Influence of Nucleotide Context on Non-Specific Amplification of DNA with Bst exo- DNA Polymerase.

Isothermal nucleic acids amplification that requires DNA polymerases with strand-displacement activity gained more attention in the last two decades. Among the DNA polymerases with strand-displacement activity, Bst exo- is the most widely used. However, it tends to carry out nonspecific DNA synthesis through multimerization. In this study, the effect of nucleotide sequence on the Bst exo- binding with DNA and on the efficiency of multimerization initiation, are reported. Preference for binding of the "closed" form of Bst exo- to the purine-rich DNA sequences, especially those containing dG at the 3'-end of the growing chain was revealed using molecular docking of the single-stranded trinucleotides (sst) and trinucleotide duplexes (dst). The data obtained in silico were confirmed in the experiments using oligonucleotide templates that differ in the structure of the 3'- and 5'-terminal motifs. It has been shown that templates with the oligopurine 3'-terminal fragment and oligopyrimidine 5'-terminal part contribute to the earlier start of multimerization. The results can be used for design of nucleotide sequences suitable for reliable isothermal amplification. To avoid multimerization, DNA templates and primers containing terminal dA and/or dG nucleotides should be excluded.

LAMPrimers iQ: New primer design software for loop-mediated isothermal amplification (LAMP).

Nucleic acids amplification is a widely used technique utilized for different manipulations with DNA and RNA. Although, polymerase chain reaction (PCR) remains the most popular amplification method, isothermal approaches are gained more attention last decades. Among these, loop-mediated isothermal amplification (LAMP) became an excellent alternative to PCR. LAMP requires an increased number of primers and, therefore, is considered a highly specific amplification reaction compared to PCR. LAMP primers design is still a non-trivial task, and all niceties should be taken into account during their selection. Here, we report on a new program called LAMPrimers iQ destined for high-quality LAMP primers design. LAMPrimers iQ is based on an original algorithm considering rigorous criteria for primers selection. Unlike alternative programs, LAMPrimers iQ can process long DNA or RNA sequences, and completely avoid primers that can form homo- and heterodimers. The quality of the primers designed was checked using SARS-CoV-2 coronavirus RNA as a model target. It was shown that primers selected with LAMPrimers iQ provide higher specificity and reliable detection of viral RNA compared to those obtained by alternative programs. The program is available at https://github.com/Restily/LAMPrimers-iQ.

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.

New method for microRNA detection based on multimerization.

Detection of specific microRNA (miRNA) is of great demand due to their essential role in genes regulation, stress response and development of diseases. However, mature miRNAs are small molecules that make it difficult to use routine amplification-based methods. Here, we report an approach for detection of miRNA based on a new type of isothermal amplification, namely, multimerization. The proposed technique is simple and versatile, excludes a reverse transcription step, and requires two conventional primers only and no additional stem-loop or fluorogenic probes. Only mature miRNAs can initiate multimerization, thereby, pri- or pre-miRNA are excluded from analysis, ensuring high accuracy of the assay. The approach was approved on miRNA from common wheat Triticum aestivum; the increase of Tae-miRNA159 level for plants affected by Stagonospora nodorum Berk infection was demonstrated. The obtained results allow to perform quantitative analysis, providing determination of specific targets with high reliability (detection limit of about 20 pM).

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.

Encoding of non-biological information for its long-term storage in DNA.

In 2019, at the World Economic Forum, DNA data storage was indicated as one of the breakthroughs expected to radically impact the global socio-economic order. Indeed, dry DNA is a relatively stable substance and an extremely capacious information carrier. One gram of DNA can hold up to 455 exabytes, provided that one nucleotide encodes two bits of information. In this critical review, the main attention is paid to nucleinography, meaning the conversion of digital data into nucleotide sequences. The evolution and diversity of approaches intended for encoding data with nucleotides are demonstrated. The most noticeable examples of storing minor as well as considerable quantities of non-biological information in DNA are given. Some issues of DNA data storage are also reported.

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.

Data on molecular docking simulations of quaternary complexes 'Bst exo- polymerase-DNA-dCTP-metal cations'.

This article reports data related to the research article entitled "Effect of metal ions on isothermal amplification with Bst exo- DNA polymerase" (R.R. Garafutdinov, A.R. Gilvanov, O.Y. Kupova, A.R. Sakhabutdinova, 2020) [1]. Here, the results of molecular simulations of the complexes of Bst exo- DNA polymerase with dCTP triphosphate, double-stranded DNA and divalent metal cations are presented. Energetic parameters, number and type of chemical bonds formed by dCTP with the environment are given.

A new digital approach to SNP encoding for DNA identification.

