Curated Optogenetic Publication Database

Abstract: Phospholipase D (PLD) and phosphatidic acid (PA) play a spatio-temporal role in regulating diverse cellular activities. Although current methodologies enable optical control of the subcellular localization of PLD and by which influence local PLD enzyme activity, the overexpression of PLD elevates the basal PLD enzyme activity and further leads to increased PA levels in cells. In this study, we employed a split protein reassembly strategy and optogenetic techniques to modify superPLD (a PLDPMF variant with a high basal activity). We splited this variants into two HKD domains and fused these domains with optogenetic elements and by which we achieved light-mediated dimerization of the two HKD proteins and then restored the PLD enzymatic activity.

Abstract: High-performance biosensors are crucial for elucidating the spatiotemporal regulatory roles and dynamics of membrane lipids, but there is a lack of improvement strategies for biosensors with low sensitivity and low-content substrates detection. Here we developed universal optogenetic strategies to improve a set of membrane biosensors by trapping them into specific region and further reducing the background signal, or by optically-controlled phase separation for membrane lipids detection and tracking. These improved biosensors were superior to typical tools and light simulation would enhance their detection performance and resolution, which might contribute to the design and optimization of other biosensors.

Abstract: Abstract not available.

Abstract: Cell-free systems, as part of the synthetic biology field, have become a critical platform in biological studies. However, there is a lack of research into developing a switch for a dynamical control of the transcriptional and translational process. The optogenetic tool has been widely proven as an ideal control switch for protein synthesis due to its nontoxicity and excellent time-space conversion. Hence, in this study, a blue light-regulated two-component system named YF1/FixJ was incorporated into an Escherichia coli-based cell-free system to control protein synthesis. The corresponding cell-free system successfully achieved a 5-fold dynamic protein expression by blue light repression and 3-fold dynamic expression by blue light activation. With the aim of expanding the applications of cell-free synthetic biology, the cell-free blue light-sensing system was used to perform imaging, light-controlled antibody synthesis, and light-triggered artificial cell assembly. This study can provide a guide for further research into the field of cell-free optical sensing. Moreover, it will also promote the development of cell-free synthetic biology and optogenetics through applying the cell-free optical sensing system to synthetic biology education, biopharmaceutical research, and artificial cell construction.

Abstract: Cryptochromes (CRYs) are a group of evolutionarily conserved flavoproteins found in many organisms. In plants, the well-studied CRY photoreceptor, activated by blue light, plays essential roles in plant growth and development. However, the mechanism of activation remains largely unknown. Here, we determined the oligomeric structures of the blue-light-perceiving PHR domain of Zea mays CRY1 and an Arabidopsis CRY2 constitutively active mutant. The structures form dimers and tetramers whose functional importance is examined in vitro and in vivo with Arabidopsis CRY2. Structure-based analysis suggests that blue light may be perceived by CRY to cause conformational changes, whose precise nature remains to be determined, leading to oligomerization that is essential for downstream signaling. This photoactivation mechanism may be widely used by plant CRYs. Our study reveals a molecular mechanism of plant CRY activation and also paves the way for design of CRY as a more efficient optical switch.