Taq DNA Polymerase Research Articles

A comparative study of extraction free detection of HBV DNA using sodium dodecyl sulfate, N-lauroylsarcosine sodium salt, and sodium dodecyl benzene sulfonate

This study aimed to develop an extraction-free method for quantitative and qualitative detection of HBV DNA compared to traditional nucleic acid extraction. Paired serum and dried blood spot (DBS) samples from 67 HBsAg-positive and 67 HBsAg-negative individuals were included. Two samples with known HBV DNA titers (~ 109 copies/mL) were examined by extraction-free detection using three surfactants (0.2 to 1% of Sodium dodecyl sulfate:SDS, N-Lauroylsarcosine sodium salt:NL, Sodium dodecyl benzene sulfonate:SDBS), two stabilizing agents (0.1 or 0.01% 2-Mercaptoethanol:2ME and 3.5 or 7% Bovine Serum Albumin:BSA) and two Taq polymerases (Fast Advanced and Prime Direct Probe). HBV DNA in all 67 HBsAg-positive and 67 HBsAg-negative serum and DBS samples was directly quantified by Rt-PCR using 0.4% SDS or 0.4% NL with Fast Advance or Prime Direct Probe Taq. Extraction-free amplification was also performed. Detection limits were varied by different surfactants and Taq. SDS combined with Fast Advanced Taq showed lower detection limits, while SDS with Prime Direct Probe Taq outperformed NL or SDBS-based detection. Adding 2ME to SDS improved detection limit with Prime Direct Probe Taq but not significantly compared to SDS alone. BSA did not significantly enhance detection limits but provided insights into sample stability. The senitivity and specificity of 0.4% SDS and NL in combination with either Fast advanced or Prime Direct Probe Taq polymerase in serum samples were > 90% and 100% resepctively, while it was > 80% and 100% respectively in DBS samples. Extraction-free HBV DNA amplification provided 100% identity with original genomes. Our study suggests that SDS, NL or SDBS-based extraction-free HBV DNA detection strategies using Prime Direct Probe Taq have potential to simplify and accelerate HBV DNA detection with high sensitivity and specificity in both serum and DBS samples, with implications for resource-limited settings and clinical applications. Utilizing surfactants with 2ME is optional, and further research and validation are necessary to broaden its application in real-world diagnostics.

Zn2+ ions improve the fidelity of metal-mediated primer extension while suppressing intrinsic and Mn2+-induced mutagenic effects by DNA polymerases.

While Mn2+ ions are well-established for reducing the fidelity of DNA polymerases, leading to the misincorporation of nucleotides, our investigation of the effects of metal ions revealed a contrasting role of Zn2+. Here, we demonstrate that Zn2+ ions enhance the fidelity of DNA polymerases (the 3' → 5' exonuclease-deficient Klenow fragment and Taq DNA polymerase) by suppressing misincorporation during primer extension reactions. Remarkably, Zn2+ ions inhibit both intrinsic misincorporation and Mn2+-induced misincorporation of nucleotides. Furthermore, Zn2+ ions also effectively suppressed misincorporation during metal-mediated primer extension reactions, which involved forming Ag+ and Hg2+ ion-mediated base pairs. These findings suggest that Zn2+ ions inhibit both intrinsic and Mn2+-induced mismatched base pair formation. Consequently, the combined use of Mn2+ and Zn2+ ions may offer a strategy for precisely regulating the fidelity of DNA polymerases. Remarkably, Zn2+ ions even suppress misincorporation in primer extension reactions that rely on metal-mediated base pairs, and conversely, this suggests that DNA polymerases recognize metal-mediated base pairs such as T-Hg2+-T, C-Ag+-A, and C-Ag+-T as relatively stable base pairs. These results imply that Zn2+ ions may also enhance the fidelity of DNA polymerases when incorporating non-canonical nucleobases, potentially paving the way for the expansion of the genetic alphabet.

First report of lily mottle virus naturally infecting lily (Lilium asiatica) in Texas, USA.

