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From single cells and single columns to cortical networks: dendritic excitability, coincidence detection and synaptic transmission in brain slices and brains

Although patch pipettes were initially designed to record extracellularly the elementary current events from muscle and neuron membranes, the whole‐cell and loose cell‐attached recording configurations proved to be useful tools for examination of signalling within and between nerve cells. In this Pa...

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Detalles Bibliográficos
Autor principal: Sakmann, Bert
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2017
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5435930/
https://www.ncbi.nlm.nih.gov/pubmed/28139019
http://dx.doi.org/10.1113/EP085776
Descripción
Sumario:Although patch pipettes were initially designed to record extracellularly the elementary current events from muscle and neuron membranes, the whole‐cell and loose cell‐attached recording configurations proved to be useful tools for examination of signalling within and between nerve cells. In this Paton Prize Lecture, I will initially summarize work on electrical signalling within single neurons, describing communication between the dendritic compartments, soma and nerve terminals via forward‐ and backward‐propagating action potentials. The newly discovered dendritic excitability endows neurons with the capacity for coincidence detection of spatially separated subthreshold inputs. When these are occurring during a time window of tens of milliseconds, this information is broadcast to other cells by the initiation of bursts of action potentials (AP bursts). The occurrence of AP bursts critically impacts signalling between neurons that are controlled by target‐cell‐specific transmitter release mechanisms at downstream synapses even in different terminals of the same neuron. This can, in turn, induce mechanisms that underly synaptic plasticity when AP bursts occur within a short time window, both presynaptically in terminals and postsynaptically in dendrites. A fundamental question that arises from these findings is: ‘what are the possible functions of active dendritic excitability with respect to network dynamics in the intact cortex of behaving animals?’ To answer this question, I highlight in this review the functional and anatomical architectures of an average cortical column in the vibrissal (whisker) field of the somatosensory cortex (vS1), with an emphasis on the functions of layer 5 thick‐tufted cells (L5tt) embedded in this structure. Sensory‐evoked synaptic and action potential responses of these major cortical output neurons are compared with responses in the afferent pathway, viz. the neurons in primary somatosensory thalamus and in one of their efferent targets, the secondary somatosensory thalamus. Coincidence‐detection mechanisms appear to be implemented in vivo as judged from the occurrence of AP bursts. Three‐dimensional reconstructions of anatomical projections suggest that inputs of several combinations of thalamocortical projections and intra‐ and transcolumnar connections, specifically those from infragranular layers, could trigger active dendritic mechanisms that generate AP bursts. Finally, recordings from target cells of a column reveal the importance of AP bursts for signal transfer to these cells. The observations lead to the hypothesis that in vS1 cortex, the sensory afferent sensory code is transformed, at least in part, from a rate to an interval (burst) code that broadcasts the occurrence of whisker touch to different targets of L5tt cells. In addition, the occurrence of pre‐ and postsynaptic AP bursts may, in the long run, alter touch representation in cortex.