A synaptic organizing principle for cortical neuronal groups

Perin, Rodrigo; Berger, Thomas; Markram, Henry

doi:10.1073/pnas.1016051108

Cited by 624 publications

(907 citation statements)

References 69 publications

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“…5). Connections between bidirectionally connected pairs generated larger EPSPs than unidirectionally connected pairs, consistent with previous reports 3,4,17 , and the RF maps of bidirectionally connected neurons were significantly more correlated than RFs of unidirectionally connected or unconnected pairs (Extended Data Fig. 5).…”

supporting

confidence: 91%

Functional organization of excitatory synaptic strength in primary visual cortex

Cossell

Iacaruso

Muir

et al. 2015

Nature

491

656

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The strength of synaptic connections fundamentally determines how neurons influence each other's firing. Excitatory connection amplitudes between pairs of cortical neurons vary over two orders of magnitude, comprising only very few strong connections among many weaker ones [1][2][3][4][5][6][7][8][9] . Although this highly skewed distribution of connection strengths is observed in diverse cortical areas 1-9 , its functional significance remains unknown: it is not clear how connection strength relates to neuronal response properties, nor how strong and weak inputs contribute to information processing in local microcircuits. Here we reveal that the strength of connections between layer 2/3 (L2/3) pyramidal neurons in mouse primary visual cortex (V1) obeys a simple rule-the few strong connections occur between neurons with most correlated responses, while only weak connections link neurons with uncorrelated responses. Moreover, we show that strong and reciprocal connections occur between cells with similar spatial receptive field structure. Although weak connections far outnumber strong connections, each neuron receives the majority of its local excitation from a small number of strong inputs provided by the few neurons with similar responses to visual features. By dominating recurrent excitation, these infrequent yet powerful inputs disproportionately contribute to feature preference and selectivity. Therefore, our results show that the apparently complex organization of excitatory connection strength reflects the Reprints and permissions information is available at www.nature.com/reprints.

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supporting

confidence: 91%

Functional organization of excitatory synaptic strength in primary visual cortex

Cossell

Iacaruso

Muir

et al. 2015

Nature

491

656

View full text Add to dashboard Cite

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“…The connections and synaptic properties in the network models are established following distance-and cell type-dependent rules adopted from the literature (32)(33)(34)(35) as well as based on in-house data. Synaptic connections are established between neurons based on the locations of their cell bodies, with synapses placed randomly over the dendritic tree (dependent on the type of connection, such as excitatory to excitatory, inhibitory to excitatory, etc.…”

Section: Systems-level Models: Three Levels Of Granularitymentioning

confidence: 99%

Inferring cortical function in the mouse visual system through large-scale systems neuroscience

Hawrylycz

Anastassiou

Arkhipov

et al. 2016

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

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The scientific mission of the Project MindScope is to understand neocortex, the part of the mammalian brain that gives rise to perception, memory, intelligence, and consciousness. We seek to quantitatively evaluate the hypothesis that neocortex is a relatively homogeneous tissue, with smaller functional modules that perform a common computational function replicated across regions. We here focus on the mouse as a mammalian model organism with genetics, physiology, and behavior that can be readily studied and manipulated in the laboratory. We seek to describe the operation of cortical circuitry at the computational level by comprehensively cataloging and characterizing its cellular building blocks along with their dynamics and their cell type-specific connectivities. The project is also building large-scale experimental platforms (i.e., brain observatories) to record the activity of large populations of cortical neurons in behaving mice subject to visual stimuli. A primary goal is to understand the series of operations from visual input in the retina to behavior by observing and modeling the physical transformations of signals in the corticothalamic system. We here focus on the contribution that computer modeling and theory make to this long-term effort.T he neocortical sheet is a layered structure with a thickness that varies by a factor of two to three, whereas its surface area varies by 50,000 between the small smoky shrew and the massive blue whale. A unique hallmark of mammals, neocortex is a highly versatile, scalable, ∼2D computational tissue that excels at real time sensory processing across modalities and making and storing associations as well as planning and producing complex motor patterns. Neocortex consists of smaller modular units (columnar circuits that reach across the depth of cortex) broadly repeated iteratively across the cortical sheet. These modules vary considerably in their connectivity and properties between regions, with some controversy whether there is, indeed, a single canonical function performed by any and all neocortical columns.A deep understanding of cortex necessitates measuring relevant biophysical variables, such as recording action and membrane potentials, and relating them to genetically identified cell types. Mapping, observing, and intervening in widespread but highly specific cellular activity are more readily accomplished in the mouse, Mus musculus, than in the human brain. The brain of the laboratory mouse is more than three orders of magnitude smaller than the human brain in weight (0.4 vs. 1,350 g) and contains 71 million vs. 86 billion nerve cells for the entire brain and 14 million vs. 16 billion nerve cells for neocortex (1).The Allen Institute for Brain Science is engaged in a 10-y, highthroughput, milestone-driven effort to characterize all cortical cell types for the mouse cortex to build a small number of distinct experimental and computational platforms, called brain observatories, for studying behaving mice and to construct abstract and biophysically realisti...

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“…Regarding the neural correlate of memory, potential memory items were found, for example, in songbirds during song and recapitulation as stereotypical sequences of spike burst (Hahnloser et al 2002) or during a spatial task, as spatiotemporal patterns (Harris et al 2003) in the hippocampus. Additionally, typical connectivity structures, so-called motifs, were measured in the cortex (Song et al 2005;Perin et al 2011). However, it is not clear whether spatiotemporal patterns or motifs are memory items [or cell assemblies, see (6)] and whether they are subject to long-term plasticity as suggested by Hebb.…”

Section: Links Between Time Scales Of Memory and Physiologymentioning

confidence: 99%

Time scales of memory, learning, and plasticity

et al. 2012

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If we stored every bit of input, the storage capacity of our nervous system would be reached after only about 10 days. The nervous system relies on at least two mechanisms that counteract this capacity limit: compression and forgetting. But the latter mechanism needs to know how long an entity should be stored: some memories are relevant only for the next few minutes, some are important even after the passage of several years. Psychology and physiology have found and described many different memory mechanisms, and these mechanisms indeed use different time scales. In this prospect we review these mechanisms with respect to their time scale and propose relations between mechanisms in learning and memory and their underlying physiological basis.

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A synaptic organizing principle for cortical neuronal groups

Cited by 624 publications

References 69 publications

Functional organization of excitatory synaptic strength in primary visual cortex

Functional organization of excitatory synaptic strength in primary visual cortex

Inferring cortical function in the mouse visual system through large-scale systems neuroscience

Time scales of memory, learning, and plasticity

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