Population coupling predicts the plasticity of stimulus responses in cortical circuits

Sweeney, Yann; Clopath, Claudia

doi:10.7554/elife.56053

Cited by 27 publications

(22 citation statements)

References 50 publications

(97 reference statements)

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“…Comparisons of how mouse and non-human primate brains differ and are similar have a long history in neuroscience, ranging from how neurons in similar brain regions respond to similar stimuli (Huberman and Niell, 2011;Sanzeni and Histed, 2020;Segev, 1992;Sweeney and Clopath, 2020;Van Hooser, 2007; to differences in the sizes of brain regions (Van Essen et al, 2018). The prior work perhaps most relevant is generally of two varieties: measurements of bulk synaptic density in neuropil (i.e., synapses/mm 3 ) in smaller volumes using EM (Ascoli et al, 2008;DeFelipe et al, 1999DeFelipe et al, , 2002Hsu et al, 2017;McGuire et al, 1991;Medalla and Luebke, 2015;Peters et al, 2008;Sherwood et al, 2020) and optical methods, particularly in primates, whereby neurons in living slices are filled and spines are counted as proxies of excitatory innervation (Gilman et al, 2017;Luebke et al, 2004;Luebke and Rosene, 2003;McGuire et al, 1991;Medalla and Luebke, 2015).…”

Section: Comparison With Previous Workmentioning

confidence: 99%

Primate neuronal connections are sparse in cortex as compared to mouse

et al. 2021

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Section: Comparison With Previous Workmentioning

confidence: 99%

Primate neuronal connections are sparse in cortex as compared to mouse

et al. 2021

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“…Additionally, modeling work has suggested that repeated offline reactivation of specific ensembles could maintain potentiated synaptic weights ( Fauth and van Rossum, 2019 ). Thus, long-term memories may be supported by a ‘backbone’ of stable spines and neurons that store gross features while the remainder might continually undergo plasticity to encode more detailed representations ( Buzsáki and Mizuseki, 2014 ; Grosmark and Buzsaki, 2016 ; Sweeney and Clopath, 2020 ). A complementary ‘memory indexing’ theory has proposed that hippocampal neurons reinstate neocortical activity patterns for memory retrieval ( Goode et al, 2020 ; Tanaka et al, 2018 ; Teyler and DiScenna, 1986 ).…”

Section: Introductionmentioning

confidence: 99%

The brain in motion: How ensemble fluidity drives memory-updating and flexibility

Mau

Hasselmo

Cai

2020

eLife

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While memories are often thought of as flashbacks to a previous experience, they do not simply conserve veridical representations of the past but must continually integrate new information to ensure survival in dynamic environments. Therefore, ‘drift’ in neural firing patterns, typically construed as disruptive ‘instability’ or an undesirable consequence of noise, may actually be useful for updating memories. In our view, continual modifications in memory representations reconcile classical theories of stable memory traces with neural drift. Here we review how memory representations are updated through dynamic recruitment of neuronal ensembles on the basis of excitability and functional connectivity at the time of learning. Overall, we emphasize the importance of considering memories not as static entities, but instead as flexible network states that reactivate and evolve across time and experience.

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“…neurons (Wang et al, 2016) for both visual stimuli and optogenetic manipulations (Sanzeni and Histed, 2020;Sweeney and Clopath, 2020). A simple potential explanation from our data suggests that feature extraction could be mediated by the pattern of inhibitory innervation, relatively similar across species, but that the magnitude of responses are encoded by the absolute number of connections, substantially different across species.…”

Section: Functional Implicationsmentioning

confidence: 79%

Primate neuronal connections are sparse as compared to mouse

Wildenberg

Rosen

Lundell

et al. 2020

Preprint

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Detailing how primate and mouse neurons differ is critical to understanding how brains evolve and for translating findings from mice into humans. However, scarce data about neuronal connections, particularly in primates, makes such comparisons difficult. We use large volume electron microscopy to address this gap, reconstructing 11,415 synapses onto morphologically equivalent adult primate and mouse neurons in Layer 2/3 of primary visual cortex (V1). Neurons from both species distribute in cortex at similar densities, have similar somatic volumes, and dendritic branching patterns, but primate excitatory and inhibitory neurons receive ∼4 times fewer excitatory and inhibitory connections than equivalent mouse neurons. The reduction in excitatory inputs is larger, resulting in a 2-fold decreased ratio of excitatory to inhibitory inputs in primate neurons. Finally, despite reductions in inhibitory synapse number, neighboring excitatory primate neurons are co-innervated by inhibitory axons at rates and proportions similar to mouse neurons. We present a first glimpse of large-scale connectivity comparisons across mouse and primate brains which underscore the need for future analyses since such differences likely represent a substantial part of how mouse and primate brains differ.

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Population coupling predicts the plasticity of stimulus responses in cortical circuits

Cited by 27 publications

References 50 publications

Primate neuronal connections are sparse in cortex as compared to mouse

Primate neuronal connections are sparse in cortex as compared to mouse

The brain in motion: How ensemble fluidity drives memory-updating and flexibility

Primate neuronal connections are sparse as compared to mouse

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