Ligation detection reaction-TaqMan procedure for single nucleotide polymorphism detection on genomic DNA.

In this article, we describe a genotyping approach applicable to both individual and multiplexed single nucleotide polymorphism (SNP) analysis, based on a ligation detection reaction (LDR) performed directly on genomic DNA. During the ligation, the biallelic state of the SNP locus is converted into a bimarker state of ligated detector oligonucleotides. The state of the markers is then determined by a 5'-nuclease assay (TaqMan) with universal fluorescent probes. The LDR-TaqMan method was successfully applied for the genotyping of 30 SNP loci of Arabidopsis thaliana. The technology is cost-effective, needs no locus-specific optimization, requires minimal manipulations, and has very good potential for automation.

Ligation-based synthesis of oligonucleotides with block structure.

We describe here a method for the synthesis of oligonucleotides with block structure (padlock probes, primers for multiplex polymerase chain reaction (PCR), and ligation-independent cloning), based on the ligation of presynthesized parts by T4 DNA ligase. The advantages of this approach are: (i) suitability of the technology for any producer-from synthesis company to laboratory, (ii) high quality and adjustable scale of synthesis, and (iii) possibility of including any modified bases inexpensively in the common part of the oligonucleotide. Clear difference of sizes of products and substrates makes the synthesis amenable to automation. For large series of padlock probes, the price per one primer approaches the price of the locus-specific parts. We demonstrate the application of this method to two different tasks: preparative-scale production of padlock probes and small-scale synthesis of PCR primers.

Rapid construction of sequencing templates by random insertion of antibiotic resistance genes.

We describe a novel and handy method for generating a population of templates for sequencing. The method is based on the random insertion of antibiotic resistance gene in plasmid DNA digested by DNase I. The advantages of this approach are the small quantity of DNA necessary for mutagenesis and the complete independence from the restriction map of the plasmid. DNase I digestion provides a random distribution of the insertions, while antibiotic selection provides low background. We also present a convenient PCR-based procedure for the analysis and ordering of obtained insertion mutants.