Synaptic Size Dynamics as an Effectively Stochastic Process

Statman, Adiel; Kaufman, Maya; Minerbi, Amir; Ziv, Noam; Brenner, Naama

doi:10.1371/journal.pcbi.1003846

Cited by 75 publications

(136 citation statements)

References 62 publications

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“…One important property of biological networks that has raised much interest is their heterogeneous topology. Analyses of metabolic, protein interaction, gene regulatory and neural networks all show heterogeneous connectivity distributions, including heavy tails and modular structure [8][9][10][11][12][13][14]. Heterogeneous networks, such as those with a broad connectivity distribution, are generally more difficult to analyze; inferring their detailed topology requires exceedingly high statistics.…”

Section: Introductionmentioning

confidence: 99%

Scale free topology as an effective feedback system

Rivkind

Schreier

Brenner

et al. 2019

Preprint

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Biological networks are often heterogeneous in their connectivity pattern, with degree distributions featuring a heavy tail of highly connected hubs. The implications of this heterogeneity on dynamical properties are a topic of much interest. Here we introduce a novel approach to analyze such networks the lumped hub approximation. Based on the observation that in finite networks a small number of hubs have a disproportionate effect on the entire system, we construct an approximation by lumping these nodes into a single effective hub, and replacing the rest by a homogeneous bulk. We use this approximation to study dynamics of networks with scale-free degree distributions, focusing on their probability of convergence to fixed points. We find that the approximation preserves convergence statistics over a wide range of settings. Our mapping provides a parametrization of scale free topology which is predictive at the ensemble level and also retains properties of individual realizations. Specifically for outgoing scale-free distributions, the role of the effective hub on the network can be elucidated by feedback analysis. We show that outgoing hubs have an organizing role that can drive the network to convergence, in analogy to suppression of chaos by an external drive. In contrast, incoming hubs have no such property, resulting in a marked difference between the behavior of networks with outgoing vs. incoming scale free degree distribution. Combining feedback analysis with mean field theory predicts a transition between convergent and divergent dynamics which is corroborated by numerical simulations. Our results show how interpreting topology as a feedback circuit can provide novel insights on dynamics. Furthermore, we highlight the effect of a handful of outlying hubs, rather than of the connectivity distribution law as a whole, on network dynamics.

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Section: Introductionmentioning

confidence: 99%

Scale free topology as an effective feedback system

Rivkind

Schreier

Brenner

et al. 2019

Preprint

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“…Recent experiments using time lapse imaging of dendritic spines have suggested that such distributions can arise from stochastic fluctuations that have a multiplicative component [3]. Another important finding is that the bigger and stronger synapses are more stable than the smaller and weaker ones [4,9,13]. This makes particularly strong synapses a good candidate for the anatomical substrate ofthose long-term memories which we may maintain for a lifetime.…”

Section: Stability Despite Constant Changementioning

confidence: 99%

The dynamic connectome

Rumpel

Triesch

2016

E-Neuroforum

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When trying to gain intuitions about the computations implemented in neural circuits, we often use comparisons with electronic circuits. However, one fundamental difference to hard-wired electronic circuits is that the structure of neural circuits undergoes constant remodeling. Here, we discuss recent findings highlighting the dynamic nature of neural circuits and the underlying mechanisms. The dynamics of neural circuits follows rules that explain steady state statistics of synaptic properties observed at a single time point. Interestingly, these rules allow the prediction of future network states and extend the insights gained from serial sectioning electron microscopy of brain samples, which inherently provides information from only a single time point. We argue how the connectome’s dynamic nature can be reconciled with stable functioning and long-termmemory storage and how it may even benefit learning.

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“…Interestingly, foci generated with fast nucleation rate also tend to have a shorter lifetime 540 evidencing a saturating mechanism or self-regulation (compare [13]). Moreover, we used 541 our model to test the influence of the nucleation location of these foci.…”

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confidence: 99%

“…Experiments imaging the shape of dendritic spines can provide snapshots at 14 distinct time points, but mathematical models are needed to bridge between these time 15 points and to understand shape fluctuations and their properties. However, so far only 16 phenomenological models have been proposed [9,[12][13][14] that describe fluctuation 17 coarsely on a timescale of days. Here, we take a different approach by modelling the fast 18 actin dynamics underlying shape fluctuations.…”

mentioning

confidence: 99%

“…In the future, the model can be extended in various directions: On the one hand, the 569 shape fluctuations may, on longer timescales, influence the model parameters such as 570 PSD size, molecule concentrations and reaction rates. Hence, the mean area around 571 which the spine fluctuates as well as other fluctuation characteristics could be 572 continuously adapted giving rise to a slower feedback-loop (compare [9] and [13]). On activity-dependent plasticity (LTP/LTD) by explicitely modelling the actin recycling 576 pathway that is modulated during plasticity (compare [17]).…”

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confidence: 99%

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Modeling the Shape of Synaptic Spines by their Actin Dynamics

Bonilla-Quintana

Wörgötter

Tetzlaff

et al. 2019

Preprint

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Dendritic spines are the morphological basis of excitatory synapses in the cortex and their size and shape correlates with functional synaptic properties. Recent experiments show that spines exhibit large shape fluctuations that are not related to activity-dependent plasticity but nonetheless might influence memory storage at their synapses. To investigate the determinants of such spontaneous fluctuations, we propose a mathematical model for the dynamics of the spine shape and analyze it in 2Drelated to experimental microscopic imagery -and in 3D. We show that the spine shape is governed by a local imbalance between membrane tension and the expansive force from actin bundles that originates from discrete actin polymerization foci.Experiments have shown that only few such polymerization foci co-exist at any time in a spine, each having limited life time. The model shows that the momentarily existing set of such foci pushes the membrane along certain directions until foci are replaced and other directions may now be affected. We explore these relations in depth and use our model to predict shape and temporal characteristics of spines from the different biophysical parameters involved in actin polymerization. Reducing the model further to a single recursive equation we finally demonstrate that the temporal evolution of the October 16, 2019 1/31 number of active foci is sufficient to predict the size of the model-spines. Thus, our model provides the first platform to study the relation between molecular and morphological properties of the spine with a high degree of biophysical detail. Author summarySynaptic spines are post-synaptic contact points for pre-synaptic signals in many cortical neurons and it has been shown that synaptic transmission is correlated with spine size. However, spine size and shape can vary quite strongly on short time scales and it is currently unknown how these shape variations emerge. In this study we present a biophysical model that links spine shape fluctuations to the dynamics of the spine's actin-based cytoskeleton. We show that shape fluctuations arise from the fact that fast actin polymerization in a spine is a discrete process happening at only few polymerization foci. Life and death of these foci determine from moment to moment how the membrane bulges or retracts. We provide an in-depth analysis of this effect for a large set of biophysical parameters and quantify the spatial-temporal structure of the spines. Our model, thus, provides a quantitative characterization of the link between spine morphology and the underlying molecular processes, which forms an essential step towards a better understanding of synaptic transmission during steady state but also during synaptic plasticity. 2 postsynaptic part of most excitatory synapses in the cortex [1]. One of the central 3 paradigms of neuroscience is that synapses store memories by changing their 4 transmission efficacies during learning [2] and it has been shown that magnitude as well 5 as synaptic transmission efficacy correlate with s...

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Synaptic Size Dynamics as an Effectively Stochastic Process

Cited by 75 publications

References 62 publications

Scale free topology as an effective feedback system

Scale free topology as an effective feedback system

The dynamic connectome

Modeling the Shape of Synaptic Spines by their Actin Dynamics

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