PCR-Based Equine Gene Doping Test for the Australian Horseracing Industry.

The term 'gene doping' is used to describe the use of any unauthorized gene therapy techniques. We developed a test for five likely candidate genes for equine gene doping: EPO, FST, GH1, IGF1, and ILRN1. The test is based on real-time polymerase chain reaction (PCR) and includes separate screening and confirmation assays that detect different unique targets in each transgene. For doping material, we used nonviral (plasmid) and viral (recombinant adeno-associated virus) vectors carrying complementary DNA for the targeted genes; the vectors were accurately quantified by digital PCR. To reduce non-specific amplification from genomic DNA observed in some assays, a restriction digest step was introduced in the PCR protocol prior to cycling to cut the amplifiable targets within the endogenous genes. We made the screening stage of the test simpler and faster by multiplexing PCR assays for four transgenes (EPO, FST, IGF1, and ILRN1), while the GH1 assay is performed in simplex. Both stages of the test reliably detect at least 20 copies of each transgene in a background of genomic DNA equivalent to what is extracted from two milliliters of equine blood. The test protocol was documented and tested with equine blood samples provided by an official doping control authority. The developed tests will form the basis for screening official horseracing samples in Australia.

Towards a robust test to detect gene doping for anabolic enhancement in human athletes.

Success in gene therapy in treating human disease makes this technology attractive to enhance athletic performance, creating the need for gene doping detection. In 2021, World Anti-Doping Agency (WADA) approved the first gene doping test. Here, we describe a new method to detect doping with four additional genes, follistatin, growth hormone 1, growth hormone-releasing hormone and insulin-like growth factor 1, that may improve performance by increasing muscle size and strength. The method utilises four hydrolysis probe-based polymerase chain reaction (PCR) assays that target the transgenes based on the coding sequence of the four endogenous genes. The assays are specific, reproducible and capable to detect five copies of transgene in the presence of very similar endogenous gene in 25,000 times excess. To underpin reliable and comparable routine method performance by doping testing laboratories, a synthetic reference material for the method was designed and generated following the ISO Guide 35. The complete method was validated in blood samples using plasma as extraction matrix and QIAamp DNA blood midi DNA extraction kit. All blood samples from different donors (n = 8) simulated to be negative or positive (1500 transgene copies spiked per millilitre of blood) for the transgenes were reported correctly. The new method that targets four additional genes will extend the capabilities of laboratories involved in doping control to protect athletes' health, fairness and equality.

Novel design of nucleic acid standards for hydrolysis probe-based PCR with melting analysis.

Probe-based polymerase chain reaction (PCR), a popular method in genetic testing, could be prone to false positive or positively biased results if standards used for positive controls or as calibrants accidentally contaminate samples during analysis. To prevent this, a unique design strategy for nucleic acid standards has been developed. Several in-house designed synthetic standards and corresponding test targets were analysed in specific probe-based PCR assays in the presence of SYTO 82™, an intercalating dye compatible with a probe-labelling FAM (6-Carboxyfluorescein) fluorophore. PCR was followed by melting and fragment size analyses. We showed that a standard can be designed to allow discrimination from the test target in post-PCR melting analysis based on differences in melting temperature (Tm). A good predictor of Tm differences for the paired amplicons was the software package uMelt, but not the length of the amplicons nor guanine-cytosine (GC) content. Tm-based determination can be complimented by electrophoresis to measure differences in amplicons' length. Designing genetic standards using the described method for tests that utilise probe-based PCR will prevent false positive and inaccurate results, while also simplifying the test and reducing its cost.

Storage Stability of Solutions of DNA Standards.

