Choji Oki scite author profile

Small-molecule ligands that control the spatial location of proteins in living cells would be valuable tools for regulating biological systems. However, the creation of such molecules remains almost unexplored because of the lack of a design methodology. Here we introduce a conceptually new type of synthetic ligands, self-localizing ligands (SLLs), which spontaneously localize to specific subcellular regions in mammalian cells. We show that SLLs bind their target proteins and relocate (tether) them rapidly from the cytoplasm to their targeting sites, thus serving as synthetic protein translocators. SLL-induced protein translocation enables us to manipulate diverse synthetic/endogenous signaling pathways. The method is also applicable to reversible protein translocation and allows control of multiple proteins at different times and locations in the same cell. These results demonstrate the usefulness of SLLs in the spatial (and temporal) control of intracellular protein distribution and biological processes, opening a new direction in the design of small-molecule tools or drugs for cell regulation.

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Designer Palmitoylation Motif-Based Self-Localizing Ligand for Sustained Control of Protein Localization in Living Cells and Caenorhabditis elegans

Nakamura

Oki

Sawada

et al. 2020

ACS Chem. Biol.

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Inducing protein translocation to the plasma membrane (PM) is an important approach for manipulating diverse signaling molecules/pathways in living cells. We previously devised a new chemogenetic system, in which a protein fused to Escherichia coli dihydrofolate reductase (eDHFR) can be rapidly translocated from the cytoplasm to the PM using a trimethoprim (TMP)-based self-localizing ligand (SL), mgcTMP. However, mgcTMP-induced protein translocation turned out to be transient and spontaneously reversed within 1 h, limiting its application. Here, we first demonstrated that the spontaneous reverse translocation was caused by cellular degradation of mgcTMP, presumably by proteases. To address this problem, we newly developed a proteolysis-resistant SL, mDcTMP. This mDcTMP now allows sustained PM localization of eDHFR-fusion proteins (over several hours to a day), and it was applicable to inducing prolonged signal activation and cell differentiation. mDcTMP also worked in live nematodes, making it an attractive new tool for probing and controlling living systems.

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Engineering Orthogonal, Plasma Membrane-Specific SLIPT Systems for Multiplexed Chemical Control of Signaling Pathways in Living Single Cells

et al. 2020

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Most cell behaviors are the outcome of processing information from multiple signals generated upon cell stimulation. Thus, a systematic understanding of cellular systems requires methods that allow the activation of more than one specific signaling molecule or pathway within a cell. However, the construction of tools suitable for such multiplexed signal control remains challenging. In this work, we aimed to develop a platform for chemically manipulating multiple signaling molecules/pathways in living mammalian cells based on self-localizing ligand-induced protein translocation (SLIPT). SLIPT is an emerging chemogenetic tool that controls protein localization and cell signaling using synthetic self-localizing ligands (SLs). Focusing on the inner leaflet of the plasma membrane (PM), where there is a hub of intracellular signaling networks, here we present the design and engineering of two new PM-specific SLIPT systems based on an orthogonal eDHFR and SNAP-tag pair. These systems rapidly induce translocation of eDHFR- and SNAP-tag-fusion proteins from the cytoplasm to the PM specifically in a time scale of minutes upon addition of the corresponding SL. We then show that the combined use of the two systems enables chemically inducible, individual translocation of two distinct proteins in the same cell. Finally, by integrating the orthogonal SLIPT systems with fluorescent reporters, we demonstrate simultaneous multiplexed activation and fluorescence imaging of endogenous ERK and Akt activities in a single cell. Collectively, orthogonal PM-specific SLIPT systems provide a powerful new platform for multiplexed chemical signal control in living single cells, offering new opportunities for dissecting cell signaling networks and synthetic cell manipulation.

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Light-controllable RNA-protein devices for translational regulation of synthetic mRNAs in mammalian cells

Nakanishi

Yoshii

Kawasaki

et al. 2021

Cell Chemical Biology

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Functional visualization of NK cell-mediated killing of metastatic single tumor cells

Ichise

Tsukamoto

Hirashima

et al. 2022

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Natural killer (NK) cells lyse invading tumor cells to limit metastatic growth in the lung, but how some cancers evade this host protective mechanism to establish a growing lesion is unknown. Here we have combined ultra-sensitive bioluminescence imaging with intravital two-photon microscopy involving genetically-encoded biosensors to examine this question. NK cells eliminated disseminated tumor cells from the lung within 24 hrs of arrival, but not thereafter. Intravital dynamic imaging revealed that 50% of NK-tumor cell encounters lead to tumor cell death in the first 4 hrs after tumor cell arrival, but after 24 hrs of arrival, nearly 100% of the interactions result in the survival of the tumor cell. During this 24 hrs period, the probability of ERK activation in NK cells upon encountering the tumor cells was decreased from 68% to 8%, which correlated with the loss of the activating ligand CD155/PVR/Necl5 from the tumor cell surface. Thus, by quantitatively visualizing the NK-tumor cell interaction at the early stage of metastasis, we have revealed the crucial parameters of NK cell immune surveillance in the lung.

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Choji Oki

Synthetic Self-Localizing Ligands That Control the Spatial Location of Proteins in Living Cells

Designer Palmitoylation Motif-Based Self-Localizing Ligand for Sustained Control of Protein Localization in Living Cells and Caenorhabditis elegans

Engineering Orthogonal, Plasma Membrane-Specific SLIPT Systems for Multiplexed Chemical Control of Signaling Pathways in Living Single Cells

Light-controllable RNA-protein devices for translational regulation of synthetic mRNAs in mammalian cells

Functional visualization of NK cell-mediated killing of metastatic single tumor cells

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