Xiaoqin Zhong

We present here a binding-induced fluorescence turn-on assay for protein detection. Key features of this assay include affinity binding-induced DNA hybridization and fluorescence enhancement of silver nanoclusters (Ag NCs) using guanine-rich DNA sequences. In an example of an assay for human α-thrombin, two aptamers (Apt15 and Apt29) were used and were modified by including additional sequence elements. A 12-nucleotide (nt) sequence was used to link the first aptamer with a nanocluster nucleation sequence at the 5'-end. The second aptamer was linked through a complementary sequence (12-nt) to a G-rich overhang at the 3'-end. Binding of the two aptamer probes to the target protein initiates hybridization between the complementary linker sequences attached to each aptamer and thereby bring the end of the G-rich overhang to close proximity to Ag NCs, resulting in a significant fluorescence enhancement. With this approach, a detection limit of 1 nM and a linear dynamic range of 5 nM-2 μM were achieved for human α-thrombin. This fluorescence assay is performed in a single tube, and it does not require washing or separation steps. The principle of the binding-induced DNA hybridization and fluorescence enhancement of Ag NCs can be extended to other homogeneous assay applications provided that two appropriate probes are available to bind with the same target molecule.

As an emerging category of fluorescent metal nanoclusters, oligonucleotide-templated silver nanoclusters (Ag NCs) have attracted a lot of interest and have shown wide application in biorelated disciplines. However, the weak fluorescence emission and poor permeability to cell membranes tethered further intracellular applications of Ag NCs. AS1411 is an antiproliferative G-rich phosphodiester oligonucleotide and currently an anticancer agent under phase II clinical trials. Herein, we present a strategy to synthesize AS1411-functionalized Ag NCs with excellent fluorescence through a facile one-pot process. Confocal laser scanning microscopy and Z-axis scanning confirmed that the AS1411-functionalized Ag NCs could be internalized into MCF-7 human breast cancer cells and were able to specifically stain nuclei with red color. To our surprise, 3-[4,5-dimethylthiazol-z-yl]-2,5-diphenyltetrazolium bromide (MTT) assay demonstrated the Ag NCs were cytocompatible and showed better inhibition effects than pure AS1411 on MCF-7 human breast cancer cells. In addition, a universal design of the oligonucleotide scaffold for synthesis of Ag NCs was extended to other aptamers, such as Sgc8c and mucin 1 aptamer. Due to the facile synthesis procedure and capability of specific target recognition, this fluorescent platform will potentially broaden the applications of Ag NCs in biosensing and biological imaging.

Abstract Enzymatic digestion for protein sequencing usually requires much time, and does not always result in high sequence coverage. Here we report the use of aqueous microdroplets to accelerate enzymatic reactions and, in particular, to improve protein sequencing. When a room temperature aqueous solution containing 10 µM myoglobin and 5 µg mL −1 trypsin is electrosonically sprayed (−3 kV) from a homemade setup to produce tiny (∼9 µm) microdroplets, we obtain 100% sequence coverage in less than 1 ms of digestion time, in sharp contrast to 60% coverage achieved by incubating the same solution at 37 °C for 14 h followed by analysis with a commercial electrospray ionization source that produces larger (∼60 µm) droplets. We also confirm the sequence of the therapeutic antibody trastuzumab (∼148 kDa), with a sequence coverage of 100% for light chains and 85% for heavy chains, demonstrating the practical utility of microdroplets in drug development.