High accuracy, reliability, and reproducibility of genetic analyses in various applications require optimized and validated protocols and standards. Optimal procedures for storing the genetic material extracted from biological samples are equally important. In this study, we investigated the stability of dilute (4000 cp/µL, nominal concentration, equivalent to 0.02 ng/mL) DNA solutions stored at 4, -20, and -80 °C in the presence or absence of nucleic acid carriers. As representative examples, we used different formulations of a linearized plasmid DNA solution considered for characterization as reference materials (RMs) for specific applications. Employing droplet digital PCR, a highly accurate and precise method for quantification of nucleic acid not requiring a calibrant, we demonstrated that inclusion of a carrier nucleic acid in the formulation (at 50 ng/µL) improved the plasmid stability at -20 and -80 °C. For the case of a DNA standard used in real-time PCR assays for human erythropoietin gene, cDNA or transcript, we found that inclusion of yeast RNA in the formulation was preferred over salmon testes DNA as it had no effect on PCR amplification and provided the lowest relative expanded uncertainty for the characterized RM. RNA background may also be preferred as it is applicable to a broader range of DNA RMs. Our findings are important in production of reliable, stable DNA standards, including DNA RMs. These results can be used when selecting protocols for stable storage of DNA either extracted from biological samples or synthesized in a laboratory.

Digital polymerase chain reaction for characterisation of DNA reference materials.

Accurate, reliable and reproducible quantification of nucleic acids (DNA/RNA) is important for many diagnostic applications and in routine laboratory testing, for example, for pathogen detection and detection of genetically modified organisms in food. To ensure reliable nucleic acid measurement, reference materials (RM) that are accurately characterised for quantity of target nucleic acid sequences (in copy number or copy number concentration) with a known measurement uncertainty are needed. Recently developed digital polymerase chain reaction (dPCR) technology allows absolute and accurate quantification of nucleic acid target sequences without need for a reference standard. Due to these properties, this technique has the potential to not only improve routine quantitative nucleic acid analysis, but also to be used as a reference method for certification of nucleic acid RM. The article focuses on the use and application of both dPCR and RMs for accurate quantification.

Transcriptional and posttranscriptional regulation of Bacillus sp. CDB3 arsenic-resistance operon ars1.

Bacillus sp. CDB3 possesses a novel eight-gene ars cluster (ars1, arsRYCDATorf7orf8) with some unusual features in regard to expression regulation. This study demonstrated that the cluster is a single operon but can also produce a short three-gene arsRYC transcript. A hairpin structure formed by internal inverted repeats between arsC and arsD was shown to diminish the expression of the full operon, thereby probably acting as a transcription attenuator. A degradation product of the arsRYC transcript was also identified. Electrophoretic mobility shift analysis demonstrated that ArsR interacts with the ars1 promoter forming a protein-DNA complex that could be impaired by arsenite. However, no interaction was detected between ArsD and the ars1 promoter, suggesting that the CDB3 ArsD protein may not play a regulatory role. Compared to other ars gene clusters, regulation of the Bacillus sp. CDB3 ars1 operon is more complex. It represents another example of specific mRNA degradation in the transporter gene region and possibly the first case of attenuator-mediated regulation of ars operons.

DNA methylation ratio variability may impede clinical application of cancer diagnostic markers.

Hypermethylation at promoter regions of tumour suppressor genes is diagnostic for many cancers. Many genomic regions that may be the targets for clinical diagnostic assays have been identified through use of measuring systems reliant on bisulphite conversion, but few of these promising markers are in clinical use. The comparability of a widely used DNA methylation measuring system involving bisulphite conversion was evaluated by supplying three experienced centres with methylated DNA reference material mixtures that were independently prepared and characterised by mass spectrometry and high-pressure liquid chromatography. A replication scheme was designed to evaluate reproducibility of key analytical steps within and between laboratories by regression analysis. In general, methylation was underestimated and methylation ratio values were highly variable. The difference in methylation ratio between CpG sites was the key contributor to variable results. The CpG site effect followed a similar pattern at all centres and at all methylation levels examined indicating that sequence context had a major effect on methylation ratio measurement using the bisulphite conversion process. The magnitude of underestimation combined with the variability of measurements between CpG sites compromises the concept of measuring genomic regional methylation by averaging the methylation ratios of many CpG sites. There were no significant differences in replicate bisulphite conversions or sample work-up and instrument analysis at each centre thus making this technique suitable for comparative intralaboratory investigations. However, it may not be suitable for a routine diagnostic assay without extensive standardisation efforts.

