Circle-to-circle amplification for precise and sensitive DNA analysis.

We present a tightly controlled process for strand-specific amplification of circularized DNA molecules. Tandem repeated complements of DNA circles are generated by rolling-circle replication, and converted to monomer circles of opposite polarity to that of the starting material. These circles are then subjected to one more round of rolling-circle replication and circularization, and the process can be further repeated.

Ligase-mediated construction of branched DNA strands: a novel DNA joining activity catalyzed by T4 DNA ligase.

Branched nucleic acid strands exist as intermediates in certain biological reactions, and bifurcating DNA also presents interesting opportunities in biotechnological applications. We describe here how T4 DNA ligase can be used for efficient construction of DNA molecules having one 5' end but two distinct 3' ends that extend from the 2' and 3' carbons, respectively, of an internal nucleotide. The nature of the reaction products is investigated, and optimal reaction conditions are reported for the construction of branched oligonucleotides.

PCR-generated padlock probes distinguish homologous chromosomes through quantitative fluorescence analysis.

Conventional cytogenetic techniques can distinguish homologous chromosomes in a qualitative manner based upon obvious morphological features or using in situ hybridization methods that yield qualitative data. We have developed a method for quantitative genotyping of single-nucleotide variants in situ using circularizable DNA probes, so-called padlock probes, targeting two different alpha satellite repeat variants present in human chromosome 7 centromeres, and a single-nucleotide variation in alpha satellite repeats on human chromosome 15 centromeres. By using these PCR-generated padlock probes, we could quantitatively distinguish homologous chromosomes and follow the transmission of the chromosomes by in situ analysis during three consecutive generations.

Making ends meet in genetic analysis using padlock probes.

Padlock probes are molecular tools that combine highly specific target sequence recognition with the potential for multiplexed analysis of large sets of target DNA or RNA sequences. In this brief review, we exemplify the ability of these probes to distinguish single-nucleotide target sequence variants. We further discuss means to detect the location of target sequences in situ, and to amplify reacted padlock probes via rolling-circle replication, as well as to sort reaction products on tag-arrays.