Pai Peng scite author profile

In nature, the formation of spider silk fibers begins with dimerizing the pH‐sensitive N‐terminal domains of silk proteins (spidroins) upon lowering pH, and provides a natural masterpiece for programmable assembly. Inspired by the similarity of pH‐dependent dimerization behaviors, introduced here is an i‐motif‐guided model to mimic the initial step of spidroin assembly at the subcellular level. A framework nucleic acid (FNA) nanoplatform is designed using two tetrahedral DNA nanostructures (TDNs) with different branched vertexes carrying a bimolecular i‐motif and a split ATP aptamer. Once TDNs enter acidic lysosomes within living cells, they assemble into a heterodimeric architecture, thereby enabling the formation of a larger‐size framework and meanwhile subcellular imaging in response to endogenous ATP, which can be dynamically manipulated by adjusting intracellular pH and ATP levels with external drug stimuli.

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DNA Logic Operations in Living Cells Utilizing Lysosome-Recognizing Framework Nucleic Acid Nanodevices for Subcellular Imaging

Peng

2019

ACS Nano

123

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DNA logic nanodevices that in situ operate within living cells have attracted increasing interest and shown great promise for gene regulation and target recognition. A challenge remains how to control their activation inside specific cellular compartments. Toward this goal, here we report a lysosomerecognizing framework nucleic acid (FNA) nanodevice using an i-motif and an ATP-binding aptamer (ABA) incorporated into a DNA triangular prism (DTP) as the logic-controlling units. Once entering the lysosomal compartments, the FNA device responds to lysosomal pH and ATP via the folding of i-motif and ABA, which triggers a structural change of FNA and the release of a reporter structure for subcellular imaging. With endogenous proton and ATP as two inputs, an AND logic gate is built and in situ operated within living lysosomes by pH and ATP modulation with external drug stimuli. Given the abnormal levels of pH and ATP within some cancer cells or dysfunctional lysosomal cells, in this context our designed FNA logic device may find extended applications in controllable drug release and disease treatment.

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Environment‐Recognizing DNA‐Computation Circuits for the Intracellular Transport of Molecular Payloads for mRNA Imaging

et al. 2020

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Programming intelligent DNA nanocarriers for the targeted transport of molecular payloads in living cells has attracted extensive attention. In vivo activation of these nanocarriers usually relies on external light irradiation. An interest is emerging in the automatic recognition of intracellular surroundings by nanocarriers and their in situ activation under the control of programmed DNA‐computation circuits. Herein, we report the integration of DNA circuits with framework nucleic acid (FNA) nanocarriers that consist of a truncated square pyramid (TSP) cage and a built‐in duplex cargo containing an antisense strand of the target mRNA. An i‐motif and ATP aptamer embedded in the TSP are employed as logic‐controlling units to respond to H+ and ATP inside cellular compartments, triggering the release of the sensing element for fluorescent mRNA imaging. Logic‐controlled FNA devices could be used to target drug delivery, enabling precise disease treatment.

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Programmable i-motif DNA folding topology for a pH-switched reversible molecular sensing device

Shi

Peng

et al. 2017

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Four-stranded DNAs including G-quadruplexes and i-motifs are formed from four stretches of identical bases (G or C). A challenge remains in controlling the intermolecular folding of different G-rich or C-rich strands due to the self-association of each component. Here, we introduce a well-designed bimolecular i-motif that does not allow the dimerization of the same strand, and illustrate its usefulness in a pH-switched ATP-sensing DNA molecular device. We analyze two groups of i-motif DNAs containing two stretches of different C-residues (Cn-1TmCn and CnTmCn-1; n = 3−6, m = 1, 3) and show that their bimolecular folding patterns (L- and H-form) noticeably differs in the thermal stability. The L-form structures generally display a relatively low stability, with a bigger difference from that of conventional i-motifs formed by CnTmCn. It inspires us to at utmost improving the structural stability by extending the core of L-form bimolecular i-motifs with a few flanking noncanonical base pairs, and therefore to avoid the dimeric association of each component. This meaningful bimolecular i-motif is then incorporated into a three-way junction (3WJ) and a four-way junction (4WJ) functionalized with two components of a ATP-binding split DNA aptamer, allowing the pH-triggered directional assembly of 3WJ and 4WJ into the desired (3+4)WJ structure that is verified by gel electrophoresis. It therefore enables the ATP-induced association of the split aptamer within the (3+4)WJ structure, as monitored by fluorescence quenching. In this way, the designed DNA system behaves as a pH-switched reversible molecular device, showing a high sensitivity and selectivity for fluorescent ATP analysis. The i-motif folding topology-programmed DNA nanoassembly may find more applications in the context of larger 2D/3D DNA nanostructures like lattices and polyhedra.

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Logic‐Gated Proximity Aptasensing for Cell‐Surface Real‐Time Monitoring of Apoptosis

et al. 2021

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In nature, intact apoptotic cells release ATP as a signaling molecule to trigger prompt phagocytic clearance, even at the earliest stage of apoptosis. Inspired by this, here we introduce a straightforward strategy for real‐time monitoring ATP exocytosis and drug‐stimulated apoptosis in the cancer cell surroundings. Triplex‐boosted G‐quadruplexes (tb‐G4s) responding to cell environmental factors (H+ and K+) are engineered to construct a DNA logic‐gated nanoplatform for proximity ATP aptasensing on the cell surface. It enables the real‐time monitoring of cell apoptosis by capturing released endogenous ATP during chemotherapy drug stimulation, providing a sensitive approach for dynamically evaluating drug‐induced apoptosis and therapeutic efficacy.

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Pai Peng

Reconfigurable Bioinspired Framework Nucleic Acid Nanoplatform Dynamically Manipulated in Living Cells for Subcellular Imaging

DNA Logic Operations in Living Cells Utilizing Lysosome-Recognizing Framework Nucleic Acid Nanodevices for Subcellular Imaging

Environment‐Recognizing DNA‐Computation Circuits for the Intracellular Transport of Molecular Payloads for mRNA Imaging

Programmable i-motif DNA folding topology for a pH-switched reversible molecular sensing device

Logic‐Gated Proximity Aptasensing for Cell‐Surface Real‐Time Monitoring of Apoptosis

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