepared by adapting the inverted emulsion technique to meet the challenging properties of LPS, namely their high self-aggregation rate in aqueous solutions. Notably, an additional emulsification step together with the adaption of solution conditions was employed to asymmetrically incorporate LPS containing long polysaccharide chains into the artificial membranes. GUV membrane asymmetry was verified with a fluorescence quenching assay. Since the necessary precautions for handling the quenching agent sodium dithionite are often underestimated and poorly described, important parameters were tested and identified to obtain a stable and reproducible assay. In the context of varied LPS incorporation, a microscopy-based technique was introduced to determine the LPS content on individual GUVs and to directly compare vesicle properties and LPS coverage. Diffusion coefficient measurements in the obtained GUVs showed that increasing LPS concentrations in the membranes resulted in decreased diffusivity. Employing LPS-GUVs we could demonstrate that a Salmonella bacteriophage bound with high specificity to its LPS receptor when presented at the GUV surface, and that the number of bound bacteriophages scaled with the amount of presented LPS receptor. In addition to binding, the bacteriophages were able to eject their DNA into the vesicle lumen. LPS-GUVs thus provide a starting platform for bottom-up approaches for the generation of more complex membranes, in which the effects of individual components on the membrane properties and the interaction with antimicrobial agents such as bacteriophages could be explored. N2 - Die wachsende Bedrohung durch antibiotikaresistente Bakterien ist in den letzten Jahrzehnten zu einer globalen Herausforderung geworden, was zu einer steigenden Nachfrage nach alternativen Behandlungsmethoden für bakterielle Infektionen geführt hat. Ein Ansatz besteht darin, die bakterielle Zellhülle anzugreifen, weshalb das Verständnis ihrer biophysikalischen Eigenschaften entscheidend ist. Insbesondere Bakteriophagen, Viren, die Bakterien infizieren, nutzen die Bakterienhülle als ersten Angriffspunkt für die Infektion und gelten als wichtige Bausteine für neue Antibiotikastrategien gegen arzneimittelresistente Bakterien. Je nach Struktur der Zellwand werden Bakterien in gramnegative und grampositive Bakterien eingeteilt. Gramnegative Bakterien sind mit einer komplexen Zellhülle ausgestattet. Daher ist es sehr wichtig, ihre biophysikalischen Eigenschaften zu untersuchen. Die hohe Komplexität der äußeren Zellhülle, auch äußere Membran genannt, erfordert ein Modellsystem, in dem der Beitrag jeder einzelnen Komponente separat bewertet werden kann. In dieser Hinsicht sind Vesikel-basierte Modellsysteme sehr vielversprechend, da sie wichtige Eigenschaften der äußeren Membran simulieren können, aber in ihrer Komplexität stark reduziert und kontrollierbar sind. Ziel dieser Arbeit war es, Methoden und Ansätze für die Herstellung und Charakterisierung eines Vesikel-basierten Modells zu entwickeln, das die äußere Membran der gramnegativen bakteriellen Zellhülle nachahmt. Ein Hauptbestandteil der äußeren Membran ist Lipopolysaccharid (LPS), das asymmetrisch auf der Außenseite der äußeren Membran vorhanden ist. Das Vesikelmodell wurde so konzipiert, dass es außen LPS und innen Phospholipide enthält. Die Herstellung des beschriebenen Modellsystems erforderte einige Anpassungen, da die Hüllkomponente LPS eine hohe Tendenz zur Bildung von Selbstaggregaten aufweist. Durch die Einführung eines zusätzlichen Schrittes in das Standardprotokoll konnten Vesikel mit LPS-Inkorporation erzeugt werden. Es wurde sowohl die Menge als auch die asymmetrische Verteilung des LPS-Einbaus bestimmt. Mit Hilfe von Bakteriophagen sollte die biologische Wirkung des Modellsystems getestet werden. Es wurde gezeigt, dass Bakteriophagen, die spezifisch LPS erkennen und binden, nach Zugabe zum Modellsystem die Vesikel binden und ihr genetisches Material in das Vesikel-Innere injizieren. Die hier beschriebenen LPS-haltigen Vesikel können als Ausgangsplattform für Bottom-up-Ansätze zur Herstellung komplexerer Membranen verwendet werden. Mit diesen komplexeren, aber kontrollierbaren Systemen lassen sich die Auswirkungen einzelner Komponenten der bakteriellen Zellhülle auf die Eigenschaften der Zellhülle sowie ihre Wechselwirkung mit antimikrobiellen Wirkstoffen wie Bakteriophagen untersuchen. KW - Bakterien KW - Bakteriophagen KW - Zellmembran KW - Vesikel KW - Konfokale Mikroskopie KW - Lipopolysaccharid KW - gramnegativ KW - bacteria KW - bacteriophage KW - cell membrane KW - vesicle KW - confocal microscopy KW - lipopolysaccharide KW - gram-negative Y1 - 2023 ER -