A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex

Giuseppe Chindemi; Marwan Abdellah; Oren Amsalem; Ruth Benavides-Piccione; Vincent Delattre; Michael Doron; András Ecker; Aurélien T. Jaquier; James King; Pramod Kumbhar; Caitlin Monney; Rodrigo Perin; Christian Rössert; Anil M. Tuncel; Werner Van Geit; Javier DeFelipe; Michael Graupner; Idan Segev; Henry Markram; Eilif B. Muller

doi:10.1038/s41467-022-30214-w

A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex

Giuseppe Chindemi^*, Marwan Abdellah, Oren Amsalem, Ruth Benavides-Piccione, Vincent Delattre, Michael Doron, András Ecker, Aurélien T. Jaquier, James King, Pramod Kumbhar, Caitlin Monney, Rodrigo Perin, Christian Rössert, Anil M. Tuncel, Werner Van Geit, Javier DeFelipe, Michael Graupner, Idan Segev, Henry Markram, Eilif B. Muller^*

^*Corresponding author for this work

Alexander Silberman Institute of Life Sciences

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

Pyramidal cells (PCs) form the backbone of the layered structure of the neocortex, and plasticity of their synapses is thought to underlie learning in the brain. However, such long-term synaptic changes have been experimentally characterized between only a few types of PCs, posing a significant barrier for studying neocortical learning mechanisms. Here we introduce a model of synaptic plasticity based on data-constrained postsynaptic calcium dynamics, and show in a neocortical microcircuit model that a single parameter set is sufficient to unify the available experimental findings on long-term potentiation (LTP) and long-term depression (LTD) of PC connections. In particular, we find that the diverse plasticity outcomes across the different PC types can be explained by cell-type-specific synaptic physiology, cell morphology and innervation patterns, without requiring type-specific plasticity. Generalizing the model to in vivo extracellular calcium concentrations, we predict qualitatively different plasticity dynamics from those observed in vitro. This work provides a first comprehensive null model for LTP/LTD between neocortical PC types in vivo, and an open framework for further developing models of cortical synaptic plasticity.

Original language	English
Article number	3038
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-30214-w
State	Published - Dec 2022

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© 2022, The Author(s).

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Chindemi, G., Abdellah, M., Amsalem, O., Benavides-Piccione, R., Delattre, V., Doron, M., Ecker, A., Jaquier, A. T., King, J., Kumbhar, P., Monney, C., Perin, R., Rössert, C., Tuncel, A. M., Van Geit, W., DeFelipe, J., Graupner, M., Segev, I., Markram, H., & Muller, E. B. (2022). A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex. Nature Communications, 13(1), Article 3038. https://doi.org/10.1038/s41467-022-30214-w

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title = "A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex",

abstract = "Pyramidal cells (PCs) form the backbone of the layered structure of the neocortex, and plasticity of their synapses is thought to underlie learning in the brain. However, such long-term synaptic changes have been experimentally characterized between only a few types of PCs, posing a significant barrier for studying neocortical learning mechanisms. Here we introduce a model of synaptic plasticity based on data-constrained postsynaptic calcium dynamics, and show in a neocortical microcircuit model that a single parameter set is sufficient to unify the available experimental findings on long-term potentiation (LTP) and long-term depression (LTD) of PC connections. In particular, we find that the diverse plasticity outcomes across the different PC types can be explained by cell-type-specific synaptic physiology, cell morphology and innervation patterns, without requiring type-specific plasticity. Generalizing the model to in vivo extracellular calcium concentrations, we predict qualitatively different plasticity dynamics from those observed in vitro. This work provides a first comprehensive null model for LTP/LTD between neocortical PC types in vivo, and an open framework for further developing models of cortical synaptic plasticity.",

author = "Giuseppe Chindemi and Marwan Abdellah and Oren Amsalem and Ruth Benavides-Piccione and Vincent Delattre and Michael Doron and Andr{\'a}s Ecker and Jaquier, {Aur{\'e}lien T.} and James King and Pramod Kumbhar and Caitlin Monney and Rodrigo Perin and Christian R{\"o}ssert and Tuncel, {Anil M.} and {Van Geit}, Werner and Javier DeFelipe and Michael Graupner and Idan Segev and Henry Markram and Muller, {Eilif B.}",

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year = "2022",

month = dec,

doi = "10.1038/s41467-022-30214-w",

language = "אנגלית",

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Chindemi, G, Abdellah, M, Amsalem, O, Benavides-Piccione, R, Delattre, V, Doron, M, Ecker, A, Jaquier, AT, King, J, Kumbhar, P, Monney, C, Perin, R, Rössert, C, Tuncel, AM, Van Geit, W, DeFelipe, J, Graupner, M, Segev, I, Markram, H & Muller, EB 2022, 'A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex', Nature Communications, vol. 13, no. 1, 3038. https://doi.org/10.1038/s41467-022-30214-w

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T1 - A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex

AU - Chindemi, Giuseppe

AU - Abdellah, Marwan

AU - Amsalem, Oren

AU - Benavides-Piccione, Ruth

AU - Delattre, Vincent

AU - Doron, Michael

AU - Ecker, András

AU - Jaquier, Aurélien T.

AU - King, James

AU - Kumbhar, Pramod

AU - Monney, Caitlin

AU - Perin, Rodrigo

AU - Rössert, Christian

AU - Tuncel, Anil M.

AU - Van Geit, Werner

AU - DeFelipe, Javier

AU - Graupner, Michael

AU - Segev, Idan

AU - Markram, Henry

AU - Muller, Eilif B.

PY - 2022/12

Y1 - 2022/12

N2 - Pyramidal cells (PCs) form the backbone of the layered structure of the neocortex, and plasticity of their synapses is thought to underlie learning in the brain. However, such long-term synaptic changes have been experimentally characterized between only a few types of PCs, posing a significant barrier for studying neocortical learning mechanisms. Here we introduce a model of synaptic plasticity based on data-constrained postsynaptic calcium dynamics, and show in a neocortical microcircuit model that a single parameter set is sufficient to unify the available experimental findings on long-term potentiation (LTP) and long-term depression (LTD) of PC connections. In particular, we find that the diverse plasticity outcomes across the different PC types can be explained by cell-type-specific synaptic physiology, cell morphology and innervation patterns, without requiring type-specific plasticity. Generalizing the model to in vivo extracellular calcium concentrations, we predict qualitatively different plasticity dynamics from those observed in vitro. This work provides a first comprehensive null model for LTP/LTD between neocortical PC types in vivo, and an open framework for further developing models of cortical synaptic plasticity.

AB - Pyramidal cells (PCs) form the backbone of the layered structure of the neocortex, and plasticity of their synapses is thought to underlie learning in the brain. However, such long-term synaptic changes have been experimentally characterized between only a few types of PCs, posing a significant barrier for studying neocortical learning mechanisms. Here we introduce a model of synaptic plasticity based on data-constrained postsynaptic calcium dynamics, and show in a neocortical microcircuit model that a single parameter set is sufficient to unify the available experimental findings on long-term potentiation (LTP) and long-term depression (LTD) of PC connections. In particular, we find that the diverse plasticity outcomes across the different PC types can be explained by cell-type-specific synaptic physiology, cell morphology and innervation patterns, without requiring type-specific plasticity. Generalizing the model to in vivo extracellular calcium concentrations, we predict qualitatively different plasticity dynamics from those observed in vitro. This work provides a first comprehensive null model for LTP/LTD between neocortical PC types in vivo, and an open framework for further developing models of cortical synaptic plasticity.

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A calcium-based plasticity model for predicting long-term potentiation and depression in the neocortex

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