Differential processing in modality-specific Mauthner cell dendrites

Key points: The present study examines dendritic integrative processes that occur in many central neurons but have been challenging to study in vivo in the vertebrate brain. The Mauthner cell of goldfish receives auditory and visual information via two separate dendrites, providing a privileged scen...

Descripción completa

Guardado en:
Detalles Bibliográficos
Autores principales: Medan, V., Mäki-Marttunen, T., Sztarker, J., Preuss, T.
Formato: JOUR
Materias:
cross-modal dendritic interaction
dendritic specialization
Mauthner cell
adult
animal cell
animal experiment
Article
auditory evoked potential
cell interaction
cell specificity
cell structure
controlled study
dendrite
neurophysiology
nonhuman
postsynaptic potential
priority journal
visual evoked potential
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00223751_v596_n4_p667_Medan
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_00223751_v596_n4_p667_Medan
record_format dspace
spelling todo:paper_00223751_v596_n4_p667_Medan2023-10-03T14:32:29Z Differential processing in modality-specific Mauthner cell dendrites Medan, V. Mäki-Marttunen, T. Sztarker, J. Preuss, T. cross-modal dendritic interaction dendritic specialization Mauthner cell adult animal cell animal experiment Article auditory evoked potential cell interaction cell specificity cell structure controlled study dendrite Mauthner cell neurophysiology nonhuman postsynaptic potential priority journal visual evoked potential Key points: The present study examines dendritic integrative processes that occur in many central neurons but have been challenging to study in vivo in the vertebrate brain. The Mauthner cell of goldfish receives auditory and visual information via two separate dendrites, providing a privileged scenario for in vivo examination of dendritic integration. The results show differential attenuation properties in the Mauthner cell dendrites arising at least partly from differences in cable properties and the nonlinear behaviour of the respective dendritic membranes. In addition to distinct modality-dependent membrane specialization in neighbouring dendrites of the Mauthner cell, we report cross-modal dendritic interactions via backpropagating postsynaptic potentials. Broadly, the results of the present study provide an exceptional example for the processing power of single neurons. Abstract: Animals process multimodal information for adaptive behavioural decisions. In fish, evasion of a diving bird that breaks the water surface depends on integrating visual and auditory stimuli with very different characteristics. How do neurons process such differential sensory inputs at the dendritic level? For that, we studied the Mauthner cells (M-cells) in the goldfish startle circuit, which receive visual and auditory inputs via two separate dendrites, both accessible for in vivo recordings. We investigated whether electrophysiological membrane properties and dendrite morphology, studied in vivo, play a role in selective sensory processing in the M-cell. The results obtained show that anatomical and electrophysiological differences between the dendrites combine to produce stronger attenuation of visually evoked postsynaptic potentials (PSPs) than to auditory evoked PSPs. Interestingly, our recordings showed also cross-modal dendritic interaction because auditory evoked PSPs invade the ventral dendrite (VD), as well as the opposite where visual PSPs invade the lateral dendrite (LD). However, these interactions were asymmetrical, with auditory PSPs being more prominent in the VD than visual PSPs in the LD. Modelling experiments imply that this asymmetry is caused by active conductances expressed in the proximal segments of the VD. The results obtained in the present study suggest modality-dependent membrane specialization in M-cell dendrites suited for processing stimuli of different time domains and, more broadly, provide a compelling example of information processing in single neurons. © 2017 The Authors. The Journal of Physiology © 2017 The Physiological Society JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00223751_v596_n4_p667_Medan
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic cross-modal dendritic interaction
dendritic specialization
Mauthner cell
adult
animal cell
animal experiment
Article
auditory evoked potential
cell interaction
cell specificity
cell structure
controlled study
dendrite
Mauthner cell
neurophysiology
nonhuman
postsynaptic potential
