Synthesis and monitored selection of nucleotide surrogates for binding T:A base pairs in homopurine-homopyrimidine DNA triple helices.

A total of 16 oligodeoxyribonucleotides of general sequence 5'-TCTTCTZTCTTTCT-3', where Z denotes an N-acyl-N-(2-hydroxyethyl)glycine residue, were prepared via solid phase synthesis. The ability of these oligonucleotides to form triplexes with the duplex 5'-AGAAGATAGAAAGA-HEG-TCTTTCTATCTTCT-3', where HEG is a hexaethylene glycol linker, was tested. In these triplexes, an 'interrupting' T:A base pair faces the Z residue in the third strand. Among the acyl moieties of Z tested, an anthraquinone carboxylic acid residue linked via a glycinyl group gave the most stable triplex, whose UV melting point was 8.4 degrees C higher than that of the triplex with 5'-TCTTCTGTCTTTCT-3' as the third strand. The results from exploratory nuclease selection experiments suggest that a combinatorial search for strands capable of recognizing mixed sequences by triple helix formation is feasible.

Monitored selection of DNA-hybrids forming duplexes with capped terminal C:G base pairs.

Reported here are the results of a search for modified oligodeoxynucleotides with a 5'-terminal cytidine residue whose affinity for target strands is enhanced by 5'-acylamido groups. These acylamido groups were envisioned to act as molecular caps that bind to the exposed terminal base pair of the duplex with the target strand. A total of 52 capped oligonucleotides of the sequence R-CGGTTGAC, where R denotes the 5'-appendage and C a 5'-amino-2',5'-dideoxycytidine residue, were tested. Among the building blocks employed to modify the 5'-amino group of the DNA strand were carboxylic acid residues, either appended directly or via an amino acid residue, and aromatic aldehydes, coupled via reductive amination. The carboxylic acids employed ranged from Fmoc-glycine to (Fmoc)(2)-vancomycin and included a number of aromatic acids and bile acids. Small libraries were subjected to MALDI-monitored nuclease selection experiments, and selected compounds were tested in UV-melting assays with target strands. Cholic acid appendages stabilized terminal C:G base pairs to the greatest extent, with melting point increases of up to 10 degrees C. Further, the cholic acid residue enhanced base pairing fidelity at the terminus, as determined in melting analyses with target strands containing a mismatched nucleobase at the 3'-terminus.

A 2'-acylamido cap that increases the stability of oligonucleotide duplexes.

[structure: see text]. Reported here is the synthesis of oligonucleotides containing a 2'-acylamido-2'-deoxyuridine residue at their 3'-terminus. Compared to control sequences bearing a thymidine residue, the quinolone-capped duplexes give higher UV melting points. In the case of (5'-ACGCGU-NA-2')2, where NA denotes a nalidixic acid residue, the melting point increase is up to 22 degrees C over that of (ACGCGT)2.

Synthesis and monitored selection of 5'-nucleobase-capped oligodeoxyribonucleotides.

Oligodeoxynucleotides bearing 5'-appendages consisting of a nucleobase and an amide linkage were prepared from 5'-amino-5'-deoxyoligonucleotides, amino acid building blocks and thymine or uracil derivatives. Small chemical libraries of 5'-modified oligonucleotides bearing the nucleobase moieties via five, three or two atom linkages were subjected to spectrometrically monitored nuclease selections to identify members with high affinity for target strands. The smallest of the appendages tested, a uracil acetic acid substituent, was found to convey the greatest duplex stabilizing effect on the octamer 5'-T*GGTTGAC-3', where T* denotes the 5'-amino-5'-deoxythymidine residue. Compared to 5'-TTGGTTGAC-3', the modified sequence 5'-u-T*GGTTGAC-3' gives a duplex with 5'-GTCAACCAA-3' that melts 4 degrees C higher. The duplex-stabilizing effect of this 5'-substituent does not require a specific residue at the 3'-terminus of the complement and the available data suggest that the uracil moiety is located in the major groove of the duplex.