The wild-type flagellar filament of the Firmicute Kurthia at 2.8 Å resolution in vivo

The wild-type flagellar filament of the Firmicute Kurthia at 2.8 Å resolution in vivo

Bacteria swim and swarm by rotating the micrometers long, helical filaments of their flagella. They change direction by reversing their flagellar rotation, which switches the handedness of the filament’s supercoil. So far, all studied functional filaments are composed of a mixture of L- and R-state...

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Veröffentlicht in:Scientific reports 2019-10, Vol.9 (1), p.14948-8, Article 14948
Hauptverfasser: Blum, Thorsten B., Filippidou, Sevasti, Fatton, Mathilda, Junier, Pilar, Abrahams, Jan Pieter
Format: Artikel
Sprache:eng
Schlagworte:
101/28
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Amino acids
Anisotropy
Bacteria
Bacterial Proteins - chemistry
Biology
Conformation
Cryoelectron Microscopy
Filaments
Firmicutes - physiology
Flagella
Flagella - physiology
Flagella - ultrastructure
Flagellin
Flagellin - chemistry
Fourier Analysis
Genomes
Glycosylation
Handedness
Humanities and Social Sciences
Monomers
multidisciplinary
Planococcaceae - physiology
Proteins
Science
Science (multidisciplinary)
Software
Symmetry
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Beschreibung
Zusammenfassung:Bacteria swim and swarm by rotating the micrometers long, helical filaments of their flagella. They change direction by reversing their flagellar rotation, which switches the handedness of the filament’s supercoil. So far, all studied functional filaments are composed of a mixture of L- and R-state flagellin monomers. Here we show in a study of the wild type Firmicute Kurthia sp., that curved, functional filaments can adopt a conformation in vivo that is closely related to a uniform, all-L-state. This sheds additional light on transitions of the flagellar supercoil and uniquely reveals the atomic structure of a wild-type flagellar filament in vivo , including six residues showing clearly densities of O-linked glycosylation.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-019-51440-1