Complete sequence-based pathway analysis by differential on-chip DNA and RNA extraction from a single cell.

We demonstrate on-chip, differential DNA and RNA extraction from a single cell using a microfluidic chip and a two-stage lysis protocol. This method enables direct use of the whole extract, without additional washing steps, reducing sample loss. Using this method, the tumor driving pathway in individual cells from a colorectal cancer cell line was determined by applying a Bayesian computational pathway model to sequences obtained from the RNA fraction of a single cell and, the mutations driving the pathway were determined by analyzing sequences obtained from the DNA fraction of the same single cell. This combined functional and mutational pathway assessment of a single cell could be of significant value for dissecting cellular heterogeneity in tumors and analyzing single circulating tumor cells.

Visualizing the entire DNA from a chromosome in a single frame.

The contiguity and phase of sequence information are intrinsic to obtain complete understanding of the genome and its relationship to phenotype. We report the fabrication and application of a novel nanochannel design that folds megabase lengths of genomic DNA into a systematic back-and-forth meandering path. Such meandering nanochannels enabled us to visualize the complete 5.7 Mbp (1 mm) stained DNA length of a Schizosaccharomyces pombe chromosome in a single frame of a CCD. We were able to hold the DNA in situ while implementing partial denaturation to obtain a barcode pattern that we could match to a reference map using the Poland-Scheraga model for DNA melting. The facility to compose such long linear lengths of genomic DNA in one field of view enabled us to directly visualize a repeat motif, count the repeat unit number, and chart its location in the genome by reference to unique barcode motifs found at measurable distances from the repeat. Meandering nanochannel dimensions can easily be tailored to human chromosome scales, which would enable the whole genome to be visualized in seconds.

Sequence variation in genes and genomic DNA: methods for large-scale analysis.

The large-scale typing of sequence variation in genes and genomic DNA presents new challenges for which it is not clear that current technologies are sufficiently sensitive, robust, or scalable. This review surveys the current platform technologies: separation-based approaches, which include mass spectrometry; homogeneous assays; and solid-phase/array-based assays. We assess techniques for discovering and typing variation on a large scale, especially that of single-nucleotide polymorphisms. The in-depth focus is the DNA chip/array platform, and some of the published large-scale studies are closely examined. The problem of large-scale amplification is addressed, and emerging technologies for present and future needs are indicated.

Oligonucleotide dendrimers: stable nano-structures.

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.

Determining the influence of structure on hybridization using oligonucleotide arrays.

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.

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.

Selecting effective antisense reagents on combinatorial oligonucleotide arrays.

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.

Discovering antisense reagents by hybridization of RNA to oligonucleotide arrays.

Antisense reagents have the potential to modify gene expression by interacting with DNA or mRNA to down-regulate transcription or translation. There have been a number of successful demonstrations of antisense activity in vivo. However, a number of problems must be solved before the method's full potential can be realized. One problem is the need for the antisense agent to form a duplex with the target molecule. We have found that most regions of mRNAs are not open to duplex formation with oligonucleotides because the bases needed for Watson-Crick base pairing are involved in intramolecular pairing. Using arrays of oligonucleotides that are complementary to extensive regions of the mRNA target, we are able to find those antisense oligonucleotides which bind optimally. There is good correspondence between the ability of an oligonucleotide to bind to its target and its activity as an antisense agent in in vivo and in vitro tests. To understand more fully the rules governing the process of duplex formation between a native RNA and complementary oligonucleotides, we have studied the interactions between tRNAphe and a complete set of complementary dodecanucleotides. Only four of the set of 65 oligonucleotides interact strongly. The four corresponding regions in the tRNA share structural features. However, other regions with similar features do not form a duplex. It is clear that ab initio prediction of patterns of interaction require much greater knowledge of the process of duplex formation than is presently available.

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.