Lily (Lilium asiatica) is an important plant grown for its range of flower colors and heavy scent. In March 2024, potyvirus-like symptoms consisting of light-yellow mottling and mosaic were noticed on 12/20 lily plants in a private property in Weslaco, Hidalgo County, Texas. Two symptomatic plants (WTX1 and WTX2) were sampled randomly for virus diagnosis. The leaf extracts of both samples were negative for the potyvirus group using Agdia's Poty ImmunoStrip® (Agdia, Inc., Elkhart, IN, USA). However, rub-inoculation of the extracts onto healthy Nicotiana benthamiana and Vigna unguiculata plants (n=4, each) induced mild mottle symptoms on the systemic leaves of both herbaceous test plants 20 to 28 days post inoculation, indicating the presence of a mechanically transmissible agent in the samples. No virus-like symptoms were observed on the mock-inoculated plants (n=1, each) of both species. To test for suspected potyvirus infection, 2-µg of total nucleic acid extracts (Dellaporta et al. 1983) from WTX1 and WTX2 were used for complimentary DNA (cDNA) synthesis with Oligo(dT) primer and the PrimeScript 1st strand cDNA synthesis kit (Takara Bio, USA). One microliter aliquot of each cDNA served as template in 12.5-µl conventional PCR reaction volumes with 5 U Taq polymerase (Roche Diagnostics, Indianapolis, IN), and two pairs of degenerate primers targeting the partial cylindrical inclusion (CI) gene and the helper component protease (HC-Pro) of potyviruses (Ha et al. 2008). The expected ~700-bp DNA product of each gene target was amplified from both samples. The amplicons were excised, gel eluted (Zymoclean™ Gel DNA Recovery kit) and cloned individually into the pJET1.2/Blunt vector (Life Technologies). Recombinant plasmids from two transformed Escherichia coli cells per cloned DNA insert were Sanger sequenced. BLASTn analysis of each gene-specific nucleotide (nt) sequence fragment revealed their identities (83 to 92 % nt) as lily mottle virus (LMoV; genus Potyvirus) at 93 to 98% query coverage. In pairwise comparison, the obtained sequences of LMoV isolates from TX specific to the CI (GenBank accession nos. PQ037260-61) and the HC-Pro (PQ037262-63) shared ~99% nt and 100% amino acid (aa) identities with each other and ~91-92% nt and 98-100% aa identities with the closest isolate, Bate5 (JN127341) from Australia. Based on these results, a pair of LMoV-specific primers (LM_v109-F: 5'-GGCCAGTAATGTGCACAAGC-3' and LM_c527-R: 5'-TCGCTGTAGCTAGCGACGTAC-3') was newly designed to target the partial CI gene, internal to the 700-bp fragment obtained above with the generic primers. The primer pair was used to screen each of the mechanically inoculated test plants by RT-PCR as previously described above. The expected 438-bp fragment of the LMoV CI gene was amplified from all the inoculated plants of both N. benthamiana and V. unguiculata; the results were confirmed by Sanger sequencing as described above. The mock-inoculated plant of each experimental host plant tested negative for LMoV. LMoV is a quarantine pest and was previously reported in the U.S. (Brierley and Smith, 1944) and other lily-producing parts of the world, such as the Netherlands, China, Korea, and Brazil. To our knowledge, this is the first confirmed report of the virus in Texas, thus expanding its geographical range. Testing of lily foundation stocks before propagation is essential to prevent further spread of LMoV via planting material.

B-208 Room Temperature Stable PCR Reagents Preparation Using Capillary-Mediated Vitrification Process

Abstract Background Polymerase chain reaction (PCR) is a sensitive, and most used molecular technique for the disease diagnosis. Reagents used for PCR is available as a one-step and ready-to-use PCR Master Mix, which contains Taq DNA polymerase, dNTPs, MgC12, PCR reaction buffer. However, to preserve bioactivity, PCR reagents must be stored and distributed as frozen. Desiccation of PCR reagents can avoid cold storage and improper handling of wet reagents and its associated errors. We discovered capillary-mediated vitrification (CMV) processes can stabilize different biomolecules and allow them to be stored at ambient temperature. Here, we hypothesized that the CMV process can preserve and improve PCR reagents thermal stability, which will reduce PCR processing time and improve the testing throughput. Methods The CMV process was performed by mixing PCR Master Mix individual or all reagents such as Taq DNA polymerase or Hot Start Taq DNA polymerase, dNTPs, 16S rRNA primers, MgC12, and PCR reaction buffer with an excipient buffer and adding the mixture to a porous scaffold. The loaded scaffolds were placed into our vitrification chamber and dried for 30 min. After drying, the CMV-stabilized sample was tested or packed in Mylar pouches and were stored at ambient and elevated temperatures for 42 days. On the day of testing, the stabilized samples were eluted with nuclease-free water and E. coli genomic DNA was added, and the 50 uL reaction was tested by conventional PCR. The PCR product was visualized under agarose gel electrophoresis. Results To assess whether the CMV process maintains PCR reagents activity and not interfering with the assay, the individual PCR reagents and as a Master mix are preserved. The CMV stabilized polymerase enzyme, primer, or dNTPs amplified DNA similar to frozen reagents and produced comparable PCR products. Notably, CMV stabilized PCR Master Mix which contains either Taq DNA polymerase or Hot Start Taq DNA polymerase enzyme, dNTPs, primers, MgC12, and reaction buffer yielded intact amplified PCR product, which is comparable to frozen reagents. Likewise, a high intense PCR product was observed in the stabilized PCR Master Mix reagents when stored at room and elevated temperatures for 42 days. Conclusions The study results indicate that the CMV process stabilized and improved the PCR Master Mix reagents activity. The study suggests that the CMV technology has the potential to enable ambient storage and shipping of PCR reagents for molecular diagnostic and other related applications.

