posted on 2013-05-07, 00:00authored byZunyi Yang, Michael Durante, Lyudmyla
G. Glushakova, Nidhi Sharma, Nicole A. Leal, Kevin M. Bradley, Fei Chen, Steven A. Benner
Methods to detect DNA and RNA (collectively
xNA) are easily plagued
by noise, false positives, and false negatives, especially with increasing
levels of multiplexing in complex assay mixtures. Here, we describe
assay architectures that mitigate these problems by converting standard
xNA analyte sequences into sequences that incorporate nonstandard
nucleotides (Z and P). Z and P are extra DNA building blocks that
form tight nonstandard base pairs without cross-binding to natural
oligonucleotides containing G, A, C, and T (GACT). The resulting improvements
are assessed in an assay that inverts the standard Luminex xTAG architecture,
placing a biotin on a primer (rather than on a triphosphate). This
primer is extended on the target to create a standard GACT extension
product that is captured by a CTGA oligonucleotide attached to a Luminex
bead. By using conversion, a polymerase incorporates dZTP opposite
template dG in the absence of dCTP. This creates a Z-containing extension
product that is captured by a bead-bound oligonucleotide containing
P, which binds selectively to Z. The assay with conversion produces
higher signals than the assay without conversion, possibly because
the Z/P pair is stronger than the C/G pair. These architectures improve
the ability of the Luminex instruments to detect xNA analytes, producing
higher signals without the possibility of competition from any natural
oligonucleotides, even in complex biological samples.