Your search keyword '"Aoi Ohnuma"' showing total 10 results

1. Use of mitochondrial sequencing to detect gene doping in horses via gene editing and somatic cell nuclear transfer

Author

Jillian Maniego, Bogusia Pesko, Jocelyn Habershon‐Butcher, Pamela Hincks, Polly Taylor, Teruaki Tozaki, Aoi Ohnuma, Graham Stewart, Christopher Proudman, and Edward Ryder

Subjects

Doping in Sports, Gene Editing, Nuclear Transfer Techniques, Animals, Pharmaceutical Science, Environmental Chemistry, Horses, CRISPR-Cas Systems, Spectroscopy, Mitochondria, Analytical Chemistry

Abstract

Gene editing and subsequent cloning techniques offer great potential not only in genetic disease correction in domestic animals but also in livestock production by enhancement of desirable traits. The existence of the technology, however, leaves it open to potential misuse in performance-led sports such as horseracing and other equestrian events. Recent advances in equine gene editing, regarding the generation of gene-edited embryos using CRISPR/Cas9 technology and somatic cell nuclear transfer, have highlighted the need to develop tools to detect potential prohibited use of the technology. One possible method involves the characterisation of the mitochondrial genome (which is not routinely preserved during cloning) and comparing it with the sequence of the registered dam. We present here our approach to whole-mitochondrial sequencing using tiled long-range PCR and next-generation sequencing. To determine whether the background mutation rate in the mitochondrial genome could potentially confound results, we sequenced 10 sets of dam and foal duos. We found variation between duos but none within duos, indicating that this method is feasible for future screening systems. Analysis of WGS data from over 100 Thoroughbred horses revealed wide variation in the mitochondria sequence within the breed, further displaying the utility of this approach.

Published

2022

2. Robustness of digital PCR and real‐time PCR against inhibitors in transgene detection for gene doping control in equestrian sports

Author

Mio Kikuchi, Aoi Ohnuma, Kei-ichi Hirota, Taichiro Ishige, Shun-ichi Nagata, Hironaga Kakoi, Kanichi Kusano, and Teruaki Tozaki

Subjects

Transgene, Pharmaceutical Science, Ethylenediaminetetraacetic acid, Real-Time Polymerase Chain Reaction, Polymerase Chain Reaction, Analytical Chemistry, law.invention, chemistry.chemical_compound, Gene doping, law, Animals, Humans, Environmental Chemistry, Digital polymerase chain reaction, Horses, Transgenes, Spectroscopy, Polymerase chain reaction, Doping in Sports, biology, Chemistry, Proteinase K, Molecular biology, genomic DNA, Real-time polymerase chain reaction, biology.protein

Abstract

Gene doping is a threat to fair competition in sports, both human and equestrian. One method of gene doping is to administer exogenous genetic materials, called transgenes, into the bodies of postnatal humans and horses. Polymerase chain reaction (PCR)-based transgene detection methods such as digital PCR and real-time PCR have been developed for gene doping testing in humans and horses. However, the significance of PCR inhibitors in gene doping testing has not been well evaluated. In this study, we evaluated the effects of PCR inhibitors on transgene detection using digital PCR and real-time PCR against gene doping. Digital PCR amplification was significantly inhibited by high concentrations of proteinase K (more than 0.1 μg/μl), ethylenediaminetetraacetic acid (more than 5 nmol/μl), and heparin (more than 0.05 unit/μl) but not by ethanol or genomic DNA. In addition, phenol affected droplet formation in the digital PCR amplification process. Real-time PCR amplification was inhibited by high concentrations of phenol (more than 1% v/v), proteinase K (more than 0.001 μg/μl), ethylenediaminetetraacetic acid (more than 1 nmol/μl), heparin (more than 0.005 unit/μl), and genomic DNA (more than 51.9 ng/μl) but not by ethanol. Although both PCR systems were inhibited by nearly the same substances, digital PCR was more robust than real-time PCR against the inhibitors. We believe that our findings are important for the development of better methods for transgene detection and prevention of false negative results in gene doping testing.

