Analysing genetic information with DNA arrays.

The large amount of DNA sequence information produced in recent years has created a need for high-throughput methods in biology and genetics. These include sequencing, comparing gene sequences and genotyping. DNA arrays promise a highly parallel means for analysis of DNA that is fast and cost-effective, and offers scope for application to complex systems and processes. Recent years have seen continued transfer of technology from the microelectronics industry. Rapid application of the technology to genotyping, antisense oligonucleotide selection and gene expression analysis has illustrated the general power of this approach.

Steric factors influencing hybridisation of nucleic acids to oligonucleotide arrays.

We have investigated the use of spacer molecules to reduce steric interference of the support on the hybridisation behaviour of immobilised oligonucleotides. These spacers are built up from a variety of monomeric units, using phosphoramidite chemistry, by condensation onto an amine-functionalised polypropylene support. The optimal spacer length was determined to be at least 40 atoms in length, giving up to 150-fold increase in the yield of hybridisation. The effects of different charged groups in the spacer were also examined, and it was shown that both positively and negatively charged groups in the spacer diminish the yield of hybridisation. Steric hindrance in hybridisation can also be a problem if the oligonucleotides attached to the support are too close to each other. Surface coverage was varied using a combination of cleavable and stable linkers, giving the highest hybridisation yields for surfaces containing approximately 50% of the maximum concentration of oligonucleotides.

Studies of oligonucleotide interactions by hybridisation to arrays: the influence of dangling ends on duplex yield.

Effects of dangling ends on duplex yield have been assessed by hybridisation of oligonucleotides to an array of oligonucleotides synthesised on the surface of a solid support. The array consists of decanucleotides and shorter sequences. One of the decanucleotides in the array was fully complementary to the decanucleotide used as solution target. Others were complementary over seven to nine bases, with overhangs of one to three bases. Duplexes involving different decanucleotides had different overhangs at the 3' and 5' ends. Some duplexes involving shorter oligonucleotides had the same regions of complementarity as these decanucleotides, but with fewer overhanging bases. This analysis allows simultaneous assessment of the effects of differing bases at both 5' and 3' ends of the oligonucleotide in duplexes formed under identical reaction conditions. The results indicate that a 5' overhang is more stabilising than a 3' overhang, which is consistent with previous results obtained with DNA overhangs. However, it is not clear whether this is due to the orientation of the overhang or to the effect of specific bases.

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

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.

Studies on the base pairing properties of deoxyinosine by solid phase hybridisation to oligonucleotides.

Extensive analyses of the base-pairing properties of deoxyinosine to A, C, G, and T were carried out by measuring the hybridisation of oligonucleotides with deoxyinosine in various positions to complementary sets of oligonucleotides made as an array on the surface of a glass microscope slide. With deoxyinosine in internal positions, results are consistent with previous studies, showing a preferential order for pairing of I-C > I-A > I-G approximately I-T. With two adjacent deoxyinosines in the centre of the oligonucleotide, the order in duplex yield is CC > CA > AA > AC > GC > GA > CG > TA > TC > CT = AG > AT > GT > TT. With deoxyinosine at the ends of the oligonucleotide, we find that at the 3' end there is the same order in duplex yield as for the deoxyinosine in internal positions, though with lower discrimination between the bases. When hybridisation is carried out in TMACI there is little base pairing discrimination with deoxyinosine, or indeed any of the four natural bases at the 5' end. Changing the cation to Na+ increased discrimination slightly.