Generation of dense statistical connectomes from sparse morphological data

Egger, Robert; Dercksen, Vincent J.; Udvary, Daniel; Hege, Hans‐Christian; Oberlaender, Marcel

doi:10.3389/fnana.2014.00129

Cited by 54 publications

(97 citation statements)

References 74 publications

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“…As described previously (Egger et al., 2014) and reviewed in the Supplemental Information, a full-scale matrix of the probability of connections between all neurons in vS1 (“dense statistical connectome”) was generated on the basis of precisely measured 3D distributions of excitatory and inhibitory somata, which are non-uniform and cell-type specific even within L4 (Figure 5B), and 3D reconstructions of in vivo- and in vitro-labeled dendrite and axon morphologies, which are highly variable even within cell types (Figure 5C). Cell-type average connection probabilities have been validated (Egger et al., 2014) by comparison with studies that used paired recordings (Feldmeyer et al., 1999, Constantinople and Bruno, 2013) or correlated light and electron microscopy (Schoonover et al., 2014). …”

Section: Resultsmentioning

confidence: 99%

“…There is strong anatomical evidence that the L4 barrel comprises a relatively complete local network, with axons and dendrites of both excitatory and inhibitory neurons remaining largely restricted to the barrel, and thalamic ventral posteromedial nucleus (VPM) axons defining the barrel boundaries. Using a statistical connectivity model based on reconstructions of the detailed 3D anatomy of the barrel cortex (Egger et al., 2014), we provide realistic estimates of the heterogeneity in input connectivity in the local L4 circuits (i.e., within the barrel) and study the resulting dynamics in an anatomically constrained network of linear integrate-and-fire (LIF) point neurons (Gerstner and Kistler, 2002). We find that non-uniformities in the distributions of excitatory and inhibitory somata (Meyer et al., 2013), and morphological diversity within and across L4 cell types (Koelbl et al., 2015, Narayanan et al., 2015) yield substantial heterogeneity in input connectivity.…”

Section: Introductionmentioning

confidence: 99%

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The Impact of Structural Heterogeneity on Excitation-Inhibition Balance in Cortical Networks

Landau

Egger

Dercksen

et al. 2016

Neuron

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SummaryModels of cortical dynamics often assume a homogeneous connectivity structure. However, we show that heterogeneous input connectivity can prevent the dynamic balance between excitation and inhibition, a hallmark of cortical dynamics, and yield unrealistically sparse and temporally regular firing. Anatomically based estimates of the connectivity of layer 4 (L4) rat barrel cortex and numerical simulations of this circuit indicate that the local network possesses substantial heterogeneity in input connectivity, sufficient to disrupt excitation-inhibition balance. We show that homeostatic plasticity in inhibitory synapses can align the functional connectivity to compensate for structural heterogeneity. Alternatively, spike-frequency adaptation can give rise to a novel state in which local firing rates adjust dynamically so that adaptation currents and synaptic inputs are balanced. This theory is supported by simulations of L4 barrel cortex during spontaneous and stimulus-evoked conditions. Our study shows how synaptic and cellular mechanisms yield fluctuation-driven dynamics despite structural heterogeneity in cortical circuits.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Impact of Structural Heterogeneity on Excitation-Inhibition Balance in Cortical Networks

Landau

Egger

Dercksen

et al. 2016

Neuron

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130

160

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“…Using this combination, we estimated the synaptic inputs impinging onto L2 PNs in rat vS1. We generated synaptic input maps by calculating the structural overlap between the dendrites of a representative L2 PN morphology and a dense statistical model of the cell type-specific axon/bouton distributions in rat vS1 (9). The number of synaptic contacts was further multiplied with in vivo-recorded AP probabilities of the respective PN cell types (7).…”

Section: Discussionmentioning

confidence: 99%

“…These data, acquired under the same experimental conditions as previously used to determine whisker-evoked spiking and 3D morphologies for PN cell types (7), were used to inform and constrain simulation experiments. Specifically, we converted the 3D soma/dendrite morphology of an in vivo-labeled L2 PN into a biophysically detailed full-compartmental model (8) and integrated the neuron model into a recently reported detailed reconstruction of the excitatory circuitry in vS1 (9). This integration enabled us to statistically measure the number and subcellular distribution of cell type-specific synaptic contacts impinging onto the exemplary L2 PN from L1 INs and L2-5 PNs, respectively.…”

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confidence: 99%

Robustness of sensory-evoked excitation is increased by inhibitory inputs to distal apical tuft dendrites