Published

2021

3. Detection of Indiscriminate Genetic Manipulation in Thoroughbred Racehorses by Targeted Resequencing for Gene-Doping Control

Author

Teruaki Tozaki, Aoi Ohnuma, Kotono Nakamura, Kazuki Hano, Masaki Takasu, Yuji Takahashi, Norihisa Tamura, Fumio Sato, Kyo Shimizu, Mio Kikuchi, Taichiro Ishige, Hironaga Kakoi, Kei-ichi Hirota, Natasha A. Hamilton, and Shun-ichi Nagata

Subjects

Gene Editing, Nucleotides, amplicon sequencing, gene doping, gene editing, horse, thoroughbred, Genetics, Animals, High-Throughput Nucleotide Sequencing, Horses, Sequence Analysis, DNA, Myostatin, Genetics (clinical)

Abstract

The creation of genetically modified horses is prohibited in horse racing as it falls under the banner of gene doping. In this study, we developed a test to detect gene editing based on amplicon sequencing using next-generation sequencing (NGS). We designed 1012 amplicons to target 52 genes (481 exons) and 147 single-nucleotide variants (SNVs). NGS analyses showed that 97.7% of the targeted exons were sequenced to sufficient coverage (depth > 50) for calling variants. The targets of artificial editing were defined as homozygous alternative (HomoALT) and compound heterozygous alternative (ALT1/ALT2) insertion/deletion (INDEL) mutations in this study. Four models of gene editing (three homoALT with 1-bp insertions, one REF/ALT with 77-bp deletion) were constructed by editing the myostatin gene in horse fibroblasts using CRISPR/Cas9. The edited cells and 101 samples from thoroughbred horses were screened using the developed test, which was capable of identifying the three homoALT cells containing 1-bp insertions. Furthermore, 147 SNVs were investigated for their utility in confirming biological parentage. Of these, 120 SNVs were amenable to consistent and accurate genotyping. Surrogate (nonbiological) dams were excluded by 9.8 SNVs on average, indicating that the 120 SNV could be used to detect foals that have been produced by somatic cloning or embryo transfer, two practices that are prohibited in thoroughbred racing and breeding. These results indicate that gene-editing tests that include variant calling and SNV genotyping are useful to identify genetically modified racehorses.

Published

2022

4. Identification of processed pseudogenes in the genome of Thoroughbred horses: Possibility of gene-doping detection considering the presence of pseudogenes

Author

Teruaki Tozaki, Aoi Ohnuma, Mio Kikuchi, Taichiro Ishige, Hironaga Kakoi, Kei‐ichi Hirota, Kanichi Kusano, and Shun‐ichi Nagata

Subjects

Doping in Sports, Genome, Genetics, Animals, Animal Science and Zoology, General Medicine, Horses, Introns, Pseudogenes, DNA Primers

Abstract

Processed pseudogenes, also known as retrocopy genes, are copies of messenger RNAs that have been reverse transcribed into DNA and inserted into the genome. In this study, we identified 62 processed pseudogene candidates as intron-less genes from whole-genome sequencing (WGS) data of Thoroughbred horses using delly structural variation software. The 62 processed pseudogene candidates were confirmed by PCR amplification of intron-less products. A total of 11 processed pseudogenes were confirmed in the genome of all 23 analysed horses, whereas three processed pseudogenes with structures of ATP11B, DPH3 and RPL17 were detected in only one of 115 horses by PCR amplification of intron-less products. Currently, most of the gene doping tests proposed in human and horse sports are adapted PCR-based methods using hydrolysis probes to detect exon/exon junctions in transgenes because the operation is simple and economical. However, when the pseudogene is present in the host genome, the PCR-based methods may have a potential risk of detecting false positives. In this study, because processed pseudogenes that exist less frequently in the horse genome may affect PCR-based transgene detection in gene-doping tests, we propose and demonstrate that PCR amplification and sequencing using primers designed on transgene and promotors and/or polyadenylation signal for gene expression are useful for gene-doping detection as an additional confirmatory test to prevent false positives.

