Experience-dependent inhibitory plasticity is mediated by CCK+ basket cells in the developing dentate gyrus

Abstract: Early postnatal experience shapes both inhibitory and excitatory networks in the hippocampus. However, the underlying circuit plasticity is unclear. Using an enriched environment (EE) paradigm, we assessed the circuit plasticity of inhibitory cell-types in the hippocampus. We found that cholecystokinin (CCK)-expressing basket cells strongly increased somatic inhibition on the excitatory granular cells (GC) following EE while another pivotal inhibitory cell-type, parvalbumin (PV)-expressing cells did not show c… Show more

“…Additionally, the change between the two groups for SF and R metrics argues that the computation can be tuned by experience-dependent mechanisms. EE induces an increased excitatory and inhibitory drive in the DG circuit [ 1 , 3 ]. The increased excitatory drive can in turn reduce the sparsification of the signal in the DG by increasing the activity of the GC in response to EC imputs.…”

“…It is not clear, however, whether and to what extent these synaptic alterations support the tuning of the computational processes performed within a circuit. Using the enrichment housing paradigm in which juvenile mice are raised in large cages with toys, a running wheel, and diverse objects, we have recently shown that the experience-dependent plasticity of the hippocampal synaptic network is not homogeneous but rather affects specific microcircuits [ 3 ]. In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ].…”

“…Using the enrichment housing paradigm in which juvenile mice are raised in large cages with toys, a running wheel, and diverse objects, we have recently shown that the experience-dependent plasticity of the hippocampal synaptic network is not homogeneous but rather affects specific microcircuits [ 3 ]. In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ]. The specificity of this structural plasticity is quite remarkable, underscoring a key role for this cell type in adjusting inhibition during development and possibly the computation in DG circuit [ 3 ].…”

“…In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ]. The specificity of this structural plasticity is quite remarkable, underscoring a key role for this cell type in adjusting inhibition during development and possibly the computation in DG circuit [ 3 ]. The DG circuit is the gateway to the hippocampus, which plays an essential role in spatial navigation, social cognition and, learning and memory.…”

“…Considering that, for the most part, GC connectivity is hardwired [ 2 ], the emergence of this computation may be controlled by genetically encoded developmental programs. In light of our recent findings demonstrating experience-dependent remodeling of the inhibitory and excitatory networks in the circuit [ 3 ], it remains to be tested whether DG computation can be tuned in response to these plasticity mechanisms. In the present study, we asked whether DG computation is stable during postnatal development or adjusted in response to a change in the rodent’s environment.…”

Moderate effect of early-life experience on dentate gyrus function

“…Additionally, the change between the two groups for SF and R metrics argues that the computation can be tuned by experience-dependent mechanisms. EE induces an increased excitatory and inhibitory drive in the DG circuit [ 1 , 3 ]. The increased excitatory drive can in turn reduce the sparsification of the signal in the DG by increasing the activity of the GC in response to EC imputs.…”

“…It is not clear, however, whether and to what extent these synaptic alterations support the tuning of the computational processes performed within a circuit. Using the enrichment housing paradigm in which juvenile mice are raised in large cages with toys, a running wheel, and diverse objects, we have recently shown that the experience-dependent plasticity of the hippocampal synaptic network is not homogeneous but rather affects specific microcircuits [ 3 ]. In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ].…”

“…Using the enrichment housing paradigm in which juvenile mice are raised in large cages with toys, a running wheel, and diverse objects, we have recently shown that the experience-dependent plasticity of the hippocampal synaptic network is not homogeneous but rather affects specific microcircuits [ 3 ]. In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ]. The specificity of this structural plasticity is quite remarkable, underscoring a key role for this cell type in adjusting inhibition during development and possibly the computation in DG circuit [ 3 ].…”

“…In the dentate gyrus (DG) of mice raised in an enriched environment (EE), we found a robust increase in the inhibitory drive onto principal excitatory cells which was primarily mediated by the addition of somatic GABAergic synapses from the cholecystokinin expressing (CCK +) interneurons (IN) [ 3 ]. The specificity of this structural plasticity is quite remarkable, underscoring a key role for this cell type in adjusting inhibition during development and possibly the computation in DG circuit [ 3 ]. The DG circuit is the gateway to the hippocampus, which plays an essential role in spatial navigation, social cognition and, learning and memory.…”

“…Considering that, for the most part, GC connectivity is hardwired [ 2 ], the emergence of this computation may be controlled by genetically encoded developmental programs. In light of our recent findings demonstrating experience-dependent remodeling of the inhibitory and excitatory networks in the circuit [ 3 ], it remains to be tested whether DG computation can be tuned in response to these plasticity mechanisms. In the present study, we asked whether DG computation is stable during postnatal development or adjusted in response to a change in the rodent’s environment.…”

Moderate effect of early-life experience on dentate gyrus function