Showing 1 - 3 of 3 results
1.
Light-dependent modulation of protein localization and function in living bacteria cells.
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McQuillen, R
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Perez, AJ
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Yang, X
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Bohrer, CH
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Smith, EL
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Chareyre, S
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Tsui, HT
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Bruce, KE
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Hla, YM
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McCausland, JW
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Winkler, ME
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Goley, ED
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Ramamurthi, KS
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Xiao, J
Abstract:
Most bacteria lack membrane-enclosed organelles and rely on macromolecular scaffolds at different subcellular locations to recruit proteins for specific functions. Here, we demonstrate that the optogenetic CRY2-CIB1 system from Arabidopsis thaliana can be used to rapidly direct proteins to different subcellular locations with varying efficiencies in live Escherichia coli cells, including the nucleoid, the cell pole, the membrane, and the midcell division plane. Such light-induced re-localization can be used to rapidly inhibit cytokinesis in actively dividing E. coli cells. We further show that CRY2-CIBN binding kinetics can be modulated by green light, adding a new dimension of control to the system. Finally, we test this optogenetic system in three additional bacterial species, Bacillus subtilis, Caulobacter crescentus, and Streptococcus pneumoniae, providing important considerations for this system's applicability in bacterial cell biology.
2.
Optogenetics Methods and Protocols
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Haller, DJ
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Castillo-Hair, SM
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Tabor, JJ
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Harmer, ZP
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McClean, MN
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Renzl, C
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Mayer, G
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Nakajima, T
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Kuwasaki, Y
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Yamamoto, S
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Otabe, T
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Sato, M
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Shkarina, K
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Broz, P
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Jia Ying Toh, P
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Kroll, KL
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Sosnick, TR
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Rock, RS
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Tadimarri, VS
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Sankaran, S
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Lindner, F
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Grossmann, S
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Diepold, A
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Knapp, F
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Hogenkamp, F
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Paik, S
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Jaeger, K
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Pietruszka, J
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Drepper, T
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Armbruster, A
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Hörner, M
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Weber, W
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Jaeger, M
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Vincentelli, R
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Lasserre, R
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Qiu, K
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Xu, X
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Zhang, K
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Diao, J
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Song, Y
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Huang, P
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Duan, L
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Li, M
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Park, BM
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Li, Z
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Huang, W
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Sun, F
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Gerrard, EJ
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Tichy, A
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Janovjak, H
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Gangemi, CG
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Wegner, SV
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Raab, CA
Abstract:
This volume explores the latest advancements in the field of optogenetics and how it uses cellular light-sensing components and genetic engineering to control proteins and biological processes. The book chapters are organized into four parts. Part One focuses on intracellular optogenetic components for control of specific cell functions; Part Two looks at externally supplied light regulators that do not require genetic manipulation of target cells; Part Three highlights optogenetic control of organelles, and Part Four introduces technical tools required for light induction in optogenetic experiments, as well as a method for performing and analyzing optogenetic cell-cell adhesion. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Cutting-edge and practical, Optogenetics: Methods and Protocols is a valuable resource to help researchers understand and apply the concepts of optogenetics and the underlying bioengineering principles, and establish the required technical light-illumination setups for administering light inputs and analysis of experimental outcomes.
3.
Optogenetic control of Bacillus subtilis gene expression.
Abstract:
The Gram-positive bacterium Bacillus subtilis exhibits complex spatial and temporal gene expression signals. Although optogenetic tools are ideal for studying such processes, none has been engineered for this organism. Here, we port a cyanobacterial light sensor pathway comprising the green/red photoreversible two-component system CcaSR, two metabolic enzymes for production of the chromophore phycocyanobilin (PCB), and an output promoter to control transcription of a gene of interest into B. subtilis. Following an initial non-functional design, we optimize expression of pathway genes, enhance PCB production via a translational fusion of the biosynthetic enzymes, engineer a strong chimeric output promoter, and increase dynamic range with a miniaturized photosensor kinase. Our final design exhibits over 70-fold activation and rapid response dynamics, making it well-suited to studying a wide range of gene regulatory processes. In addition, the synthetic biology methods we develop to port this pathway should make B. subtilis easier to engineer in the future.
