Structure, amphipathy, and topology of the membrane-proximal helix 8 influence apelin receptor plasma membrane localization

Aditya Pandey; Danielle M. LeBlanc; Hirendrasinh B. Parmar; Trần Thanh Tâm Phạm; Muzaddid Sarker; Lingling Xu; Roy Duncan; Xiang Qin Liu; J. K. Rainey

doi:10.1016/j.bbamem.2019.183036

Structure, amphipathy, and topology of the membrane-proximal helix 8 influence apelin receptor plasma membrane localization

Aditya Pandey, Danielle M. LeBlanc, Hirendrasinh B. Parmar, Trần Thanh Tâm Phạm, Muzaddid Sarker, Lingling Xu, Roy Duncan, Xiang Qin Liu, J. K. Rainey

Medicine

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4 Citas (Scopus)

Resumen

G-protein coupled receptors (GPCRs) typically have an amphipathic helix (“helix 8”) immediately C-terminal to the transmembrane helical bundle. To date, a number of functional roles have been associated with GPCR helix 8 segments, but structure-function analysis for this region remains limited. Here, we examine helix 8 of the apelin receptor (AR or APJ), a class A GPCR with wide physiological and pathophysiological relevance. The 71 residue C-terminal tail of the AR is primarily intrinsically disordered, with a detergent micelle-induced increase in helical character. This helicity was localized to the helix 8 region, in good agreement with the recent AR crystal structure. A series of helix 8 mutants were made to reduce helicity, remove amphipathy, or flip the hydrophobic and hydrophilic faces. Each mutant AR was tested both biophysically, in the isolated C-terminal tail, and functionally in HEK 293 T cells, for full-length AR. In all instances, micelle interactions were maintained, and steady-state AR expression was efficient. However, removal of amphipathy or helical character led to a significant decrease in cell surface localization. Flipping of helix 8 amphipathic topology restored cell surface localization to some degree, but still was significantly reduced relative to wild-type. Structural integrity, amphipathy to drive membrane association, and correct topology of helix 8 membrane association all thus appear important for cell surface localization of the AR. This behavior correlates well to GPCR C-terminal tail sequence motifs, implying that these serve to specify key topological features of helix 8 and its proximity to the transmembrane domain.

Idioma original	English
Número de artículo	183036
Publicación	Biochimica et Biophysica Acta - Biomembranes
Volumen	1861
N.º	11
DOI	https://doi.org/10.1016/j.bbamem.2019.183036
Estado	Published - nov. 1 2019

Nota bibliográfica

Funding Information:
Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500 MHz NMR spectrometer support (NMR 3 ) and Ian Burton for 700 MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants ( MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants ( RGPIN/41823-2015 to X.Q.L., OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award .

Funding Information:
Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500?MHz NMR spectrometer support (NMR3) and Ian Burton for 700?MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants (MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants (RGPIN/41823-2015 to X.Q.L. OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award.

Publisher Copyright:
© 2019 Elsevier B.V.

ASJC Scopus Subject Areas

Biophysics
Biochemistry
Cell Biology

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10.1016/j.bbamem.2019.183036

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Pandey, A., LeBlanc, D. M., Parmar, H. B., Phạm, T. T. T., Sarker, M., Xu, L., Duncan, R., Liu, X. Q., & Rainey, J. K. (2019). Structure, amphipathy, and topology of the membrane-proximal helix 8 influence apelin receptor plasma membrane localization. Biochimica et Biophysica Acta - Biomembranes, 1861(11), Artículo 183036. https://doi.org/10.1016/j.bbamem.2019.183036

Structure, amphipathy, and topology of the membrane-proximal helix 8 influence apelin receptor plasma membrane localization. / Pandey, Aditya; LeBlanc, Danielle M.; Parmar, Hirendrasinh B. et al.
En: Biochimica et Biophysica Acta - Biomembranes, Vol. 1861, N.º 11, 183036, 01.11.2019.

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

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abstract = "G-protein coupled receptors (GPCRs) typically have an amphipathic helix (“helix 8”) immediately C-terminal to the transmembrane helical bundle. To date, a number of functional roles have been associated with GPCR helix 8 segments, but structure-function analysis for this region remains limited. Here, we examine helix 8 of the apelin receptor (AR or APJ), a class A GPCR with wide physiological and pathophysiological relevance. The 71 residue C-terminal tail of the AR is primarily intrinsically disordered, with a detergent micelle-induced increase in helical character. This helicity was localized to the helix 8 region, in good agreement with the recent AR crystal structure. A series of helix 8 mutants were made to reduce helicity, remove amphipathy, or flip the hydrophobic and hydrophilic faces. Each mutant AR was tested both biophysically, in the isolated C-terminal tail, and functionally in HEK 293 T cells, for full-length AR. In all instances, micelle interactions were maintained, and steady-state AR expression was efficient. However, removal of amphipathy or helical character led to a significant decrease in cell surface localization. Flipping of helix 8 amphipathic topology restored cell surface localization to some degree, but still was significantly reduced relative to wild-type. Structural integrity, amphipathy to drive membrane association, and correct topology of helix 8 membrane association all thus appear important for cell surface localization of the AR. This behavior correlates well to GPCR C-terminal tail sequence motifs, implying that these serve to specify key topological features of helix 8 and its proximity to the transmembrane domain.",

