Curated Optogenetic Publication Database

Search precisely and efficiently by using the advantage of the hand-assigned publication tags that allow you to search for papers involving a specific trait, e.g. a particular optogenetic switch or a host organism.

Showing 1 - 4 of 4 results
1.

Coordination of protrusion dynamics within and between collectively migrating border cells by myosin II.

blue AsLOV2 D. melanogaster in vivo Control of cytoskeleton / cell motility / cell shape
Mol Biol Cell, 7 Aug 2019 DOI: 10.1091/mbc.e19-02-0124 Link to full text
Abstract: Collective cell migration is emerging as a major driver of embryonic development, organogenesis, tissue homeostasis, and tumor dissemination. In contrast to individually migrating cells, collectively migrating cells maintain cell-cell adhesions and coordinate direction-sensing as they move. While non-muscle myosin II has been studied extensively in the context of cells migrating individually in vitro, its roles in cells migrating collectively in three-dimensional, native environments are not fully understood. Here we use genetics, Airyscan microscopy, live imaging, optogenetics, and Förster resonance energy transfer to probe the localization, dynamics, and functions of myosin II in migrating border cells of the Drosophila ovary. We find that myosin accumulates transiently at the base of protrusions, where it functions to retract them. E-cadherin and myosin co-localize at border cell-border cell contacts and cooperate to transmit directional information. A phosphomimetic form of myosin is sufficient to convert border cells to a round morphology and blebbing migration mode. Together these studies demonstrate that distinct and dynamic pools of myosin II regulate protrusion dynamics within and between collectively migrating cells and suggest a new model for the role of protrusions in collective direction sensing in vivo. Movie S1 Movie S1 Live imaging of border cell specification and delamination from anterior epithelium From Figure 1D-I. Slbo promoter driving Lifeact-GFP (green) marks border cells, Upd-Gal4, UAS-DsRed.nls (red) mark polar cell nuclei. Hoechst 33342 (blue) marks DNA. Time resolution is 4 min. Movie S2 Movie S2 Representative Z-projected and registered live imaging of Sqh-mCherry accumulating in cortical junctions (flashing arrows) during border cell migration. From Figure 3J-K. Time resolution is 25 sec. Movie S3 Movie S3 Representative Z-projected and registered live imaging of E-cad-GFP during border cell migration. From Figure 3M-N. Time resolution is 60 sec. Movie S4 Movie S4 Representative Z-projection of control flpout cells from hs-Flp;, Slbo>Lifeact-GFP; AyGal4, UAS-RFP. Clonal cells are marked by magenta nuclei (nls-RFP). Time resolution is 2.5 min. From Supp. Figure 3 A-D. Movie S5 Movie S5 Representative Z-projection of Sqh-RNAi flpout cells from hs-Flp;, Slbo>Lifeact-GFP; AyGal4, UAS-RFP, UAS-sqh-RNAi. Clonal cells are marked by magenta nuclei (nls-RFP). Time resolution is 2.5 min. From Supp. Figure 3 E-H. Movie S6 Movie S6 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-white RNAi. Time resolution is 2 min. From Supp. Figure 4 A-D. Movie S7 Movie S7 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-sqh-RNAi showing frequent side protrusions. Time resolution is 2 min. From Supp. Figure 4 E-H. White arrows indicate ectopic side and rear protrusions. Movie S8 Movie S8 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-sqh-RNAi showing long lived side protrusions. Time resolution is 2 min. From Supp. Figure 4 I-L. Movie S9 Movie S9 Representative Z-projected live imaging of c306-Gal4 driving UAS-white-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during periods of protrusive and round migration phases. From Figure 6A-D. 25 min corresponds to 6A and B and 1hr:25 min corresponds to 6C and D. Time resolution is 2.5 min. Movie S10 Movie S10 Sqh-mCherry (magenta) channel from Supplementary Movie 9. From Figure 6A-D. 25 min corresponds to 6A and B and 1hr:25 min corresponds to 6C and D. Time resolution is 2.5 min. Movie S11 Movie S11 Representative Z-projected live imaging of c306-Gal4 driving UAS-Ecad-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during a protrusive phase of migration. From Figure 6E-F. Time resolution is 2.5 min. Movie S12 Movie S12 Sqh-mCherry (magenta) channel from Supplementary Movie 11. From Figure 6E-F. Time resolution is 2.5 min. Movie S13 Movie S13 Representative Z-projected live imaging of c306-Gal4 driving UAS-Ecad-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during a rounded phase of migration. From Figure 6G-H. Time resolution is 2.5 min. Movie S14 Movie S14 Sqh-mCherry (magenta) channel from Supplementary Movie 13. From Figure 6G-H. Time resolution is 2.5 min. Movie S15 Movie S15 Example segmentation analysis from a representative Z-projected time lapse of a cluster expressing c306-Gal4 driving UAS-white-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during migration. Time lapse analyzed in Imaris by 1. segmentation of the cluster using Lifeact-GFP, 2. Rendering of Sqh-mCherry by masking the inside of the Life-act surface, 3. performing a distance transformation using the masked Sqh-mCherry that is color coded for distance from membrane (dark colors are short distances and bright/white colors are more distant), 4. combining the distance transformation with the Sqh-mCherry mask to only include the cortical 2 μm of the original Sqh-mCherry signal for quantification in Figure 6I. Movie S16 Movie S16 Representative Z-projected time lapse of Lifeact-GFP and Sqh-mCherry expressing clusters used for quantification of Figure 7B-C during protrusion/retractions cycles. Time resolution is 2 min. Movie S17 Movie S17 Sqh-mCherry channel from Supplementary movie 16. Time resolution is 2 min. Movie S18 Movie S18 Representative Z-projections of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-Sqh-E20E21 migrating border cells clusters that split. Time resolution is 2 min. Movie S19 Movie S19 Representative Z-projections of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-LifeactGFP and UAS-Sqh-E20E21 migrating border cells clusters during protrusive phase. Time resolution is 2 min. Movie S20 Movie S20 Representative Z-projection of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-Sqh-E20E21 border cells cluster at the oocyte border during a blebbing phase. Time resolution is 2 min. Movie S21 Movie S21 Representative Z-projection of control cluster expressing slbo-Gal4; UAS-PLCδ1-PH-GFP. Time resolution is 2 min. Movie S22 Movie S22 Representative Z-projection of cluster expressing slbo-Gal4; UAS-PLCδ1-PH-GFP, UAS-Rho1V14. Blebs are marked by white arrows. Time resolution is 2 min.
2.

