Quantifying molecular aggregation by super resolution microscopy within an excitatory synapse from mouse hippocampal neurons

Neurons have a membrane periodic skeleton (MPS) composed of actin rings interconnected by spectrin. Here, combining chemical and genetic gain- and loss-of-function assays, we show that in rat hippocampal neurons the MPS is an actomyosin network that controls axonal expansion and contraction. Using super-resolution microscopy, we analyzed the localization of axonal non-muscle myosin II (NMII). We show that active NMII light chains are colocalized with actin rings and organized in a circular periodic manner throughout the axon shaft. In contrast, NMII heavy chains are mostly positioned along the longitudinal axonal axis, being able to crosslink adjacent rings. NMII filaments can play contractile or scaffolding roles determined by their position relative to actin rings and activation state. We also show that MPS destabilization through NMII inactivation affects axonal electrophysiology, increasing action potential conduction velocity. In summary, our findings open new perspectives on axon diameter regulation, with important implications in neuronal biology.

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Super-Resolution Microscopy Reveals Presynaptic Localization of the ALS/FTD Related Protein FUS in Hippocampal Neurons

Frontiers in Cellular Neuroscience ◽

10.3389/fncel.2015.00496 ◽

2016 ◽

Vol 9 ◽

Cited By ~ 24

Author(s):

Michael Schoen ◽

Jochen M. Reichel ◽

Maria Demestre ◽

Stefan Putz ◽

Dhruva Deshpande ◽

...

Keyword(s):

Hippocampal Neurons ◽

Super Resolution ◽

Related Protein ◽

Super Resolution Microscopy

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CAP1 and cofilin1 cooperate in neuronal actin dynamics, growth cone function and neuron connectivity

10.1101/2020.08.12.247932 ◽

2020 ◽

Author(s):

Felix Schneider ◽

Thuy-An Duong ◽

Isabell Metz ◽

Jannik Winkelmeier ◽

Christian A. Hübner ◽

...

Keyword(s):

Growth Cone ◽

Hippocampal Neurons ◽

Super Resolution ◽

Growth Cones ◽

Actin Dynamics ◽

Actin Binding ◽

Control Growth ◽

Cone Function ◽

And Function ◽

Super Resolution Microscopy

AbstractNeuron connectivity depends on growth cones that navigate axons through the developing brain. Growth cones protrude and retract actin-rich structures to sense guidance cues. These cues control local actin dynamics and steer growth cones towards attractants and away from repellents, thereby directing axon outgrowth. Hence, actin binding proteins (ABPs) moved into the focus as critical regulators of neuron connectivity. We found cyclase-associated protein 1 (CAP1), an ABP with unknown brain function, abundant in growth cones. Super-resolution microscopy and live cell imaging combined with pharmacological approaches on hippocampal neurons from gene-targeted mice revealed a crucial role for CAP1 in actin dynamics that is critical for growth cone morphology and function. Growth cone defects in mutant neurons compromised neuron differentiation and was associated with impaired neuron connectivity in CAP1 mutant brains. Mechanistically, we found that CAP1 and cofilin1 synergistically control growth cone actin dynamic and morphology. Together, we identified CAP1 as a novel actin regulator in growth cone that is relevant for neuron connectivity.

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Flux of signalling endosomes undergoing axonal retrograde transport is encoded by presynaptic activity and TrkB

Nature Communications ◽

10.1038/ncomms12976 ◽

2016 ◽

Vol 7 (1) ◽

Cited By ~ 30

Author(s):

Tong Wang ◽

Sally Martin ◽

Tam H. Nguyen ◽

Callista B. Harper ◽

Rachel S. Gormal ◽

...

Keyword(s):

Motor Neurons ◽

Hippocampal Neurons ◽

Super Resolution ◽

Retrograde Transport ◽

Synaptic Activity ◽

Neurotrophin Receptor ◽

Independent Manner ◽

Cholera Toxin Subunit B ◽

Super Resolution Microscopy ◽

Subunit B

AbstractAxonal retrograde transport of signalling endosomes from the nerve terminal to the soma underpins survival. As each signalling endosome carries a quantal amount of activated receptors, we hypothesized that it is the frequency of endosomes reaching the soma that determines the scale of the trophic signal. Here we show that upregulating synaptic activity markedly increased the flux of plasma membrane-derived retrograde endosomes (labelled using cholera toxin subunit-B: CTB) in hippocampal neurons cultured in microfluidic devices, and liveDrosophilalarval motor neurons. Electron and super-resolution microscopy analyses revealed that the fast-moving sub-diffraction-limited CTB carriers contained the TrkB neurotrophin receptor, transiently activated by synaptic activity in a BDNF-independent manner. Pharmacological and genetic inhibition of TrkB activation selectively prevented the coupling between synaptic activity and the retrograde flux of signalling endosomes. TrkB activity therefore controls the encoding of synaptic activity experienced by nerve terminals, digitalized as the flux of retrogradely transported signalling endosomes.

