Analysis of biosensor chips for identification of nucleic acids.

Abstract

Two novel DNA-sequencing methods are described that use DNA hybridization biosensor chips. These two techniques involve either labeling the free nucleic acid with enriched stable isotopes or hybridizing DNA without labels to immobilized peptide nucleic acid (PNA) and detecting the phosphorus present in the DNA but not in the PNA. Sputter-initiated resonance ionization microprobe analysis was used to detect the presence of enriched tin isotope-labeled DNA and of phosphorus in natural DNA as a means to identify the presence of DNA after hybridization to oligodeoxynucleotides (ODNs) or PNAs, respectively, immobilized on a biosensor chip. The data clearly demonstrate that excellent discrimination between complementary and noncomplementary sequences can be obtained during hybridization of DNA to either ODNs or PNAs. The capability to detect different enriched stable isotope-labeled DNAs simultaneously allows high degrees of multiplexing which may be very advantageous for hybridization kinetics studies in complex systems, as well as significantly increasing the speed of analysis. Alternatively, by using natural DNA with PNA biosensor chips, discrimination for single-point mutation could be increased because of improved hybridization kinetics and direct analysis of genomic DNA may become possible without amplification. Both methods have the potential to provide a rapid method for DNA/RNA sequencing, diagnostics, and mapping.