Long term ex vivo culturing of Drosophila brain as a method to live image pupal brains: insights into the cellular mechanisms of neuronal remodeling

Rabinovich, Dana; Mayseless, Oded; Schuldiner, Oren

doi:10.3389/fncel.2015.00327

Cited by 27 publications

(40 citation statements)

References 32 publications

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“…Our key goal was to follow subcellular dynamics at the resolution limit of conventional light microscopy with fast enough time-lapse to quantitatively describe subcellular dynamic properties in developing brains over many hr. Important advances in Drosophila ex vivo brain imaging have recently established high-resolution imaging in short developmental time windows ( Medioni et al, 2015 ; Zschätzsch, et al, 2014) and over long periods at low resolution and with slow time lapse ( Rabinovich et al, 2015 ). We identify phototoxicity and drift as key problems to obtain high spatial and temporal resolution 3D dynamics data over long developmental time periods, for which the imaging system presented here provides a successful approach.…”

Section: Discussionmentioning

confidence: 99%

“…However, intravital imaging has reduced resolution in deeper brain regions and is limited to early pupal stages. Previous imaging in cultured brains established high-resolution imaging in short developmental time windows ( Medioni et al, 2015 ; Zschätzsch, et al, 2014) and over long periods at low resolution and with slow time lapse ( Rabinovich et al, 2015 ), thus preventing in depth analysis of the role of filopodial dynamics during an entire neural circuit assembly process. Here we present the development of an ex vivo imaging method for Drosophila eye-brain development using 2-photon microscopy that allows widely applicable continuous, fast, high-resolution 4D live imaging anywhere in the fly brain throughout pupal development.…”

Section: Introductionmentioning

confidence: 99%

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Filopodial dynamics and growth cone stabilization in Drosophila visual circuit development

Özel

Langen

Hassan

et al. 2015

eLife

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Filopodial dynamics are thought to control growth cone guidance, but the types and roles of growth cone dynamics underlying neural circuit assembly in a living brain are largely unknown. To address this issue, we have developed long-term, continuous, fast and high-resolution imaging of growth cone dynamics from axon growth to synapse formation in cultured Drosophila brains. Using R7 photoreceptor neurons as a model we show that >90% of the growth cone filopodia exhibit fast, stochastic dynamics that persist despite ongoing stepwise layer formation. Correspondingly, R7 growth cones stabilize early and change their final position by passive dislocation. N-Cadherin controls both fast filopodial dynamics and growth cone stabilization. Surprisingly, loss of N-Cadherin causes no primary targeting defects, but destabilizes R7 growth cones to jump between correct and incorrect layers. Hence, growth cone dynamics can influence wiring specificity without a direct role in target recognition and implement simple rules during circuit assembly.DOI: http://dx.doi.org/10.7554/eLife.10721.001

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Filopodial dynamics and growth cone stabilization in Drosophila visual circuit development

Özel

Langen

Hassan

et al. 2015

eLife

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“…Elucidating the molecular basis of such developmental processes is not only essential for understanding basic neuroscience, but is also important for discovering new treatments for neurological diseases and cancer. Modern imaging approaches have proven indispensable in studying development in intact zebrafish (Danio rario) and Drosophila tissues (Barbosa & Ninkovic, 2016;Dray et al, 2015;Medioni et al, 2015;Rabinovich et al, 2015;Cabernard & Doe., 2013;Graeden & Sive, 2009). Tissue imaging approaches have also been combined with functional genetic screens, for example to discover neuroblast (NB) behaviour underlying defects in brain size or tumour formation (Berger et al, 2012;Homem & Knoblich, 2012;Neumüller et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

CytoCensus: mapping cell identity and division in tissues and organs using machine learning

Hailstone

Waithe

Samuels

et al. 2017

Preprint

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In BriefWe have optimised imaging of Hailstone et al Page ! 2017/5/14 2 SUMMARYBrain malformations often result from subtle changes in neural stem cell behaviour, which are difficult to characterise using current methods on fixed material. Here, we tackle this issue by establishing optimised approaches for extended 3D time-lapse imaging of living explanted Drosophila brains and developing QBrain image analysis software, a novel implementation of supervised machine learning. We combined these tools to investigate brain enlargement of a previously difficult to characterise mutant phenotype, identifying a defect in developmental timing.QBrain significantly outperforms existing freely available state-of-the-art image analysis approaches in accuracy and speed of cell identification, determining cell number, location, density and division rate from large 3D time-lapse datasets. Our use of QBrain illustrates its wide applicability to characterise development in complex tissue, such as tumours or organoids, in terms of the behaviour in 3D of individual cells in their native environment.

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“…To determine whether Non-stop regulates SCAR entry into a proteasomal degradation pathway 3 rd instar larval brains were cultured ex vivo to permit pharmacological inhibition of the proteasome in defined genetic backgrounds (83,84). Wandering 3 rd instar larval brains were isolated from non-stop homozygous mutant larvae and cultured for 24 hours in the presence of MG132 proteasome inhibitor.…”

Section: Atxn7 and Non-stop Coordinate Scar Protein Levelsmentioning

confidence: 99%

“…Ex vivo culturing of larval brains was performed as described (83,84). Third instar brains were dissected in 1xPBS and quickly placed into culture media (Schneider's insect media supplemented with 10% FBS, 1% pen/strp, 1:10,000 insulin, and 2 µg/ml ecdysone) in 24 well dish.…”

Section: Ex Vivo Culturing Of Third Instar Brainsmentioning

confidence: 99%

Ataxin-7 and Non-stop coordinate SCAR protein levels, subcellular localization, and actin cytoskeleton organization

Cloud

Momtahan

Jack

et al. 2018

Preprint

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SummarySAGA subunits Ataxin-7 and Non-stop regulate stability and subcellular localization of WRC subunit SCAR. Loss of Ataxin-7 increases, while loss of Non-stop decreases, SCAR protein levels and F-actin network assembly. AbstractAtaxin-7 (Atxn7), a subunit of the SAGA transcriptional coactivator complex, is subject to polyglutamine expansion at the amino terminus, causing spinocerebellar ataxia type 7 (SCA7), a progressive retinal and neurodegenerative disease. Within SAGA, the Atxn7 amino terminus anchors the Non-stop deubiquitinase to the complex. To understand the consequences of

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Long term ex vivo culturing of Drosophila brain as a method to live image pupal brains: insights into the cellular mechanisms of neuronal remodeling

Cited by 27 publications

References 32 publications

Filopodial dynamics and growth cone stabilization in Drosophila visual circuit development

Filopodial dynamics and growth cone stabilization in Drosophila visual circuit development

CytoCensus: mapping cell identity and division in tissues and organs using machine learning

Ataxin-7 and Non-stop coordinate SCAR protein levels, subcellular localization, and actin cytoskeleton organization

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