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Neuronal Aβ42 is enriched in small vesicles at the presynaptic side of synapses

Life Science Alliance ◽

10.26508/lsa.201800028 ◽

2018 ◽

Vol 1 (3) ◽

pp. e201800028 ◽

Cited By ~ 18

Author(s):

Yang Yu ◽

Daniel C Jans ◽

Bengt Winblad ◽

Lars O Tjernberg ◽

Sophia Schedin-Weiss

Keyword(s):

Hippocampal Neurons ◽

Memory Function ◽

Three Dimensional ◽

Amyloid Β ◽

Super Resolution ◽

Long Term Potentiation ◽

Synaptic Function ◽

Amyloid Β Peptide ◽

Term Potentiation ◽

Super Resolution Microscopy

The amyloid β-peptide (Aβ) is a physiological ubiquitously expressed peptide suggested to be involved in synaptic function, long-term potentiation, and memory function. The 42 amino acid-long variant (Aβ42) forms neurotoxic oligomers and amyloid plaques and plays a key role in the loss of synapses and other pathogenic events of Alzheimer disease. Still, the exact localization of Aβ42 in neurons and at synapses has not been reported. Here, we used super-resolution microscopy and show that Aβ42 was present in small vesicles in presynaptic compartments, but not in postsynaptic compartments, in the neurites of hippocampal neurons. Some of these vesicles appeared to lack synaptophysin, indicating that they differ from the synaptic vesicles responsible for neurotransmitter release. The Aβ42-containing vesicles existed in presynapses connected to stubby spines and mushroom spines, and were also present in immature presynapses. These vesicles were scarce in other parts of the neurites, where Aβ42 was instead present in large, around 200–600 nm, vesicular structures. Three-dimensional super-resolution microscopy confirmed that Aβ42 was present in the presynapse and absent in the postsynapse.

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Super-Resolution Microscopy in Studying the Structure and Function of the Cell Nucleus

Acta Naturae ◽

10.32607/2075851-2017-9-4-42-51 ◽

2017 ◽

Vol 9 (4) ◽

pp. 42-51

Author(s):

S. S. Ryabichko ◽

◽

A. N. Ibragimov ◽

L. A. Lebedeva ◽

E. N. Kozlov ◽

...

Keyword(s):

Cell Nucleus ◽

Super Resolution ◽

Structure And Function ◽

And Function ◽

Super Resolution Microscopy

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Structural Evidence of Photoisomerization Pathways in Fluorescent Proteins

10.26434/chemrxiv.9209450.v1 ◽

2019 ◽

Author(s):

Jeffrey Chang ◽

Matthew Romei ◽

Steven Boxer

Keyword(s):

Rational Design ◽

Fluorescent Protein ◽

Fluorescent Proteins ◽

Super Resolution ◽

Unit Cell Size ◽

Chlorine Substituent ◽

Gfp Chromophore ◽

The One ◽

Green Fluorescent ◽

Super Resolution Microscopy

Double-bond photoisomerization in molecules such as the green fluorescent protein (GFP) chromophore can occur either via a volume-demanding one-bond-flip pathway or via a volume-conserving hula-twist pathway. Understanding the factors that determine the pathway of photoisomerization would inform the rational design of photoswitchable GFPs as improved tools for super-resolution microscopy. In this communication, we reveal the photoisomerization pathway of a photoswitchable GFP, rsEGFP2, by solving crystal structures of cis and trans rsEGFP2 containing a monochlorinated chromophore. The position of the chlorine substituent in the trans state breaks the symmetry of the phenolate ring of the chromophore and allows us to distinguish the two pathways. Surprisingly, we find that the pathway depends on the arrangement of protein monomers within the crystal lattice: in a looser packing, the one-bond-flip occurs, whereas in a tighter packing (7% smaller unit cell size), the hula-twist occurs.

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