NASBA is an isothermal nucleic acid amplification method which is particularly suited to detection and quantification of genomic, ribosomal or messenger RNA. The product of NASBA is single-stranded RNA of opposite sense to the original target. The initial NASBA methods relied on liquid or gel-based probe-hybridisation for post-amplification detection of products. More recently, real-time procedures incorporating amplification and detection in a single step have been applied to a wide range of RNA and some DNA targets. Real-time NASBA has become a sensitive and specific method for detection, quantification and differentiation of RNA and DNA targets. Molecular beacons have been used in real-time NASBA in commercially-available kits in published assays. The increase in availability of fluorimeters suitable for real-time NASBA ensures that this methodology will become a realistic alternative to real-time reverse transcriptase PCR.

NASBA technology is an alternative method to standard proceduresfor the amplification and detection of a range of nucleic acid targets. The majority of applications have been developed for detection and analysis of RNA targets including viral genomes, viroids, ribosomal RNA (rRNA) and messenger RNA (mRNA). Advantages of NASBA over methods such as reverse transcriptase PCR include fast amplification kinetics and selective amplification of RNA in a background of DNA. The amplification is isothermal and thus there is no requirement for thermocycling during the procedure. Single-stranded RNA amplicons are produced by NASBA which can be used directly in subsequent rounds of amplification or probed for detection without the need for denaturation or strand separation.

Real-time NASBA assays are rapid, specific and sensitive with RNA amplification and a target-specific fluorescent signal achieved simultaneously in one tube with measurements obtained through a fluorimeter. Qualitative, quantitative, monoplex and multiplex formats of real-time NASBA have now been described. The methodology seems to be a suitable alternative to other amplification procedures without the need for expensive thermocyclers. Since the original reports of real-time NASBA in 1998 the number of applications, available kits and expansion to include DNA targets is apparent and likely to continue over the next few years.

from Fox et al in "Chapter 12: Real-Time NASBA" from Real-Time PCR: Current Technology and Applications

Further reading: Real-Time PCR: Current Technology and Applications

Labels: DNA, NASBA, real-time PCR, RNA, RT-PCR