Identification of individuals has become an urgent problem for mankind. In the last three decades, STR-based DNA identification has actively evolved along with traditional biometric methods. Nonetheless, single-nucleotide polymorphisms (SNPs) are now of great interest and a number of relevant SNP panels have been proposed for DNA identification. Here, a simple approach to SNP data digitization that can provide assigning a unique genetic identification number (GIN) to each person is proposed. The key points of this approach are as follows: 1) SNP data are digitized as whole 4-bit boxes in the most convenient binary format, where character "1" (YES) is assigned to revealed nucleotides, and character "0" (NO) to missing nucleotides after SNP-typing; 2) all SNPs should be considered tetra-allelic. Calculations showed that a 72-plex SNP panel is enough to provide the population with unique GINs, which can be represented in digital (binary or hexadecimal) or graphic (linear or two-dimensional) formats. Simple software for SNP data processing and GINs creation in any format was written. It is likely that the national and global GIN databases will facilitate the solution of problems related to identification of individuals or human biological materials. The proposed approach may be extended to other living organisms as well.

The influence of quality of primers on the formation of primer dimers in PCR.

Polymerase chain reaction (PCR) is the most commonly used method for nucleic acids amplification. PCR performance depends on several causes, among which the quality of primers is one of the main determinants affecting specificity, sensitivity and reliability of the reaction. Here, we report on the results of the detailed study devoted to the dimerization of the primers during PCR. The course and specificity of the reaction were studied on the model DNA templates as well as genomic DNA using primers that form amplifiable heterodimeric structures with different thermodynamic stability. It was confirmed that more than two 3'-overlapping nucleotides cause a considerable accumulation of primer dimers. It turned out that the presence of any DNA promotes the formation of dimers even for primers, which do not tend to nonspecific amplification in the absence of DNA. It was shown that dimerization could not be eliminated by commonly used techniques. Even the use of hot-start DNA polymerases does not prevent PD formation if primers with stable 3'-overlapping are employed. Despite several advantages of PCR with abutting primers, their close disposition has no benefits regarding the formation of PD if low-quality primers are utilized.

Enhancement of PCR efficiency using mono- and disaccharides.

Polymerase chain reaction is the most commonly used approach for nucleic acids amplification. Despite the variety of PCR methods have been proposed, new techniques are being developed to improve this reaction. We found that, in general, mono- and disaccharides can serve as effective PCR enhancers. Unlike oligo- and polysaccharides, low molecular-weight carbohydrates accelerate amplification and increase products yield. The ability of carbohydrates to enhance PCR is not related to their reducing property. The best result was obtained for sucrose providing the most specific and reliable amplification. The effect of carbohydrates is leveled as the size of the amplification region increases.

Effect of metal ions on isothermal amplification with Bst exo- DNA polymerase.

Over the last two decades, the isothermal amplification has become actively used for nucleic acids analysis. To perform isothermal techniques, DNA polymerases with strand-displacement activity are needed, and Bst exo- polymerase is one of the most widely used. However, Bst exo- is prone to non-specific DNA synthesis (e.g., DNA multimerization) occurring in the absence of the DNA target of interest. Here, we report on the activity of Bst exo- in the presence of Mg2+, Mn2+, Ca2+, Cd2+, Co2+, Cu2+, Ni2+ and Zn2+ in the model molecular systems which included amplification of circular and linear DNA templates; conditions providing effective and highly specific isothermal amplification were determined. It was found that amplification can proceed not only with Mg2+ but with Mn2+, Ca2+, Cd2+ and Cu2+ depending on the type of Bst exo- polymerase and the buffer. Manganese ions turned out to be the most suitable alternative cofactor, which prevents multimerization in some buffers. Molecular docking simulations showed the highest stability for the quaternary 'polymerase-DNA-triphosphate-cations' complexes containing Mg2+ and Mn2+, and the moderate one for complexes with Ca2+, Cd2+ and Cu2+. The frequency of nucleotide misincorporation increased in the following row: Mg2+ ≈ Mn2+ ≤ Cd2+ < Ca2+ â‰ª Cu2+.

Data on multimerization efficiency for short linear DNA templates and phosphoryl guanidine primers during isothermal amplification with Bst exo- DNA polymerase.

This article reports experimental data related to the research article entitled "Prevention of DNA multimerization using phosphoryl guanidine primers during isothermal amplification with Bst exo- DNA polymerase" (R.R. Garafutdinov, A.R. Sakhabutdinova, M.S. Kupryushkin, D.V. Pyshnyi, 2020) [1]. Here, multimerization efficiency in terms of Tt (time-to-threshold) values obtained for artificial DNA templates with the different nucleotide sequences during isothermal amplification with Bst exo- DNA polymerase is given. Data on the influence of phosphoryl guanidine primers (PGO) on multimerization for the LTc template which has shown high efficiency of multimerization are presented as well.

The Influence of Reaction Conditions on DNA Multimerization During Isothermal Amplification with Bst exo- DNA Polymerase.

