Yuka Hatano

Bio: Yuka Hatano is an academic researcher from Nagoya Institute of Technology. The author has contributed to research in topics: Protein subcellular localization prediction & Fusion protein. The author has an hindex of 2, co-authored 4 publications receiving 5 citations.

An Improved Intracellular Synthetic Lipidation-Induced Plasma Membrane Anchoring System for SNAP-Tag Fusion Proteins.

Abstract: The ability to chemically introduce lipid modifications to specific intracellular protein targets would enable the conditional control of protein localization and activity in living cells. We recently developed a chemical-genetic approach in which an engineered SNAP-tag fusion protein can be rapidly relocated and anchored from the cytoplasm to the plasma membrane (PM) upon post-translational covalent lipopeptide conjugation in cells. However, the first-generation system achieved only low to moderate protein anchoring (recruiting) efficiencies and lacked wide applicability. Herein, we describe the rational design of an improved system for intracellular synthetic lipidation-induced PM anchoring of SNAP-tag fusion proteins. In the new system, the SNAPf protein engineered to contain an N-terminal hexalysine (K6) sequence and a C-terminal 10-amino acid deletion, termed K6-SNAPΔ, is fused to a protein of interest. In addition, a SNAP-tag substrate containing a metabolic-resistant myristoyl-DCys lipopeptidomimetic, called mDcBCP, is used as a cell-permeable chemical probe for intracellular SNAP-tag lipidation. The use of this combination allows significantly improved conditional PM anchoring of SNAP-tag fusion proteins. This second-generation system was applied to activate various signaling proteins, including Tiam1, cRaf, PI3K, and Sos, upon synthetic lipidation-induced PM anchoring/recruitment, offering a new and useful research tool in chemical biology and synthetic biology.

A chemogenetic platform for controlling plasma membrane signaling and synthetic signal oscillation

Abstract: Chemogenetic methods that enable the rapid translocation of specific signaling proteins in living cells using small molecules are powerful tools for manipulating and interrogating intracellular signaling networks. However, existing techniques rely on chemically induced dimerization of two protein components and have certain limitations, such as a lack of reversibility, bioorthogonality, and usability. Here, by expanding our self-localizing ligand-induced protein translocation (SLIPT) approach, we have developed a versatile chemogenetic system for plasma membrane (PM)-targeted protein translocation. In this system, a novel engineered Escherichia coli dihydrofolate reductase in which a hexalysine (K6) sequence is inserted in a loop region (iK6DHFR) is used as a universal protein tag for PM-targeted SLIPT. Proteins of interest that are fused to the iK6DHFR tag can be specifically recruited from the cytoplasm to the PM within minutes by addition of a myristoyl-O_SCPLOWDC_SCPLOW-Cys-tethered trimethoprim ligand (mDcTMP). We demonstrated the broad applicability and robustness of this engineered protein-synthetic ligand pair as a tool for the conditional activation of various types of signaling molecules, including protein and lipid kinases, small GTPases, heterotrimeric G proteins, and second messengers. In combination with a competitor ligand and a culture-medium flow chamber, we further demonstrated the application of the system for chemically manipulating protein localization in a reversible and repeatable manner to generate synthetic signal oscillations in living cells. The present bioorthogonal iK6DHFR/mDcTMP-based SLIPT system affords rapid, reversible, and repeatable control of the PM recruitment of target proteins, offering a versatile and easy-to-use chemogenetic platform for chemical and synthetic biology applications.

Improved synthetic lipidation-based protein translocation system for SNAP-tag fusion proteins

Abstract: The ability to artificially attach lipids to specific intracellular protein targets would be a valuable approach for controlling protein localization and function in cells. We recently devised a chemogenetic method in which a SNAP-tag fusion protein can be translocated from the cytoplasm to the plasma membrane by post-translationally and covalently conjugating a synthetic lipopeptide in cells. However, the first-generation system lacked general applicability. Herein, we present an improved synthetic lipidation system that enables efficient plasma membrane translocation of SNAP-tag fusion proteins in cells. This second-generation system is now applicable to the control of various cell-signaling molecules, offering a new and useful research tool in chemical biology and synthetic biology.

Chemogenetic Control of Protein Localization and Mammalian Cell Signaling by SLIPT.

