Nucleic acid sequence-based amplification (NASBA) is a sensitive, isothermal, transcription-based amplification system specifically designed for the detection of RNA targets. In some NASBA systems, DNA is also amplified though very inefficiently and only in the absence of the corresponding RNA target or in case of an excess (>1,000-fold) of target DNA over RNA. As NASBA is primer-dependent and amplicon detection is based on probe binding, primer and probe design rules are included. An overview of various target nucleic acids that have been amplified successfully using NASBA is presented. For the isolation of nucleic acids prior to NASBA, the "Boom" method, based on the denaturing properties of guanidine isothiocyanate and binding of nucleic acid to silica particles, is preferred. Currently, electro-chemiluminescence (ECL) is recommended for the detection of the amplicon at the end of amplification. In the near future, molecular beacons will be introduced enabling "real-time detection," i.e., amplicon detection during amplification. Quantitative HIV-1 NASBA and detection of up to 48 samples can then be performed in only 90 min.
We discovered a highly virulent variant of subtype-B HIV-1 in the Netherlands. One hundred nine individuals with this variant had a 0.54 to 0.74 log
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increase (i.e., a ~3.5-fold to 5.5-fold increase) in viral load compared with, and exhibited CD4 cell decline twice as fast as, 6604 individuals with other subtype-B strains. Without treatment, advanced HIV—CD4 cell counts below 350 cells per cubic millimeter, with long-term clinical consequences—is expected to be reached, on average, 9 months after diagnosis for individuals in their thirties with this variant. Age, sex, suspected mode of transmission, and place of birth for the aforementioned 109 individuals were typical for HIV-positive people in the Netherlands, which suggests that the increased virulence is attributable to the viral strain. Genetic sequence analysis suggests that this variant arose in the 1990s from de novo mutation, not recombination, with increased transmissibility and an unfamiliar molecular mechanism of virulence.
From mutational analysis of the 3′-terminal hairpin of turnip yellow mosaic virus (TYMV) RNA and use of nonstructured C-rich RNA templates, we conclude that the main determinant in the tRNA-like structure of TYMV RNA for initiation of minus-strand synthesis by the viral RNA-dependent RNA polymerase (RdRp) is the non-base-paired 3′ ACC(A) end. Base pairing of this 3′ end reduces the transcription efficiency drastically, and deletion of only the 3′-terminal A residue results in a fivefold drop in efficiency. The two C residues of the 3′ ACCA end are required for efficient transcription, as shown by substitution mutations. However, the 5′ A residue is not specifically involved in initiation of transcription, as shown by substitution mutations. Furthermore, the hairpin stem and loop upstream of the 3′ ACCA end also do not interact with the RdRp in a base-specific way. However, for efficient transcription, the hairpin stem should be at least five bp in length, while the calculated ΔG value should be less than −10.5 kcal/mol. Unexpectedly, the use of nonstructured C-rich RNA templates showed that the RdRp can start internally on an NCCN or NUCN sequence. Therefore, a possible function of the tRNA-like structure of TYMV RNA may be to prevent internal initiation of minus-strand synthesis.
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