Abstract
We present a novel method for fabricating unimolecular double-stranded DNA microarrays on solid surfaces, which were used to probe sequence-specific DNA/protein interactions. For manufacturing the unimolecular double-stranded DNA microarrays, two kinds of special single-stranded oligonucleotides, constant oligonucleotide and target oligonucleotide, were chemically synthesized. The constant oligonucleotides with internal aminated dT were used to capture and immobilize the target oligonucleotides onto the solid surface, and also to provide a primer for later enzymatic extension reactions, while target oligonucleotides took the role of harbouring DNA-binding sites of DNA-binding proteins. The variant target oligonucleotides were annealed and ligated with the constant oligonucleotides to form the new unimolecular oligonucleotides for microspotting. The prepared unimolecular oligonucleotides were microspotted on aldehyde-derivatized glass slides to make partial-dsDNA microarrays. Finally, the partial-dsDNA microarrays were converted into a unimolecular complete-dsDNA microarray by a DNA polymerase extension reaction. The efficiency and accuracy of the polymerase synthesis were demonstrated by the fluorescent-labeled dUTP incorporation in the enzymatic extension reaction and the restriction endonuclease digestion of the fabricated unimolecular complete-dsDNA microarray. The accessibility and specificity of the sequence-specific DNA-binding proteins binding to the immobilized unimolecular dsDNA probes were demonstrated by the binding of Cy3 labeled NF-κB (p50·p50) to the unimolecular dsDNA microarray. This unimolecular dsDNA microarray provides a general technique for high-throughput DNA-protein or DNA-drugs interactions.
Highlights
The interactions of DNA-binding proteins and DNA-binding drugs with double-stranded DNA in the genome are involved in many important biological functions, including gene transcription regulation [1], DNA recombination [2], restriction [3], replication [4] and DNA-drug intercalation [5,6]
Church’s lab saw the great potentials of double-stranded DNA (dsDNA) microarrays for studying sequence-specific DNA/protein interactions [37], and fabricated dsDNA microarray for explor ing the DNA-binding specificities of zinc fingers with arrayed DNA targets [38, 39]. Their creative work verified the feasibility and high effectiveness of dsDNA microarrays in studying sequence-specific DNA/protein interaction. Their dsDNA microarray fabrication replied on the Affymetrix proprietary technology of photo-addressable oligonucleotide synthesis which is unaffordable for general laboratories until now
We have presented a novel method for fabricating unimolecular dsDNA microarray and verified its reliability
Summary
The interactions of DNA-binding proteins and DNA-binding drugs with double-stranded DNA (dsDNA) in the genome are involved in many important biological functions, including gene transcription regulation [1], DNA recombination [2], restriction [3], replication [4] and DNA-drug intercalation [5,6]. Lots of techniques including nitrocellulose-binding assays [7], gel mobility-shift analysis [8, 9], Southwestern blotting [10, 11], ELISA [12], reporter constructs in yeast [13], Chromatin immunoprecipitation (ChIP) [14], phage display [15], binding-site signatures [16], in- vitro selection [17], UV crosslinking [18], and methylization interfering assay [19] and X-ray crystallography [20,21] were developed to effectively examine sequence-specific DNA-protein interactions, and many techniques including UV absorption [22], melting temperature (thermodynamics) [23], NMR [24], X-ray crystallography [25, 26], free solution capillary electrophoresis (FSCE) [27], scanning force microscopy (SFM) [28,29,30], atomic force microscopy (AFM) [31], surface plasmon resonance (SPR) [32], polymerase chain reaction (PCR) [33, 34] and footprinting [35, 36] were used to effectively study DNA-drug interactions These techniques using non-immobilized free dsDNAs in the liquid-phase to probe dsDNA interactions with other molecules such as proteins, ligands and drugs suffered from being laborious , time-consuming and incapable of high-throughput parallel analysis. This kind of surface-coupled dsDNA were high informative, but suffered from economic problems [45]
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