Abstract: Chemical control of protein localization is a powerful approach for manipulating mammalian cellular processes. Self-localizing ligand-induced protein translocation (SLIPT) is an emerging platform that enables control of protein localization in living mammalian cells using synthetic self-localizing ligands (SLs). We recently established a chemogenetic SLIPT system, in which any protein of interest fused to an engineered variant of Escherichia coli dihydrofolate reductase, DHFRiK6, can be rapidly and specifically translocated from the cytoplasm to the inner leaflet of the plasma membrane (PM) using a trimethoprim (TMP)-based PM-targeting SL, mDcTMP. The mDcTMP-mediated PM recruitment of DHFRiK6-fusion proteins can be efficiently returned to the cytoplasm by subsequent addition of free TMP, enabling temporal and reversible control over the protein localization. Here we describe the use of this mDcTMP/DHFRiK6-based SLIPT system for inducing (1) reversible protein translocation and (2) synthetic activation of the Raf/ERK pathway. This system provides a simple and versatile tool in mammalian synthetic biology for temporally manipulating various signaling molecules and pathways at the PM.

Synthetic Protein Condensates That Inducibly Recruit and Release Protein Activity in Living Cells.

Abstract: Compartmentation of proteins into biomolecular condensates or membraneless organelles formed by phase separation is an emerging principle for the regulation of cellular processes. Creating synthetic condensates that accommodate specific intracellular proteins on demand would have various applications in chemical biology, cell engineering, and synthetic biology. Here, we report the construction of synthetic protein condensates capable of recruiting and/or releasing proteins of interest in living mammalian cells in response to a small molecule or light. By a modular combination of a tandem fusion of two oligomeric proteins, which forms phase-separated synthetic protein condensates in cells, with a chemically induced dimerization tool, we first created a chemogenetic protein condensate system that can rapidly recruit target proteins from the cytoplasm to the condensates by addition of a small-molecule dimerizer. We next coupled the protein-recruiting condensate system with an engineered proximity-dependent protease, which gave a second protein condensate system wherein target proteins previously expressed inside the condensates are released into the cytoplasm by small-molecule-triggered protease recruitment. Furthermore, an optogenetic condensate system that allows reversible release and sequestration of protein activity in a repeatable manner using light was constructed successfully. These condensate systems were applicable to control protein activity and cellular processes such as membrane ruffling and ERK signaling in a time scale of minutes. This proof-of-principle work provides a new platform for chemogenetic and optogenetic control of protein activity in mammalian cells and represents a step toward tailor-made engineering of synthetic protein condensate-based soft materials with various functionalities for biological and biomedical applications.

Chemo-optogenetic Protein Translocation System Using a Photoactivatable Self-Localizing Ligand.

Abstract: Manipulating subcellular protein localization using light is a powerful approach for controlling signaling processes with high spatiotemporal precision. The most widely used strategy for this is based on light-induced protein heterodimerization. The use of small synthetic molecules that can control the localization of target proteins in response to light without the need for a second protein has several advantages. However, such methods have not been well established. Herein, we present a chemo-optogenetic approach for controlling protein localization using a photoactivatable self-localizing ligand (paSL). We developed a paSL that can recruit tag-fused proteins of interest from the cytoplasm to the plasma membrane within seconds upon light illumination. This paSL-induced protein translocation (paSLIPT) is reversible and enables the spatiotemporal control of signaling processes in living cells, even in a local region. paSLIPT can also be used to implement simultaneous optical stimulation and multiplexed imaging of molecular processes in a single cell, offering an attractive and novel chemo-optogenetic platform for interrogating and engineering dynamic cellular functions.

A chemogenetic platform for controlling plasma membrane signaling and synthetic signal oscillation

Abstract: Chemogenetic methods enabling the rapid translocation of specific proteins to the plasma membrane (PM) in a single protein-single ligand manner are useful tools in cell biology. We recently developed a technique, in which proteins fused to an Escherichia coli dihydrofolate reductase (eDHFR) variant carrying N-terminal hexalysine residues are recruited from the cytoplasm to the PM using the synthetic myristoyl-d-Cys-tethered trimethoprim (mDcTMP) ligand. However, this system achieved PM-specific translocation only when the eDHFR tag was fused to the N terminus of proteins, thereby limiting its application. In this report, we engineered a universal PM-targeting tag for mDcTMP-induced protein translocation by grafting the hexalysine motif into an intra-loop region of eDHFR. We demonstrate the broad applicability of the new loop-engineered eDHFR tag and mDcTMP pair for conditional PM recruitment and activation of various tag-fused signaling proteins with different fusion configurations and for reversibly and repeatedly controlling protein localization to generate synthetic signal oscillations.