Pyramidal Cell-Interneuron Circuit Architecture and Dynamics in Hippocampal Networks

English, Daniel F.; McKenzie, Sam; Evans, Talfan; Kim, Kanghwan; Yoon, Euisik; Buzsáki, György

doi:10.1016/j.neuron.2017.09.033

Cited by 224 publications

(355 citation statements)

References 77 publications

(106 reference statements)

Supporting

Mentioning

304

Contrasting

Order By: Relevance

“…Next, we quantified the relationship between neuronal spiking and LFP in the gRSC. We isolated single units, which were classified as putative pyramidal neurons or interneurons 35 (Supplementary Fig. 2).…”

Section: Transient Ripple (140-200 Hz) Oscillations In the Grscmentioning

confidence: 99%

See 1 more Smart Citation

Propagation of Hippocampal Ripples to the Neocortex by Way of a Subiculum-Retrosplenial Pathway

Nitzan

McKenzie

Beed

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

SUMMARYBouts of high frequency activity known as sharp wave ripples (SPW-Rs) facilitate communication between the hippocampus and neocortex. However, the paths and mechanisms by which SPW-Rs broadcast their content are not well understood. Due to its anatomical positioning, the granular retrosplenial cortex (gRSC) may be a bridge for this hippocampo-cortical dialogue. Using silicon probe recordings in awake, head-fixed mice, we show the existence of SPW-R analogues in gRSC and demonstrate their coupling to hippocampal SPW-Rs. gRSC neurons reliably distinguished different subclasses of hippocampal SPW-Rs according to ensemble activity patterns in CA1. We demonstrate that this coupling is brain state-dependent, and delineate a topographically-organized anatomical pathway via VGlut2-expressing, bursty neurons in the subiculum. Optogenetic stimulation or inhibition of bursty subicular cells induced or reduced responses in superficial gRSC, respectively. These results identify a specific path and underlying mechanisms by which the hippocampus can convey neuronal content to the neocortex during SPW-Rs.

show abstract

Section: Transient Ripple (140-200 Hz) Oscillations In the Grscmentioning

confidence: 99%

“…Units with firing rate < 0.5 Hz or ISI violation > 0.01 were discarded. Units were separated into putative pyramids and interneurons based on the spike width, waveform asymmetry and firingrate using k-means 35 .…”

Section: Histological Processingmentioning

confidence: 99%

Propagation of Hippocampal Ripples to the Neocortex by Way of a Subiculum-Retrosplenial Pathway

Nitzan

McKenzie

Beed

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…We hypothesized that the changes in SWR participation of synaptically activated interneurons and the place field remapping, particularly of non-stimulated cells, was due to a reorganization of lateral inhibition. To explore this hypothesis, we examined spike transmission between pairs of monosynaptically connected pyramidal cells and interneurons (PYR-INT) 18 Methods) to measure changes in the influence of the presynaptic drive to the postsynaptic interneuron while regressing out changes in postsynaptic firing rate ( Figure 4A; Figure S4). We found that putative synaptic coupling strength, as approximated by our spike transmission measure, varied 64.7±0.5% around the mean over the recording session ( Figure 4A,B, Figure S4).…”

mentioning

confidence: 99%

Preexisting hippocampal network dynamics constrain optogenetically induced place fields

