An Interscholastic Network to Generate LexA Enhancer Trap Lines in<i>Drosophila</i>

Kockel, Lutz; Griffin, Catherine; Ahmed, Yaseen; Fidelak, Lauren; Rajan, Arjun; Gould, Ethan P; Haigney, Miles; Ralston, Benjamin; Tercek, Rex J; Galligani, Lara; Rao, Sagar; Huq, Lutfi; Bhargava, Hersh K.; Dooner, Ailis C; Lemmerman, Emily G; Malusa, Ruby F.; Nguyen, Tran Hong Nha; Chung, Julie S; Gregory, Sara M.; Kuwana, Kiyomasa M.; Regenold, Jonathan; Wei, Alexander; Ashton, Jake; Dickinson, Patrick; Martel, Kate; Cai, Connie; Chen, Carissa; Price, Stephen J.; Qiao, Jeffrey; Shepley, David; Zhang, Joanna; Chalasani, Meghana; Nguyen, Khanh; Aalto, August; Kim, Byung-Jun; Tazawa-Goodchild, Erik; Sherwood, Amanda R.; Rahman, Azimah Abd; Wu, Sum Ying Celeste; Lotzkar, Joel; Michaels, Serena; Aristotle, Hillary; Clark, Antigone; Gasper, Grace; Xiang, Evan; Schlör, Frieda Luna; Lu, Melissa; Haering, Kate; Friberg, Julia; Kuwana, Alyssa; Liu, Alan; Norton, Emma; Hamad, Leena; Lee, Clara; Okeremi, Dara; diTullio, Harry; Dumoulin, Katherine; Gordon, Sun Yu; Derossi, Grayson S; Horowitch, Rose E; Issa, Elias C; Le, Dan T; Morales, Bryce C; Noori, Ayush; Shao, Justin; Cho, Sophia; Hoang, M.; Johnson, Ian M.; Lee, Katherine C.; Lee, Maria; Madamidola, Elizabeth A.; Byan, Gabriel; Park, Taeyoung; Chen, Jonathan; Monovoukas, Alexi; Kang, Madison J.; McGowan, Tanner; Walewski, Joseph J.; Simon, Brennan; Zu, Sophia J.; Miller, Grover P.; Fitzpatrick, Kate B; Lantz, Nicole; Fox, Elizabeth; Collette, Jeanette; Kurtz, Richard; Duncan, Chris; Palmer, Ryan; Rotondo, Cheryl; Janicki, Eric; Chisholm, Townley; Rankin, Anne E; Park, Sangbin; Kim, Seung K.

doi:10.1101/552513

Cited by 2 publications

(7 citation statements)

References 40 publications

(50 reference statements)

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“…This illustrates the feasibility of building an interscholastic network to generate unfulfilled scientific resource needs, while providing paradigms for STEM education. Resources and outcomes described here significantly extend, develop and complement the interscholastic partnerships in experiment-based science pedagogy described in our prior studies, which focused on generating LexA enhancer trap lines (Kockel et al 2016(Kockel et al , 2019. The current study involved collaborations between Stanford and Oxford University investigators with students and teachers at the Lawrenceville School and the Phillips Exeter Academy, two U.S. secondary schools.…”

Section: Discussionmentioning

confidence: 79%

“…For example, simultaneous use of two independent binary expression systems allowed clonal analysis of multiple cell populations (Lai and Lee 2006;Bosch et al 2015), studies of tissue epistasis (Yagi et al 2010), and elucidation of otherwise undetected contacts between cells (Gordon and Scott 2009;Macpherson et al 2015). To address a growing need for unique fly strains permitting flexible intersectional approaches, we are expanding our efforts to create new genetic tools suitable for this purpose (Kockel et al 2016(Kockel et al , 2019Wendler et al 2020). Here we describe (1) a genetic tool to convert existing Gal4 lines to LexA.G4H by CRISPR/Cas9-mediated gene editing, (2) a universal cloning method to generate LexAop-based shRNA transgenic lines from functionally validated UAS-based shRNA transgenic lines, and (3) a research-based pedagogy to leverage effort by collaborating students in our secondary school network (Kockel et al 2016(Kockel et al , 2019.…”

