In vivo assembly and trafficking of olfactory Ionotropic Receptors.
Journal
BMC biology
ISSN: 1741-7007
Titre abrégé: BMC Biol
Pays: England
ID NLM: 101190720
Informations de publication
Date de publication:
17 04 2019
17 04 2019
Historique:
received:
28
10
2018
accepted:
22
03
2019
entrez:
19
4
2019
pubmed:
19
4
2019
medline:
9
11
2019
Statut:
epublish
Résumé
Ionotropic receptors (IRs) are a large, divergent subfamily of ionotropic glutamate receptors (iGluRs) that are expressed in diverse peripheral sensory neurons and function in olfaction, taste, hygrosensation and thermosensation. Analogous to the cell biological properties of their synaptic iGluR ancestors, IRs are thought to form heteromeric complexes that localise to the ciliated dendrites of sensory neurons. IR complexes are composed of selectively expressed 'tuning' receptors and one of two broadly expressed co-receptors (IR8a or IR25a). While the extracellular ligand-binding domain (LBD) of tuning IRs is likely to define the stimulus specificity of the complex, the role of this domain in co-receptors is unclear. We identify a sequence in the co-receptor LBD, the 'co-receptor extra loop' (CREL), which is conserved across IR8a and IR25a orthologues but not present in either tuning IRs or iGluRs. The CREL contains a single predicted N-glycosylation site, which we show bears a sugar modification in recombinantly expressed IR8a. Using the Drosophila olfactory system as an in vivo model, we find that a transgenically encoded IR8a mutant in which the CREL cannot be N-glycosylated is impaired in localisation to cilia in some, though not all, populations of sensory neurons expressing different tuning IRs. This defect can be complemented by the presence of endogenous wild-type IR8a, indicating that IR complexes contain at least two IR8a subunits and that this post-translational modification is dispensable for protein folding or complex assembly. Analysis of the subcellular distribution of the mutant protein suggests that its absence from sensory cilia is due to a failure in exit from the endoplasmic reticulum. Protein modelling and in vivo analysis of tuning IR and co-receptor subunit interactions by a fluorescent protein fragment complementation assay reveal that the CREL N-glycosylation site is likely to be located on the external face of a heterotetrameric IR complex. Our data reveal an important role for the IR co-receptor LBD in control of intracellular transport, provide novel insights into the stoichiometry and assembly of IR complexes and uncover an unexpected heterogeneity in the trafficking regulation of this sensory receptor family.
Sections du résumé
BACKGROUND
Ionotropic receptors (IRs) are a large, divergent subfamily of ionotropic glutamate receptors (iGluRs) that are expressed in diverse peripheral sensory neurons and function in olfaction, taste, hygrosensation and thermosensation. Analogous to the cell biological properties of their synaptic iGluR ancestors, IRs are thought to form heteromeric complexes that localise to the ciliated dendrites of sensory neurons. IR complexes are composed of selectively expressed 'tuning' receptors and one of two broadly expressed co-receptors (IR8a or IR25a). While the extracellular ligand-binding domain (LBD) of tuning IRs is likely to define the stimulus specificity of the complex, the role of this domain in co-receptors is unclear.
RESULTS
We identify a sequence in the co-receptor LBD, the 'co-receptor extra loop' (CREL), which is conserved across IR8a and IR25a orthologues but not present in either tuning IRs or iGluRs. The CREL contains a single predicted N-glycosylation site, which we show bears a sugar modification in recombinantly expressed IR8a. Using the Drosophila olfactory system as an in vivo model, we find that a transgenically encoded IR8a mutant in which the CREL cannot be N-glycosylated is impaired in localisation to cilia in some, though not all, populations of sensory neurons expressing different tuning IRs. This defect can be complemented by the presence of endogenous wild-type IR8a, indicating that IR complexes contain at least two IR8a subunits and that this post-translational modification is dispensable for protein folding or complex assembly. Analysis of the subcellular distribution of the mutant protein suggests that its absence from sensory cilia is due to a failure in exit from the endoplasmic reticulum. Protein modelling and in vivo analysis of tuning IR and co-receptor subunit interactions by a fluorescent protein fragment complementation assay reveal that the CREL N-glycosylation site is likely to be located on the external face of a heterotetrameric IR complex.
CONCLUSIONS
Our data reveal an important role for the IR co-receptor LBD in control of intracellular transport, provide novel insights into the stoichiometry and assembly of IR complexes and uncover an unexpected heterogeneity in the trafficking regulation of this sensory receptor family.