B-237 Engineered Reverse Transcriptases and Taq DNA Polymerases deliver robust yield in the presence of clinically relevant inhibitors

Abstract Background The past five years has seen explosive growth in molecular diagnostic assays that rely on sensitive and accurate detection of nucleic acids across a wide range of sample types. As the assays are required to become increasingly sensitive, the need for highly functional and purpose-built enzymatic tools has grown. Reverse transcriptase (RT) and Taq DNA Polymerase (Taq DNAP) are commonly used to detect RNA and/or DNA viruses in patient samples for point of care (POC) diagnostics. However, crude patient samples introduce inhibitors that decrease enzyme activity and increase false negative results in POC testing. In addition, there is a need for faster turn-around time for patient diagnosis which can be enabled by engineering more active and sensitive Taq variants. Herein, we present on our engineered RT and Taq DNAP enzymes that were developed to confer greater activity, thermostability, inhibitor tolerance and/or sensitivity. Methods We take a 3-pronged approach to protein engineering: rational design, computational design and directed evolution. Using these techniques, we identified and characterized many RT and Taq DNAP variants. We deeply characterized each RT variant by measuring processivity, inhibitor tolerance and thermostability. First strand synthesis was done at temperatures from 42-65°C in the presence and absence of various clinically relevant inhibitors followed by qPCR to assess cDNA yield. Next, we characterized the inhibitor tolerance of the Taq variants by performing qPCR reactions in the presence of inhibitors. To determine if the Taq variant would be an appropriate fit for fast PCR, the polymerization activity of the Taq DNAP variants were characterized using a primer extension assay. Results Reverse transcriptases termed; StellarScript, StellarScript HT and StellarScript HT+ exhibit high processivity at 42°C. StellarScript HT+ exhibited the highest inhibitor tolerance, processivity and thermostability at temperatures up to 65°C thus making StellarScript HT+ well suited to produce high yields with clinical samples. Taq Pol variants were identified that efficiently amplify DNA in the presence of inhibitors. Conclusions Based on the increased polymerase activity and inhibitor tolerance, WMG Taq variants are well suited to give robust DNA yields with clinical samples. We were successful in engineering RT and Taq DNAP variants that are highly thermostable, active and inhibitor tolerant and thus will enable breakthroughs in existing POC diagnostics.

B-206 Tick-borne disease molecular testing positivity and coinfection incidence in the northeastern united states: 2021-2023

Abstract Background The CDC estimates that Lyme disease affects hundreds of thousands of people each year in the United States. Tick-borne diseases caused by pathogens such as Anaplasma phagocytophilum, Babesia microti, Ehrlichia chaffeensis, and species of Borrelia follow a seasonal pattern due to the life cycle of disease-carrying ticks. In endemic areas, like the northeastern United States, the risk of coinfection by multiple tick-borne disease pathogens is higher and can complicate patient treatment. For example, while Anaplasma and Borrelia can be treated with doxycycline a Babesia coinfection would not be resolved with this medication. In this study, we performed a retrospective analysis of tick-borne disease molecular testing results to monitor positivity rates and incidence of coinfection. Methods This retrospective analysis included whole blood specimens submitted to a regional clinical laboratory in the northeastern United States for tick-borne disease molecular testing. Test results from 2021-2023 were analyzed for positivity rate trends and coinfection incidence. DNA was isolated from patient specimens and tested using laboratory developed real-time Taq polymerase PCR assays. Results Positivity rates for all tick-borne disease pathogens studied followed typical seasonal patterns (Table). Beginning in the early spring, as nymphs ended their dormancy and began to feed, infection rates of tick-borne disease climbed. Infections peaked in mid-summer and remained elevated through late autumn. For Anaplasma, a biphasic pattern was observed, with a smaller peak in late autumn when adult ticks are most active. Coinfections with Anaplasma and Babesia were observed in 136 specimens, while coinfections with Borrelia and Babesia were observed in 145 specimens. Conclusions Positivity rates for tick-borne disease pathogens followed expected seasonal patterns in the northeastern US. The incidence of coinfections involving Babesia microti highlights the importance of properly identifying tick-borne infections given the different treatment regimens indicated.

