Insertion of Chemical Handles into the Backbone of DNA during Solid-Phase Synthesis by Oxidative Coupling of Amines to Phosphites.

Conjugation of molecules or proteins to oligonucleotides can improve their functional and therapeutic capacity. However, such modifications are often limited to the 5' and 3' end of oligonucleotides. Herein, we report the development of an inexpensive and simple method that allows for the insertion of chemical handles into the backbone of oligonucleotides. This method is compatible with standardized automated solid-phase oligonucleotide synthesis, and relies on formation of phosphoramidates. A unique phosphoramidite is incorporated into a growing oligonucleotide, and oxidized to the desired phosphoramidate using iodine and an amine of choice. Azides, alkynes, amines, and alkanes have been linked to oligonucleotides via internally positioned phosphoramidates with oxidative coupling yields above 80 %. We show the design of phosphoramidates from secondary amines that specifically hydrolyze to the phosphate only at decreased pH. Finally, we show the synthesis of an antibody-DNA conjugate, where the oligonucleotide can be selectively released in a pH 5.5 buffer.

One-Step Conversion of NHS Esters to Reagents for Site-Directed Labeling of IgG Antibodies.

Antibody conjugates are extensively used for diagnostics and therapeutics, and as a tool for molecular biology. To prepare such conjugates N-hydroxysuccinimide (NHS) esters are most often used due to the straightforward experimental procedure and the commercial accessibility of the reagents. Such conjugates are however highly heterogeneous, since only the reactivity of the lysines determines the distribution of labels. This has inspired the development of methods that experimentally are as facile but produce conjugates of higher quality. Herein, we report the development of a reagent that can, in one step, be activated with an NHS ester of choice and subsequently can be directly used for site-directed labeling of antibodies. The reagent can be prepared in three synthetic steps and produces conjugates with similar ease as for NHS esters, however in a site-directed manner. We show that the reagent is quantitatively activated by a variety of NHS esters, and we use these to functionalize IgG1, IgG2, and IgG4 antibodies.

Preparation of Maleimide-Modified Oligonucleotides from the Corresponding Amines Using N-Methoxycarbonylmaleimide.

Oligonucleotide conjugates constitute a versatile tool for research and bioanalytical purposes. Often, such conjugates are prepared by reaction between a thiol on the protein with a maleimide-modified oligonucleotide. Unlike most other chemical handles the maleimide functionality cannot be introduced directly during the solid-phase oligonucleotide synthesis, and therefore the standard method to introduce the maleimide functionality is to react an amino-modified DNA with a heterobifunctional linker containing an activated ester and a maleimide. Here, we present an alternative method for preparation of maleimide and monobromomaleimide-modified oligonucleotides from the corresponding amine using N-methoxycarbonylmaleimide and N-methoxycarbonylbromomaleimide, respectively. In this method, no additional linker is attached to the oligonucleotide, as the maleimide functionality is formed directly on the existing amine. The maleimide can thereby be positioned close to the oligonucleotide, providing a high degree of control over the final construct. The reaction occurs in 30-60 min under alkaline conditions. Maleimide-modified oligonucleotides prepared in this manner were conjugated to bovine serum albumin, and the reaction shows comparable reactivity to the corresponding oligonucleotide modified using the 4-(N-maleimidomethyl)-cyclohexane-1-carboxylate (SMCC) linker.

On-demand synthesis of phosphoramidites.

Automated chemical synthesis of oligonucleotides is of fundamental importance for the production of primers for the polymerase chain reaction (PCR), for oligonucleotide-based drugs, and for numerous other medical and biotechnological applications. The highly optimised automised chemical oligonucleotide synthesis relies upon phosphoramidites as the phosphate precursors and one of the drawbacks of this technology is the poor bench stability of phosphoramidites. Here, we report on the development of an on-demand flow synthesis of phosphoramidites from their corresponding alcohols, which is accomplished with short reaction times, near-quantitative yields and without the need of purification before being submitted directly to automated oligonucleotide synthesis. Sterically hindered as well as redox unstable phosphoramidites are synthesised using this methodology and the subsequent couplings are near-quantitative for all substrates. The vision for this technology is direct integration into DNA synthesisers thereby omitting manual synthesis and storage of phosphoramidites.

A Single Molecule Polyphenylene-Vinylene Photonic Wire.

Nanoscale transport of light through single molecule systems is of fundamental importance for light harvesting, nanophotonic circuits, and for understanding photosynthesis. Studies on organization of molecular entities for directional transfer of excitation energy have focused on energy transfer cascades via multiple small molecule dyes. Here, we investigate a single molecule conjugated polymer as a photonic wire. The phenylene-vinylene-based polymer is functionalized with multiple DNA strands and immobilized on DNA origami by hybridization to a track of single-stranded staples extending from the origami structure. Donor and acceptor fluorophores are placed at specific positions along the polymer which enables energy transfer from donor to polymer, through the polymer, and from polymer to acceptor. The structure is characterized by atomic force microscopy, and the energy transfer is studied by ensemble fluorescence spectroscopy and single molecule TIRF microscopy. It is found that the polymer photonic wire is capable of transferring light over distances of 24 nm. This demonstrates the potential residing in the use of conjugated polymers for nanophotonics.