Published

2021

5. Low-copy transgene detection using nested digital polymerase chain reaction for gene-doping control

Author

Mio Kikuchi, Aoi Ohnuma, Shun-ichi Nagata, Kei-ichi Hirota, Taichiro Ishige, Kanichi Kusano, Natasha A. Hamilton, Hironaga Kakoi, and Teruaki Tozaki

Subjects

Doping in Sports, Transgene, Pharmaceutical Science, DNA, Biology, Proteinase K, Real-Time Polymerase Chain Reaction, Molecular biology, Analytical Chemistry, genomic DNA, Real-time polymerase chain reaction, Gene doping, biology.protein, Environmental Chemistry, Animals, Digital polymerase chain reaction, Horses, Transgenes, Gene, Spectroscopy, DNA Primers

Abstract

Gene doping is prohibited for fair competition in human and horse sports. One style of gene doping is the administration of an exogeneous gene, called a transgene, to postnatal humans and horses. Although many transgene detection methods based on quantitative polymerase chain reaction (PCR), including real-time PCR and digital PCR, have been recently developed, it remains difficult to reliably detect low-copy transgenes. In this study, we developed and validated a nested digital PCR method to specifically detect low-copy transgenes. The nested digital PCR consists of (1) preamplification using conventional PCR and (2) droplet digital PCR detection using a hydrolysis probe. Using 5, 10, 20, 60 and 120 transgene copies as template, 496.0, 1089.7, 1820.7, 4313.3 and 7840.0 copies per microlitre, respectively, were detected using our nested digital PCR. Although high concentrations of phenol, proteinase K, ethanol, EDTA, heparin and genomic DNA all inhibited preamplification, their effects on the digital PCR detection were limited. Once preamplification was successful, even substitution of bases within the primers and probes had minimal effects on transgene detection. The nested digital PCR developed in this study successfully detected low-copy transgenes and can be used to perform a qualitative test, indicating its usefulness in the prevention of false positives and false negatives in gene-doping detection.

Published

2021

6. Rare and common variant discovery by whole-genome sequencing of 101 Thoroughbred racehorses

Author

Kanichi Kusano, Mio Kikuchi, Aoi Ohnuma, Taichiro Ishige, Teruaki Tozaki, Hironaga Kakoi, Kei-ichi Hirota, and Shun-ichi Nagata

Subjects

Male, Genotype, Science, Population, Biology, Breeding, Polymorphism, Single Nucleotide, Article, Genetics, Animals, Horses, Allele, education, X chromosome, Whole genome sequencing, education.field_of_study, Multidisciplinary, Whole Genome Sequencing, Breed, Pedigree, Phenotype, Medicine, Female, Zoology

Abstract

The Thoroughbred breed was formed by crossing Oriental horse breeds and British native horses and is currently used in horseracing worldwide. In this study, we constructed a single-nucleotide variant (SNV) database using data from 101 Thoroughbred racehorses. Whole genome sequencing (WGS) revealed 11,570,312 and 602,756 SNVs in autosomal (1–31) and X chromosomes, respectively, yielding a total of 12,173,068 SNVs. About 6.9% of identified SNVs were rare variants observed only in one allele in 101 horses. The number of SNVs detected in individual horses ranged from 4.8 to 5.3 million. Individual horses had a maximum of 25,554 rare variants; several of these were functional variants, such as non-synonymous substitutions, start-gained, start-lost, stop-gained, and stop-lost variants. Therefore, these rare variants may affect differences in traits and phenotypes among individuals. When observing the distribution of rare variants among horses, one breeding stallion had a smaller number of rare variants compared to other horses, suggesting that the frequency of rare variants in the Japanese Thoroughbred population increases through breeding. In addition, our variant database may provide useful basic information for industrial applications, such as the detection of genetically modified racehorses in gene-doping control and pedigree-registration of racehorses using SNVs as markers.