Effect of poly(dA) stretch in a template sequence on the rate and yield of polymerase chain reaction with electroactive modified 2′-deoxyuridine-5′-triphosphates

The effective incorporation of electroactive labeled nucleotides into DNA during its enzymatic amplification provides the ground for developing assays based on direct electrochemical detection of amplification products. Yet, whether the template sequence can affect the incorporation efficiency of modified nucleotides is still poorly understood. Here we examined the effects of a poly(dA) stretch in template sequence on the rate and yield of polymerase chain reaction (PCR) in the presence of modified 2′-deoxyuridine-5′-triphosphates (dUTP) in the reaction mixture. Four dUTP derivatives carrying 4-hydroxyphenyl (tyrosine; dUTP-Y1 and dUTP-Y2), 4-nitrophenyl (dUTP-N1), or indolyl (tryptophan; dUTP-W1) aromatic groups were tested as substrates for Taq and KTN (lacking 3′-5′ exonuclease activity) polymerases at 100 % substitution of 2′-deoxythymidine-5′-triphosphate (dTTP) in the PCR mixture. The 120 base pair long synthetic DNA templates contained poly(dA)·poly(dT) tracts of various length (dAn·dTn, where n = 2–10). In all cases, full-size amplicons have been obtained. Overall, in the presence of modified dUTP, the PCR yield was higher with KTN polymerase than that with Taq polymerase. The PCR yield slightly (for dUTP-Y1 and dUTP-Y2) or significantly (for dUTP-N1 and dUTP-W1) decreased with an increase of n in the dAn·dTn tract. In most cases, in the presence of modified dUTP, the PCR rate substantially decreased with n ≥ 4 in dAn·dTn. No changes in amplicon sequences due to potential incorrect nucleotide pairing during amplification with the complete substitution of dTTP with dUTP-Y2 were revealed. Electrochemical activity of tyrosine labeled PCR products dsDNA-Y2 differing in the length of stretches of modified nucleotides was similar. The findings demonstrate that the incorporation efficiency for base-modified nucleotides can in general depend on template sequence, in particular on the presence of long poly(dA) stretches when the modified dUTP are used. That has to be taken into account when developing electrochemical or other DNA assays with a specific modified nucleotide.

Structural Basis for C2′-methoxy Recognition by DNA Polymerases and Function Improvement

DNA modified with C2′-methoxy (C2′-OMe) greatly enhances its resistance to nucleases, which is beneficial for the half-life of aptamers and DNA nanomaterials. Although the unnatural DNA polymerases capable of incorporating C2′-OMe modified nucleoside monophosphates (C2′-OMe-NMPs) were engineered via directed evolution, the detailed molecular mechanism by which an evolved DNA polymerase recognizes C2′-OMe-NTPs remains poorly understood. Here, we present the crystal structures of the evolved Stoffel fragment of Taq DNA polymerase SFM4-3 processing the C2′-OMe-GTP in different states. Our results reveal the structural basis for recognition of C2′-methoxy by SFM4-3. Based on the analysis of other mutated residues in SFM4-3, a new Stoffel fragment variant with faster catalytic rate and stronger inhibitor-resistance was obtained. In addition, the capture of a novel pre-insertion co-existing with template 5′-overhang stacking conformation provides insight into the catalytic mechanism of Taq DNA polymerase.

Oncogenic and telomeric G-quadruplexes: Targets for porphyrin-triphenylphosphonium conjugates

DNA chains with sequential guanine (G) repeats can lead to the formation of G-quadruplexes (G4), which are found in functional DNA and RNA regions like telomeres and oncogene promoters. The development of molecules with adequate structural features to selectively stabilize G4 structures can counteract cell immortality, highly described for cancer cells, and also downregulate transcription events underlying cell apoptosis and/or senescence processes.We describe here, the efficiency of four highly charged porphyrins-phosphonium conjugates to act as G4 stabilizing agents. The spectrophotometric results allowed to select the conjugates P2-PPh3 and P3-PPh3 as the most promising ones to stabilize selectively G4 structures. Molecular dynamics simulation experiments were performed and support the preferential binding of P2-PPh3 namely to MYC and of P3-PPh3 to KRAS. The ability of both ligands to block the activity of Taq polymerase was confirmed and also their higher cytotoxicity against the two melanoma cell lines A375 and SK-MEL-28 than to immortalized skin keratinocytes. Both ligands present efficient cellular uptake, nuclear co-localization and high ability to generate 1O2 namely when interacting with G4 structure. The obtained data points the synthesized porphyrins as promising ligands to be used in a dual approach that can combine G4 stabilization and Photodynamic therapy (PDT).

