Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps

Department of Plant and Environmental Sciences

Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps. / Reyer, Antonella; Häßler, Melanie; Scherzer, Sönke; Huang, Shouguang; Pedersen, Jesper Torbøl; Al-Rascheid, Khaled A S; Bamberg, Ernst; Palmgren, Michael; Dreyer, Ingo; Nagel, Georg; Hedrich, Rainer; Becker, Dirk.

In: Proceedings of the National Academy of Sciences of the United States of America, Vol. 117, No. 34, 2020, p. 20920-20925.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Reyer, A, Häßler, M, Scherzer, S, Huang, S, Pedersen, JT, Al-Rascheid, KAS, Bamberg, E, Palmgren, M, Dreyer, I, Nagel, G, Hedrich, R & Becker, D 2020, 'Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps', Proceedings of the National Academy of Sciences of the United States of America, vol. 117, no. 34, pp. 20920-20925. https://doi.org/10.1073/pnas.2005626117

APA

Reyer, A., Häßler, M., Scherzer, S., Huang, S., Pedersen, J. T., Al-Rascheid, K. A. S., Bamberg, E., Palmgren, M., Dreyer, I., Nagel, G., Hedrich, R., & Becker, D. (2020). Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps. Proceedings of the National Academy of Sciences of the United States of America, 117(34), 20920-20925. https://doi.org/10.1073/pnas.2005626117

Vancouver

Reyer A, Häßler M, Scherzer S, Huang S, Pedersen JT, Al-Rascheid KAS et al. Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps. Proceedings of the National Academy of Sciences of the United States of America. 2020;117(34):20920-20925. https://doi.org/10.1073/pnas.2005626117

Author

Reyer, Antonella ; Häßler, Melanie ; Scherzer, Sönke ; Huang, Shouguang ; Pedersen, Jesper Torbøl ; Al-Rascheid, Khaled A S ; Bamberg, Ernst ; Palmgren, Michael ; Dreyer, Ingo ; Nagel, Georg ; Hedrich, Rainer ; Becker, Dirk. / Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps. In: Proceedings of the National Academy of Sciences of the United States of America. 2020 ; Vol. 117, No. 34. pp. 20920-20925.

Bibtex

@article{c1d943e850264952b8164c446400854c,

title = "Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps",

abstract = "In plants, environmental stressors trigger plasma membrane depolarizations. Being electrically interconnected via plasmodesmata, proper functional dissection of electrical signaling by electrophysiology is basically impossible. The green alga Chlamydomonas reinhardtii evolved blue light-excited channelrhodopsins (ChR1, 2) to navigate. When expressed in excitable nerve and muscle cells, ChRs can be used to control the membrane potential via illumination. In Arabidopsis plants, we used the algal ChR2-light switches as tools to stimulate plasmodesmata-interconnected photosynthetic cell networks by blue light and monitor the subsequent plasma membrane electrical responses. Blue-dependent stimulations of ChR2 expressing mesophyll cells, resting around -160 to -180 mV, reproducibly depolarized the membrane potential by 95 mV on average. Following excitation, mesophyll cells recovered their prestimulus potential not without transiently passing a hyperpolarization state. By combining optogenetics with voltage-sensing microelectrodes, we demonstrate that plant plasma membrane AHA-type H+-ATPase governs the gross repolarization process. AHA2 protein biochemistry and functional expression analysis in Xenopus oocytes indicates that the capacity of this H+ pump to recharge the membrane potential is rooted in its voltage- and pH-dependent functional anatomy. Thus, ChR2 optogenetics appears well suited to noninvasively expose plant cells to signal specific depolarization signatures. From the responses we learn about the molecular processes, plants employ to channel stress-associated membrane excitations into physiological responses.",

author = "Antonella Reyer and Melanie H{\"a}{\ss}ler and S{\"o}nke Scherzer and Shouguang Huang and Pedersen, {Jesper Torb{\o}l} and Al-Rascheid, {Khaled A S} and Ernst Bamberg and Michael Palmgren and Ingo Dreyer and Georg Nagel and Rainer Hedrich and Dirk Becker",

note = "Correction: www.pnas.org/cgi/doi/10.1073/pnas.2017782117",

year = "2020",

doi = "10.1073/pnas.2005626117",

language = "English",

volume = "117",

pages = "20920--20925",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

issn = "0027-8424",

publisher = "The National Academy of Sciences of the United States of America",

number = "34",

}

RIS

TY - JOUR

T1 - Channelrhodopsin-mediated optogenetics highlights a central role of depolarization-dependent plant proton pumps

