Curated Optogenetic Publication Database

Abstract: Inflammatory bowel disease demands spatiotemporally precise drug delivery, yet the variable gut redox environment limits stimuli-responsive nanocarriers. Here we report a living biohybrid platform in which optogenetically engineered Shewanella oneidensis MR-1 is electrostatically conjugated with azo-bond covalent organic frameworks (TA-COFs) loaded with anti-inflammatory drugs magnolol or 4-iodobenzoic acid. Under intestinal conditions and non-invasive red-light irradiation (660 nm), light-induced restoration of the metal-reducing pathway promotes extracellular electron transfer, thereby cleaving azo bonds in the COF. This triggers rapid structural disassembly and a 2.8-fold increase in drug release. Although wild-type Shewanella is thermally inactivated at 37 °C and cannot utilize abundant colonic acetate, expression of heat-shock genes (groES/thiF) and an acetate-to-TCA pathway (ato1/ato2/gltA) confers 37 °C tolerance and robust metabolism in the gut. In DSS-induced colitis mice, oral administration of the biohybrid significantly alleviates inflammation, restores epithelial barrier integrity, rebalances gut microbiota (enrichment of Akkermansia, Muribaculaceae, and Lachnospiraceae). This work presents a generalizable strategy for constructing electroactive living composites by integrating microbial electron generation with stimuli-responsive nanomaterials, offering a new paradigm for light-programmed smart therapeutics and programmable living materials in biomedical applications.

Abstract: Performance of near-infrared probes and optogenetic tools derived from bacterial phytochromes is limited by availability of their biliverdin chromophore. To address this, we use a biliverdin reductase-A knock-out mouse model (Blvra-/-), which elevates endogenous biliverdin levels. We show that Blvra⁻/⁻ significantly enhances function of bacterial phytochrome-based systems. Light-controlled transcription using iLight optogenetic tool improves ~25-fold in Blvra-/- cells, compared to wild-type controls, and achieves ~100-fold activation in neurons. Light-induced insulin production in Blvra-/- mice reduces blood glucose by ~60% in diabetes model. To overcome depth limitations in imaging, we employ 3D photoacoustic, ultrasound, and two-photon fluorescence microscopy. This enables simultaneous photoacoustic imaging of DrBphP in neurons and super-resolution ultrasound localization microscopy of brain vasculature at depths of ~7 mm through intact scalp and skull. Two-photon microscopy achieves cellular resolution of miRFP720-expressing neurons at ~2.2 mm depth. Overall, Blvra-/- model represents powerful platform for improving efficacy of biliverdin-dependent tools for deep-tissue imaging and optogenetic manipulation.

Abstract: Bacteria-based therapies hold great promise for cancer treatment due to their selective tumor colonization and proliferation. However, clinical application is hindered by the need for safe, precise control systems to regulate local therapeutic payload expression and release. Here we developed a near-infrared (NIR) light-mediated PadC-based photoswitch (NETMAP) system based on a chimeric phytochrome-activated diguanylyl cyclase (PadC) and a cyclic diguanylate monophosphate-dependent transcriptional activator (MrkH). The NETMAP-engineered bacteria exhibited antitumor performance in mouse tumor models with different levels of immunogenicity. Specifically, in immunogenic lymphoma tumors, NIR-induced PD-L1 and CTLA-4 nanobodies enhanced the activation of adaptive immunity. In low-immunogenic tumors-including mouse-derived colon cancer models, an orthotopic human breast cancer cell line-derived xenograft model and a colorectal cancer patient-derived xenograft model-NIR-induced azurin and cytolysin A predominantly led to tumor inhibition. Our study identifies an NIR light-mediated therapeutic platform for engineered bacteria-based therapies with customizable outputs and precise dosage control.

Abstract: We developed near-infrared (NIR) photoacoustic and fluorescence probes, as well as optogenetic tools from bacteriophytochromes, and enhanced their performance using biliverdin reductase-A knock-out model (Blvra-/-). Blvra-/- elevates endogenous heme-derived biliverdin chromophore for bacteriophytochrome-derived NIR constructs. Consequently, light-controlled transcription with IsPadC-based optogenetic tool improved up to 25-fold compared to wild-type cells, with 100-fold activation in Blvra-/- neurons. In vivo, light-induced insulin production in Blvra-/- reduced blood glucose in diabetes by ∼60%, indicating high potential for optogenetic therapy. Using 3D photoacoustic, ultrasound, and two-photon fluorescence imaging, we overcame depth limitations of recording NIR probes. We achieved simultaneous photoacoustic imaging of DrBphP in neurons and super-resolution ultrasound localization microscopy of blood vessels ∼7 mm deep in the brain, with intact scalp and skull. Two-photon microscopy provided cell-level resolution of miRFP720-expressing neurons ∼2.2 mm deep. Blvra-/- significantly enhances efficacy of biliverdin-dependent NIR systems, making it promising platform for interrogation and manipulation of biological processes.

Abstract: 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.

Abstract: Optogenetic tools (OTs) operating in the far-red and near-infrared (NIR) region offer advantages for light-controlling biological processes in deep tissues and spectral multiplexing with fluorescent probes and OTs acting in the visible range. However, many NIR OTs suffer from background activation in darkness. Through shortening linkers, we engineered a novel NIR OT, iLight2, which exhibits a significantly reduced background activity in darkness, thereby increasing the light-to-dark activation contrast. The resultant optimal configuration of iLight2 components suggests a molecular mechanism of iLight2 action. Using a biliverdin reductase knock-out mouse model, we show that iLight2 exhibits advanced performance in mouse primary cells and deep tissues in vivo. Efficient light-controlled cell migration in wound healing cellular model demonstrates the possibility of using iLight2 in therapy and, overall, positions it as a valuable addition to the NIR OT toolkit for gene transcription applications.

Abstract: Near-infrared (NIR) optogenetic systems for transcription regulation are in high demand because NIR light exhibits low phototoxicity, low scattering, and allows combining with probes of visible range. However, available NIR optogenetic systems consist of several protein components of large size and multidomain structure. Here, we engineer single-component NIR systems consisting of evolved photosensory core module of Idiomarina sp. bacterial phytochrome, named iLight, which are smaller and packable in adeno-associated virus. We characterize iLight in vitro and in gene transcription repression in bacterial and gene transcription activation in mammalian cells. Bacterial iLight system shows 115-fold repression of protein production. Comparing to multi-component NIR systems, mammalian iLight system exhibits higher activation of 65-fold in cells and faster 6-fold activation in deep tissues of mice. Neurons transduced with viral-encoded iLight system exhibit 50-fold induction of fluorescent reporter. NIR light-induced neuronal expression of green-light-activatable CheRiff channelrhodopsin causes 20-fold increase of photocurrent and demonstrates efficient spectral multiplexing.