McKenzie

Huszár

English

et al. 2019

Preprint

Self Cite

View full text Add to dashboard Cite

Neuronal circuits face a fundamental tension between maintaining existing structure and changing to accommodate new information. Memory models often emphasize the need to encode novel patterns of neural activity imposed by "bottom-up" sensory drive. In such models, learning is achieved through synaptic alterations, a process which potentially interferes with previously stored knowledge 1-3 . Alternatively, neuronal circuits generate and maintain a preconfigured stable dynamic, sometimes referred to as an attractor, manifold, or schema 4-7 , with a large reservoir of patterns available for matching with novel experiences 8-13 . Here, we show that incorporation of arbitrary signals is constrained by preexisting circuit dynamics. We optogenetically stimulated small groups of hippocampal neurons as mice traversed a chosen segment of a linear track, mimicking the emergence of place fields 1,14,15 , while simultaneously recording the activity of stimulated and nonstimulated neighboring cells. Stimulation of principal neurons in CA1, but less so CA3 or the dentate gyrus, induced persistent place field remapping. Novel place fields emerged in both stimulated and non-stimulated neurons, which could be predicted from sporadic firing in the new place field location and the temporal relationship to peer neurons prior to the optogenetic perturbation. Circuit modification was reflected by altered spike transmission between connected pyramidal cell -inhibitory interneuron pairs, which persisted during post-experience sleep. We hypothesize that optogenetic perturbation unmasked subthreshold, pre-existing place fields 16,17 . Plasticity in recurrent/lateral inhibition may drive learning through rapid exploration of existing states.The ability for hippocampal circuits to imprint a random, novel pattern was tested in transgenic mice in which channelrhodopsin2 (ChR2) was expressed in excitatory neurons (N = 6 CaMKIIα-Cre:: Ai32 mice). Stimulation was achieved through μLED illumination 18 , which was delivered as mice ran on a linear track (1.2 m) for water reward ( Figure 1A). After ten baseline trials, stimulation (1s half sine wave) was given for one to ten trials (see Supplemental Table 1) at a fixed position and running direction that changed daily. Optogenetic stimulation induced highly focal drive in CA1 neurons (N = 715; rate change on stimulated shank, Wilcoxon signed-rank test p = 4.1 -183 , median number stimulated = 12 neurons , range 1-50 neurons), as pyramidal cells on the neighboring shanks (≥ 250μm away; N = 420) showed no increase in firing even at the highest stimulation intensity ( Figure S1, rate change on non-stim shank, Wilcoxon signed-rank test p = 0.40, median number stimulated = 0 neurons, range 0-5 neurons). On the track, pyramidal cells on the non-stimulated shanks were moderately suppressed in the stimulation zone, as compared to baseline, non-stimulated trials (mean rate change -0.10 ± 0.07 Hz, sign-test, p =7.34 -5 ). In CA3 and the dentate gyrus (DG), the activity of pyramidal neurons on neighboring sha...

show abstract

“…Modeling and experiments in-vitro suggest that pyramidal cells are more susceptible to polarization than are symmetrical interneurons 27,28 , so we tested whether this was evident in-vivo. We used the width of extracellularly recorded action potentials to segregate putative pyramidal neurons from non-pyramidal neurons, a common analysis that was recently validated by cell-type specific optogenetic stimulation 40 for these broad classes of neurons (but has limitations 41 ). Figure 3a shows that the distribution of spike waveform width is bimodal, and the average spike shape of each cluster (pyramidal "RS" cells: ≥250µs, N=1812) and blue (non-pyramidal "FS" cells: <250µs, N=859).…”

Section: Direction Of Modulation Depends On Cell Typementioning

confidence: 99%

“…Comparison between tDCS and Sham experiments were made using independent t-tests. The number of neurons N varied from session to session and we discarded any session with N<10 (experiments included; Monkey S: 59, Monkey W: 40), with N ranging from 10 to 54 with median of 27. Results for both monkeys were similar, and we combined experiments to increase power for statistical analysis.…”

Section: Neural Population Dynamics Dimensionality Reduction and Analmentioning

confidence: 99%

Cortical network mechanisms of anodal and cathodal transcranial direct current stimulation in awake primates

Bogaard

Lajoie

Boyd

et al. 2019

Preprint

View full text Add to dashboard Cite

words)Transcranial direct current stimulation (tDCS) is a non-invasive neuromodulation technique that is widely used to stimulate the sensorimotor cortex, and yet the mechanism by which it influences the natural activity of cortical networks is still under debate. Here, we characterize the effects of anodal and cathodal tDCS on underlying neurons in active macaque sensorimotor cortex across a range of doses. We find changes in spike rates that are sensitive to both current intensity and polarity, behavioral state, and that are cell-type specific. At high currents, effects persist after the offset of stimulation, and the spatiotemporal activity associated with motor activity of the contralateral limb, measured by dynamics of neural ensembles, are altered. These data suggest that tDCS induces reproducible and noticeable changes in cortical neuron activity and support the theory that it affects brain activity through a combination of single neuron polarization and network interactions.

show abstract

Pyramidal Cell-Interneuron Circuit Architecture and Dynamics in Hippocampal Networks

Cited by 224 publications

References 77 publications

Propagation of Hippocampal Ripples to the Neocortex by Way of a Subiculum-Retrosplenial Pathway

Propagation of Hippocampal Ripples to the Neocortex by Way of a Subiculum-Retrosplenial Pathway

Preexisting hippocampal network dynamics constrain optogenetically induced place fields

Cortical network mechanisms of anodal and cathodal transcranial direct current stimulation in awake primates

Contact Info

Product

Resources

About