Published

2021

7. Sequence determination of phosphorothioated oligonucleotides using MALDI-TOF mass spectrometry for controlling gene doping in equestrian sports

Author

Minoru Hirata, Shun-ichi Nagata, Mio Kikuchi, Kotono Nakamura, Aoi Ohnuma, Kei-ichi Hirota, Masaki Takasu, Hironaga Kakoi, Ho-Geun Kwak, Takashi Nirasawa, Kanichi Kusano, Taichiro Ishige, Hideaki Ishii, and Teruaki Tozaki

Subjects

Detection limit, Doping in Sports, Sequence analysis, Oligonucleotide, Chemistry, Pharmaceutical Science, Phosphorothioate Oligonucleotides, Computational biology, Mass spectrometry, Analytical Chemistry, Matrix-assisted laser desorption/ionization, Gene Expression Regulation, Gene doping, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Environmental Chemistry, Animals, Horses, Gene, Sequence Analysis, Spectroscopy, Reference genome

Abstract

In human and equestrian sporting events, one method of gene doping is the illegal use of therapeutic oligonucleotides to alter gene expression. In this study, we aimed to identify therapeutic oligonucleotides via sequencing using matrix-assisted laser desorption/ionisation-time-of-flight mass spectrometry (MALDI-TOF MS). As a model of therapeutic oligonucleotides, 22 bp-long phosphorothioated oligonucleotides (PSOs) were used. By using a Clarity OTX kit for extracting short-length oligonucleotides, a spectrum of singly charged PSO with a mean intensity of 6.08 × 104 (standard deviation: 4.34 × 103 ) was detected from 500 pmol PSO in 1 ml horse plasma using the linear negative mode of MALDI-TOF MS. In addition, a 17 bp sequence was determined using in-source decay (ISD) mode, indicating that 500 pmol of a PSO in 1 ml plasma is the detection limit for sequencing. Using the determined sequences (17 bp), a targeted gene for PSO was singly identified on the horse reference genome, EquCab2.0, via a GGGenome search. These procedures can be potentially used to identify therapeutic oligonucleotides, whose nucleotides are unknown, for gene doping control.

Published

2021

8. Detection of non-targeted transgenes by whole-genome resequencing for gene-doping control

Author

Aoi Ohnuma, Taichiro Ishige, Kanichi Kusano, Kei-ichi Hirora, Teruaki Tozaki, Shun-ichi Nagata, Masaki Takasu, Kotono Nakamura, Norihisa Tamura, Hironaga Kakoi, and Mio Kikuchi

Subjects

0301 basic medicine, Genetic enhancement, Transgene, Biology, Genome, Structural variation, Animals, Genetically Modified, 03 medical and health sciences, 0302 clinical medicine, Gene doping, Complementary DNA, Genetics, Animals, Horses, Transgenes, Molecular Biology, Erythropoietin, Doping in Sports, Intron, Genetically modified organism, 030104 developmental biology, 030220 oncology & carcinogenesis, Molecular Medicine, human activities, Algorithms

Abstract

Gene doping has raised concerns in human and equestrian sports and the horseracing industry. There are two possible types of gene doping in the sports and racing industry: (1) administration of a gene-doping substance to postnatal animals and (2) generation of genetically engineered animals by modifying eggs. In this study, we aimed to identify genetically engineered animals by whole-genome resequencing (WGR) for gene-doping control. Transgenic cell lines, in which the erythropoietin gene (EPO) cDNA form was inserted into the genome of horse fibroblasts, were constructed as a model of genetically modified horse. Genome-wide screening of non-targeted transgenes was performed to find structural variation using DELLY based on split-read and paired-end algorithms and Control-FREEC based on read-depth algorithm. We detected the EPO transgene as an intron deletion in the WGR data by the split-read algorithm of DELLY. In addition, single-nucleotide polymorphisms and insertions/deletions artificially introduced in the EPO transgene were identified by WGR. Therefore, genome-wide screening using WGR can contribute to gene-doping control even if the targets are unknown. This is the first study to detect transgenes as intron deletions for gene-doping detection.