Section: Discussionmentioning

confidence: 99%

“…To address a growing need for unique fly strains permitting flexible intersectional approaches, we are expanding our efforts to create new genetic tools suitable for this purpose (Kockel et al 2016(Kockel et al , 2019Wendler et al 2020). Here we describe (1) a genetic tool to convert existing Gal4 lines to LexA.G4H by CRISPR/Cas9-mediated gene editing, (2) a universal cloning method to generate LexAop-based shRNA transgenic lines from functionally validated UAS-based shRNA transgenic lines, and (3) a research-based pedagogy to leverage effort by collaborating students in our secondary school network (Kockel et al 2016(Kockel et al , 2019. Our results demonstrate that in vivo gene regulation by LexAop-based gene suppression succeeded in multiple tissue contexts.…”

Section: Discussionmentioning

confidence: 99%

“…To address this need, we and others have made systematic efforts to expand the number of wellcharacterized, publicly available LexA fly lines, either by linking defined enhancers to sequences encoding LexA (Pfeiffer et al 2010) or by mobilizing a LexA-containing transposable element to insert at genomic sites near enhancers, resulting in 'enhancer trap' LexA lines with unique expression patterns (Kockel et al 2016(Kockel et al , 2019. Although these resources are slowly growing, there are many wellcharacterized Gal4 enhancer lines that lack cognate LexA lines.…”

Section: Introductionmentioning

confidence: 99%

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Transgenic Drosophila lines for LexA-dependent gene and growth regulation

Chang

Tsao

Bennett

et al. 2021

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Conditional expression of short hairpin RNAs (shRNAs) with binary genetic systems is an indispensable tool for studying gene function. Addressing mechanisms underlying cell-cell communication in vivo benefits from simultaneous use of two independent gene expression systems. To complement the abundance of existing Gal4/UAS-based resources in Drosophila, we and others have developed LexA/LexAop-based genetic tools. Here, we describe experimental and pedagogical advances that promote the efficient conversion of Drosophila Gal4 lines to LexA lines, and the generation of LexAop-shRNA lines to suppress gene function. We developed a CRISPR/Cas9-based knock-in system to replace Gal4 coding sequences with LexA, and a LexAop-based shRNA expression vector to achieve shRNA-mediated gene silencing. We demonstrate the use of these approaches to achieve targeted genetic loss-of-function in multiple tissues. We also detail our development of secondary school curricula that enable students to create transgenic flies, thereby magnifying the production of well-characterized LexA/LexAop lines for the scientific community. The genetic tools and teaching methods presented here provide LexA/LexAop resources that complement existing resources to study intercellular communication coordinating metazoan physiology and development.

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Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Transgenic Drosophila lines for LexA-dependent gene and growth regulation

Chang

Tsao

Bennett

et al. 2021

Preprint

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“…There are thousands of enhancer-LexA or -GAL4 drivers targeting several cell types simultaneously [11,14,27,120,121]. The LOV-LexA can be placed downstream of broadly expressed enhancers, in order to elicit transgene expression in the neuron type of interest with delivery of light specifically to its somata.…”

Section: Discussionmentioning

confidence: 99%

Spatial and temporal control of expression with light-gated LOV-LexA

Ribeiro

Essbauer

Kutlesa

et al. 2021

Preprint

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The ability to drive expression of exogenous genes in different tissues and cell types, under control of specific enhancers, has catapulted discovery in biology. While many enhancers drive expression broadly, several genetic tricks have been developed to obtain access to isolated cell types. However, studies of topographically organized neuropiles, such as the optic lobe in fruit flies, have raised the need for a system that can access subsets of cells within a single neuron type, a feat currently dependent on stochastic flip-out methods. To access the same subsets of cells consistently across flies, we developed LOV-LexA, a light-gated expression system based on the bacterial LexA transcription factor and the plant-derived LOV photosensitive domain. Expression of LOV-Lex in larval fat body as well as pupal and adult neurons enables spatial and temporal control of expression of transgenes under LexAop sequences with blue light. The LOV-LexA tool thus provides another layer of intersectional genetics, allowing for light-controlled genetic access to the same subsets of cells within an expression pattern across individual flies.

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An Interscholastic Network to Generate LexA Enhancer Trap Lines inDrosophila

Cited by 2 publications

References 40 publications

Transgenic Drosophila lines for LexA-dependent gene and growth regulation

Transgenic Drosophila lines for LexA-dependent gene and growth regulation

Spatial and temporal control of expression with light-gated LOV-LexA

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