Loss of focal adhesions in glia disrupts both glial and photoreceptor axon migration in the <i>Drosophila</i> visual system

Xie, Xiaojun; Gilbert, Mary; Petley-Ragan, Lindsay; Auld, Vanessa J.

doi:10.1242/dev.101972

Cited by 28 publications

(33 citation statements)

References 58 publications

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“…Wrapping glial morphogenesis depends on Integrin and Laminin signaling (Petley-Ragan et al, 2016;Xie & Auld, 2011;Xie, Gilbert, Petley-Ragan, & Auld, 2014) and requires enzymes controlling sphingolipid biosynthesis (Ghosh et al, 2013). In line with that, a role for the glycosphingolipid synthesis in peripheral glial development was shown in mutants of the glycosyltransferase egghead (Dahlgaard et al, 2012).…”

Section: Wrapping Glial Cellsmentioning

confidence: 70%

Drosophila glia: Few cell types and many conserved functions

Yildirim

Petri

Kottmeier

et al. 2018

Glia

147

153

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Glial cells constitute without any dispute an essential element in providing an efficiently operating nervous system. Work in many labs over the last decades has demonstrated that neuronal function, from action potential generation to its propagation, from eliciting synaptic responses to the subsequent postsynaptic integration, is evolutionarily highly conserved. Likewise, the biology of glial cells appears conserved in its core elements and therefore, a deeper understanding of glial cells is expected to benefit from analyzing model organisms such as Drosophila melanogaster. Drosophila is particularly well suited for studying glial biology since in the fly nervous system only a limited number of glial cells exists, which can be individually identified based on position and a set of molecular markers. In combination with the well‐known genetic tool box an unprecedented level of analysis is feasible, that not only can help to identify novel molecules and principles governing glial cell function but also will help to better understand glial functions first identified in the mammalian nervous system. Here we review the current knowledge on Drosophila glia to spark interest in using this system to analyze complex glial traits in the future.

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Section: Wrapping Glial Cellsmentioning

confidence: 70%

Drosophila glia: Few cell types and many conserved functions

Yildirim

Petri

Kottmeier

et al. 2018

Glia

147

153

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“…Most crosses were raised at 25 C under standard conditions. Exceptions were the ones using the tub-Gal80 ts (McGuire et al, 2003) that were raised at 18 C for approximately 72 h and then moved to 25 C. The following stocks (described in FlyBase, unless stated otherwise) were used: If-GFP (DGRC #115467; Xie et al, 2014), repo-Gal4 (pan-glia; Xiong et al, 1994), moody-Gal4 (subperineurial glia; Bainton et al, 2005), Mz97-Gal4, UAS Stinger (wrapping glia; Hummel et al, 2002), UAS-dicer-2 (Dietzl et al, 2007), UAS-lacZ, UAS-CD8GFP (Lee and Luo, 1999), UAS-CD4tdTOM (Han et al, 2011), UAS-aPS2 RNAi (JF02695, previously validated Liu et al, 2013), UAS-bPS RNAi (VDRC KK100518; and GD15002, previously validated (Nishimura et al, 2014;Xie and Auld, 2011) and TRIP JF02819), UAS-aPS3 RNAi (JF02696; and VDRC KK106326, both previously validated by Vanderploeg et al, 2012), UAS-talin RNAi (HMS00799 and HMS00856), UAS-RpL7a RNAi (VDRC GD10934), UAS-eIF-4a RNAi (VDRC GD14111), UAS-Ef1c RNAi (VDRC GD7427), UAS-aPS3 EY10270 , UAS-Egfr ktop (Queenan et al, 1997), and repo4.3-Gal4 (Lee and Jones, 2005). For bPS, aPS3, and Talin the lines used were KK100518, JF02696, and HMS00799, respectively, except where otherwise stated.…”

Section: Fly Husbandrymentioning

confidence: 99%

“…To study aPS3 expression ( Fig. 1G-J) we used a validated anti-aPS3 antibody (Wada et al, 2007;Xie and Auld, 2011;Xie et al, 2014; and Supp. Info.…”

Section: Expression Patterns Of A-integrins In the Eye Imaginal Disc mentioning

confidence: 99%

Drosophila PS2 and PS3 integrins play distinct roles in retinal photoreceptors–glia interactions

Tavares

Pereira

Correia

et al. 2015

Glia

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Cellular migration and differentiation are important developmental processes that require dynamic cellular adhesion. Integrins are heterodimeric transmembrane receptors that play key roles in adhesion plasticity. Here, we explore the developing visual system of Drosophila to study the roles of integrin heterodimers in glia development. Our data show that αPS2 is essential for retinal glia migration from the brain into the eye disc and that glial cells have a role in the maintenance of the fenestrated membrane (Laminin-rich ECM layer) in the disc. Interestingly, the absence of glial cells in the eye disc did not affect the targeting of retinal axons to the optic stalk. In contrast, αPS3 is not required for retinal glia migration, but together with Talin, it functions in glial cells to allow photoreceptor axons to target the optic stalk. Thus, we present evidence that αPS2 and αPS3 integrin have different and specific functions in the development of retinal glia.

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“…The lack of glial spreading suggests a role for Raw in SPG, while the reduced number of glia populating the eye imaginal disc suggests that Raw may have a specific role in the PG or WG. Therefore, to explore the requirement for Raw in specific glial subtypes, glial subtype-specific Gal4 drivers were utilized to knockdown raw in the comparing pan-glial knockdown to glial subtype-specific knockdown (Xie et al, 2014). The lack of a glial reduction phenotype suggests that…”

Section: Resultsmentioning

confidence: 99%

“…Finally, cell adhesion proteins also function as critical regulators of neuron-glia interactions in the developing eye. Specifically, integrins are required in multiple glial layers for glial migration, organization of glia and neurons in the eye disc and optic stalk, and for axonal projections through the optic stalk to the brain (Tavares et al, 2015;Xie, Gilbert, Petley-Ragan, & Auld, 2014).…”

mentioning

confidence: 99%

Raw regulates glial population of the eye imaginal disc

Hans

Wendt

Patel

et al. 2018

Genesis

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Summary Glia are critical for proper development, support, and function of the nervous system. The Drosophila eye has proven an excellent model for gaining significant insight into the molecular mechanisms regulating glial development and function. Recent studies have demonstrated that Raw is required in glia of the central and peripheral nervous systems; however, the function of Raw in glia of the developing eye has not been explored. These studies demonstrate that raw knockdown results in a reduction in the number of glia in the third instar eye imaginal disc and reduced glial spreading across the field of differentiating photoreceptor neurons. Expression of a raw enhancer trap reveals that raw is expressed in eye disc glia. Exploration of the mechanism by which raw knockdown results in glial reduction reveals that Raw is required for glial proliferation and migration into the eye disc. In addition, Raw negatively regulates Jun N‐terminal kinase (JNK) signaling in glia of the developing eye and increased JNK signaling results in a reduction in the number of glia populating the eye disc, similar to that observed upon raw knockdown. Thus, Raw functions as a critical regulator of glial population of the eye imaginal disc by regulating glial proliferation and migration and inhibiting JNK signaling.

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Loss of focal adhesions in glia disrupts both glial and photoreceptor axon migration in the Drosophila visual system

Cited by 28 publications

References 58 publications

Drosophila glia: Few cell types and many conserved functions

Drosophila glia: Few cell types and many conserved functions

Drosophila PS2 and PS3 integrins play distinct roles in retinal photoreceptors–glia interactions

Raw regulates glial population of the eye imaginal disc

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