Identifiants
pubmed: 30995910
doi: 10.1186/s12915-019-0651-7
pii: 10.1186/s12915-019-0651-7
pmc: PMC6472016
doi:
Substances chimiques
Drosophila Proteins
0
Receptors, Ionotropic Glutamate
0
Types de publication
Journal Article
Research Support, N.I.H., Extramural
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
34Subventions
Organisme : NIH HHS
ID : P40 OD018537
Pays : United States
Organisme : NIGMS NIH HHS
ID : R01 GM074830
Pays : United States
Références
Elife. 2017 Mar 23;6:
pubmed: 28332980
Neuron. 2018 Sep 5;99(5):956-968.e4
pubmed: 30122377
J Vis Exp. 2012 Mar 14;(61):
pubmed: 22453204
Cell. 2009 Jan 9;136(1):149-62
pubmed: 19135896
J Cell Sci. 2016 Apr 15;129(8):1635-48
pubmed: 26906425
Cell Rep. 2017 Jan 17;18(3):737-750
pubmed: 28099851
Arthropod Struct Dev. 2000 Jul;29(3):211-29
pubmed: 18088928
Nat Commun. 2016 Feb 11;7:10687
pubmed: 26864722
Nucleic Acids Res. 2004 Mar 19;32(5):1792-7
pubmed: 15034147
J Proteome Res. 2010 Apr 5;9(4):2016-29
pubmed: 20170199
Nature. 2010 Dec 2;468(7324):691-5
pubmed: 21085119
PLoS One. 2008 Sep 19;3(9):e3241
pubmed: 18802472
Elife. 2016 Apr 29;5:
pubmed: 27126188
Curr Opin Struct Biol. 2016 Dec;41:119-127
pubmed: 27454049
Neuron. 2017 Feb 8;93(3):661-676.e6
pubmed: 28111079
Curr Biol. 2017 Sep 25;27(18):2741-2750.e4
pubmed: 28889974
Neurosci Behav Physiol. 2009 Oct;39(8):763-73
pubmed: 19779829
PLoS Genet. 2010 Aug 19;6(8):e1001064
pubmed: 20808886
Elife. 2017 Dec 12;6:
pubmed: 29231818
Anal Biochem. 1997 Jul 15;250(1):82-101
pubmed: 9234902
Nature. 2015 Nov 26;527(7579):516-20
pubmed: 26580016
Nature. 2011 Sep 28;478(7368):236-40
pubmed: 21964331
Chem Senses. 2016 Jun;41(5):381-98
pubmed: 27107425
Insect Biochem Mol Biol. 2013 Sep;43(9):888-97
pubmed: 23459169
Nat Methods. 2012 Jun 28;9(7):676-82
pubmed: 22743772
Sci Rep. 2016 Dec 16;6:34871
pubmed: 27982028
Nature. 2016 Nov 3;539(7627):93-97
pubmed: 27776356
PLoS Biol. 2016 May 04;14(5):e1002454
pubmed: 27145030
Neuron. 2014 Aug 20;83(4):850-65
pubmed: 25123314
J Cell Biol. 2016 Sep 26;214(7):875-89
pubmed: 27646273
Nat Genet. 2008 Apr;40(4):476-83
pubmed: 18311141
Cell. 2000 Jul 21;102(2):147-59
pubmed: 10943836
J Neurosci. 2013 Jun 26;33(26):10741-9
pubmed: 23804096
Semin Cell Dev Biol. 2018 Nov;83:51-58
pubmed: 29559335
Elife. 2017 Mar 06;6:
pubmed: 28262096
Neuron. 2011 Jan 13;69(1):44-60
pubmed: 21220098
Bioinformatics. 2009 May 1;25(9):1189-91
pubmed: 19151095
Elife. 2016 Sep 22;5:
pubmed: 27656904
PLoS Biol. 2006 Feb;4(2):e20
pubmed: 16402857
Nucleic Acids Res. 2018 Jul 2;46(W1):W296-W303
pubmed: 29788355
EMBO J. 2008 Nov 19;27(22):3056-68
pubmed: 18923416
Nature. 2015 Jun 22;534(7608):E5-7
pubmed: 27337300
Nat Commun. 2018 Oct 12;9(1):4252
pubmed: 30315166
Nucleic Acids Res. 2016 Jul 8;44(W1):W410-5
pubmed: 27131380
Proc Natl Acad Sci U S A. 2007 Feb 27;104(9):3312-7
pubmed: 17360644
Curr Opin Insect Sci. 2017 Apr;20:19-27
pubmed: 28602232
Neuron. 2017 May 17;94(4):713-730
pubmed: 28521126
F1000Res. 2017 Sep 26;6:1753
pubmed: 29034089
Curr Opin Biotechnol. 2003 Dec;14(6):610-7
pubmed: 14662390
Cold Spring Harb Protoc. 2011 Jul 01;2011(7):824-38
pubmed: 21724819
J Physiol. 2012 Jan 1;590(1):63-72
pubmed: 22106178
Elife. 2017 Jun 16;6:
pubmed: 28621663
Neuron. 2019 Feb 20;101(4):738-747.e3
pubmed: 30654923
Nature. 2009 Dec 10;462(7274):745-56
pubmed: 19946266
Curr Biol. 2016 May 23;26(10):1352-8
pubmed: 27161501