1.Mitochondrial genome sequence characteristics and phylogenetic analysis of Schizothorax argentatus.
Yuping LIU ; Jianyong HU ; Zijun NING ; Peiyi XIAO ; Tianyan YANG
Chinese Journal of Biotechnology 2023;39(7):2965-2985
Schizothorax argentatus that only distributes in the Ili River basin in Xinjiang is one of the rare and endangered species of schizothorax in China, thus has high scientific and economic values. In this study, the complete mitochondrial genome sequence of S. argenteus with a length of 16 580 bp was obtained by high-throughput sequencing. The gene compositions and arrangement were similar to those of typical vertebrates. It contained 13 protein-coding genes, 22 tRNA genes, 2 rRNA genes, and a non-coding region (D-loop). The nucleotide compositions were A (30.25%), G (17.28%), C (27.20%), and T (25.27%), respectively, showing obvious AT bias and anti-G bias. Among the tRNA genes, only tRNA-Ser(GCU) could not form a typical cloverleaf structure due to the lack of dihydrouracil arm. The AT-skew and GC-skew values of the ND6 gene were fluctuating the most, suggesting that the gene may experience different selection and mutation pressures from other genes. The mitochondrial control region of S. argenteus contained three different domains, i.e., termination sequence region (ETAS), central conserved region (CSB-F, CSB-E, CSB-D, and CSB-B), and conserved sequence region (CSB1, CSB2, and CSB3). The conserved sequence fragment TT (AT) nGTG, which was ubiquitous in Cypriniformes, was identified at about 50 bp downstream CSB3. Phylogenetic relationships based on the complete mitochondrial genome sequence of 28 Schizothorax species showed that S. argenteus had differentiated earlier and had a distant relationship with other species, which may be closely related to the geographical location and the hydrological environment where it lives.
Animals
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Genome, Mitochondrial/genetics*
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Phylogeny
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Sequence Analysis, DNA
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Cyprinidae/genetics*
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RNA, Transfer/genetics*
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DNA, Mitochondrial/genetics*
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Genes, Mitochondrial
2.Mitochondrial DNA Heteroplasmy of Hair Shaft Using HID Ion GeneStudioTM S5 Sequencing System.
Feng CHENG ; Qing Xia ZHANG ; Cheng Jian CHEN ; Wan Ting LI ; Jia Rong ZHANG ; Geng Qian ZHANG ; Jiang Wei YAN
Journal of Forensic Medicine 2021;37(1):21-25
Objective To study the heteroplasmy of the whole mitochondrial genome genotyping result of hair shaft samples using HID Ion GeneStudioTM S5 Sequencing System. Methods The buccal swabs and blood of 8 unrelated individuals, and hair shaft samples from different parts of the same individual were collected. Amplification of whole mitochondrial genome was performed using Precision ID mtDNA Whole Genome Panel. Analysis and detection of whole mitochondrial genome were carried out using the HID Ion GeneStudioTM S5 Sequencing System. Results The mitochondrial DNA sequences in temporal hair shaft samples from 2 individuals showed heteroplasmy, while whole mitochondrial genome genotyping results of buccal swabs, blood, and hair samples from the other 6 unrelated individuals were consistent. A total of 119 base variations were observed from the 8 unrelated individuals. The numbers of variable sites of the individuals were 29, 40, 38, 35, 13, 36, 40 and 35, respectively. Conclusion Sequence polymorphism can be fully understood using HID Ion GeneStudioTM S5 Sequencing system.
DNA, Mitochondrial/genetics*
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Genome, Mitochondrial/genetics*
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Heteroplasmy
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High-Throughput Nucleotide Sequencing
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Humans
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Sequence Analysis, DNA
3.Analysis of 28S rRNA and COⅠ Gene Sequence of Nine Necrophagous Calliphorid Flies from Luoyang.
Lin Lin ZHAO ; Xian Dun ZHAI ; Zhe ZHENG ; Zhou LÜ ; Yong Lin LI ; Yao Nan MO
Journal of Forensic Medicine 2019;35(2):181-186
Objective To assess the feasibility of using 28S ribosomal RNA (28S rRNA) and mitochondrial cytochrome c oxidase subunit Ⅰ (COⅠ) gene sequences of nine necrophagous Calliphorid flies for the identification of common necrophagous Calliphorid flies, and to provide technical support for postmortem interval (PMI) estimation. Methods Twenty-three Calliphorid flies were collected and identified morphologically, and DNA were extracted from legs. The gene fragments of 28S rRNA and COⅠ were amplified and sequenced, then the sequence alignment was performed with BLAST. The composition of obtained sequences was analyzed and evolutionary divergence rate between species and intraspecies were established. The phylogeny tree was constructed with neighbor-joining method. Results The 23 necrophagous Calliphorid flies were identified to 9 species of 5 genera. The 715 bp from 28S rRNA and 637 bp from COⅠ gene were obtained and the online BLAST result showed more than 99% of similarity. The phylogeny tree showed that the necrophagous flies could cluster well into 9 groups, which was consistent with morphological identification results. The intraspecific difference in 28S rRNA was 0 and the interspecific difference was 0.001-0.033. The intraspecific difference in COⅠ was 0-0.008 and the interspecific difference was 0.006-0.101. Conclusion Combined use of 28S rRNA and COⅠ gene sequence fragments can effectively identify the nine Calliphorid flies in this study. However, for closely related blowfly species, more genetic markers should be explored and used in combination in future.
