Summary
An expectant mother’s brain undergoes dramatic structural remodeling during pregnancy. These changes are thought to be elicited by hormones, orchestrating the behavioural and physiological adaptations necessary for infant care. Despite the scale of these effects, we know little about the neural mechanisms by which pregnancy affects the brain. Recent methodological advances now offer the exciting opportunity to address these questions. This project will use a multidisciplinary approach to uncover the molecular, cellular and circuit-level mechanisms of pregnancy hormone action in a mouse model.
We will first focus on which aspects of parenting, feeding and aggression are affected by pregnancy – and over which time course these behavioural adaptations occur. This will provide important clues about the nature of underlying neural plasticity mechanisms. Next, we will determine which nodes of the circuits controlling these behaviours are sensitive to pregnancy hormones. This will then allow us to address the functional consequences of pregnancy at the network level, using in vivo calcium imaging approaches. Finally, we will study the biophysical and cellular mechanisms underlying pregnancy hormone action in genetically defined neurons, through a combination of electrophysiology and transcriptomic profiling.
By integrating these complementary lines of evidence, we aim to obtain a mechanistic understanding of the neural adaptations occurring during pregnancy. I believe that these innovative studies will generate novel and highly generalizable insights into how physiological states shape information processing in the brain.
We will first focus on which aspects of parenting, feeding and aggression are affected by pregnancy – and over which time course these behavioural adaptations occur. This will provide important clues about the nature of underlying neural plasticity mechanisms. Next, we will determine which nodes of the circuits controlling these behaviours are sensitive to pregnancy hormones. This will then allow us to address the functional consequences of pregnancy at the network level, using in vivo calcium imaging approaches. Finally, we will study the biophysical and cellular mechanisms underlying pregnancy hormone action in genetically defined neurons, through a combination of electrophysiology and transcriptomic profiling.
By integrating these complementary lines of evidence, we aim to obtain a mechanistic understanding of the neural adaptations occurring during pregnancy. I believe that these innovative studies will generate novel and highly generalizable insights into how physiological states shape information processing in the brain.
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/847873 |
Start date: | 01-12-2019 |
End date: | 31-05-2025 |
Total budget - Public funding: | 1 494 393,00 Euro - 1 494 393,00 Euro |
Cordis data
Original description
An expectant mother’s brain undergoes dramatic structural remodeling during pregnancy. These changes are thought to be elicited by hormones, orchestrating the behavioural and physiological adaptations necessary for infant care. Despite the scale of these effects, we know little about the neural mechanisms by which pregnancy affects the brain. Recent methodological advances now offer the exciting opportunity to address these questions. This project will use a multidisciplinary approach to uncover the molecular, cellular and circuit-level mechanisms of pregnancy hormone action in a mouse model.We will first focus on which aspects of parenting, feeding and aggression are affected by pregnancy – and over which time course these behavioural adaptations occur. This will provide important clues about the nature of underlying neural plasticity mechanisms. Next, we will determine which nodes of the circuits controlling these behaviours are sensitive to pregnancy hormones. This will then allow us to address the functional consequences of pregnancy at the network level, using in vivo calcium imaging approaches. Finally, we will study the biophysical and cellular mechanisms underlying pregnancy hormone action in genetically defined neurons, through a combination of electrophysiology and transcriptomic profiling.
By integrating these complementary lines of evidence, we aim to obtain a mechanistic understanding of the neural adaptations occurring during pregnancy. I believe that these innovative studies will generate novel and highly generalizable insights into how physiological states shape information processing in the brain.
Status
SIGNEDCall topic
ERC-2019-STGUpdate Date
27-04-2024
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