Though the successful development of DNA chip technology has facilitated the simultaneous measurement of thousands of mRNA transcripts in a single sample, the technology is presently incapable of distinguishing between alternatively spliced transcripts. As much of the complexity of the mammalian proteome is due to the occurrence of alternatively spliced mRNAs, an automated method to detect these transcripts would be immensely valuable. This is especially true for neurodegenerative diseases, where some of the major suspect genes occur in different splice forms; tau, for example, has six.

In this month's Nature Biotechnology, researchers in Xiang-Dong Fu's lab at the University of California, San Diego, report the development of just such a tool. Their method uses a combination of polymerase chain reaction (PCR) followed by a solid-state detection assay. At the heart of the technique are multifunctional "smart" oligonucleotides. These are designed in pairs to match sequences on the donor and acceptor side of known splice sites. Prior to amplification, mRNA samples are incubated with a mixture of these oligos, which also serve as a template for PCR primers, and those that fall on either side of a junction are ligated together. This facilitates amplification and ensures that only splice sites that occur within the RNA sample are amplified, as in the absence of a given junction its two oligos will not ligate.

Following amplification, splice sites are detected by a fiber-optic microarray that contains thousands of DNA "addresses"-microbeads that have unique nucleotide sequences attached. The "smart" oligos also have a complementary "address" that allows the DNA amplified from a splice junction to be captured on the microarray. The presence of the captured DNA can then be detected by fluorescence.

Yeakley et al. used the technique to measure alternative splicing of six different genes in five different cell types, and the data compared well with the profile obtained using conventional reverse transcription-PCR. The technique promises to be useful for detecting changes in splicing patterns that may arise when, for example, a normal cell turns cancerous, as Paula Grabowski, University of Pittsburgh, points out in an accompanying News and Views.

The authors also point out the method's limitations. It fails to detect distinct isoforms of the receptor tyrosine phosphatase, PTPRC, known to be expressed in U-937 and Jurkat cells (see also comment below by George Church). However, it may be possible to overcome this limitation by the use of "smarter" oligonucleotides.—Tom Fagan

Comments

  1. These two articles rightly emphasize that RNA splicing measures are extremely important and poorly served by array methods so far. However, there are some problems with using exon junctions for array assays as they propose. (1) Many alternatively spliced RNAs involve multiple exons (e.g. Dscam has 130 exons). (2) If you measure expression levels at two different junctions in the same gene, it is hard to tell if they actually occur together on any RNA molecule in the complex mixture; i.e the assay is only local and therefore the encoded proteins are unknown. (3) The choice of probe (critical for getting specificity) is extremely limited for junction probes relative to exon probes (often 100 times more limited).

    To address these three problems, we have developed a method to amplify single molecules and ask what exons are found in each molecule in a mixture. A gene with N exons means up to N2 possible splice junctions and 2N possible RNAs. Even if only subsets are used in a given cell, one has to determine which. Our method uses only N exon probes instead of N2 junction probes to measure the whole set. We are very interested in having this new technologies available broadly. Our first paper heading
    this direction has been published (pdf of Mitra & Church, 1999), and a couple more are in preparation.

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References

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Primary Papers

  1. . Profiling alternative splicing on fiber-optic arrays. Nat Biotechnol. 2002 Apr;20(4):353-8. PubMed.
  2. . Alternative splicing in parallel. Nat Biotechnol. 2002 Apr;20(4):346-7. PubMed.