Digital polymerase chain reaction measured pUC19 marker as calibrant for HPLC measurement of DNA quantity.

Digital polymerase chain reaction (dPCR) is potentially a primary method for quantifying target DNA regions in a background of nontarget material and is independent of external calibrators. Accurate dPCR measurements require single-molecule detection by conventional PCR assays that may be subject to bias due to inhibition, interference, or sequence-derived PCR inefficiency. Elimination or control of such biases is essential for validation of PCR assays, but this may require a substantial investment in resources. Here we present a mechanism for DNA quantification that does not require PCR assay validation in situations where target DNA quantity is high enough to be measured by physical techniques such as quantitative high-performance liquid chromatography (HPLC) or electrophoresis. A commercially available DNA marker derived from pUC19 was quantified by dPCR and was then used to calibrate an HPLC measuring system for quantifying a DNA amplicon that had a high content of guanidine and cytidine. The dPCR-calibrated HPLC measurement was verified by independent measurement using isotope dilution mass spectrometry (IDMS). HPLC quantification, calibrated with dPCR or IDMS measured DNA markers, provides an effective method for certifying the quantity of genetic reference materials that may be difficult to analyze by PCR. These secondary reference materials may then be used to validate and calibrate quantitative PCR measurements and thus could expand the breadth of applications for which traceability to the International System of Units is possible.

The effect of input DNA copy number on genotype call and characterising SNP markers in the humpback whale genome using a nanofluidic array.

Recent advances in nanofluidic technologies have enabled the use of Integrated Fluidic Circuits (IFCs) for high-throughput Single Nucleotide Polymorphism (SNP) genotyping (GT). In this study, we implemented and validated a relatively low cost nanofluidic system for SNP-GT with and without Specific Target Amplification (STA). As proof of principle, we first validated the effect of input DNA copy number on genotype call rate using well characterised, digital PCR (dPCR) quantified human genomic DNA samples and then implemented the validated method to genotype 45 SNPs in the humpback whale, Megaptera novaeangliae, nuclear genome. When STA was not incorporated, for a homozygous human DNA sample, reaction chambers containing, on average 9 to 97 copies, showed 100% call rate and accuracy. Below 9 copies, the call rate decreased, and at one copy it was 40%. For a heterozygous human DNA sample, the call rate decreased from 100% to 21% when predicted copies per reaction chamber decreased from 38 copies to one copy. The tightness of genotype clusters on a scatter plot also decreased. In contrast, when the same samples were subjected to STA prior to genotyping a call rate and a call accuracy of 100% were achieved. Our results demonstrate that low input DNA copy number affects the quality of data generated, in particular for a heterozygous sample. Similar to human genomic DNA, a call rate and a call accuracy of 100% was achieved with whale genomic DNA samples following multiplex STA using either 15 or 45 SNP-GT assays. These calls were 100% concordant with their true genotypes determined by an independent method, suggesting that the nanofluidic system is a reliable platform for executing call rates with high accuracy and concordance in genomic sequences derived from biological tissue.

Evaluation of a droplet digital polymerase chain reaction format for DNA copy number quantification.

Droplet digital polymerase chain reaction (ddPCR) is a new technology that was recently commercialized to enable the precise quantification of target nucleic acids in a sample. ddPCR measures absolute quantities by counting nucleic acid molecules encapsulated in discrete, volumetrically defined, water-in-oil droplet partitions. This novel ddPCR format offers a simple workflow capable of generating highly stable partitioning of DNA molecules. In this study, we assessed key performance parameters of the ddPCR system. A linear ddPCR response to DNA concentration was obtained from 0.16% through to 99.6% saturation in a 20,000 droplet assay corresponding to more than 4 orders of magnitude of target DNA copy number per ddPCR. Analysis of simplex and duplex assays targeting two distinct loci in the Lambda DNA genome using the ddPCR platform agreed, within their expanded uncertainties, with values obtained using a lower density microfluidic chamber based digital PCR (cdPCR). A relative expanded uncertainty under 5% was achieved for copy number concentration using ddPCR. This level of uncertainty is much lower than values typically observed for quantification of specific DNA target sequences using currently commercially available real-time and digital cdPCR technologies.

