Design and Synthesis of Boronic Acid-Modified Nucleotides for Fluorescent Sensing and Cell Imaging

Yang, Xiaochuan

17 December 2009

With the rapidly increasing interest in the field of glycomics, which is the comprehensive study of the roles carbohydrates play in a living system, urgent need for developing quick and highly selective carbohydrate sensors is growing. The boronic acid group, with its electron-deficient structure (6 valence electrons with an open shell), acts as a Lewis acid with high intrinsic affinity towards Lewis bases such as fluoride, cyanide and hydroxyl groups. Specifically, formation of a 5- or 6- membered ring between the boronic acid moiety and a1,2- or 1,3-diol in aqueous solution has been fully explored as a strategy of carbohydrate sensor design. Along this line, those binders were termed as ¡°boronolectins¡± because of their similar functions as lectins. One challenge in developing boronic acid-based carbohydrate sensors is to enhance the discriminating ability among various carbohydrate analytes with diverse building blocks and complex linkage patterns. One approach is using polypeptide or oligonucleotide as a backbone or scaffold with functionalized boronic acid moiety to create a molecular library, and then selecting binders with favorable properties. The work presented here includes three general research parts: synthesis of a naphthalimide-based boronic acid-conjugated thymidine triphosphate (NB-TTP), fluorescence property studies of NB-TTP incorporated DNA (NB-DNA), and cellular imaging studies using NB-TTP: 1) 4-Amino-1,4-naphthalimide (Nap) was chosen as the fluorophore because of its relatively long excitation and emission wavelengths, and stability. The synthesis of naphthalimide-based boronic acid (NB) followed similar route as previously published work. Tethering of boronic acid moiety and TTP was accomplished through Cu(I)-catalyzed azide-alkyne cyclization (CuAAC), known as click chemistry. The synthesized NB-TTP showed fluorescence enhancements at long wavelength (¦Ëem: 540 nm) upon sugar addition. 2) NB-TTP was incorporated into DNA through Klenow fragment-catalyzed primer extension reactions. Different DNA sequences were designed with varying number and spacing for NB-TTP incorporation. The preliminary study provided certain insight into several factors that affect the fluorescent properties of different NB -DNA. 3) NB-TTP was added into Hela cell culture medium to study its cell imaging properties. With the observation under fluorescent microscope, it was demonstrated that NB-TTP showed good cell membrane permeability and significant accumulation in cell nucleus.

DNA

Carbohydrate sensor

Cell imaging

Fluorescence

Boronic acid

Chemistry