Designing primer-probe sets for Escherichia coli and E. coli O157 detection: Comparative genomic approach and food interference assessment

This study aimed to develop novel primer-probe sets specifically optimized for detecting E. coli and E. coli O157 through comparative genomic analysis. Genomic data from 2396 E. coli strains, including 228 strains of E. coli O157, were retrieved from the National Center for Biotechnology Information (NCBI). From the analysis, yegR and GDP-mannose mannosyl hydrolase (GDPMH) genes were selected as primer targets for E. coli and E. coli O157:H7, respectively. The sensitivity and specificity of the designed primer-probe sets were evaluated in 48 E. coli strains (including 30 E. coli O157) and 17 non-E. coli strains, totaling 65 strains, and the results indicated high sensitivity and specificity. Tryptic soy broth (TSB), carrots, chicken, milk, potatoes, apple juice, and orange juice did not significantly interfere with detecting E. coli and E. coli O157; however, 50% potato samples did. The efficacy of the designed primers was compared among ground pork, lettuce, and potato samples. Reduced detection efficiency was noted in the lettuce and potato samples. Wavelength interference with components of the lettuce homogenate may have reduced detection efficiency. For potato samples, the high affinity of chlorogenic acid, a compound found in potatoes, for Taq DNA polymerase, a component of the mastermix, contributed to the reduced detection efficiency. The primer and probe sets described in this study, coupled with an understanding of possible interference from food components, will aid in detecting E. coli O157 in the food industry.

Production of Reverse Transcriptase and DNA Polymerase in Bacterial Expression Systems.

DNA amplification and reverse transcription enzymes have proven to be invaluable in fast and reliable diagnostics and research applications because of their processivity, specificity, and robustness. Our study focused on the production of mutant Taq DNA polymerase and mutant M-MLV reverse transcriptase in the expression hosts Vibrio natriegens and Escherichia coli under various expression conditions. We also examined nonspecific extracellular production in V. natriegens. Intracellularly, M-MLV was produced in V. natriegens at the level of 11% of the total cell proteins (TCPs) compared with 16% of TCPs in E. coli. We obtained a soluble protein that accounted for 11% of the enzyme produced in V. natriegens and 22% of the enzyme produced in E. coli. Taq pol was produced intracellularly in V. natriegens at the level of 30% of TCPs compared with 26% of TCPs in E. coli. However, Taq pol was almost non-soluble in E. coli, whereas in V. natriegens, we obtained a soluble protein that accounted for 23% of the produced enzyme. We detected substantial extracellular production of Taq pol. Thus, V. natriegens is a suitable alternative host with the potential for production of recombinant proteins.

A novel mediator probe and universal fluorescence probe (MP-UP) system for highly sensitive and versatile nucleic acid detection

Real-time qPCR and digital PCR are powerful techniques for detecting nucleic acids with high specificity and sensitivity, relying on sequence-specific labeled probes. However, each target requires the design and synthesis of specific probes, incurring significant costs. Therefore, the development of a specific and universal detection technique is both urgent and beneficial. Previously, a universal detection method was developed using a modified mediator probe and a universal hairpin reporter. However, our experiments uncovered that the mediator primers, generated by Taq polymerase cleaving mediator probes, deviate from the expected sequence, indicating a severe compromise in detection ability. Additionally, the high cost of the modified mediator probe and hairpin reporter impedes the practicality of their method. To overcome these challenges, we have developed a novel universal detection method (MP-UP) using Taqman probes, unmodified mediator probes and helper target, enabling the utilization of all mediator primers to produce abundant fluorescence. Enhanced MP-UP qPCR with an increased signal-to-noise ratio, MP-UP ddPCR, and multiplex MP-UP were established, exhibiting remarkable sensitivity, specificity, and precision comparable to specific probe assays or commercial testing kit. The mediator probe and helper target cost only one-tenth of a specific Taqman probe, rendering it feasible to replace the latter in specific nucleic acid detection.

Genetic analyses of the structural protein E2 bovine viral diarrhea virus isolated from dairy cattle in Yogyakarta, Indonesia.

