Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons

Research output: Contribution to journalJournal articleResearchpeer-review

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Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons. / Christensen, Emma Kragelund; Konomi-Pilkati, Ainoa; Rombach, Joscha; Comaposada-Baro, Raquel; Wang, Huan; Li, Yulong; Sørensen, Andreas Toft.

In: Frontiers in Cellular Neuroscience, Vol. 17, 1221147, 2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Christensen, EK, Konomi-Pilkati, A, Rombach, J, Comaposada-Baro, R, Wang, H, Li, Y & Sørensen, AT 2023, 'Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons', Frontiers in Cellular Neuroscience, vol. 17, 1221147. https://doi.org/10.3389/fncel.2023.1221147

APA

Christensen, E. K., Konomi-Pilkati, A., Rombach, J., Comaposada-Baro, R., Wang, H., Li, Y., & Sørensen, A. T. (2023). Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons. Frontiers in Cellular Neuroscience, 17, [1221147]. https://doi.org/10.3389/fncel.2023.1221147

Vancouver

Christensen EK, Konomi-Pilkati A, Rombach J, Comaposada-Baro R, Wang H, Li Y et al. Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons. Frontiers in Cellular Neuroscience. 2023;17. 1221147. https://doi.org/10.3389/fncel.2023.1221147

Author

Christensen, Emma Kragelund ; Konomi-Pilkati, Ainoa ; Rombach, Joscha ; Comaposada-Baro, Raquel ; Wang, Huan ; Li, Yulong ; Sørensen, Andreas Toft. / Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons. In: Frontiers in Cellular Neuroscience. 2023 ; Vol. 17.

Bibtex

@article{093e3628887849ba8789d270a5c4fa93,
title = "Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons",
abstract = "Neuropeptide Y (NPY) is an abundantly expressed peptide in the nervous system. Its widespread distribution along with its receptors, both centrally and peripherally, indicates its broad functions in numerous biological processes. However, the low endogenous concentration and diffuse distribution of NPY make it challenging to study its actions and dynamics directly and comprehensively. Studies on the role of NPY have primarily been limited to exogenous application, transgene expression, or knock-out in biological systems, which are often combined with pharmacological probes to delineate the involvement of specific NPY receptors. Therefore, to better understand the function of NPY in time and space, direct visualization of the real-time dynamics of endogenous NPY is a valuable and desired tool. Using the first-generation and newly developed intensiometric green fluorescent G-protein-coupled NPY sensor (GRAB NPY1.0), we, for the first time, demonstrate and characterize the direct detection of endogenously released NPY in cultured cortical neurons. A dose-dependent fluorescent signal was observed upon exogenous NPY application in nearly all recorded neurons. Pharmacologically evoked neuronal activity induced a significant increase in fluorescent signal in 32% of neurons, reflecting the release of NPY, despite only 3% of all neurons containing NPY. The remaining pool of neurons expressing the sensor were either non-responsive or displayed a notable decline in the fluorescent signal. Such decline in fluorescent signal was not rescued in cortical cultures transduced with an NPY overexpression vector, where 88% of the neurons were NPY-positive. Overexpression of NPY did, however, result in sensor signals that were more readily distinguishable. This may suggest that biological factors, such as subtle changes in intracellular pH, could interfere with the fluorescent signal, and thereby underestimate the release of endogenous NPY when using this new sensor in its present configuration. However, the development of next-generation NPY GRAB sensor technology is expected soon, and will eventually enable much-wanted studies on endogenous NPY release dynamics in both cultured and intact biological systems.",
keywords = "biosensor, genetically encoded fluorescent sensor, GRAB sensor, neuronal cultures, neuropeptides, NPY, NPY release",
author = "Christensen, {Emma Kragelund} and Ainoa Konomi-Pilkati and Joscha Rombach and Raquel Comaposada-Baro and Huan Wang and Yulong Li and S{\o}rensen, {Andreas Toft}",
note = "Publisher Copyright: Copyright {\textcopyright} 2023 Christensen, Konomi-Pilkati, Rombach, Comaposada-Baro, Wang, Li and S{\o}rensen.",
year = "2023",
doi = "10.3389/fncel.2023.1221147",
language = "English",
volume = "17",
journal = "Frontiers in Cellular Neuroscience",
issn = "1662-5102",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Detection of endogenous NPY release determined by novel GRAB sensor in cultured cortical neurons

AU - Christensen, Emma Kragelund

AU - Konomi-Pilkati, Ainoa

AU - Rombach, Joscha

AU - Comaposada-Baro, Raquel

AU - Wang, Huan

AU - Li, Yulong

AU - Sørensen, Andreas Toft

N1 - Publisher Copyright: Copyright © 2023 Christensen, Konomi-Pilkati, Rombach, Comaposada-Baro, Wang, Li and Sørensen.

