Curated Optogenetic Publication Database

Abstract: Wnt/β-catenin signaling and its dysregulation play critical roles in the fate determination of stem cells and the pathology of various diseases. However, the application of translated Wnt ligand in regenerative medicine is hampered by its hydrophobicity and cross-reactivity with Frizzled (FZD) receptors. Here, we generate an engineered water-soluble, FZD subtype-specific agonist, RRP-pbFn, for high-efficiency Wnt/β-catenin signaling activation. In the absence of direct binding to LRP5/6, RRP-pbFn stimulates Wnt/β-catenin signaling more potently than surrogate Wnt. RRP-pbFn supports the growth of a variety of mouse and human organoids, and induces the expansion of liver and intestine progenitors in vivo. Meanwhile, we develop a synthetic LRP antagonist, RRP-Dkk1c, which exhibits heightened effectiveness in attenuating Wnt/β-catenin signaling activity compared to Dkk1, thereby abolishing the formation of CT26-derived colon cancer xenograft in vivo. Together, these two paired Wnt/β-catenin signaling manipulators hold great promise for biomedical research and potential therapeutics.

Abstract: The myocardin‐related transcription factor A (MRTF‐A) controls the transcriptional activity of the serum response factor (SRF) in a tightly controlled actin‐dependent manner. In turn, MRTF‐A is crucial for many actin‐dependent processes including adhesion, migration, and contractility and has emerged as novel targets for anti‐tumor strategies. MRTF‐A rapidly shuttles between cytoplasmic and nuclear compartment via dynamic actin interactions within its N‐terminal RPEL domain. Here, optogenetics is used to spatiotemporally control MRTF‐A nuclear localization by blue light using the light‐oxygen‐voltage‐sensing domain 2‐domain based system LEXY (light‐inducible nuclear export system). It is found that light‐regulated nuclear export of MRTF‐A occurs within 10–20 min. Importantly, MRTF‐A‐LEXY shuttling is independent of perturbations of actin dynamics. Furthermore, light‐regulation of MRTF‐A‐LEXY is reversible and repeatable for several cycles of illumination and its subcellular localization correlates with SRF transcriptional activity. As a consequence, optogenetic control of MRTF‐A subcellular localization determines subsequent cytoskeletal dynamics such as non‐apoptotic plasma membrane blebbing as well as invasive tumor‐cell migration through 3D collagen matrix. This data demonstrate robust optogenetic regulation of MRTF as a powerful tool to control SRF‐dependent transcription as well as cell motile behavior.