Egger

Schmitt

Wallace

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Cortical inhibitory interneurons (INs) are subdivided into a variety of morphologically and functionally specialized cell types. How the respective specific properties translate into mechanisms that regulate sensory-evoked responses of pyramidal neurons (PNs) remains unknown. Here, we investigated how INs located in cortical layer 1 (L1) of rat barrel cortex affect whisker-evoked responses of L2 PNs. To do so we combined in vivo electrophysiology and morphological reconstructions with computational modeling. We show that whisker-evoked membrane depolarization in L2 PNs arises from highly specialized spatiotemporal synaptic input patterns. Temporally L1 INs and L2-5 PNs provide near synchronous synaptic input. Spatially synaptic contacts from L1 INs target distal apical tuft dendrites, whereas PNs primarily innervate basal and proximal apical dendrites. Simulations of such constrained synaptic input patterns predicted that inactivation of L1 INs increases trial-to-trial variability of whisker-evoked responses in L2 PNs. The in silico predictions were confirmed in vivo by L1-specific pharmacological manipulations. We present a mechanism-consistent with the theory of distal dendritic shunting-that can regulate the robustness of sensory-evoked responses in PNs without affecting response amplitude or latency.echanistic understanding of the principles that underlie sensory-evoked neuronal responses remains a key challenge in neuroscience research. Although electrophysiological and optical imaging techniques provide access to activity patterns of individual and/or populations of neurons in live animals, information about the organization of the underlying synaptic input patterns that drive neuronal activity remains scarce. Here, we investigate the mechanisms underlying whisker deflection-evoked responses in pyramidal neurons (PNs) in the vibrissal part of rat primary somatosensory cortex (vS1, i.e., barrel cortex) (1). Specifically, we wanted to know whether and how L1 interneurons (INs) shape responses of L2 PNs. L1 is densely populated by apical tuft dendrites from multiple types of excitatory PNs and a sparse population of GABAergic INs (2). Recent studies in acute parasagittal (3) and coronal (4) brain slices in vitro have shown that L1 INs have axonal projections largely confined to L1, where they form synaptic connections with the dendrites from PNs located in L2/3 (5) and L5 (4). These connections place L1 INs in a perfect position to manipulate the activity of PNs, for example, by feed-forward inhibition and/or more indirect mechanisms such as disinhibition (4, 6). However, the influence of L1 INs on the sensory-evoked responses of PNs remains unclear.To address this, we performed whole-cell patch-clamp recordings in vivo and reconstructed the 3D morphologies of the recorded L1 INs. These data, acquired under the same experimental conditions as previously used to determine whisker-evoked spiking and 3D morphologies for PN cell types (7), were used to inform and constrain simulation experiments. Specifically, we...

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“…The proportion of axonal pathlength both within HVC and within a 200 µm radius from the soma was computed in Amira for each neuron using the ZIB extension package (Egger et al, 2014). Axonal boutons and dendritic spines were annotated manually in Amira using high-resolution LM stacks.…”

Section: Methodsmentioning

confidence: 99%

EM connectomics reveals axonal target variation in a sequence-generating network

Kornfeld

Benezra

Narayanan

et al. 2017

eLife

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108

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The sequential activation of neurons has been observed in various areas of the brain, but in no case is the underlying network structure well understood. Here we examined the circuit anatomy of zebra finch HVC, a cortical region that generates sequences underlying the temporal progression of the song. We combined serial block-face electron microscopy with light microscopy to determine the cell types targeted by HVC(RA) neurons, which control song timing. Close to their soma, axons almost exclusively targeted inhibitory interneurons, consistent with what had been found with electrical recordings from pairs of cells. Conversely, far from the soma the targets were mostly other excitatory neurons, about half of these being other HVC(RA) cells. Both observations are consistent with the notion that the neural sequences that pace the song are generated by global synaptic chains in HVC embedded within local inhibitory networks.DOI: http://dx.doi.org/10.7554/eLife.24364.001

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Generation of dense statistical connectomes from sparse morphological data

Cited by 54 publications

References 74 publications

The Impact of Structural Heterogeneity on Excitation-Inhibition Balance in Cortical Networks

The Impact of Structural Heterogeneity on Excitation-Inhibition Balance in Cortical Networks

Robustness of sensory-evoked excitation is increased by inhibitory inputs to distal apical tuft dendrites

EM connectomics reveals axonal target variation in a sequence-generating network

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