Chemoattractant receptors activate, recruit and capture G proteins for wide range chemotaxis

The wide range sensing of extracellular signals is a common feature of various sensory cells. Eukaryotic chemotactic cells driven by GPCRs and their cognate G proteins are one example. This system endows the cells directional motility towards their destination over long distances. There are several...

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Bibliographic Details
Published in:Biochemical and biophysical research communications 2018-12, Vol.507 (1-4), p.304-310
Main Authors: Miyanaga, Yukihiro, Kamimura, Yoichiro, Kuwayama, Hidekazu, Devreotes, Peter N., Ueda, Masahiro
Format: Article
Language:English
Subjects:
60 APPLIED LIFE SCIENCES
AMP
Chemotaxis
Cyclic AMP - metabolism
Dictyostelium - cytology
Dictyostelium - metabolism
Dynamic range extension
Eukaryotic chemotaxis
G protein-coupled receptor
Gradient sensing
GTP-ASES
GTP-Binding Proteins - metabolism
Intracellular Space - metabolism
Protozoan Proteins - metabolism
RECEPTORS
Receptors, G-Protein-Coupled - metabolism
Signal Transduction
Single-molecule analysis
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Summary:The wide range sensing of extracellular signals is a common feature of various sensory cells. Eukaryotic chemotactic cells driven by GPCRs and their cognate G proteins are one example. This system endows the cells directional motility towards their destination over long distances. There are several mechanisms to achieve the long dynamic range, including negative regulation of the receptors upon ligand interaction and spatial regulation of G proteins, as we found recently. However, these mechanisms are insufficient to explain the 105-fold range of chemotaxis seen in Dictyostelium. Here, we reveal that the receptor-mediated activation, recruitment, and capturing of G proteins mediate chemotactic signaling at the lower, middle and higher concentration ranges, respectively. These multiple mechanisms of G protein dynamics can successfully cover distinct ranges of ligand concentrations, resulting in seamless and broad chemotaxis. Furthermore, single-molecule imaging analysis showed that the activated Gα subunit forms an unconventional complex with the agonist-bound receptor. This complex formation of GPCR-Gα increased the membrane-binding time of individual Gα molecules and therefore resulted in the local accumulation of Gα. Our findings provide an additional chemotactic dynamic range mechanism in which multiple G protein dynamics positively contribute to the production of gradient information. [Display omitted] •Chemotactic GPCR forms an unconventional complex with the activated Gα.•Receptors activate, recruit and capture G proteins at different cAMP concentrations.•Capture of Gα can contribute to gradient sensing at high cAMP concentrations.
ISSN:0006-291X
1090-2104
DOI:10.1016/j.bbrc.2018.11.029