Emergence of local and global synaptic organization on cortical dendrites

Kirchner, Jan H.; Gjorgjieva, Julijana

doi:10.1038/s41467-021-23557-3

Cited by 35 publications

(60 citation statements)

References 105 publications

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“…Several modeling studies have made predictions on the mechanisms that underlie the formation of functional clusters (Legenstein and Maass, 2011 ; Limbacher and Legenstein, 2020 ). Kirchner and Gjorgjieva ( 2021 ) successfully recapitulated previous experimental findings on the functional clustering of excitatory synapses in visual cortical areas by using a heterosynaptic plasticity model based on activity-dependent interactions between BDNF and proBDNF (Winnubst et al, 2015 ). The authors found that this introduced a distance-dependent and timing-dependent competition between synapses.…”

Section: Implications Of Heterosynaptic Plasticitymentioning

confidence: 77%

“…Due to these differences, we have some insight into the prerequisites for functional clustering. For example, the presence of cortical columns or topographic maps, in which there exists a spatial organization of neurons with similar response properties, can explain differences in functional clustering between species (Kirchner and Gjorgjieva, 2021 ). In V1, neurons demonstrate functional clustering for orientation preference specifically in species that have orientation columns and small receptive field diameters for visual space, such as macaques and ferrets (Wilson et al, 2016 ; Ju et al, 2020 ; Scholl et al, 2021 ).…”

Section: In Vivo Plasticity-mediated Synaptic Reorganization On Dendritesmentioning

confidence: 99%

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Heterosynaptic Plasticity and the Experience-Dependent Refinement of Developing Neuronal Circuits

Jenks

Tsimring

et al. 2021

Front. Neural Circuits

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Neurons remodel the structure and strength of their synapses during critical periods of development in order to optimize both perception and cognition. Many of these developmental synaptic changes are thought to occur through synapse-specific homosynaptic forms of experience-dependent plasticity. However, homosynaptic plasticity can also induce or contribute to the plasticity of neighboring synapses through heterosynaptic interactions. Decades of research in vitro have uncovered many of the molecular mechanisms of heterosynaptic plasticity that mediate local compensation for homosynaptic plasticity, facilitation of further bouts of plasticity in nearby synapses, and cooperative induction of plasticity by neighboring synapses acting in concert. These discoveries greatly benefited from new tools and technologies that permitted single synapse imaging and manipulation of structure, function, and protein dynamics in living neurons. With the recent advent and application of similar tools for in vivo research, it is now feasible to explore how heterosynaptic plasticity contribute to critical periods and the development of neuronal circuits. In this review, we will first define the forms heterosynaptic plasticity can take and describe our current understanding of their molecular mechanisms. Then, we will outline how heterosynaptic plasticity may lead to meaningful refinement of neuronal responses and observations that suggest such mechanisms are indeed at work in vivo. Finally, we will use a well-studied model of cortical plasticity—ocular dominance plasticity during a critical period of visual cortex development—to highlight the molecular overlap between heterosynaptic and developmental forms of plasticity, and suggest potential avenues of future research.

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Section: Implications Of Heterosynaptic Plasticitymentioning

confidence: 77%

Section: In Vivo Plasticity-mediated Synaptic Reorganization On Dendritesmentioning

confidence: 99%

Heterosynaptic Plasticity and the Experience-Dependent Refinement of Developing Neuronal Circuits

Jenks

Tsimring

et al. 2021

Front. Neural Circuits

View full text Add to dashboard Cite

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“…We argue that these two disparities can be resolved, if the individual continuous inputs provided to our model are seen as the resulting currents of clustered, correlated synapses. How this clustering could be organized by synaptic plasticity is a matter of ongoing research ( 68 ), and it will have to be the subject of future work to reconcile these plasticity mechanisms with representation learning.…”

Section: Discussionmentioning

confidence: 99%

Local dendritic balance enables learning of efficient representations in networks of spiking neurons

Mikulasch

Rudelt

Priesemann

2021

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

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How can neural networks learn to efficiently represent complex and high-dimensional inputs via local plasticity mechanisms? Classical models of representation learning assume that feedforward weights are learned via pairwise Hebbian-like plasticity. Here, we show that pairwise Hebbian-like plasticity works only under unrealistic requirements on neural dynamics and input statistics. To overcome these limitations, we derive from first principles a learning scheme based on voltage-dependent synaptic plasticity rules. Here, recurrent connections learn to locally balance feedforward input in individual dendritic compartments and thereby can modulate synaptic plasticity to learn efficient representations. We demonstrate in simulations that this learning scheme works robustly even for complex high-dimensional inputs and with inhibitory transmission delays, where Hebbian-like plasticity fails. Our results draw a direct connection between dendritic excitatory–inhibitory balance and voltage-dependent synaptic plasticity as observed in vivo and suggest that both are crucial for representation learning.

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“…There is accumulating evidence that a substantial amount of the dendritic organization across these scales emerges already during early development ( ; ; ; ; ; ). This early emergence is particularly noteworthy as neural activity during these early phases primarily arises spontaneously ( ), raising the question of how the brain can precisely arrange synaptic inputs across scales without sensory input.…”

Section: Organization Of Excitatory Synapsesmentioning

confidence: 99%

“…Specific activity-dependent plasticity mechanisms drive this connectivity refinement ( ). The exact form of these plasticity mechanisms and their functional implications are an active area of research ( ; ; ; ; ).…”

Section: Introductionmentioning

confidence: 99%

Emergence of synaptic organization and computation in dendrites

Kirchner

Gjorgjieva

2021

Neuroforum

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Single neurons in the brain exhibit astounding computational capabilities, which gradually emerge throughout development and enable them to become integrated into complex neural circuits. These capabilities derive in part from the precise arrangement of synaptic inputs on the neurons’ dendrites. While the full computational benefits of this arrangement are still unknown, a picture emerges in which synapses organize according to their functional properties across multiple spatial scales. In particular, on the local scale (tens of microns), excitatory synaptic inputs tend to form clusters according to their functional similarity, whereas on the scale of individual dendrites or the entire tree, synaptic inputs exhibit dendritic maps where excitatory synapse function varies smoothly with location on the tree. The development of this organization is supported by inhibitory synapses, which are carefully interleaved with excitatory synapses and can flexibly modulate activity and plasticity of excitatory synapses. Here, we summarize recent experimental and theoretical research on the developmental emergence of this synaptic organization and its impact on neural computations.

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Emergence of local and global synaptic organization on cortical dendrites

Cited by 35 publications

References 105 publications

Heterosynaptic Plasticity and the Experience-Dependent Refinement of Developing Neuronal Circuits

Heterosynaptic Plasticity and the Experience-Dependent Refinement of Developing Neuronal Circuits

Local dendritic balance enables learning of efficient representations in networks of spiking neurons

Emergence of synaptic organization and computation in dendrites

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