AU - Reyer, Antonella

AU - Häßler, Melanie

AU - Scherzer, Sönke

AU - Huang, Shouguang

AU - Pedersen, Jesper Torbøl

AU - Al-Rascheid, Khaled A S

AU - Bamberg, Ernst

AU - Palmgren, Michael

AU - Dreyer, Ingo

AU - Nagel, Georg

AU - Hedrich, Rainer

AU - Becker, Dirk

N1 - Correction: www.pnas.org/cgi/doi/10.1073/pnas.2017782117

PY - 2020

Y1 - 2020

N2 - In plants, environmental stressors trigger plasma membrane depolarizations. Being electrically interconnected via plasmodesmata, proper functional dissection of electrical signaling by electrophysiology is basically impossible. The green alga Chlamydomonas reinhardtii evolved blue light-excited channelrhodopsins (ChR1, 2) to navigate. When expressed in excitable nerve and muscle cells, ChRs can be used to control the membrane potential via illumination. In Arabidopsis plants, we used the algal ChR2-light switches as tools to stimulate plasmodesmata-interconnected photosynthetic cell networks by blue light and monitor the subsequent plasma membrane electrical responses. Blue-dependent stimulations of ChR2 expressing mesophyll cells, resting around -160 to -180 mV, reproducibly depolarized the membrane potential by 95 mV on average. Following excitation, mesophyll cells recovered their prestimulus potential not without transiently passing a hyperpolarization state. By combining optogenetics with voltage-sensing microelectrodes, we demonstrate that plant plasma membrane AHA-type H+-ATPase governs the gross repolarization process. AHA2 protein biochemistry and functional expression analysis in Xenopus oocytes indicates that the capacity of this H+ pump to recharge the membrane potential is rooted in its voltage- and pH-dependent functional anatomy. Thus, ChR2 optogenetics appears well suited to noninvasively expose plant cells to signal specific depolarization signatures. From the responses we learn about the molecular processes, plants employ to channel stress-associated membrane excitations into physiological responses.

AB - In plants, environmental stressors trigger plasma membrane depolarizations. Being electrically interconnected via plasmodesmata, proper functional dissection of electrical signaling by electrophysiology is basically impossible. The green alga Chlamydomonas reinhardtii evolved blue light-excited channelrhodopsins (ChR1, 2) to navigate. When expressed in excitable nerve and muscle cells, ChRs can be used to control the membrane potential via illumination. In Arabidopsis plants, we used the algal ChR2-light switches as tools to stimulate plasmodesmata-interconnected photosynthetic cell networks by blue light and monitor the subsequent plasma membrane electrical responses. Blue-dependent stimulations of ChR2 expressing mesophyll cells, resting around -160 to -180 mV, reproducibly depolarized the membrane potential by 95 mV on average. Following excitation, mesophyll cells recovered their prestimulus potential not without transiently passing a hyperpolarization state. By combining optogenetics with voltage-sensing microelectrodes, we demonstrate that plant plasma membrane AHA-type H+-ATPase governs the gross repolarization process. AHA2 protein biochemistry and functional expression analysis in Xenopus oocytes indicates that the capacity of this H+ pump to recharge the membrane potential is rooted in its voltage- and pH-dependent functional anatomy. Thus, ChR2 optogenetics appears well suited to noninvasively expose plant cells to signal specific depolarization signatures. From the responses we learn about the molecular processes, plants employ to channel stress-associated membrane excitations into physiological responses.

U2 - 10.1073/pnas.2005626117

DO - 10.1073/pnas.2005626117

M3 - Journal article

C2 - 32788371

VL - 117

SP - 20920

EP - 20925

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

SN - 0027-8424

IS - 34

ER -

ID: 248241137