Radial contractility of Actomyosin-II rings facilitates cargo trafficking and maintains axonal structural stability following cargo-induced transient axonal expansion

Wang, Tong; Li, Wei; Martin, Sally; Papadopulos, Andreas; Jiang, Anmin; Shamsollahi, Golnoosh; Amor, Rumelo; Lanoue, Vanessa; Padmanabhan, Pranesh; Meunier, Frédéric A.

doi:10.1101/492959

Cited by 6 publications

(5 citation statements)

References 79 publications

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“…Although we were not able to directly visualize adducin at the ultrastructural level, our results suggest that this lateral binding role is dominant to enhance actin rings interaction with spectrins. Further studies are needed to clarify the precise localization and role of adducin as well as to confirm the localization of myosin filaments associated with the MPS, in order to explain how actin-associated proteins can regulate radial and longitudinal tension along the axon as well as axonal diameter Wang et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

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Ultrastructure of the axonal periodic scaffold reveals a braid-like organization of actin rings

Vassilopoulos

Gibaud

Jimenez

et al. 2019

Preprint

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Recent super-resolution microscopy studies have unveiled a periodic scaffold of actin rings regularly spaced by spectrins under the plasma membrane of axons. However, ultrastructural details are unknown, limiting a molecular and mechanistic understanding of these enigmatic structures. Here, we combine platinum-replica electron and optical super-resolution microscopy to investigate the cortical cytoskeleton of axons at the ultrastructural level. Immunogold labeling and correlative super-resolution/ electron microscopy allow us to unambiguously resolve actin rings as braids made of two long, intertwined actin filaments connected by a dense mesh of aligned spectrins. This molecular arrangement contrasts with the currently assumed model of actin rings made of short, capped actin filaments. Along the proximal axon, we resolved the presence of phospho-myosin light chain and the scaffold connection with microtubules via ankyrin G. We propose that braided rings explain the observed stability of the actin-spectrin scaffold and ultimately participate in preserving the axon integrity.

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Section: Discussionmentioning

confidence: 99%

“…3e, brackets). These filaments could be myosins associated with the MPS, and suggest that myosins can crosslink neighboring rings (Wang et al, 2018).…”

Section: Ultrastructural Organization Of Proximal Mps Componentsmentioning

confidence: 98%

Ultrastructure of the axonal periodic scaffold reveals a braid-like organization of actin rings

Vassilopoulos

Gibaud

Jimenez

et al. 2019

Preprint

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“…This effect may also provide another cause for the observed stall of NGF signaling endosomes ( Figure 2). Indeed, transient radial expansions of axonal diameter were recently described to facilitate the processivity of the fast-moving retrograde carriers 44 . Accordingly, the inhibition of these expansions prompted by graphene (Figure 4h), along with the reduced MT interdistance (Figure 4j), might create a more crowded space that inhibits cargo mobility and reduces the retrograde transport of NGF-loaded endosomes, ultimately favoring their local action on axon outgrowth.…”

Section: Reduced Microtubule Distance and Elongated Axonal Topology Omentioning

confidence: 99%

Graphene Promotes Axon Elongation through Local Stall of Nerve Growth Factor Signaling Endosomes

et al. 2020

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Several works reported increased differentiation of neuronal cells grown on graphene; however, the molecular mechanism driving axon elongation on this material has remained elusive. Here, we study the axonal transport of nerve growth factor (NGF), the neurotrophin supporting development of peripheral neurons, as a key player in the time course of axonal elongation of dorsal root ganglion neurons on graphene. We find that graphene drastically reduces the number of retrogradely transported NGF vesicles in favor of a stalled population in the first two days of culture, in which the boost of axon elongation is observed. This correlates with a mutual charge redistribution, observed via Raman spectroscopy and electrophysiological recordings. Furthermore, ultrastructural analysis indicates a reduced microtubule distance and an elongated axonal topology. Thus, both electrophysiological and structural effects can account for graphene action on neuron development. Unraveling the molecular players underneath this interplay may open new avenues for axon regeneration applications.

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“…Cargos that are transported in axons may occasionally contact the axonal cortex (Topalidou et al, 2012; Narayanareddy et al, 2014; Wortman et al, 2014). For instance, in axons, retrogradely moving lysotracker-marked vesicles induce local stretching of the plasma membrane of the axon (Wang et al, 2018). This could lead to increased drag, and may cause moving organelles to encounter greater stiffness from the proximate axonal cortex compared to stiffness encountered within the cytosol.…”

Section: Physical Barriers To Diffusive and Active Cargo Movementmentioning

confidence: 99%

“…Cytosolic diffusion is affected by the viscosity of the medium where the cytoskeletal filaments themselves can act as molecular sieves (Lewis et al, 2009; Song et al, 2009). On the other hand, active transport by molecular motors on MT tracks is affected by crowding on MT tracks (Hagiwara et al, 1994; Akhmanova and Steinmetz, 2015; Gumy et al, 2017), by the axonal plasma membrane (Narayanareddy et al, 2014; Leite et al, 2016; Wang et al, 2018), organelles, and cytoskeletal filaments near the tracks (Figures 1B,D,E) (Sood et al, 2018; Bommel et al, 2019). Both diffusion and motor-dependent movement face physical constraints that cargo must circumvent for steady transport.…”

Section: Physical Barriers To Diffusive and Active Cargo Movementmentioning

confidence: 99%

Crowd Control: Effects of Physical Crowding on Cargo Movement in Healthy and Diseased Neurons

Sabharwal

Koushika

2019

Front. Cell. Neurosci.

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High concentration of cytoskeletal filaments, organelles, and proteins along with the space constraints due to the axon’s narrow geometry lead inevitably to intracellular physical crowding along the axon of a neuron. Local cargo movement is essential for maintaining steady cargo transport in the axon, and this may be impeded by physical crowding. Molecular motors that mediate active transport share movement mechanisms that allow them to bypass physical crowding present on microtubule tracks. Many neurodegenerative diseases, irrespective of how they are initiated, show increased physical crowding owing to the greater number of stalled organelles and structural changes associated with the cytoskeleton. Increased physical crowding may be a significant factor in slowing cargo transport to synapses, contributing to disease progression and culminating in the dying back of the neuronal process. This review explores the idea that physical crowding can impede cargo movement along the neuronal process. We examine the sources of physical crowding and strategies used by molecular motors that might enable cargo to circumvent physically crowded locations. Finally, we describe sub-cellular changes in neurodegenerative diseases that may alter physical crowding and discuss the implications of such changes on cargo movement.

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Radial contractility of Actomyosin-II rings facilitates cargo trafficking and maintains axonal structural stability following cargo-induced transient axonal expansion

Cited by 6 publications

References 79 publications

Ultrastructure of the axonal periodic scaffold reveals a braid-like organization of actin rings

Ultrastructure of the axonal periodic scaffold reveals a braid-like organization of actin rings

Graphene Promotes Axon Elongation through Local Stall of Nerve Growth Factor Signaling Endosomes

Crowd Control: Effects of Physical Crowding on Cargo Movement in Healthy and Diseased Neurons

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