Quantitative expansion microscopy for the characterization of the spectrin periodic skeleton of axons using fluorescence microscopy

Martínez, Gaby F.; Gazal, Nahir G.; Quassollo, Gonzalo; Szalai, Alan M.; Cid-Pellitero, Esther Del; Durcan, Thomas M.; Fon, Edward A.; Bisbal, Mariano; Stefani, Fernando D.; Unsain, Nicolás

doi:10.1038/s41598-020-59856-w

Cited by 18 publications

(21 citation statements)

References 36 publications

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“…1F). Our average micro expansion factors are lower than the commonly reported 4-4.5X macro expansion factor for proExM, which is consistent with other reports using micro expansion factor measurements 14,15 (but see also ref 26 ), reinforcing the notion that each sample type needs to be independently optimized and validated for ExM.…”

Section: Discussionsupporting

confidence: 91%

“…Others, however, have reported minimal to no differences in micro vs macro expansion factors 6,18 . We did not measure macro expansion factors here, but our average micro expansion factors are lower than the commonly reported 4-4.5X macro expansion factor for proExM, which is consistent with other reports using micro expansion factor measurements 13,14 (but see also ref 25 ), reinforcing the notion that each sample type needs to be independently optimized and validated for ExM.…”

Section: Dendritic Spines Are Best Resolved In Expanded Gfp or Rfp-imsupporting

confidence: 89%

“…Others have used ExM to visualize subcellular structures, including mitochondria 1,2,23–25 and/or spines 2,20,23 in brain tissue, but few have systematically analyzed how fluorescence intensities and expansion factors compare across protocols or with unexpanded measurements. This is critically important as several groups have noted discrepancies in micro versus macro expansion factors in other sample types 7,14,17,26–28 , including dissimilarities in expansion factors of different subcellular organelles 14 or of subcellular organelles across neighboring cells and tissues 17 . Others, however, have reported minimal to no differences in micro vs macro expansion factors 6,19 .…”

Section: Discussionmentioning

confidence: 99%

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Visualizing subcellular structures in neuronal tissue with expansion microscopy

Campbell

Pannoni

Savory

et al. 2020

Preprint

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Protein expansion microscopy (proExM) is a powerful technique that crosslinks proteins to a swellable hydrogel to physically expand and optically clear biological samples. The resulting increased resolution (~70 nm) and physical separation of labeled proteins make it an attractive tool for studying the localization of subcellular organelles in densely packed tissues, such as the brain. However, the digestion and expansion process greatly reduces fluorescence signals making it necessary to optimize ExM conditions per sample for specific end goals. Here we describe a proExM workflow optimized for resolving subcellular organelles (mitochondria and the Golgi apparatus) and reporter-labeled spines in fixed mouse brain tissue. By directly comparing proExM staining and digestion protocols, we found that immunostaining before proExM and using a Proteinase K based digestion for 8 hours consistently resulted in the best fluorescence signal to resolve subcellular organelles while maintaining sufficient reporter labeling to visualize spines and trace individual neurons. With these methods, we more accurately quantified mitochondria size and number and better visualized Golgi ultrastructure in reconstructed CA2 neurons of the hippocampus.

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Section: Discussionsupporting

confidence: 91%

Section: Dendritic Spines Are Best Resolved In Expanded Gfp or Rfp-imsupporting

confidence: 89%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Visualizing subcellular structures in neuronal tissue with expansion microscopy

Campbell

Pannoni

Savory

et al. 2020

Preprint

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“…However, these processes do not only depend on the properties of the motors and their assemblies, but also on the structural organization of the actin cytoskeleton. In the future, our approach should be complemented by imaging and modelling of the actin cytoskeleton using super-resolution microscopy (Martinez et al, 2020;Qi et al, 2019;Shelden et al, 2016;Wassie et al, 2019). In a next step, our insights into the distinct cellular roles of the different NM II isoforms should be transferred to the tissue context, e.g.…”

Section: Discussionmentioning

confidence: 99%

Distinct roles of nonmuscle myosin II isoforms for establishing tension and elasticity during cell morphodynamics

Weißenbruch

Grewe

Hippler

et al. 2020

Preprint

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Nonmuscle myosin II (NM II) is an integral part of essential cellular processes, including adhesion and migration. Mammalian cells express up to three isoforms termed NM IIA, B, and C. We used U2OS cells to create CRISPR/Cas9-based knockouts of all three isoforms and analyzed the phenotypes on homogeneous and micropatterned substrates. We find that NM IIA is essential to build up cellular tension during initial stages of force generation, while NM IIB is necessary to elastically stabilize NM IIA-generated tension. The knockout of NM IIC has no detectable effects. A scale-bridging mathematical model explains our observations by relating actin fiber stability to the molecular rates of the myosin crossbridge cycle. We also find that NM IIA initiates and guides co-assembly of NM IIB into heterotypic minifilaments. We finally use mathematical modeling to explain the different exchange dynamics of NM IIA and B in minifilaments, as measured in FRAP experiments.

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“…Such a negative pattern reduces the size of the fluorescent region and scanning of this sharpened focal spot generates a super-resolution image. Through the use of STED, actin and ABP have been thoroughly investigated ( Urban et al, 2011 ; Lukinavičius et al, 2014 ; Leite et al, 2016 ; Sidenstein et al, 2016 ; Barabas et al, 2017 ; D’este et al, 2017 ; Krieg et al, 2017 ; Martínez et al, 2020 ).…”

Section: Visualization Techniques In the Nanoscale To Study Actin Andmentioning

confidence: 99%

Direct Visualization of Actin Filaments and Actin-Binding Proteins in Neuronal Cells

Jung

Kim

Mun

2020

Front. Cell Dev. Biol.

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Actin networks and actin-binding proteins (ABPs) are most abundant in the cytoskeleton of neurons. The function of ABPs in neurons is nucleation of actin polymerization, polymerization or depolymerization regulation, bundling of actin through crosslinking or stabilization, cargo movement along actin filaments, and anchoring of actin to other cellular components. In axons, ABP–actin interaction forms a dynamic, deep actin network, which regulates axon extension, guidance, axon branches, and synaptic structures. In dendrites, actin and ABPs are related to filopodia attenuation, spine formation, and synapse plasticity. ABP phosphorylation or mutation changes ABP–actin binding, which regulates axon or dendritic plasticity. In addition, hyperactive ABPs might also be expressed as aggregates of abnormal proteins in neurodegeneration. Those changes cause many neurological disorders. Here, we will review direct visualization of ABP and actin using various electron microscopy (EM) techniques, super resolution microscopy (SRM), and correlative light and electron microscopy (CLEM) with discussion of important ABPs in neuron.

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Quantitative expansion microscopy for the characterization of the spectrin periodic skeleton of axons using fluorescence microscopy

Cited by 18 publications

References 36 publications

Visualizing subcellular structures in neuronal tissue with expansion microscopy

Visualizing subcellular structures in neuronal tissue with expansion microscopy

Distinct roles of nonmuscle myosin II isoforms for establishing tension and elasticity during cell morphodynamics

Direct Visualization of Actin Filaments and Actin-Binding Proteins in Neuronal Cells

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