author = "Aditya Pandey and LeBlanc, {Danielle M.} and Parmar, {Hirendrasinh B.} and Phạm, {Trần Thanh T{\^a}m} and Muzaddid Sarker and Lingling Xu and Roy Duncan and Liu, {Xiang Qin} and Rainey, {J. K.}",

note = "Funding Information: Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500 MHz NMR spectrometer support (NMR 3 ) and Ian Burton for 700 MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants ( MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants ( RGPIN/41823-2015 to X.Q.L., OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award . Funding Information: Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500?MHz NMR spectrometer support (NMR3) and Ian Burton for 700?MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants (MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants (RGPIN/41823-2015 to X.Q.L. OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award. Publisher Copyright: {\textcopyright} 2019 Elsevier B.V.",

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AU - Phạm, Trần Thanh Tâm

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AU - Duncan, Roy

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N1 - Funding Information: Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500 MHz NMR spectrometer support (NMR 3 ) and Ian Burton for 700 MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants ( MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants ( RGPIN/41823-2015 to X.Q.L., OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award . Funding Information: Thanks to Bruce Stewart for expert assistance; to Mike Lumsden for 500?MHz NMR spectrometer support (NMR3) and Ian Burton for 700?MHz NMR spectrometer support (NRC); to Xiao Feng at the Dalhousie Chemistry Mass Spectrometry Laboratory; and, to expertise and infrastructure in the Flow Cytometry and Cellular Microscopy and Digital Imaging core facilities (CORES, Dalhousie University, Faculty of Medicine). This work was supported by Canadian Institutes of Health Research (CIHR) Operating Grants (MOP-111138 to J.K.R.; FDN-143305 to R.D.); a Nova Scotia Health Research Foundation (NSHRF) Scotia Support Grant (to J.K.R. and R.D.); and, Natural Sciences and Engineering Research Council of Canada Discovery Grants (RGPIN/41823-2015 to X.Q.L. OGP-0183745 to R.D.) A.P. was supported by the Beatrice Hunter Cancer Research Institute with funds provided by the Canadian Imperial Bank of Commerce and the Harvey Graham Cancer Research Fund as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR; J.K.R. was supported by a CIHR New Investigator Award. Publisher Copyright: © 2019 Elsevier B.V.

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N2 - G-protein coupled receptors (GPCRs) typically have an amphipathic helix (“helix 8”) immediately C-terminal to the transmembrane helical bundle. To date, a number of functional roles have been associated with GPCR helix 8 segments, but structure-function analysis for this region remains limited. Here, we examine helix 8 of the apelin receptor (AR or APJ), a class A GPCR with wide physiological and pathophysiological relevance. The 71 residue C-terminal tail of the AR is primarily intrinsically disordered, with a detergent micelle-induced increase in helical character. This helicity was localized to the helix 8 region, in good agreement with the recent AR crystal structure. A series of helix 8 mutants were made to reduce helicity, remove amphipathy, or flip the hydrophobic and hydrophilic faces. Each mutant AR was tested both biophysically, in the isolated C-terminal tail, and functionally in HEK 293 T cells, for full-length AR. In all instances, micelle interactions were maintained, and steady-state AR expression was efficient. However, removal of amphipathy or helical character led to a significant decrease in cell surface localization. Flipping of helix 8 amphipathic topology restored cell surface localization to some degree, but still was significantly reduced relative to wild-type. Structural integrity, amphipathy to drive membrane association, and correct topology of helix 8 membrane association all thus appear important for cell surface localization of the AR. This behavior correlates well to GPCR C-terminal tail sequence motifs, implying that these serve to specify key topological features of helix 8 and its proximity to the transmembrane domain.

AB - G-protein coupled receptors (GPCRs) typically have an amphipathic helix (“helix 8”) immediately C-terminal to the transmembrane helical bundle. To date, a number of functional roles have been associated with GPCR helix 8 segments, but structure-function analysis for this region remains limited. Here, we examine helix 8 of the apelin receptor (AR or APJ), a class A GPCR with wide physiological and pathophysiological relevance. The 71 residue C-terminal tail of the AR is primarily intrinsically disordered, with a detergent micelle-induced increase in helical character. This helicity was localized to the helix 8 region, in good agreement with the recent AR crystal structure. A series of helix 8 mutants were made to reduce helicity, remove amphipathy, or flip the hydrophobic and hydrophilic faces. Each mutant AR was tested both biophysically, in the isolated C-terminal tail, and functionally in HEK 293 T cells, for full-length AR. In all instances, micelle interactions were maintained, and steady-state AR expression was efficient. However, removal of amphipathy or helical character led to a significant decrease in cell surface localization. Flipping of helix 8 amphipathic topology restored cell surface localization to some degree, but still was significantly reduced relative to wild-type. Structural integrity, amphipathy to drive membrane association, and correct topology of helix 8 membrane association all thus appear important for cell surface localization of the AR. This behavior correlates well to GPCR C-terminal tail sequence motifs, implying that these serve to specify key topological features of helix 8 and its proximity to the transmembrane domain.

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Structure, amphipathy, and topology of the membrane-proximal helix 8 influence apelin receptor plasma membrane localization

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