Purkinje cell microzones mediate distinct kinematics of a single movement

François G.C. Blot; Joshua J. White; Amy van Hattem; Licia Scotti; Vaishnavi Balaji; Youri Adolfs; R. Jeroen Pasterkamp; Chris I. De Zeeuw; Martijn Schonewille

doi:10.1038/s41467-023-40111-5

Purkinje cell microzones mediate distinct kinematics of a single movement

François G.C. Blot, Joshua J. White, Amy van Hattem, Licia Scotti, Vaishnavi Balaji, Youri Adolfs, R. Jeroen Pasterkamp, Chris I. De Zeeuw, Martijn Schonewille^*

^*Corresponding author for this work

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Abstract

The classification of neuronal subpopulations has significantly advanced, yet its relevance for behavior remains unclear. The highly organized flocculus of the cerebellum, known to fine-tune multi-axial eye movements, is an ideal substrate for the study of potential functions of neuronal subpopulations. Here, we demonstrate that its recently identified subpopulations of 9+ and 9- Purkinje cells exhibit an intermediate Aldolase C expression and electrophysiological profile, providing evidence for a graded continuum of intrinsic properties among PC subpopulations. By identifying and utilizing two Cre-lines that genetically target these floccular domains, we show with high spatial specificity that these subpopulations of Purkinje cells participate in separate micromodules with topographically organized connections. Finally, optogenetic excitation of the respective subpopulations results in movements around the same axis in space, yet with distinct kinematic profiles. These results indicate that Purkinje cell subpopulations integrate in discrete circuits and mediate particular parameters of single movements.

Original language	English
Article number	4358
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-40111-5
Publication status	Published - 19 Jul 2023

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title = "Purkinje cell microzones mediate distinct kinematics of a single movement",

abstract = "The classification of neuronal subpopulations has significantly advanced, yet its relevance for behavior remains unclear. The highly organized flocculus of the cerebellum, known to fine-tune multi-axial eye movements, is an ideal substrate for the study of potential functions of neuronal subpopulations. Here, we demonstrate that its recently identified subpopulations of 9+ and 9- Purkinje cells exhibit an intermediate Aldolase C expression and electrophysiological profile, providing evidence for a graded continuum of intrinsic properties among PC subpopulations. By identifying and utilizing two Cre-lines that genetically target these floccular domains, we show with high spatial specificity that these subpopulations of Purkinje cells participate in separate micromodules with topographically organized connections. Finally, optogenetic excitation of the respective subpopulations results in movements around the same axis in space, yet with distinct kinematic profiles. These results indicate that Purkinje cell subpopulations integrate in discrete circuits and mediate particular parameters of single movements.",

author = "Blot, {Fran{\c c}ois G.C.} and White, {Joshua J.} and {van Hattem}, Amy and Licia Scotti and Vaishnavi Balaji and Youri Adolfs and Pasterkamp, {R. Jeroen} and {De Zeeuw}, {Chris I.} and Martijn Schonewille",

note = "Funding Information: Support was provided by an ERC starter grant (ERC-Stg #680235; MS) and NWO-VENI (016.Veni.192.270; JJW), as well as the Dutch Organization for Medical Sciences (ZonMW 91120067; CIDZ), Life Sciences (NWO-ALW 824.02.001 (CIDZ), Medical Neuro-Delta (MD 01092019-31082023; CIDZ), INTENSE (LSH-NWO TTW/00798883; CIDZ), Gravitation Program NWO (DBI2; CIDZ) and the Vriendenfonds NIN for Albinism (CIDZ). We thank Catarina Osorio and Dick Jaarsma for valuable input. We thank Laura Post, Elize Haasdijk and Erika Goedknegt for technical assistance. We thank Antoine Michelet for editing the videos. Funding Information: Support was provided by an ERC starter grant (ERC-Stg #680235; MS) and NWO-VENI (016.Veni.192.270; JJW), as well as the Dutch Organization for Medical Sciences (ZonMW 91120067; CIDZ), Life Sciences (NWO-ALW 824.02.001 (CIDZ), Medical Neuro-Delta (MD 01092019-31082023; CIDZ), INTENSE (LSH-NWO TTW/00798883; CIDZ), Gravitation Program NWO (DBI2; CIDZ) and the Vriendenfonds NIN for Albinism (CIDZ). We thank Catarina Osorio and Dick Jaarsma for valuable input. We thank Laura Post, Elize Haasdijk and Erika Goedknegt for technical assistance. We thank Antoine Michelet for editing the videos. Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = jul,

day = "19",

doi = "10.1038/s41467-023-40111-5",

language = "English",

volume = "14",

journal = "Nature Communications",

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T1 - Purkinje cell microzones mediate distinct kinematics of a single movement

AU - Blot, François G.C.

