Emergence of Functional Specificity in Balanced Networks with Synaptic Plasticity

AbstractThe dynamics of local cortical networks are irregular, but correlated. Dynamic excitatory– inhibitory balance is a plausible mechanism that generates such irregular activity, but it remains unclear how balance is achieved and maintained in plastic neural networks. In particular, it is not fully understood how plasticity induced changes in the network affect balance, and in turn, how correlated, balanced activity impacts learning. How does the dynamics of balanced networks change under different plasticity rules? How does correlated spiking activity in recurrent networks change the evolution of weights, their eventual magnitude, and structure across the network? To address these questions, we develop a general theory of plasticity in balanced networks. We show that balance can be attained and maintained under plasticity induced weight changes. We find that correlations in the input mildly, but significantly affect the evolution of synaptic weights. Under certain plasticity rules, we find an emergence of correlations between firing rates and synaptic weights. Under these rules, synaptic weights converge to a stable manifold in weight space with their final configuration dependent on the initial state of the network. Lastly, we show that our framework can also describe the dynamics of plastic balanced networks when subsets of neurons receive targeted optogenetic input.

Download Full-text

Specific depletion of the motor protein KIF5B leads to deficits in dendritic transport, synaptic plasticity and memory

eLife ◽

10.7554/elife.53456 ◽

2020 ◽

Vol 9 ◽

Cited By ~ 5

Author(s):

Junjun Zhao ◽

Albert Hiu Ka Fok ◽

Ruolin Fan ◽

Pui-Yi Kwan ◽

Hei-Lok Chan ◽

...

Keyword(s):

Synaptic Plasticity ◽

Gene Duplication ◽

Hippocampal Neurons ◽

Motor Proteins ◽

Arginine Methylation ◽

Memory Formation ◽

Conditional Knockout ◽

Excitatory Synapses ◽

Functional Specificity ◽

Spine Morphogenesis

The kinesin I family of motor proteins are crucial for axonal transport, but their roles in dendritic transport and postsynaptic function are not well-defined. Gene duplication and subsequent diversification give rise to three homologous kinesin I proteins (KIF5A, KIF5B and KIF5C) in vertebrates, but it is not clear whether and how they exhibit functional specificity. Here we show that knockdown of KIF5A or KIF5B differentially affects excitatory synapses and dendritic transport in hippocampal neurons. The functional specificities of the two kinesins are determined by their diverse carboxyl-termini, where arginine methylation occurs in KIF5B and regulates its function. KIF5B conditional knockout mice exhibit deficits in dendritic spine morphogenesis, synaptic plasticity and memory formation. Our findings provide insights into how expansion of the kinesin I family during evolution leads to diversification and specialization of motor proteins in regulating postsynaptic function.

Download Full-text

Reconciling contrast invariance and non-linear computation in cortical circuits

10.1101/2021.04.23.441165 ◽

2021 ◽

Author(s):

L. Bernáez Timón ◽

P. Ekelmans ◽

S. Konrad ◽

A. Nold ◽

T. Tchumatchenko

Keyword(s):

Synaptic Plasticity ◽

Piriform Cortex ◽

Mean Field ◽

Dependent Manner ◽

Cortical Circuits ◽

Stimulus Contrast ◽

Spiking Network ◽

Network Simulations ◽

Contrast Invariance ◽

Balanced Networks

AbstractNetwork selectivity for orientation is invariant to changes in the stimulus contrast in the primary visual cortex. Similarly, the selectivity for odor identity is invariant to changes in odorant concentration in the piriform cortex. Interestingly, invariant network selectivity appears robust to local changes in synaptic strength induced by synaptic plasticity, even though: i) synaptic plasticity can potentiate or depress connections between neurons in a feature-dependent manner, and ii) in networks with balanced excitation and inhibition, synaptic plasticity is a determinant for the network non-linearity. In this study, we investigate whether network contrast invariance is consistent with a variety of synaptic states and connectivities in balanced networks. By using mean-field models and spiking network simulations, we show how the synaptic state controls the non-linearity in the network response to contrast and how it can lead to the emergence of contrast-invariant or contrast-dependent selectivity. Different forms of synaptic plasticity sharpen or broaden the network selectivity, while others do not affect it. Our results explain how the physiology of individual synapses is linked to contrast-invariant selectivity at the network level.

Download Full-text