PY - 2023

Y1 - 2023

N2 - Neuropeptide Y (NPY) is an abundantly expressed peptide in the nervous system. Its widespread distribution along with its receptors, both centrally and peripherally, indicates its broad functions in numerous biological processes. However, the low endogenous concentration and diffuse distribution of NPY make it challenging to study its actions and dynamics directly and comprehensively. Studies on the role of NPY have primarily been limited to exogenous application, transgene expression, or knock-out in biological systems, which are often combined with pharmacological probes to delineate the involvement of specific NPY receptors. Therefore, to better understand the function of NPY in time and space, direct visualization of the real-time dynamics of endogenous NPY is a valuable and desired tool. Using the first-generation and newly developed intensiometric green fluorescent G-protein-coupled NPY sensor (GRAB NPY1.0), we, for the first time, demonstrate and characterize the direct detection of endogenously released NPY in cultured cortical neurons. A dose-dependent fluorescent signal was observed upon exogenous NPY application in nearly all recorded neurons. Pharmacologically evoked neuronal activity induced a significant increase in fluorescent signal in 32% of neurons, reflecting the release of NPY, despite only 3% of all neurons containing NPY. The remaining pool of neurons expressing the sensor were either non-responsive or displayed a notable decline in the fluorescent signal. Such decline in fluorescent signal was not rescued in cortical cultures transduced with an NPY overexpression vector, where 88% of the neurons were NPY-positive. Overexpression of NPY did, however, result in sensor signals that were more readily distinguishable. This may suggest that biological factors, such as subtle changes in intracellular pH, could interfere with the fluorescent signal, and thereby underestimate the release of endogenous NPY when using this new sensor in its present configuration. However, the development of next-generation NPY GRAB sensor technology is expected soon, and will eventually enable much-wanted studies on endogenous NPY release dynamics in both cultured and intact biological systems.

AB - Neuropeptide Y (NPY) is an abundantly expressed peptide in the nervous system. Its widespread distribution along with its receptors, both centrally and peripherally, indicates its broad functions in numerous biological processes. However, the low endogenous concentration and diffuse distribution of NPY make it challenging to study its actions and dynamics directly and comprehensively. Studies on the role of NPY have primarily been limited to exogenous application, transgene expression, or knock-out in biological systems, which are often combined with pharmacological probes to delineate the involvement of specific NPY receptors. Therefore, to better understand the function of NPY in time and space, direct visualization of the real-time dynamics of endogenous NPY is a valuable and desired tool. Using the first-generation and newly developed intensiometric green fluorescent G-protein-coupled NPY sensor (GRAB NPY1.0), we, for the first time, demonstrate and characterize the direct detection of endogenously released NPY in cultured cortical neurons. A dose-dependent fluorescent signal was observed upon exogenous NPY application in nearly all recorded neurons. Pharmacologically evoked neuronal activity induced a significant increase in fluorescent signal in 32% of neurons, reflecting the release of NPY, despite only 3% of all neurons containing NPY. The remaining pool of neurons expressing the sensor were either non-responsive or displayed a notable decline in the fluorescent signal. Such decline in fluorescent signal was not rescued in cortical cultures transduced with an NPY overexpression vector, where 88% of the neurons were NPY-positive. Overexpression of NPY did, however, result in sensor signals that were more readily distinguishable. This may suggest that biological factors, such as subtle changes in intracellular pH, could interfere with the fluorescent signal, and thereby underestimate the release of endogenous NPY when using this new sensor in its present configuration. However, the development of next-generation NPY GRAB sensor technology is expected soon, and will eventually enable much-wanted studies on endogenous NPY release dynamics in both cultured and intact biological systems.

KW - biosensor

KW - genetically encoded fluorescent sensor

KW - GRAB sensor

KW - neuronal cultures

KW - neuropeptides

KW - NPY

KW - NPY release

U2 - 10.3389/fncel.2023.1221147

DO - 10.3389/fncel.2023.1221147

M3 - Journal article

C2 - 37545877

AN - SCOPUS:85166587861

VL - 17

JO - Frontiers in Cellular Neuroscience

JF - Frontiers in Cellular Neuroscience

SN - 1662-5102

M1 - 1221147

ER -

ID: 362687962