Bovine viral diarrhea (BVD), a highly pathogenic ribonucleic acid (RNA) virus, causes devastating financial losses and reproductive deaths among dairy cattle in Yogyakarta and globally. This study aimed to identify point mutations within the E2 structural protein of the acquired BVD virus (BVDV) isolates using genetic analysis. The study period shows that we performed the research in 2023. We collected 118 serum samples from 2019 to 2023, among which only 10 BVDV positive were used and 108 were negative lacking the BVDV antigen. An anti-Erns monoclonal antibody-coated protein was used in indirect antigen capture enzyme-linked immunosorbent assay (I-ACE) to detect the BVD antigen present in positive BVDV serum specimens. In the initial step of the two-step reverse transcription polymerase chain reaction, the enzyme (superscript III reverse transcriptase) and the primer (random hexamer) were used to convert the RNA of the BVDV into complementary deoxyribonucleic acid (cDNA) during the process of reverse transcription. The final step involved the amplification of the E2 gene of the resultant BVDV cDNA through gene-specific primers (E2_fwd: 5'-TGGTGGCCTTATGAGAC-3' and P7_rev: 5'-CCCATCATCACTATTTCACC-3') and enzyme (platinum taq DNA polymerase high fidelity). For conducting Sanger sequencing, those 3 BVDV-1-positive isolates (about 2.6% of all isolates) were selected as a typical specimen for each site and year between 2019 and 2023 using a proportional computation. Therefore, only two BVDV isolates with complete genomes were chosen to perform their homological and genetic analysis based on the E2 gene by means of Blast and MEGA Version 11 in addition to the Bioedit 7.2.5 program. By applying phylogenetic analysis relying on the E2 gene, a sum of 1011 nucleotides of the BVDV-1 isolates derived from each of the two BVDV-1 Indonesian isolates (n = 2) and its 23 reference BVDV strains were acquired from the National Center for Biotechnology Information (NCBI) database. The findings of the genetic analysis inside the phylogenetic tree revealed that the two BVDV Indonesian isolates were clustered into BVDV-1a subgenotype, while the reference BVDV strains were clustered into the five BVDV subgenotype, BVDV-1a (n = 6), BVDV-1b (n = 3), BVDV-1c (n = 11), BVDV-1m (n = 1), and BVDV-1n (n = 2). The branch exists in phylogenetic tree located before the division of our two BVDV isolates was divided into two branches with the same maximum bootstrap values of 99%, indicating a high degree of confidence, was seen. Next, we observed the branch near our study samples, which displayed the bootstrap value of 100, indicating that our 02 isolates were identical. In both isolates, V11 BVDV1/Indonesia/Yogyakarta/2023 and V16 BVDV1/Indonesia/Yogyakarta/2023 with GenBank accession numbers PP836388 and PP836389, respectively, conserved D7E residues were mutated as well as cysteine changed/altered into serine (S) was identified at amino acid position 201. We identified two isolates of BVDV belonging to the BVDV-1a subgenotype. Our findings indicate that the conserved D7E residues of isolates V11 BVDV1/Indonesia/Yogyakarta/2023 and V16 BVDV1/Indonesia/Yogyakarta/2023 were altered. The Indonesian BVDV isolates exhibited a cysteine to serine mutation at amino acid position 201, leads to vaccination failure, range of animal's host will increase, and diagnostic kit will not be effective.

Target-responsive triplex aptamer nanoswitch enables label-free and ultrasensitive detection of antibody in human serum via lighting-up RNA aptamer transcriptions

Accurate and sensitive monitoring of the concentration change of anti-digoxigenin (Anti-Dig) antibody is of great importance for diagnosing infectious and immunological diseases. Combining a novel triplex aptamer nanoswitch and the high signal-to-noise ratio of lighting-up RNA aptamer signal amplification, a label-free and ultrasensitive fluorescent sensing approach for detecting Anti-Dig antibodies is described. The target Anti-Dig antibodies recognize and bind with the nanoswitch to open its triplex helix stem structure to release Taq DNA polymerase and short ssDNA primer simultaneously, which activates the Taq DNA polymerase to initiate downstream strand extension of ssDNA primer to yield specific dsDNA containing RNA promoter sequence. T7 RNA polymerase recognizes and binds to these promoter sequences to initiate RNA transcription reaction to produce many RNA aptamer sequences. These aptamers can recognize and bind with Malachite Green (MG) dye specifically and produce highly amplified fluorescent signal for monitoring Anti-Dig antibodies from 50 pM to 50 nM with a detection limit down to 33 pM. The method also exhibits high selectivity for Anti-Dig antibodies and can be used to discriminate trace Anti-Dig antibodies in diluted serum samples. Our method is superior to many immunization-based Anti-Dig antibody detection methods and thus holds great potential for monitoring disease progression and efficacy.

One-step reverse transcriptase-free miRNA detection system and its application for detection of gastrointestinal cancers

MicroRNAs (miRNAs) play pivotal roles in gene regulation and their dysregulation is implicated in various diseases, including cancer. Current methods for miRNA analysis often involve complex procedures and high costs, limiting their clinical utility. Therefore, there is a critical need for the development of simpler and more cost-effective miRNA detection techniques to enable early disease diagnosis. In this study, we introduce a novel one-enzyme for miRNA one-step detection method using Taq DNA polymerase, termed OSMOS-qPCR. We optimized the PCR buffer, PCR program, Taq DNA Polymerase concentrations and reverse PCR primer concentrations, resulted in a wide linear range from 100 fM to 0.001 fM (R2 > 0.98 for each miRNA), the detection limit for OSMOS-qPCR was 0.0025 fM. Furthermore, OSMOS-qPCR demonstrates excellent specificity to differentiation of less than 0.1 % nonspecific signal. Finally, we demonstrated the robust amplification efficiency, enabling the detection of trace amounts of cell-free miRNA in serum samples, and the excellent discrimination ability between gastrointestinal cancers and control subjects (AUC value = 1.0) if combined two miRNAs. The development of OSMOS-qPCR offering a simpler, cost-effective, and efficient detection method, has the potential to be non-invasive strategy for early detection of gastrointestinal cancers.

