A Direct Glimpse of Cross-Hybridization: Background-Passified Microarrays That Allow Mass-Spectrometric Detection of Captured Oligonucleotides

ChipCheckII - predicting binding curves for multiple analyte strands on small DNA microarrays

Incomplete binding, saturation, and cross-hybridization between partially complementary strands complicate the parallel detection of nucleic acids via DNA microarrays. Treating the competing equilibria governing binding to microarrays requires computational tools. We have developed the web-based program ChipCheckII that calculates total hybridization matrices for target strands interacting with probes on small DNA microarrays. The program can be used to compute the extent of cross-hybridization and other phenomena affecting fidelity of detection based on sequences, quantities of strands, and hybridization conditions as inputs. Enthalpy and entropy of duplex formation are generated locally with UNAfold, including those for complexes that are partially matched. Simulated binding versus temperature curves for portions of a commercial genome chip demonstrate the extent to which cross-hybridization can complicate DNA detection. ChipCheckII is expected to aid nucleic acid chemists in developing high fidelity DNA microarrays.

Optimizing the stacking moiety and linker of 2'-acylamido caps of DNA duplexes with 3'-terminal adenine residues

Reported here is the synthesis of oligodeoxynucleotides with a 3'-terminal 2'-acylamido-2'-deoxyadenosine residue. The route to these oligonucleotides employs an N,O-Alloc-protected 5'-phosphoramidite of 2'-amino-2'-deoxyadenosine that was prepared in 11 steps from arabinoadenosine. Small combinatorial libraries of oligonucleotides were generated via acylation with a mixture of linker amino acids and subsequent acylation of their amino groups. Mass spectrometrically monitored nuclease selection assays led to oligonucleotides whose 2'-substituent increases the thermal stability of the DNA duplexes. A linker with three methylene groups between a perylene stacking moiety and the amido group gives a UV-melting point increase of up to 27.9 degrees C for the DNA sequence (TGCGCA*)2, where A* denotes the 2'-acylamidoadenosine residue. The same acylamido group improves mismatch discrimination at the terminal position with a melting point depression of >or=7 degrees C for any of the three mismatches in the target sequence of the octamer 5'-AGGTTGAA-3'. These results demonstrate how even a very weakly base-pairing nucleotide at the 3'-terminus of a DNA probe strand can be enforced to engage in strong and highly sequence-selective base-pairing interactions.

Synthesis of oligonucleotides with 3'-terminal 5-(3-acylamidopropargyl)-3'-amino-2',3'-dideoxyuridine residues and their reactivity in single-nucleotide steps of chemical replication

Oligonucleotides with a 3'-terminal 5-alkynyl-3'-amino-2',3'-dideoxyuridine residue were prepared, starting from 2'-deoxyuridine. The optimized route employs a 2',3'-dideoxy-3'-trifluoroacetamido-5-iodouridine 5'-phosphoramidite as building block for DNA synthesis and involves on-support Sonogashira coupling with N-tritylpropargylamine to generate oligonucleotides. The amino group of the propargylamine side chain was acylated to accelerate primer extension reactions involving the 3'-amino group. Three acyl groups were identified that decrease the half-life for DNA-templated extension steps with 7-azabenzotriazole esters of 2'-deoxynucleotides. The residue of 4-pyrenylbutyric acid was found to accelerate primer extension reactions and to render them more selective than those of the control primer. With this substituent, primer extension is also faster than previously measured for three-strand systems involving template, aminoprimer, and a downstream-binding helper oligonucleotide. Fast-reacting primers might become useful for genotyping single nucleotides.