Manipulating Hippocampal Place Cell Activity by Single-Cell Stimulation in Freely Moving Mice

Diamantaki, Maria; Coletta, Stefano; Nasr, Khaled; Zeraati, R; Laturnus, Sophie; Berens, Philipp; Preston-Ferrer, Patricia; Burgalossi, Andrea

doi:10.1016/j.celrep.2018.03.031

Cited by 73 publications

(98 citation statements)

References 51 publications

(84 reference statements)

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“…Previous studies in CA1 have shown that a single episode of intracellular stimulation, that is strong enough to evoke complex spikes associated with dendritic plateau potentials, can create a new place field at the stimulation location in head‐fixed mice (Bittner et al, ; Bittner, Milstein, Grienberger, Romani, & Magee, ). A recent study also has shown that juxtacellular stimulation, that is strong enough to induce complex spikes in CA3 or CA1 neurons, can create a new place field at the stimulation location in freely‐moving mice (Diamantaki et al, ). The stimulation effects on CA3 versus CA1 neurons were not compared quantitatively in this study, hence it is unclear whether and how spatial firing stability differs between CA3 and CA1 neurons.…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies have shown more stable spatial firing in CA3 than CA1 over time (Mankin et al, ; Manns, Howard, & Eichenbaum, ) and in response to ventral tegmental area stimulation (Martig & Mizumori, ) and reward location changes (Dupret, O'Neill, Pleydell‐Bouverie, & Csicsvari, ). Nevertheless, the study by Diamantaki et al () suggests that it is possible to induce long‐lasting changes in CA3 spatial firing by artificially activating CA3 pyramidal neurons. Our mossy fiber stimulations may have failed to create permanent place fields because they came short of generating sufficiently strong complex spikes, even at 50 Hz, due to accordingly increased feedforward inhibition.…”

Section: Discussionmentioning

confidence: 99%

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Transient effect of mossy fiber stimulation on spatial firing of CA3 neurons

et al. 2019

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Strong hippocampal mossy fiber synapses are thought to function as detonators, imposing “teaching” signals onto CA3 neurons during new memory formation. For an empirical test of this long‐standing view, we examined effects of optogenetically stimulating mossy fibers on spatial firing of CA3 neurons in freely‐moving mice. We found that spatially restricted mossy fiber stimulation drives novel place‐specific firing in some CA3 pyramidal neurons. Such neurons comprise only a minority, however, and many more CA3 neurons showed inhibited spatial firing during mossy fiber stimulation. Also, changes in spatial firing induced by mossy fiber stimulation, both activated and inhibited, reverted immediately upon stimulation termination, leaving CA3 place fields unaltered. Our results do not support the traditional view that mossy fibers impose teaching signals onto CA3 network, and show robustness of established CA3 spatial representations.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Transient effect of mossy fiber stimulation on spatial firing of CA3 neurons

et al. 2019

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“…9 When both initial ramp amplitude and relative input timing are considered, it is apparent 10 that the preferred conditions for large synaptic depression are that spatial inputs 1) have 11 already been strengthened by previous plasticity, resulting in elevated postsynaptic 12 depolarization at the time of presynaptic spikes, and 2) are activated within a time window 13 ~2 -4 seconds away from a plateau ( Fig. 1J, trace color indicates initial ramp amplitude; 14 Fig 1K; two-dimensional interpolation from data, trace color indicates change in ramp 15 amplitude, see Materials and Methods). In summary, BTSP can either strengthen or 16 weaken synapses in a small number of trials, providing a bidirectional learning 17 mechanism capable of both rapid memory storage and erasure.…”

Section: D)mentioning

confidence: 99%

“…To account for the long time course of BTSP, both models (1,3,15,16,18). 13 Biologically, these traces could correspond to the enzymatic activity of calcium- 14 dependent kinases and phosphatases, and post-translational modification and synaptic 15 localization of proteins that regulate synaptic function (18)(19)(20)(21)(22)(23). While in the voltage- 16 dependent model, the amplitudes of these eligibility signals were modulated by the 17 value of postsynaptic depolarization at the time of presynaptic activation ( Fig.…”

