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1. The bright frontiers of microbial metabolic optogenetics

   https://doi.org/10.1016/j.cbpa.2022.102207  

   Wegner, Scott A.; Barocio-Galindo, Rachel M.; Avalos, José L. (December 2022, Current Opinion in Chemical Biology)

   In recent years, light-responsive systems from the field of optogenetics have been applied to several areas of metabolic engineering with remarkable success. By taking advantage of light's high tunability, reversibility, and orthogonality to host endogenous processes, optogenetic systems have enabled unprecedented dynamical controls of microbial fermentations for chemical production, metabolic flux analysis, and population compositions in co-cultures. In this article, we share our opinions on the current state of this new field of metabolic optogenetics.We make the case that it will continue to impact metabolic engineering in increasingly new directions, with the potential to challenge existing paradigms for metabolic pathway and strain optimization as well as bioreactor operation. 

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2. Red-Light-Induced Genetic System for Control of Extracellular Electron Transfer

   https://doi.org/10.1021/acssynbio.3c00684  

   Zhao, Fengjie; Niman, Christina M; Ostovar, Ghazaleh; Chavez, Marko S; Atkinson, Joshua T; Bonis, Benjamin M; Gralnick, Jeffrey A; El-Naggar, Mohamed Y; Boedicker, James Q (May 2024, ACS Synthetic Biology)

   Optogenetics is a powerful tool for spatiotemporal control of gene expression. Several light-inducible gene regulators have been developed to function in bacteria, and these regulatory circuits have been ported to new host strains. Here, we developed and adapted a red-light-inducible transcription factor for Shewanella oneidensis. This regulatory circuit is based on the iLight optogenetic system, which controls gene expression using red light. A thermodynamic model and promoter engineering were used to adapt this system to achieve differential gene expression in light and dark conditions within a S. oneidensis host strain. We further improved the iLight optogenetic system by adding a repressor to invert the genetic circuit and activate gene expression under red light illumination. The inverted iLight genetic circuit was used to control extracellular electron transfer within S. oneidensis. The ability to use both red- and blue-light-induced optogenetic circuits simultaneously was also demonstrated. Our work expands the synthetic biology capabilities in S. oneidensis, which could facilitate future advances in applications with electrogenic bacteria. 

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3. Lights up on organelles: Optogenetic tools to control subcellular structure and organization

   https://doi.org/10.1002/wsbm.1500  

   Kichuk, Therese C.; Carrasco‐López, César; Avalos, José L. (July 2020, WIREs Mechanisms of Disease)

   Abstract Since the neurobiological inception of optogenetics, light‐controlled molecular perturbations have been applied in many scientific disciplines to both manipulate and observe cellular function. Proteins exhibiting light‐sensitive conformational changes provide researchers with avenues for spatiotemporal control over the cellular environment and serve as valuable alternatives to chemically inducible systems. Optogenetic approaches have been developed to target proteins to specific subcellular compartments, allowing for the manipulation of nuclear translocation and plasma membrane morphology. Additionally, these tools have been harnessed for molecular interrogation of organelle function, location, and dynamics. Optogenetic approaches offer novel ways to answer fundamental biological questions and to improve the efficiency of bioengineered cell factories by controlling the assembly of synthetic organelles. This review first provides a summary of available optogenetic systems with an emphasis on their organelle‐specific utility. It then explores the strategies employed for organelle targeting and concludes by discussing our perspective on the future of optogenetics to control subcellular structure and organization. This article is categorized under:Metabolic Diseases > Molecular and Cellular Physiology 

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4. Novel Optics-Based Approaches for Cardiac Electrophysiology: A Review

   https://doi.org/10.3389/fphys.2021.769586  

   Müllenbroich, M. Caroline; Kelly, Allen; Acker, Corey; Bub, Gil; Bruegmann, Tobias; Di Bona, Anna; Entcheva, Emilia; Ferrantini, Cecilia; Kohl, Peter; Lehnart, Stephan E.; et al (November 2021, Frontiers in Physiology)

   Optical techniques for recording and manipulating cellular electrophysiology have advanced rapidly in just a few decades. These developments allow for the analysis of cardiac cellular dynamics at multiple scales while largely overcoming the drawbacks associated with the use of electrodes. The recent advent of optogenetics opens up new possibilities for regional and tissue-level electrophysiological control and hold promise for future novel clinical applications. This article, which emerged from the international NOTICE workshop in 2018 1 , reviews the state-of-the-art optical techniques used for cardiac electrophysiological research and the underlying biophysics. The design and performance of optical reporters and optogenetic actuators are reviewed along with limitations of current probes. The physics of light interaction with cardiac tissue is detailed and associated challenges with the use of optical sensors and actuators are presented. Case studies include the use of fluorescence recovery after photobleaching and super-resolution microscopy to explore the micro-structure of cardiac cells and a review of two photon and light sheet technologies applied to cardiac tissue. The emergence of cardiac optogenetics is reviewed and the current work exploring the potential clinical use of optogenetics is also described. Approaches which combine optogenetic manipulation and optical voltage measurement are discussed, in terms of platforms that allow real-time manipulation of whole heart electrophysiology in open and closed-loop systems to study optimal ways to terminate spiral arrhythmias. The design and operation of optics-based approaches that allow high-throughput cardiac electrophysiological assays is presented. Finally, emerging techniques of photo-acoustic imaging and stress sensors are described along with strategies for future development and establishment of these techniques in mainstream electrophysiological research. 

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5. Overexpression of enhanced yellow fluorescent protein fused with Channelrhodopsin‐2 causes contractile dysfunction in skeletal muscle

   https://doi.org/10.1096/fj.202401664RR  

   Lamia, Syeda_N; Davis, Carol_S; Macpherson, Peter_C_D; Willingham, T_Brad; Zhang, Yingfan; Liu, Chengyu; Iannucci, Leanne; Ganji, Elahe; Harden, Desmond; Bhattacharya, Iman; et al (November 2024, The FASEB Journal)

   Abstract Skeletal muscle activation using optogenetics has emerged as a promising technique for inducing noninvasive muscle contraction and assessing muscle function both in vivo and in vitro. Transgenic mice overexpressing the optogenetic fusion protein, Channelrhodopsin 2‐EYFP (ChR2‐EYFP) in skeletal muscle are widely used; however, overexpression of fluorescent proteins can negatively impact the functionality of activable tissues. In this study, we characterized the contractile properties of ChR2‐EYFP skeletal muscle and introduced the ChR2‐only mouse model that expresses light‐responsive ChR2 without the fluorescent EYFP in their skeletal muscles. We found a significant reduction in the contractile ability of ChR2‐EYFP muscles compared with ChR2‐only and WT mice, observed under both electrical and optogenetic stimulation paradigms. Bulk RNAseq identified the downregulation of genes associated with transmembrane transport and metabolism in ChR2‐EYFP muscle, while the ChR2‐only muscle did not demonstrate any notable deviations from WT muscle. The RNAseq results were further corroborated by a reduced protein‐level expression of ion channel‐related HCN2 in ChR2‐EYFP muscles and gluconeogenesis‐modulating FBP2 in both ChR2‐EYFP and ChR2‐only muscles. Overall, this study reveals an intrinsic skeletal dysfunction in the widely used ChR2‐EYFP mice model and underscores the importance of considering alternative optogenetic models, such as the ChR2‐only, for future research in skeletal muscle optogenetics. 

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