Leiliang He

Self-Assembled Supramolecular Nanoprobes for Ratiometric Fluorescence Measurement of Intracellular pH Values

Self-assembly of small building blocks into functional supramolecular nanostructure has opened prospects for the design of novel materials. With this molecular engineering strategy, we have developed self-assembled supramolecular nanoprobes (SSNPs) for ratiometric fluorescence measurement of pH values in cells. The nanoprobes with a diameter of ∼30 nm could be formulated just by mixing pH-sensitive adamantane-fluorescein (Ad-F) and pH-insensitive adamantane-Rhodamine B (Ad-R) with β-cyclodextrin polymer (poly-β-CD) at one time. The nanoprobes with good biocompatibility have been successfully applied to measure intracellular pH in the pH range of 4-8 and estimate pH fluctuations associated with different stimuli in cells. Moreover, we expect that this self-assembled approach is applicable to the construction of nanoprobes for other targets in cells just by replacing the respective indicator dyes with relevant indicators.

Competitive Host–Guest Interaction between β-Cyclodextrin Polymer and Pyrene-Labeled Probes for Fluorescence Analyses

We developed a novel homogeneous fluorescence analysis based on a novel competitive host-guest interaction (CHGI) mechanism between β-cyclodextrin polymer (polyβ CD) and pyrene-labeled probe for biochemical assay. Pyrene labeling with oligonucleotide strands can be recruited and reside in lipophilic cavities of polyβ CD. This altered lipophilic microenvironment provides favored polarity for enhanced quantum efficiencies and extraordinarily increases the luminescence intensity of pyrene. However, with addition of complementary DNA, the pyrene-labeled probe formed double-strand DNA to hinder pyrene from entering the cavities of polyβ CD. The release of pyrene from polyβ CD, which are followed by fluorescence extinguishing, will provide the clear signal turn-off in the presence of target DNA. We also introduced Exodeoxyribonuclease I (Exo I) and Exodeoxyribonuclease III (Exo III) to improve the sensitivity of this system, and the following product of cleavage reaction, pyrene-nucleotide, could more easily host-guest interact with polyβ CD and emit stronger fluorescence than pyrene-labeled probe. In addition, the successful detection of adenosine is also demonstrated by using the similar sensing scheme. Although this scheme might be easily interfered by some biomolecules in the real test sample, it holds promising potential for detecting a broad range of other types of aptamer-binding chemicals and biomolecules.

Electrochemical biosensors for detection of point mutation based on surface ligation reaction and oligonucleotides modified gold nanoparticles

An electrochemical method for point mutation detection based on surface ligation reaction and oligonucleotides (ODNs) modified gold nanoparticles (AuNPs) was demonstrated. Point mutation identification was achieved using Escherichia coli DNA ligase. This system for point mutation detection relied on a sandwich assay comprising capture ODN immobilized on Au electrodes, target ODN and ligation ODN. Because of the sequence-specific surface reactions of E. coli DNA ligase, the ligation ODN covalently linked to the capture ODN only in the presence of a perfectly complementary target ODN. The presence of ligation products on Au electrode was detected using chronocoulometry through hybridization with reporter ODN modified AuNPs. The use of AuNPs improved the sensitivity of chronocoulometry in this approach, a detection limit of 0.9 pM complementary ODN was obtained. For single base mismatched ODN (smODN), a negligible signal was observed. Even if the concentration ratio of complementary ODN to smODN was decreased to 1:1000, a detectable signal was observed. This work may provide a specific, sensitive and cost-efficient approach for point mutant detection.

G-quadruplex fluorescence quenching ability: a simple and efficient strategy to design a single-labeled DNA probe

A single labeled fluorescence probe was designed based on the efficient quenching ability of a G-quadruplex instead of traditional quenchers. Using this probe, we have investigated the quenching ability of a G-quadruplex and developed a new approach to analyze mercury ions and cysteine with high specificity and sensitivity. Owing to the high quenching ability of the G-quadruplex and the fidelity of the “thymine–Hg2+–thymine” binding motif, this approach can detect 4.0 nM mercury ions, which is lower than the 10 nM US EPA limit in drinking water.

Dopamine modulated ionic permeability in mesoporous silica sphere based biomimetic compartment

The building of artificial systems with similar structure and function as cellular compartments will expand our understanding of compartmentalization related biological process and facilitate the construction of biomimetic highly functional structures. Herein, surface phenylboronic acid functionalized mesoporous silica sphere was developed as a biomimetic dopamine gated compartment, in which the ionic permeability can be well modulated through the dopamine-binding induced charge reversal. As the phenylboronic acid is negatively charged, the negatively charged 1, 3, 6, 8-pyrenetetrasulfonic acid (TPSA) was hindered from permeation into the biomimetic compartment. However, the presence of dopamine and its binding with phenylboronic acid reversed the gatekeeper shell from negative to positive charged and gated the permeation of TPSA into the interior. The dopamine gated permeation phenomenon resembles that in biological system, and thus the phenylboronic acid functionalized mesoporous silica sphere was taken as a simple model for dopamine gated ion channel decorated biological compartment. It will also contribute to the development of artificial cell and responsive nanoreactor.