Detection of Specific RNA Targets by Multimerization

Detection of specific RNA targets via amplification-mediated techniques is widely used in fundamental studies and medicine due to essential role of RNA in transfer of genetic information and development of diseases. Here, we report on an approach for detection of RNA targets based on the particular type of isothermal amplification, namely, reaction of nucleic acid multimerization. The proposed technique requires only a single DNA polymerase possessing reverse transcriptase, DNA-dependent DNA polymerase, and strand-displacement activities. Reaction conditions that lead to efficient detection of the target RNAs through multimerization mechanism were determined. The approach was verified by using genetic material of the SARS-CoV-2 coronavirus as a model viral RNA. Reaction of multimerization allowed to differentiate the SARS-CoV-2 RNA-positive samples from the SARS-CoV-2 negative samples with high reliability. The proposed technique allows detection of RNA even in the samples, which were subjected to multiple freezing-thawing cycles.

Reverse transcriptase-free detection of viral RNA using Hemo Klentaq DNA polymerase.

COVID-19 pandemic highlighted the demand for the fast and reliable detection of viral RNA. Although various methods for RNA amplification and detection have been proposed, some limitations, including those caused by reverse transcription (RT), need to be overcome. Here, we report on the direct detection of specific RNA by conventional polymerase chain reaction (PCR) requiring no prior RT step. It was found that Hemo KlenTaq (HKTaq), which is posed as DNA-dependent DNA polymerase, possesses reverse transcriptase activity and provides reproducible amplification of RNA targets with an efficiency comparable to common RT-PCR. Using nasopharyngeal swab extracts from COVID-19-positive patients, the high reliability of SARS-CoV-2 detection based on HKTaq was demonstrated. The most accurate detection of specific targets are provided by nearby primers, which allow to determine RNA in solutions affected to multiple freeze-thaw cycles. HKTaq can be used for elaboration of simplified amplification techniques intended for the analysis of any specific RNA and requiring only one DNA polymerase.

Convective polymerase chain reaction in standard microtubes.

Polymerase chain reaction (PCR) is the most widely used method for nucleic acids amplification. To date, a huge number of versatile PCR techniques have been developed. One of the relevant goals is to shorten PCR duration, which can be achieved in several ways. Here, we report on the results regarding nucleic acids amplification by convective PCR (cPCR) in standard 0.2 ml polypropylene microtubes. The following conditions were found to be optimal for such amplification: 1) 70 µl reaction volume, 2) the supply of external temperature 145°Ð¡ for the denaturation zone and 0°Ð¡ for the annealing zone, 3) ∼30° inclination of the microtube main axis, 4) the use of nearby primers, and 5) duration of the reaction 15-20 min. At these conditions, the amplification products are accumulated in an amount sufficient to be registered by gel electrophoresis, and high sensitivity of the reaction comparable to that of conventional PCR is achieved. cPCR provided the reliable detection of SARS-CoV-2 coronavirus RNA isolated from nasopharyngeal swabs of COVID-19 patients.

Inhibition of nonspecific polymerase activity using Poly(Aspartic) acid as a model anionic polyelectrolyte.

DNA polymerases with strand-displacement activity allow to amplify nucleic acids under isothermal conditions but often lead to undesirable by-products. Here, we report the increase of specificity of isothermal amplification in the presence of poly (aspartic) acids (pAsp). We hypothesized that side reactions occur due to the binding of the phosphate backbone of synthesized DNA strands with surface amino groups of the polymerase, and weakly acidic polyelectrolytes could shield polymerase molecules from DNA and thereby inhibit nonspecific amplification. Suppression of nonspecific polymerase activity by pAsp was studied on multimerization as a model side reaction. It was found that a low concentration of pAsp (0.01%) provides successful amplification of specific DNA targets. The inhibitory effect of pAsp is due to its polymeric structure since aspartic acid did affect neither specific nor nonspecific amplification. Strongly acidic polyelectrolyte heparin does not possess the same selectivity since it suppresses any DNA synthesis. The applicability of pAsp to prevent nonspecific reactions and reliable detection of the specific target has been demonstrated on the genetic material of SARS-CoV-2 coronavirus using Loop-mediated isothermal amplification.