Bacillus sp. CDB3 isolated from cattle dip-sites possesses two ars gene clusters.

Contamination of soil and water by arsenic is a global problem. In Australia, the dipping of cattle in arsenic-containing solution to control cattle ticks in last centenary has left many sites heavily contaminated with arsenic and other toxicants. We had previously isolated five soil bacterial strains (CDB1-5) highly resistant to arsenic. To understand the resistance mechanism, molecular studies have been carried out. Two chromosome-encoded arsenic resistance (ars) gene clusters have been cloned from CDB3 (Bacillus sp.). They both function in Escherichia coli and cluster 1 exerts a much higher resistance to the toxic metalloid. Cluster 2 is smaller possessing four open reading frames (ORFs) arsRorf2BC, similar to that identified in Bacillus subtilis Skin element. Among the eight ORFs in cluster 1 five are analogs of common ars genes found in other bacteria, however, organized in a unique order arsRBCDA instead of arsRDABC. Three other putative genes are located directly downstream and designated as arsTIP based on the homologies of their theoretical translation sequences respectively to thioredoxin reductases, iron-sulphur cluster proteins and protein phosphatases. The latter two are novel of any known ars operons. The arsD gene from Bacillus species was cloned for the first time and the predict protein differs from the well studied E. coli ArsD by lacking two pairs of C-terminal cysteine residues. Its functional involvement in arsenic resistance has been confirmed by a deletion experiment. There exists also an inverted repeat in the intergenic region between arsC and arsD implying some unknown transcription regulation.

Effect of sustained elevated temperature prior to amplification on template copy number estimation using digital polymerase chain reaction.

Digital polymerase chain reaction (dPCR) has the potential to enable accurate quantification of target DNA copy number provided that all target DNA molecules are successfully amplified. Following duplex dPCR analysis from a linear DNA target sequence that contains single copies of two independent template sequences, we have observed that amplification of both templates in a single partition does not always occur. To investigate this finding, we heated the target DNA solution to 95 °C for increasing time intervals and then immediately chilled on ice prior to preparing the dPCR mix. We observed an exponential decline in estimated copy number (R(2)≥ 0.98) of the two template sequences when amplified from either a linearized plasmid or a 388 base pair (bp) amplicon containing the same two template sequences. The distribution of amplifiable templates and the final concentration (copies per µL) were both affected by heat treatment of the samples at 95 °C from 0 s to 30 min. The proportion of target sequences from which only one of the two templates was amplified in a single partition (either 1507 or hmg only) increased over time, while the proportion of target sequences where both templates were amplified (1507 and hmg) in each individual partition declined rapidly from 94% to 52% (plasmid) and 88% to 31% (388 bp amplicon) suggesting an increase in number of targets from which both templates no longer amplify. A 10 min incubation at 95 °C reduced the initial amplifiable template concentration of the plasmid and the 388 bp amplicon by 59% and 91%, respectively. To determine if a similar decrease in amplifiable target occurs during the default pre-activation step of typical PCR amplification protocol, we used mastermixes with a 20 s or 10 min hot-start. The choice of mastermix and consequent pre-activation time did not affect the estimated plasmid concentration. Therefore, we conclude that prolonged exposure of this DNA template to elevated temperatures could lead to significant bias in dPCR measurements. However, care must be taken when designing PCR and non-PCR based experiments by reducing exposure of the DNA template to sustained elevated temperatures in order to improve accuracy in copy number estimation and concentration determination.

Comparison of methods for accurate quantification of DNA mass concentration with traceability to the international system of units.