Published

2020

9. Microfluidic Quantitative PCR Detection of 12 Transgenes from Horse Plasma for Gene Doping Control

Author

Kanichi Kusano, Mio Kikuchi, Aoi Ohnuma, Shun-ichi Nagata, Hironaga Kakoi, Taichiro Ishige, Teruaki Tozaki, and Kei-ichi Hirota

Subjects

0301 basic medicine, Male, multiple-target detection, lcsh:QH426-470, Transgene, Microfluidics, Computational biology, Biology, Athletic Performance, Real-Time Polymerase Chain Reaction, 01 natural sciences, Article, 03 medical and health sciences, gene doping, Gene doping, Genetics, TaqMan, Animals, Horses, Transgenes, Gene, Erythropoietin, Genetics (clinical), Detection limit, Doping in Sports, 010401 analytical chemistry, transgene, 0104 chemical sciences, horse, microfluidic qPCR, lcsh:Genetics, genomic DNA, 030104 developmental biology, Real-time polymerase chain reaction, Primer (molecular biology)

Abstract

Gene doping, an activity which abuses and misuses gene therapy, is a major concern in sports and horseracing industries. Effective methods capable of detecting and monitoring gene doping are urgently needed. Although several PCR-based methods that detect transgenes have been developed, many of them focus only on a single transgene. However, numerous genes associated with athletic ability may be potential gene-doping material. Here, we developed a detection method that targets multiple transgenes. We targeted 12 genes that may be associated with athletic performance and designed two TaqMan probe/primer sets for each one. A panel of 24 assays was prepared and detected via a microfluidic quantitative PCR (MFQPCR) system using integrated fluidic circuits (IFCs). The limit of detection of the panel was 6.25 copy/&mu, L. Amplification-specificity was validated using several concentrations of reference materials and animal genomic DNA, leading to specific detection. In addition, target-specific detection was successfully achieved in a horse administered 20 mg of the EPO transgene via MFQPCR. Therefore, MFQPCR may be considered a suitable method for multiple-target detection in gene-doping control. To our knowledge, this is the first application of microfluidic qPCR (MFQPCR) for gene-doping control in horseracing.

Published

2020

10. Droplet Digital PCR Detection of the Erythropoietin Transgene from Horse Plasma and Urine for Gene-Doping Control

Author

Mio Kikuchi, Shun-ichi Nagata, Aoi Ohnuma, Kanichi Kusano, Teruaki Tozaki, Kei-ichi Hirota, Masaki Takasu, and Hironaga Kakoi

Subjects

0301 basic medicine, morphologic traits, equine genetics, lcsh:QH426-470, Transgene, Urine, Biology, Polymerase Chain Reaction, 01 natural sciences, Article, 03 medical and health sciences, exercise traits, Gene doping, disease mechanisms, Genetics, TaqMan, medicine, Animals, Humans, Digital polymerase chain reaction, Horses, Transgenes, Erythropoietin, Genetics (clinical), Doping in Sports, 010401 analytical chemistry, domestic horse, Molecular biology, 0104 chemical sciences, Transgenesis, lcsh:Genetics, 030104 developmental biology, genome-to-phenome, Primer (molecular biology), Plasmids, medicine.drug

Abstract

Indiscriminate genetic manipulation to improve athletic ability is a major threat to human sports and the horseracing industry, in which methods involving gene-doping, such as transgenesis, should be prohibited to ensure fairness. Therefore, development of methods to detect indiscriminate genetic manipulation are urgently needed. Here, we developed a highly sensitive method to detect horse erythropoietin (EPO) transgenes using droplet digital PCR (ddPCR). We designed two TaqMan probe/primer sets, and the EPO transgene was cloned into a plasmid for use as a model. We extracted the spiked EPO transgene from horse plasma and urine via magnetic beads, followed by ddPCR amplification for absolute quantification and transgene detection. The results indicated high recovery rates (at least ~60% and ~40% in plasma and urine, respectively), suggesting successful detection of the spiked transgene at concentrations of &gt, 130 and 200 copies/mL of plasma and urine, respectively. Additionally, successful detection was achieved following intramuscular injection of 20 mg of the EPO transgene. This represents the first study demonstrating a method for detecting the EPO transgene in horse plasma and urine, with our results demonstrating its efficacy for promoting the control of gene-doping in the horseracing industry.

Published

2019