Multi‐locus sequence typing indicates multiple strains of Mycoplasma in desert bighorn sheep and aoudad in Texas

AbstractEpizootic events of pneumonia, presumably caused by Mycoplasma ovipneumoniae, in bighorn sheep (Ovis canadensis) have been observed in the western United States and Canada. Until recently, it was thought that populations of Mexican (O. c. mexicana) and Nelson's (O. c. nelsoni) desert bighorn sheep in Texas, USA, had not been exposed to Mycoplasma. Evidence of disease and potential population decline from outbreaks of M. ovipneumoniae are now known from several populations across the Trans‐Pecos Ecoregion with documented instances of pneumonia and bluetongue in desert bighorn sheep from the Van Horn Mountains and Black Gap Wildlife Management Area. These disease events, especially those in 2019–2021, may be a result of increasing populations of aoudad (Ammotragus lervia), an introduced and invasive ungulate, in the region. With large population sizes and similar movement patterns as desert bighorn sheep, aoudad potentially are the reservoirs for bacterial and viral diseases, such as pneumonia and bluetongue, and are possibly contributing to the decline of desert bighorn sheep. Herein, we optimized the multi‐locus sequence typing (MLST) with modifications in the Taq polymerase and annealing temperatures to determine the genetic identity of Mycoplasma strains or species within the nasal passages of desert bighorn sheep and aoudad in the Trans‐Pecos Ecoregion of Texas. Four loci (small ribosomal unit, 16S; 16S‐23S intergenic spacer region, IGS; RNA polymerase B, rpoB; gyrase B, gyrB) were characterized using MLST. Based on results from the modified MLST technique, we identified 9 desert bighorn sheep and 5 aoudad with M. ovipneumoniae, 9 aoudad with bacterial sequences genetically similar to M. conjunctivae, and 10 aoudad with bacterial sequences genetically similar M. hyopneumoniae. Of these, 9 aoudad possessed bacterial sequences genetically similar to both M. conjunctivae and M. hyopneumoniae. Among the 4 diagnostic loci, genetic divergence of M. ovipneumoniae ranged from 0.00–0.90% among desert bighorn sheep and aoudad. Future sampling efforts of seemingly asymptomatic aoudad, and asymptomatic, visibly sick, or deceased desert bighorn sheep, are important to monitor the spread of disease in desert bighorn sheep populations across mountain ranges in western Texas. It is imperative that aoudad removal plans are implemented to reduce and eliminate current infections and putative transmission of M. ovipneumoniae, prevent future disease outbreaks of pneumonia, and ultimately conserve desert bighorn sheep for future generations.

High-level expression of codon-optimized Taq DNA polymerase under the control of rhaBAD promoter

A DNA polymerase from Thermus aquaticus remains the most popular among DNA polymerases. It was widely applied in various fields involving the application of polymerase chain reaction (PCR), implying the high commercial value of this enzyme. For this reason, an attempt to obtain a high yield of Taq DNA polymerase is continuously conducted. In this study, the l-rhamnose-inducible promoter rhaBAD was utilized due to its ability to produce recombinant protein under tight control in E. coli expression system. Instead of full-length Taq polymerase, an N-terminal deletion of Taq polymerase was selected. To obtain a high-level expression, we attempted to optimize the codon by reducing the rare codon and GC content, and in a second attempt, we optimized the culture conditions for protein expression. The production of Taq polymerase using the optimum culture condition improved the level of expression by up to 3-fold. This approach further proved that a high level of recombinant protein expression could be achieved by yielding a purified Taq polymerase of about 8.5 mg/L of culture. This is the first research publication on the production of Taq polymerase with N-terminal deletion in E. coli with the control of the rhaBAD promoter system.

Systematic evaluation of the influence of Taq enzyme choice and amplification conditions on targeted environmental DNA assay performance and detection in field samples