Section: D)mentioning

confidence: 99%

“…However, the two models made 11 qualitatively different predictions about the causal role of the activation state of the 12 postsynaptic neuron in controlling the magnitude and direction of plasticity. While in the 13 voltage-dependent model, correlation between presynaptic activity and postsynaptic 14 depolarization influences the sign of plasticity, in the alternative model, the sign of 15 plasticity is independent of postsynaptic voltage, and is modulated instead by current 16 synaptic weight such that weak synapses tend to potentiate and strong synapses tend to 17 depress (3,(24)(25)(26)(27)(28)(29). 18 We next sought to distinguish between the two model classes with an in vivo 19 perturbation experiment where neuronal Vm was experimentally depolarized by 20 intracellular current injection during plasticity induction trials.…”

Section: D)mentioning

confidence: 99%

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Bidirectional synaptic plasticity rapidly modifies hippocampal representations

Milstein

Bittner

et al. 2020

Preprint

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15According to standard models of synaptic plasticity, correlated activity between 16 connected neurons drives changes in synaptic strengths to store associative 17 memories. Here we tested this hypothesis in vivo by manipulating the activity of 18 hippocampal place cells and measuring the resulting changes in spatial selectivity. 19 We found that the spatial tuning of place cells was rapidly reshaped via 20 bidirectional synaptic plasticity. To account for the magnitude and direction of 21 plasticity, we evaluated two models -a standard model that depended on 22 synchronous pre-and post-synaptic activity, and an alternative model that 23 1 depended instead on whether active synaptic inputs had previously been 1 potentiated. While both models accounted equally well for the data, they predicted 2 opposite outcomes of a perturbation experiment, which ruled out the standard 3 correlation-dependent model. Finally, network modeling suggested that this form 4 of bidirectional synaptic plasticity enables population activity, rather than pairwise 5 neuronal correlations, to drive plasticity in response to changes in the 6 environment. 7 8 Main Text 9 Activity-dependent changes in synaptic strength can flexibly alter the selectivity of 10 neuronal firing for particular features of the environment, providing a cellular substrate for 11 learning and memory. Various forms of Hebbian synaptic plasticity have been considered 12 for decades to be the main or even only synaptic plasticity mechanisms present within 13 most brain regions of a number of species. The core feature of such plasticity 14mechanisms is that they are autonomously driven by the repeated presence of correlated 15 presynaptic and postsynaptic activity that leads to either increases or decreases in 16 synaptic strength depending on the exact temporal coincidence (1-4). 17 The hippocampus plays an important role in many forms of learning and memory, 18 and the spatial firing rates of hippocampal place cells have been shown to change with 19 alterations in environmental context or the locations of salient features, like reward (5-20 11). Furthermore in CA1 neurons, place cell activity can emerge in a single trial following 21 a dendritic calcium spike (also called a plateau potential) (12-14). The form of synaptic 22 plasticity responsible for this rapid change in selectivity, termed behavioral timescale 23 2 synaptic plasticity (BTSP), modifies synaptic inputs active within a multi-second time 1 window around the plateau potential. That BTSP strengthens many synaptic inputs whose 2 activation did not cause or even coincide with postsynaptic activity suggests that it might 3 be a fundamentally different form of plasticity than classical correlation-driven Hebbian 4 plasticity (1-3). Such a plasticity rule could enable representation learning in cortical brain 5 regions like the hippocampus to be guided by delayed behavioral outcomes, rather than 6 by short timescale associations of neuronal input and output. However, it was not clear 7 from previous experiments...

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Single-neuron detection of place cells remapping in short-term memory using motion microelectrode arrays

Yang

et al. 2022

Biosensors and Bioelectronics

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Manipulating Hippocampal Place Cell Activity by Single-Cell Stimulation in Freely Moving Mice

Cited by 73 publications

References 51 publications

Transient effect of mossy fiber stimulation on spatial firing of CA3 neurons

Transient effect of mossy fiber stimulation on spatial firing of CA3 neurons

Bidirectional synaptic plasticity rapidly modifies hippocampal representations

Single-neuron detection of place cells remapping in short-term memory using motion microelectrode arrays

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