Methods for isothermal amplification of nucleic acids are gained more attention in the last two decades. For isothermal amplification, DNA polymerases with strand displacement activity are required, and Bst exo- is one of the most commonly used polymerases. However, Bst exo- is able to cause nonspecific DNA amplification through multimerization, which leads to a set of undesirable by-products. In this study, circumstances that facilitate DNA multimerization by Bst exo- polymerase have been determined. We found that an essential requirement for multimerization is the presence of short (50-60 bp) DNA duplexes formed through primer extension after annealing on the template or in homo- and heterodimers. The highest multimerization efficiency is observed for Bst 2.0 polymerase in buffers with a high salt concentration and/or in the presence of reducing agents (for example, ß-mercaptoethanol). Multimerization occurs mainly at 55-60 °Ð¡, while specific isothermal amplification is more efficient at 60-65 °Ð¡. The SYBR Green I intercalating dye inhibits multimerization with Bst LF and Bst 2.0 polymerases in concentrations above 0.25×, whereas inhibition with Bst 3.0 polymerase occurs only above 1.25×. The obtained results allow to elaborate accurate and reliable methods for isothermal amplification of nucleic acids.

Prevention of DNA multimerization using phosphoryl guanidine primers during isothermal amplification with Bst exo- DNA polymerase.

Over the last two decades, isothermal amplification of nucleic acids has gained more attention due to a number of advantages over the widely used polymerase chain reaction. For isothermal amplification, DNA polymerases with strand-displacement activity are needed, and Bst exo- polymerase is one of the most commonly used. Unfortunately, Bst exo- causes nonspecific DNA amplification (so-called multimerization) under isothermal conditions that results in undesirable products (multimers) consisting of tandem nucleotide repeats. Multimerization occurs only for short ssDNA or primer dimers, and the efficiency of multimerization depends significantly on the reaction conditions, but slightly depends on the sequence of DNA templates. In this study we report the prevention of DNA multimerization using a new type of modified oligonucleotide primers with internucleosidic phosphates containing 1,3-dimethyl-2-imino-imidazolidine moieties (phosphoryl guanidine (PG) groups). Primers with one, two or three PG groups located at the 3'- or 5'-ends or in the middle of the primers were designed. It turned out, such bulky groups interfere with the moving of Bst exo- polymerase along DNA chains. However, one modified phosphate does not notably affect the efficiency of polymerization, and the elongation is completely inhibited only when three contiguous modifications occur. Multimerization of the linear ssDNA templates is blocked by three modifications in the middle of both primers whereas specific amplification of the circular ssDNA by rolling circle amplification is not inhibited. Thus, incorporation of three PG groups is sufficient to prevent multimerization and allows to create improved primers for reliable isothermal amplification with Bst exo- DNA polymerase.

The influence of CpG (5'-d(CpG)-3' dinucleotides) methylation on ultrasonic DNA fragmentation.

DNA methylation is an important way of gene regulation. The variety of methods for DNA methylation analysis based on chemical modification or enzyme digestion has been proposed. However, DNA is able to undergo transformations under physical power. Here, we report that the cytosine methylation in CpG dinucleotides determines the difference in fragmentation rate of methylated and unmethylated DNA under sonication. We found that at the beginning of sonication, methylated DNAs are degraded faster than unmethylated one, and the difference in fragmentation degree can be evaluated with high reliability by quantitative polymerase chain reaction (qPCR). The optimal parameters that provide the greatest difference in amount of amplifiable DNA targets corresponding to fragmentation degree are the following: moderate amplicon size (about 150-250 bp), medium CpG sparseness (one CpG dinucleotide per ∼12-14 nucleotides of the chain), and short sonication time (less than 5 min). Along with CpG, the CpA and CpT contents of amplified regions should be taken into account for proper DNA fragmentation by ultrasound as well. The obtained data could be used for elaboration of a method for comparative methylation testing, when there is no need to detect methylation of certain CpG dinucleotides. This method will be simple (can be used by any technician familiar with PCR), low cost (no need to use an expensive reagents), and fast (only brief DNA sonication and conventional qPCR are carried out). Communicated by Ramaswamy H. Sarma.

Polymerase chain reaction with nearby primers.

DNA analysis of biological specimens containing degraded nucleic acids such as mortal remains, archaeological artefacts, forensic samples etc. has gained more attention in recent years. DNA extracted from these samples is often inapplicable for conventional polymerase chain reaction (PCR), so for its amplification the nearby primers are commonly used. Here we report the data that clarify the features of PCR with nearby and abutting primers. We have shown that the proximity of primers leads to significant reduction of the reaction time and ensures the successful performance of DNA amplification even in the presence of PCR inhibitors. The PCR with abutting primers is usually characterized by the absence of nonspecific amplification products that causes extreme sensitivity with limit of detection on single copy level. The feasibility of PCR with abutting primers was demonstrated on species identification of 100 years old rotten wood.