Yulin Du scite author profile

Cell−cell interactions are mediated through compositions expressed on the membrane. Engineering the cell surface to display functional modules with high biocompatibility, high controllability, and high stability would offer great opportunities for studying and manipulating these intercellular reactions. However, it remains a technical challenge because of the complex and dynamic nature of the cell membrane. Herein, by using three-dimensional (3D) amphiphilic pyramidal DNA as the scaffold, we develop a biocompatible, effective, and versatile strategy for engineering the cell surface with DNA probes. Compared with linear DNA constructs, these pyramidal probes show higher (nearly 100-fold) membrane-anchoring stability and higher (about 2.5-fold) target accessibility. They enable specific, effective, and tunable connections between cells. Meanwhile, our results indicate that connecting cells in close proximity are critical to initiate intercellular communication. By combining high programmability and high diversity of DNA probes, this strategy is expected to provide a powerful and designable membrane-anchored nanoplatform for studying multicellular communication networks.

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Aptamer-based optical manipulation of protein subcellular localization in cells

Xie

Zhang

et al. 2020

Nat Commun

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Protein-dominant cellular processes cannot be fully decoded without precise manipulation of their activity and localization in living cells. Advances in optogenetics have allowed spatiotemporal control over cellular proteins with molecular specificity; however, these methods require recombinant expression of fusion proteins, possibly leading to conflicting results. Instead of modifying proteins of interest, in this work, we focus on design of a tunable recognition unit and develop an aptamer-based near-infrared (NIR) light-responsive nanoplatform for manipulating the subcellular localization of specific proteins in their native states. Our results demonstrate that this nanoplatform allows photocontrol over the cytoplasmicnuclear shuttling behavior of the target RelA protein (a member of the NF-κβ family), enabling regulation of RelA-related signaling pathways. With a modular design, this aptamer-based nanoplatform can be readily extended for the manipulation of different proteins (e.g., lysozyme and p53), holding great potential to develop a variety of label-free protein photoregulation strategies for studying complex biological events.

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Membrane-anchored DNA nanojunctions enable closer antigen-presenting cell–T-cell contact in elevated T-cell receptor triggering

Lyu

Lin

et al. 2023

Nat. Nanotechnol.

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Functional nucleic acid-based cell imaging and manipulation

et al. 2021

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Chemically Synthetic Membrane Receptors Establish Cells with Artificial Sense-and-Respond Signaling Pathways

Zheng

Ling

et al. 2023

J. Am. Chem. Soc.

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Chemically synthetic receptors that establish cells a new sense-and-respond capability to interact with outer worlds are highly desired, but rarely reported. In this work, we develop a membrane-anchored synthetic receptor (Ts-pHLIP-Pr) using DNA and peptide as the building block to equip cells with artificial signaling pathways. Upon sensing external pH stimuli, the Pr module can be translocated across the cell membrane via the conformation switch of pHLIP, enabling membrane-proximal recruitment of specific proteins to trigger downstream signaling cascades. Our experimental results demonstrate the capability of Ts-pHLIP-Pr for regulating PKCε-related signaling events upon responding to external pH reduction. With a modular feature, this receptor can be extended to elicit T cell activation through low-pH environment-induced directional movement of cytoplasmic ZAP70. Our work is expected to offer a new paradigm for intelligent synthetic biology and customized cell engineering.

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Artificial Sandwich Base for Monitoring Single-Nucleobase Changes and Charge-Transfer Rates in DNA

et al. 2018

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Developing a convenient method to discriminate among different types of DNA nucleotides within a target sequence of the human genome is extremely challenging. We herein report an artificial ferrocene-base (Fe-base) that was synthesized and incorporated into different loci of a DNA strand. The Fe-base replacement on a nucleobase can interact with DNA bases and efficiently discriminate among A, T, G, and C DNA bases of the complementary locus on the basis of interacting electrochemical properties. Furthermore, cyclic-voltammetry (CV) studies demonstrated the electrochemical stability of DNA strands incorporated with Fe-bases and the reversibility of the incorporation. Square-wave voltammetry (SWV) was performed to measure current changes between Fe-bases and bases of interest in the DNA duplex. The changes in the charge-transfer rates appeared to be correlated with the position of the Fe-base in the DNA strand, allowing rapid and efficient sensing of single-nucleobase changes in DNA and showing promise for the design of Fe-oligomer chip technology as a tool for DNA sequencing.

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Ligand Dilution Analysis Facilitates Aptamer Binding Characterization at the Single‐Molecule Level

Lyu

et al. 2022

Angew Chem Int Ed

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Cell-specific aptamers offer a powerful tool to study membrane receptors at the single-molecule level. Most target receptors of aptamers are highly expressed on the cell surface, but difficult to analyze in situ because of dense distribution and fast velocity. Therefore, we herein propose a random sampling-based analysis strategy termed ligand dilution analysis (LDA) for easily implemented aptamer-based receptor study.Receptor density on the cell surface can be calculated based on a regression model. By using a synergistic ligand dilution design, colocalization and differentiation of aptamer and monoclonal antibody (mAb) binding on a single receptor can be realized. Once this is accomplished, precise binding site and detailed aptamerreceptor binding mode can be further determined using molecular docking and molecular dynamics simulation. The ligand dilution strategy also sets the stage for an aptamer-based dynamics analysis of two-and threedimensional motion and fluctuation of highly expressed receptors on the live cell membrane.

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A Dynamic Control Center Based on a DNA Reaction Network for Programmable Building of DNA Nanostructures

Chen

Wang

et al. 2023

ACS Nano

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DNA-based nanostructures allow for complex self-assembly with nanometer precision through the specificity of Watson−Crick base pairing, but network behavior-directed control of the kinetic process is less studied. Here we show how the DNA reaction network (DRN), which has emerged as a reliable and programmable way to implement artificial network dynamics, can be built as the control center of programmable nanostructures, allowing spatiotemporal control over the dynamic behavior of DNA nanotubes. We chose a common network motif in biological control systems, the feed-forward loop, as the model network and demonstrated that dynamic behaviors, such as self-tuning control and multilayer hierarchical assembly, could be programmed by constructing an inhibition network and an excitation network, separately, in buffer solution and inside protocells.

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Yulin Du

Cell-Membrane-Anchored DNA Nanoplatform for Programming Cellular Interactions

Aptamer-based optical manipulation of protein subcellular localization in cells

Membrane-anchored DNA nanojunctions enable closer antigen-presenting cell–T-cell contact in elevated T-cell receptor triggering

Functional nucleic acid-based cell imaging and manipulation

Chemically Synthetic Membrane Receptors Establish Cells with Artificial Sense-and-Respond Signaling Pathways

Artificial Sandwich Base for Monitoring Single-Nucleobase Changes and Charge-Transfer Rates in DNA

Ligand Dilution Analysis Facilitates Aptamer Binding Characterization at the Single‐Molecule Level

A Dynamic Control Center Based on a DNA Reaction Network for Programmable Building of DNA Nanostructures

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