Light activated cell migration in synthetic extracellular matrices.

blue AsLOV2 hMSCs Control of cytoskeleton / cell motility / cell shape
Biomaterials, 11 Aug 2012 DOI: 10.1016/j.biomaterials.2012.07.013 Link to full text
Abstract: Synthetic extracellular matrices provide a framework in which cells can be exposed to defined physical and biological cues. However no method exists to manipulate single cells within these matrices. It is desirable to develop such methods in order to understand fundamental principles of cell migration and define conditions that support or inhibit cell movement within these matrices. Here, we present a strategy for manipulating individual mammalian stem cells in defined synthetic hydrogels through selective optical activation of Rac, which is an intracellular signaling protein that plays a key role in cell migration. Photoactivated cell migration in synthetic hydrogels depended on mechanical and biological cues in the biomaterial. Real-time hydrogel photodegradation was employed to create geometrically defined channels and spaces in which cells could be photoactivated to migrate. Cell migration speed was significantly higher in the photo-etched channels and cells could easily change direction of movement compared to the bulk hydrogels.
3.

Spatiotemporal control of small GTPases with light using the LOV domain.

blue LOV domains Review
Meth Enzymol, 11 May 2011 DOI: 10.1016/b978-0-12-385075-1.00016-0 Link to full text
Abstract: Signaling networks in living systems are coordinated through subcellular compartmentalization and precise timing of activation. These spatiotemporal aspects ensure the fidelity of signaling while contributing to the diversity and specificity of downstream events. This is studied through development of molecular tools that generate localized and precisely timed protein activity in living systems. To study the molecular events responsible for cytoskeletal changes in real time, we generated versions of Rho family GTPases whose interactions with downstream effectors is controlled by light. GTPases were grafted to the phototropin LOV (light, oxygen, or voltage) domain (Huala, E., Oeller, P. W., Liscum, E., Han, I., Larsen, E., and Briggs, W. R. (1997). Arabidopsis NPH1: A protein kinase with a putative redox-sensing domain. Science278, 2120-2123.) via an alpha helix on the LOV C-terminus (Wu, Y. I., Frey, D., Lungu, O. I., Jaehrig, A., Schlichting, I., Kuhlman, B., and Hahn, K. M. (2009). A genetically encoded photoactivatable Rac controls the motility of living cells. Nature461, 104-108.). The LOV domain sterically blocked the GTPase active site until it was irradiated. Exposure to 400-500nm light caused unwinding of the helix linking the LOV domain to the GTPase, relieving steric inhibition. The change was reversible and repeatable, and the protein could be returned to its inactive state simply by turning off the light. The LOV domain incorporates a flavin as the active chromophore. This naturally occurring molecule is incorporated simply upon expression of the LOV fusion in cells or animals, permitting ready control of GTPase function in different systems. In cultured single cells, light-activated Rac leads to membrane ruffling, protrusion, and migration. In collectively migrating border cells in the Drosophila ovary, focal activation of photoactivatable Rac (PA-Rac) in a single cell is sufficient to redirect the entire group. PA-Rac in a single cell also rescues the phenotype caused by loss of endogenous guidance receptor signaling in the whole group. These findings demonstrate that cells within the border cell cluster communicate and are guided collectively. Here, we describe optimization and application of PA-Rac using detailed examples that we hope will help others apply the approach to different proteins and in a variety of different cells, tissues, and organisms.
4.

Light-mediated activation reveals a key role for Rac in collective guidance of cell movement in vivo.

blue AsLOV2 D. melanogaster in vivo Schneider 2 Control of cytoskeleton / cell motility / cell shape
Nat Cell Biol, 16 May 2010 DOI: 10.1038/ncb2061 Link to full text
Abstract: The small GTPase Rac induces actin polymerization, membrane ruffling and focal contact formation in cultured single cells but can either repress or stimulate motility in epithelial cells depending on the conditions. The role of Rac in collective epithelial cell movements in vivo, which are important for both morphogenesis and metastasis, is therefore difficult to predict. Recently, photoactivatable analogues of Rac (PA-Rac) have been developed, allowing rapid and reversible activation or inactivation of Rac using light. In cultured single cells, light-activated Rac leads to focal membrane ruffling, protrusion and migration. Here we show that focal activation of Rac is also sufficient to polarize an entire group of cells in vivo, specifically the border cells of the Drosophila ovary. Moreover, activation or inactivation of Rac in one cell of the cluster caused a dramatic response in the other cells, suggesting that the cells sense direction as a group according to relative levels of Rac activity. Communication between cells of the cluster required Jun amino-terminal kinase (JNK) but not guidance receptor signalling. These studies further show that photoactivatable proteins are effective tools in vivo.
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