Kalim U. Mir scite author profile

An array of 1,938 oligodeoxynucleotides (ONs) ranging in length from monomers to 17-mers was fabricated on the surface of a glass plate and used to measure the potential of oligonucleotide for heteroduplex formation with rabbit beta-globin mRNA. The oligonucleotides were complementary to the first 122 bases of mRNA comprising the 5' UTR and bases 1 to 69 of the first exon. Surprisingly few oligonucleotides gave significant heteroduplex yield. Antisense activity, measured in a RNase H assay and by in vitro translation, correlated well with yield of heteroduplex on the array. These results help to explain the variable success that is commonly experienced in the choice of antisense oligonucleotides. For the optimal ON, the concentration required to inhibit translation by 50% was found to be five times less than for any other ON. We find no obvious features in the mRNA sequence or the predicted secondary structure that can explain the variation in heteroduplex yield. However, the arrays provide a simple empirical method of selecting effective antisense oligonucleotides for any RNA target of known sequence.

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Determining the influence of structure on hybridization using oligonucleotide arrays

Mir

1999

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We have studied the effects of structure on nucleic acid heteroduplex formation by analyzing hybridization of tRNAphe to a complete set of complementary oligonucleotides, ranging from single nucleotides to dodecanucleotides. The analysis points to features in tRNA that determine heteroduplex yield. All heteroduplexes that give high yield include both double-stranded stems as well as single-stranded regions. Bases in the single-stranded regions are stacked onto the stems, and heteroduplexes terminate at potential interfaces for coaxial stacking. Heteroduplex formation is disfavored by sharp turns or a lack of helical order in single-stranded regions, competition from bases displaced from a stem, and stable tertiary interactions. The study is relevant to duplex formation on oligonucleotide microarrays and to antisense technologies.

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Arrays of complementary oligonucleotides for analysing the hybridisation behaviour of nucleic acids

et al. 1994

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Arrays of oligonucleotides corresponding to a full set of complements of a known sequence can be made in a single series of base couplings in which each base in the complement is added in turn. Coupling is carried out on the surface of a solid support such as a glass plate, using a device which applies reagents in a defined area. The device is displaced by a fixed movement after each coupling reaction so that consecutive couplings overlap only a portion of previous ones. The shape and size of the device and the amount by which it is displaced at each step determines the length of the oligonucleotides. Certain shapes create arrays of oligonucleotides from mononucleotides up to a given length in a single series of couplings. The array is used in a hybridisation reaction to a labelled target sequence, and shows the hybridisation behaviour of every oligonucleotide in the target sequence with its complement in the array. Applications include sequence comparison to test for mutation, analysis of secondary structure, and optimisation of PCR primer and antisense oligonucleotide design.

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Oligonucleotide dendrimers: stable nano-structures

Shchepinov

Mir²,

Elder³

et al. 1999

Nucleic Acids Research

129

110

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DNA dendrimers with two, three, six, nine or 27 arms were reassociated as complementary pairs in solution or with an array of complementary oligonucleotides on a solid support. In all cases, duplex stabilities were greater than those of unbranched molecules of equal length. A theoretical treatment for the process of dissociation of dendrimers explains the major properties of the complexes. The favourable features of DNA dendrimers-their enhanced stability and the simple predictability of their association behaviour-makes them promising as building blocks for the 'bottom up' approach to nano-assembly. These features also suggest applications in oligonucleotide array/DNA chip technology when higher hybridisation temperatures are required, for example, to melt secon-dary structure in the target.

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Kalim U. Mir

Molecular interactions on microarrays

Selecting effective antisense reagents on combinatorial oligonucleotide arrays

Determining the influence of structure on hybridization using oligonucleotide arrays

Arrays of complementary oligonucleotides for analysing the hybridisation behaviour of nucleic acids

Oligonucleotide dendrimers: stable nano-structures

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