AU - White, Joshua J.

AU - van Hattem, Amy

AU - Scotti, Licia

AU - Balaji, Vaishnavi

AU - Adolfs, Youri

AU - Pasterkamp, R. Jeroen

AU - De Zeeuw, Chris I.

AU - Schonewille, Martijn

N1 - Funding Information: Support was provided by an ERC starter grant (ERC-Stg #680235; MS) and NWO-VENI (016.Veni.192.270; JJW), as well as the Dutch Organization for Medical Sciences (ZonMW 91120067; CIDZ), Life Sciences (NWO-ALW 824.02.001 (CIDZ), Medical Neuro-Delta (MD 01092019-31082023; CIDZ), INTENSE (LSH-NWO TTW/00798883; CIDZ), Gravitation Program NWO (DBI2; CIDZ) and the Vriendenfonds NIN for Albinism (CIDZ). We thank Catarina Osorio and Dick Jaarsma for valuable input. We thank Laura Post, Elize Haasdijk and Erika Goedknegt for technical assistance. We thank Antoine Michelet for editing the videos. Funding Information: Support was provided by an ERC starter grant (ERC-Stg #680235; MS) and NWO-VENI (016.Veni.192.270; JJW), as well as the Dutch Organization for Medical Sciences (ZonMW 91120067; CIDZ), Life Sciences (NWO-ALW 824.02.001 (CIDZ), Medical Neuro-Delta (MD 01092019-31082023; CIDZ), INTENSE (LSH-NWO TTW/00798883; CIDZ), Gravitation Program NWO (DBI2; CIDZ) and the Vriendenfonds NIN for Albinism (CIDZ). We thank Catarina Osorio and Dick Jaarsma for valuable input. We thank Laura Post, Elize Haasdijk and Erika Goedknegt for technical assistance. We thank Antoine Michelet for editing the videos. Publisher Copyright: © 2023, The Author(s).

PY - 2023/7/19

Y1 - 2023/7/19

N2 - The classification of neuronal subpopulations has significantly advanced, yet its relevance for behavior remains unclear. The highly organized flocculus of the cerebellum, known to fine-tune multi-axial eye movements, is an ideal substrate for the study of potential functions of neuronal subpopulations. Here, we demonstrate that its recently identified subpopulations of 9+ and 9- Purkinje cells exhibit an intermediate Aldolase C expression and electrophysiological profile, providing evidence for a graded continuum of intrinsic properties among PC subpopulations. By identifying and utilizing two Cre-lines that genetically target these floccular domains, we show with high spatial specificity that these subpopulations of Purkinje cells participate in separate micromodules with topographically organized connections. Finally, optogenetic excitation of the respective subpopulations results in movements around the same axis in space, yet with distinct kinematic profiles. These results indicate that Purkinje cell subpopulations integrate in discrete circuits and mediate particular parameters of single movements.

AB - The classification of neuronal subpopulations has significantly advanced, yet its relevance for behavior remains unclear. The highly organized flocculus of the cerebellum, known to fine-tune multi-axial eye movements, is an ideal substrate for the study of potential functions of neuronal subpopulations. Here, we demonstrate that its recently identified subpopulations of 9+ and 9- Purkinje cells exhibit an intermediate Aldolase C expression and electrophysiological profile, providing evidence for a graded continuum of intrinsic properties among PC subpopulations. By identifying and utilizing two Cre-lines that genetically target these floccular domains, we show with high spatial specificity that these subpopulations of Purkinje cells participate in separate micromodules with topographically organized connections. Finally, optogenetic excitation of the respective subpopulations results in movements around the same axis in space, yet with distinct kinematic profiles. These results indicate that Purkinje cell subpopulations integrate in discrete circuits and mediate particular parameters of single movements.

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DO - 10.1038/s41467-023-40111-5

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SN - 2041-1723

VL - 14

JO - Nature Communications

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Purkinje cell microzones mediate distinct kinematics of a single movement

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