priority journal
visual evoked potential
spellingShingle cross-modal dendritic interaction
dendritic specialization
Mauthner cell
adult
animal cell
animal experiment
Article
auditory evoked potential
cell interaction
cell specificity
cell structure
controlled study
dendrite
Mauthner cell
neurophysiology
nonhuman
postsynaptic potential
priority journal
visual evoked potential
Medan, V.
Mäki-Marttunen, T.
Sztarker, J.
Preuss, T.
Differential processing in modality-specific Mauthner cell dendrites
topic_facet cross-modal dendritic interaction
dendritic specialization
Mauthner cell
adult
animal cell
animal experiment
Article
auditory evoked potential
cell interaction
cell specificity
cell structure
controlled study
dendrite
Mauthner cell
neurophysiology
nonhuman
postsynaptic potential
priority journal
visual evoked potential
description Key points: The present study examines dendritic integrative processes that occur in many central neurons but have been challenging to study in vivo in the vertebrate brain. The Mauthner cell of goldfish receives auditory and visual information via two separate dendrites, providing a privileged scenario for in vivo examination of dendritic integration. The results show differential attenuation properties in the Mauthner cell dendrites arising at least partly from differences in cable properties and the nonlinear behaviour of the respective dendritic membranes. In addition to distinct modality-dependent membrane specialization in neighbouring dendrites of the Mauthner cell, we report cross-modal dendritic interactions via backpropagating postsynaptic potentials. Broadly, the results of the present study provide an exceptional example for the processing power of single neurons. Abstract: Animals process multimodal information for adaptive behavioural decisions. In fish, evasion of a diving bird that breaks the water surface depends on integrating visual and auditory stimuli with very different characteristics. How do neurons process such differential sensory inputs at the dendritic level? For that, we studied the Mauthner cells (M-cells) in the goldfish startle circuit, which receive visual and auditory inputs via two separate dendrites, both accessible for in vivo recordings. We investigated whether electrophysiological membrane properties and dendrite morphology, studied in vivo, play a role in selective sensory processing in the M-cell. The results obtained show that anatomical and electrophysiological differences between the dendrites combine to produce stronger attenuation of visually evoked postsynaptic potentials (PSPs) than to auditory evoked PSPs. Interestingly, our recordings showed also cross-modal dendritic interaction because auditory evoked PSPs invade the ventral dendrite (VD), as well as the opposite where visual PSPs invade the lateral dendrite (LD). However, these interactions were asymmetrical, with auditory PSPs being more prominent in the VD than visual PSPs in the LD. Modelling experiments imply that this asymmetry is caused by active conductances expressed in the proximal segments of the VD. The results obtained in the present study suggest modality-dependent membrane specialization in M-cell dendrites suited for processing stimuli of different time domains and, more broadly, provide a compelling example of information processing in single neurons. © 2017 The Authors. The Journal of Physiology © 2017 The Physiological Society
format JOUR
author Medan, V.
Mäki-Marttunen, T.
Sztarker, J.
Preuss, T.
author_facet Medan, V.
Mäki-Marttunen, T.
Sztarker, J.
Preuss, T.
author_sort Medan, V.
title Differential processing in modality-specific Mauthner cell dendrites
title_short Differential processing in modality-specific Mauthner cell dendrites
title_full Differential processing in modality-specific Mauthner cell dendrites
title_fullStr Differential processing in modality-specific Mauthner cell dendrites
title_full_unstemmed Differential processing in modality-specific Mauthner cell dendrites
title_sort differential processing in modality-specific mauthner cell dendrites
url http://hdl.handle.net/20.500.12110/paper_00223751_v596_n4_p667_Medan
work_keys_str_mv AT medanv differentialprocessinginmodalityspecificmauthnercelldendrites
AT makimarttunent differentialprocessinginmodalityspecificmauthnercelldendrites
AT sztarkerj differentialprocessinginmodalityspecificmauthnercelldendrites
AT preusst differentialprocessinginmodalityspecificmauthnercelldendrites
_version_ 1807323521672544256

Ejemplares similares