Accurate estimation of total DNA concentration (mass concentration, e.g., ng/muL) that is traceable to the International System of Units (SI) is a crucial starting point for improving reproducible measurements in many applications involving nucleic acid testing and requires a DNA reference material which has been certified for its total DNA concentration. In this study, the concentrations of six different lambda DNA preparations were determined using different measurement platforms: UV Absorbance at 260 nm (A(260)) with and without prior sodium hydroxide (NaOH) treatment of the DNA, PicoGreen assay, and digital polymerase chain reaction (dPCR). DNA concentration estimates by A(260) with and without prior NaOH treatment were significantly different for five of the six samples tested. There were no significant differences in concentration estimates based on A(260) with prior NaOH treatment, PicoGreen analysis, and dPCR for two of the three samples tested using dPCR. Since the measurand in dPCR is amount (copy number) concentration (copies/muL), the results suggest that accurate estimation of DNA mass concentration based on copy number concentration is achievable provided the DNA is fully characterized and in the double-stranded form or amplification is designed to be initiated from only one of the two complementary strands.

Absolute quantification of genetically modified MON810 maize (Zea mays L.) by digital polymerase chain reaction.

Quantitative analysis of genetically modified (GM) foods requires estimation of the amount of the transgenic event relative to an endogenous gene. Regulatory authorities in the European Union (EU) have defined the labelling threshold for GM food on the copy number ratio between the transgenic event and an endogenous gene. Real-time polymerase chain reaction (PCR) is currently being used for quantification of GM organisms (GMOs). Limitations in real-time PCR applications to detect very low number of DNA targets has led to new developments such as the digital PCR (dPCR) which allows accurate measurement of DNA copies without the need for a reference calibrator. In this paper, the amount of maize MON810 and hmg copies present in a DNA extract from seed powders certified for their mass content and for their copy number ratio was measured by dPCR. The ratio of these absolute copy numbers determined by dPCR was found to be identical to the ratios measured by real-time quantitative PCR (qPCR) using a plasmid DNA calibrator. These results indicate that both methods could be applied to determine the copy number ratio in MON810. The reported values were in agreement with estimations from a model elaborated to convert mass fractions into copy number fractions in MON810 varieties. This model was challenged on two MON810 varieties used for the production of MON810 certified reference materials (CRMs) which differ in the parental origin of the introduced GM trait. We conclude that dPCR has a high metrological quality and can be used for certifying GM CRMs in terms of DNA copy number ratio.

Detection and identification of multiple genetically modified events using DNA insert fingerprinting.

Current screening and event-specific polymerase chain reaction (PCR) assays for the detection and identification of genetically modified organisms (GMOs) in samples of unknown composition or for the detection of non-regulated GMOs have limitations, and alternative approaches are required. A transgenic DNA fingerprinting methodology using restriction enzyme digestion, adaptor ligation, and nested PCR was developed where individual GMOs are distinguished by the characteristic fingerprint pattern of the fragments generated. The inter-laboratory reproducibility of the amplified fragment sizes using different capillary electrophoresis platforms was compared, and reproducible patterns were obtained with an average difference in fragment size of 2.4 bp. DNA insert fingerprints for 12 different maize events, including two maize hybrids and one soy event, were generated that reflected the composition of the transgenic DNA constructs. Once produced, the fingerprint profiles were added to a database which can be readily exchanged and shared between laboratories. This approach should facilitate the process of GMO identification and characterization.

Single molecule detection in nanofluidic digital array enables accurate measurement of DNA copy number.

Digital polymerase chain reaction (PCR) is a promising technique for estimating target DNA copy number. PCR solution is distributed throughout numerous partitions, and following amplification, target DNA copy number is estimated based on the proportion of partitions containing amplified DNA. Here, we identify approaches for obtaining reliable digital PCR data. Single molecule amplification efficiency was significantly improved following fragmentation of total DNA and bias in copy number estimates reduced by analysis of short intact target DNA fragments. Random and independent distribution of target DNA molecules throughout partitions, which is critical to accurate digital PCR measurement, was demonstrated by spatial distribution analysis. The estimated relative uncertainty for target DNA concentration was under 6% when analyzing five digital panels comprising 765 partitions each, provided the panels contained an average of 212 to 3,365 template molecules. Partition volume was a major component of this uncertainty estimate. These findings can be applied to other digital PCR studies to improve confidence in such measurements.