Structure and function of the archaeal response regulator CheY

Motility is a central feature of many microorganisms and provides an efficient strategy to respond to environmental changes. Bacteria and archaea have developed fundamentally different rotary motors enabling their motility, termed flagellum and archaellum, respectively. Bacterial motility along chem...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2018-02, Vol.115 (6), p.E1259-E1268
Main Authors: Quax, Tessa E. F., Altegoer, Florian, Rossi, Fernando, Li, Zhengqun, Rodriguez-Franco, Marta, Kraus, Florian, Bange, Gert, Albers, Sonja-Verena
Format: Article
Language:English
Subjects:
Amino Acid Sequence
Archaea
Archaea - physiology
Archaeal Proteins - chemistry
Archaeal Proteins - metabolism
Bacteria
Biological Sciences
Chemotaxis
Chemotaxis - physiology
CheY protein
Crystallography, X-Ray
Electrostatic properties
Environmental changes
Flagella
Machinery and equipment
Magnesium
Microorganisms
Models, Molecular
Motors
Phosphorylation
PNAS Plus
Protein Conformation
Proteins
Sequence Homology
Structure-function relationships
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Summary:Motility is a central feature of many microorganisms and provides an efficient strategy to respond to environmental changes. Bacteria and archaea have developed fundamentally different rotary motors enabling their motility, termed flagellum and archaellum, respectively. Bacterial motility along chemical gradients, called chemotaxis, critically relies on the response regulator CheY, which, when phosphorylated, inverses the rotational direction of the flagellum via a switch complex at the base of the motor. The structural difference between archaellum and flagellum and the presence of functional CheY in archaea raises the question of how the CheY protein changed to allow communication with the archaeal motility machinery. Here we show that archaeal CheY shares the overall structure and mechanism of magnesium-dependent phosphorylation with its bacterial counterpart. However, bacterial and archaeal CheY differ in the electrostatic potential of the helix α4. The helix α4 is important in bacteria for interaction with the flagellar switch complex, a structure that is absent in archaea. We demonstrated that phosphorylation-dependent activation, and conserved residues in the archaeal CheY helix α4, are important for interaction with the archaeal-specific adaptor protein CheF. This forms a bridge between the chemotaxis system and the archaeal motility machinery. Conclusively, archaeal CheY proteins conserved the central mechanistic features between bacteria and archaea, but differ in the helix α4 to allow binding to an archaellum-specific interaction partner.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1716661115