Your search keyword '"Weiss GL"' showing total 4 results

1. Mechanism of bacterial predation via ixotrophy.

Author

Lien YW, Amendola D, Lee KS, Bartlau N, Xu J, Furusawa G, Polz MF, Stocker R, Weiss GL, and Pilhofer M

Subjects

Cryoelectron Microscopy, Single-Cell Analysis, Bacterial Adhesion, Bacteroidetes physiology, Bacteroidetes ultrastructure, Type VI Secretion Systems metabolism, Type VI Secretion Systems ultrastructure, Vibrio physiology, Vibrio ultrastructure, Flagella ultrastructure

Abstract

Ixotrophy is a contact-dependent predatory strategy of filamentous bacteria in aquatic environments for which the molecular mechanism remains unknown. We show that predator-prey contact can be established by gliding motility or extracellular assemblages we call "grappling hooks." Cryo-electron microscopy identified the grappling hooks as heptamers of a type IX secretion system substrate. After close predator-prey contact is established, cryo-electron tomography and functional assays showed that puncturing by a type VI secretion system mediated killing. Single-cell analyses with stable isotope-labeled prey revealed that prey components are taken up by the attacker. Depending on nutrient availability, insertion sequence elements toggle the activity of ixotrophy. A marine metagenomic time series shows coupled dynamics of ixotrophic bacteria and prey. We found that the mechanism of ixotrophy involves multiple cellular machineries, is conserved, and may shape microbial populations in the environment.

Published

2024

2. Architecture and function of human uromodulin filaments in urinary tract infections.

Author

Weiss GL, Stanisich JJ, Sauer MM, Lin CW, Eras J, Zyla DS, Trück J, Devuyst O, Aebi M, Pilhofer M, and Glockshuber R

Subjects

Adhesins, Bacterial chemistry, Cryoelectron Microscopy, Glycosylation, Humans, Ligands, Urinary Tract Infections metabolism, Uromodulin chemistry, Uromodulin physiology

Abstract

Uromodulin is the most abundant protein in human urine, and it forms filaments that antagonize the adhesion of uropathogens; however, the filament structure and mechanism of protection remain poorly understood. We used cryo-electron tomography to show that the uromodulin filament consists of a zigzag-shaped backbone with laterally protruding arms. N-glycosylation mapping and biophysical assays revealed that uromodulin acts as a multivalent ligand for the bacterial type 1 pilus adhesin, presenting specific epitopes on the regularly spaced arms. Imaging of uromodulin-uropathogen interactions in vitro and in patient urine showed that uromodulin filaments associate with uropathogens and mediate bacterial aggregation, which likely prevents adhesion and allows clearance by micturition. These results provide a framework for understanding uromodulin in urinary tract infections and in its more enigmatic roles in physiology and disease., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

3. In situ architecture, function, and evolution of a contractile injection system.

Author

Böck D, Medeiros JM, Tsao HF, Penz T, Weiss GL, Aistleitner K, Horn M, and Pilhofer M

Subjects

Bacteriophages chemistry, Bacteriophages ultrastructure, Cryoelectron Microscopy, Electron Microscope Tomography, Multigene Family, Phagosomes chemistry, Phagosomes ultrastructure, Phylogeny, Protein Conformation, Symbiosis, Type VI Secretion Systems classification, Type VI Secretion Systems genetics, Type VI Secretion Systems ultrastructure, Amoeba microbiology, Bacteroidetes physiology, Type VI Secretion Systems chemistry

Abstract

Contractile injection systems mediate bacterial cell-cell interactions by a bacteriophage tail-like structure. In contrast to extracellular systems, the type 6 secretion system (T6SS) is defined by intracellular localization and attachment to the cytoplasmic membrane. Here we used cryo-focused ion beam milling, electron cryotomography, and functional assays to study a T6SS in Amoebophilus asiaticus The in situ architecture revealed three modules, including a contractile sheath-tube, a baseplate, and an anchor. All modules showed conformational changes upon firing. Lateral baseplate interactions coordinated T6SSs in hexagonal arrays. The system mediated interactions with host membranes and may participate in phagosome escape. Evolutionary sequence analyses predicted that T6SSs are more widespread than previously thought. Our insights form the basis for understanding T6SS key concepts and exploring T6SS diversity., (Copyright © 2017 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2017

4. Marine tubeworm metamorphosis induced by arrays of bacterial phage tail-like structures.

Author

Shikuma NJ, Pilhofer M, Weiss GL, Hadfield MG, Jensen GJ, and Newman DK

Subjects

Animals, Aquatic Organisms growth & development, Aquatic Organisms microbiology, Bacteriocins genetics, Bacteriophages ultrastructure, Genes, Bacterial physiology, Larva growth & development, Larva microbiology, Molecular Sequence Data, Open Reading Frames, Pseudoalteromonas genetics, Viral Tail Proteins genetics, Bacteriocins metabolism, Biofilms, Metamorphosis, Biological, Polychaeta growth & development, Polychaeta microbiology, Pseudoalteromonas physiology, Pseudoalteromonas virology, Viral Tail Proteins physiology

Abstract

Many benthic marine animal populations are established and maintained by free-swimming larvae that recognize cues from surface-bound bacteria to settle and metamorphose. Larvae of the tubeworm Hydroides elegans, an important biofouling agent, require contact with surface-bound bacteria to undergo metamorphosis; however, the mechanisms that underpin this microbially mediated developmental transition have been enigmatic. Here, we show that a marine bacterium, Pseudoalteromonas luteoviolacea, produces arrays of phage tail-like structures that trigger metamorphosis of H. elegans. These arrays comprise about 100 contractile structures with outward-facing baseplates, linked by tail fibers and a dynamic hexagonal net. Not only do these arrays suggest a novel form of bacterium-animal interaction, they provide an entry point to understanding how marine biofilms can trigger animal development.

Published

2014