AbstractTargeted environmental DNA (eDNA) studies mainly rely on quantitative real‐time polymerase chain reaction (qPCR) to amplify extremely low concentrations of DNA present in environmental samples. Understanding factors that influence targeted eDNA assay performance and detection in field samples, such as Taq DNA polymerase enzyme type and thermocycle protocol, is critical for the interpretation of qPCR results. We completed a systematic performance evaluation of five distinct targeted eDNA assays (eANFI6, eFISH1, eANBO5, eGLIN1, and eLICA3 targeting sablefish, general fish, Boreal toad, wood turtle, and the American bullfrog) by subjecting the same samples to analysis by five different Taq enzyme reagent mixes (Immolase, Environmental Master Mix (EMM), Amplitaq, QIAcuity, and QuantiNova) and the commonly used 2‐step (95°C, 60°C) and 3‐step (95°C, 64°C, 72°C) thermocycle protocols. We evaluated assay performance using a standardized dilution series of synthetic dsDNA target sequences and calculated limits of detection (LOD) and quantification (LOQ) and 95% confidence intervals for each combination of Taq enzyme and thermocycle protocol. All assays performed within acceptable performance criteria as defined by the Canadian national standard for targeted eDNA assays. Based on data generated by synthetic dsDNA fragments, the eDNA assays performed comparably regardless of the enzyme reagent mix and protocol used, except for eANFI6 and eGLIN1 using EMM and the 3‐step protocol, where no amplification was observed. On freshwater field samples, EMM and Immolase performed best. On marine field samples, Immolase, EMM, Qiacuity, and QuantiNova performed equally well, although EMM failed to amplify some samples. The work reveals that an enzyme reaction mix or thermocycle protocol can affect the result of an eDNA assay, but the appropriate choice also depends on the nature of the field sample. It is therefore imperative that these are considered when selecting appropriate reaction conditions and that they are clearly reported.

Cost-effective in-house COVID-19 reverse transcription-polymerase chain reaction testing with yeast-derived Taq polymerase.

Despite the decline of the COVID-19 pandemic, there continues to be a persistent requirement for reliable testing methods that can be adapted to future outbreaks and areas with limited resources. While the standard approach of using reverse transcription-polymerase chain reaction (RT-PCR) with Taq polymerase is effective, it faces challenges such as limited access to high-quality enzymes and the presence of bacterial DNA contamination in commercial kits, which can impact the accuracy of test results. This study investigates the production of recombinant Taq polymerase in yeast cells and assesses its crude lysate in a multiplex RT-PCR assay for detecting the SARS-CoV-2 RNA-dependent RNA polymerase (RdRP) and N genes, with human Ribonuclease P serving as an internal control. The unpurified yeast Taq polymerase demonstrates sensitivity comparable to commercially purified bacterial Taq polymerase and unpurified bacterial counterparts in detecting the RdRP and N genes. It exhibits the highest specificity, with 100% accuracy, for the N gene. The specificity for the RdRP gene closely aligns with that of commercially purified bacterial Taq polymerase and unpurified bacterial Taq polymerase. The use of unpurified recombinant yeast Taq polymerase shows promise as a cost-effective approach for conducting in-house COVID-19 RT-PCR testing. By eliminating the need for chromatography purification steps, the production of RT-PCR kits can be streamlined, potentially improving accessibility and scalability, especially in resource-limited settings and future pandemics.

Characterization of genetic diversity in Curcuma longa L. cultivars using Start Codon Targeted (SCoT) markers

Curcuma longa L. (Family- Zingiberaceae), commonly called turmeric, is one of the most important commercial spices. Being a center of turmeric's diversity, India boasts of more than fifty cultivars with variable agronomic characters and curcumin content. However, the quest for calibrating their genetic variability remains debatable as popular molecular marker-based studies have yielded inconsistent results. A promising PCR-based approach, known as the Start Codon Targeted (SCoT)-PCR system has been established to be more efficient than random DNA marker systems because this technique can generate more information on genetic polymorphism patterns. Hence, the present study proposes to use Start Codon Targeted (SCoT) markers to assess inter-cultivar genetic diversity of turmeric. We report an orthogonal L16 (45) design-based approach to investigate the influence of five crucial factors (dNTPs, Taq DNA polymerase, primer, template DNA and annealing temperature of primer) on the efficiency of the polymerase chain reaction (PCR) for development of an optimized Start Codon Targeted (SCoT) amplification protocol using twenty-seven different cultivars of C. longa. The optimized PCR protocol yields best results with a 20 uL reaction mixture, containing 10×PCR Buffer (with 15 mM MgCl2), 2.5 mM dNTPs, 10 mM SCoT primer, Taq polymerase (2 U), template DNA (50 ng), which was verified by using twenty-five SCoT primers. This standardized rapid protocol of SCoT-PCR reported here was employed to examine genetic diversity among twenty-seven Indian cultivars of turmeric, revealing high range of polymorphism ranging from 81.25 % to 100 %. Unweighted pair group method of arithmetic averages (UPGMA) cluster analysis of the SCoT marker data segregated the twenty-seven cultivars into two main clusters. The first cluster comprised of nine cultivars (36 % of the cultivars) which was further divided into three sub-clusters and the second one consisted of eighteen cultivars (64 %) which further divided into four sub-clusters. From the results of this study, it can be inferred that the employment of SCoT markers can be an effective tool for analysing genetic variability, phylogenetic relationships and develop a rich genetic resource management system for C. longa cultivars.