Animals
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DNA, Mitochondrial/genetics*
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Diptera/genetics*
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Phylogeny
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RNA, Ribosomal, 28S/genetics*
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Sequence Analysis, DNA
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Species Specificity
4.Association study on the mitochondrial genome region np16181-16193 variation with type 2 diabetes mellitus.
Fang-jian CHEN ; Hong YU ; Hong LIN ; Chao-hui HU ; Ya-guo HU ; Jian-xin LV
Chinese Journal of Medical Genetics 2009;26(3):340-344
OBJECTIVETo investigate the association of the mitochondrial DNA region np16181-16193 variations with type 2 diabetes mellitus (T2DM).
METHODSBlood samples of 199 unrelated T2DM patients and 205 normal controls were collected to detect the mitochondrial DNA region np16181-16193 variations by PCR and sequencing, and to analyze the association of the variations with the major clinical symptoms.
RESULTSThe mitochondrial DNA np16181-16193 region is a hypervariable area, with several polymorphisms. Four types of np16181-16193 region variations were found only in T2DM. The 1-hour postprandial blood glucose (P1BG) in the T2DM individuals with np16181-16193 region variations was significantly higher than those without variations (P<0.05), while there was no significant difference in other biochemical parameters (P>0.05).
CONCLUSIONThe mitochondrial DNA np16181-16193 variations could not be regarded as a risk factor for T2DM.
Adult ; Complementarity Determining Regions ; genetics ; DNA Mutational Analysis ; DNA, Mitochondrial ; analysis ; Diabetes Mellitus, Type 2 ; genetics ; Female ; Genetic Predisposition to Disease ; Genome, Mitochondrial ; genetics ; Humans ; Male ; Sequence Analysis, DNA
5.Rapid screening of MT3243A>G mutation in mitochondrial diabetes with high resolution melting curve analysis and pyrosequencing.
Xinjun WEI ; ; crwang@sjtu.edu.cn. ; Xiujuan DU ; Congrong WANG ; Jingbin YAN
Chinese Journal of Medical Genetics 2016;33(4):447-451
OBJECTIVETo establish a rapid, accurate, noninvasive and low cost method for screening MT3243A>G mutation in mitochondrial diabetes.
METHODSBlood, saliva, and urine sediment samples were collected from 6 patients with confirmed mitochondrial diabetes and 50 healthy controls from Shanghai Children's Hospital and Shanghai Sixth People's Hospital. The heterozygosity levels of MT3243A>G mutation in above samples were detected with pyrosequencing, and the data were compared. MT3243A>G mutations were rapidly screened with high resolution melting curve analysis (HRM) in the urine sediment samples of 1070 diabetic patients from 4 communities in Shanghai. Furthermore, pyrosequencing was used to validate the suspected positive samples, and the heterozygosity levels were also quantified.
RESULTSComparative experiments found that heterozygosity of MT3243A>G mutation was 2 to 7 times higher in urine sediment than in saliva and blood samples from the 6 patients with confirmed mitochondrial diabetes. However, the heterozygosity was slightly higher in saliva than blood samples. MT3243A>G mutation was not detected in the 50 healthy controls. Two samples with suspected MT3243A>G mutation were identified in the 1070 urine sediment samples of diabetes patients with HRM screening, which were validated by pyrosequencing. The heterozygosity of MT3243A>G mutation were 33.32% and 14.67% in the urine sediment samples, respectively.
CONCLUSIONUrine sediment samples can be used for rapid screening of MT3243A>G mutation for its ease to collect, noninvasiveness and higher level of heterozygosity. HRM is suitable for rapid screening for mitochondrian mutations for its low cost, while such mutations could be detected with sensitivity and accuracy by pyrosequencing.
DNA, Mitochondrial ; genetics ; Diabetes Mellitus ; genetics ; Heterozygote ; Humans ; Mutation ; Sequence Analysis, DNA ; methods ; Transition Temperature
6.Mutational analysis of 117 patients with non-syndromic hearing loss.
Leilei WANG ; Ying GU ; Shuting YANG ; Huafen MAO ; Xinxin TANG ; Tianlong XU ; Min WU ; Yuhua SUN ; Xiucui LUO
Chinese Journal of Medical Genetics 2019;36(2):108-111
OBJECTIVE:
To determine the frequencies of deafness gene mutations among patients with non-syndromic hearing loss (NSHL) from northern Jiangsu province.
METHODS:
A total of 117 patients with NSHL were enrolled. The coding region of GJB2 gene, IVS7-2A>G and 2168A>G mutations of SLC26A4 gene, and 1555A>G and 1494C>T mutations of mitochondrial DNA 12S rRNA were subjected to Sanger sequencing. Patients in whom no mutation was detected were further tested by targeted gene capture and high-throughput sequencing.
RESULTS:
Among the 117 patients, 86 (73.50%) were found to carry mutations. GJB2 gene mutations were found in 61 patients (52.14%), including 22 (18.80%) with homozygous mutations and 39 (33.33%) with heterozygous mutations. SLC26A4 gene mutations were found in 19 patients (16.24%), including 4 (3.42%) with homozygous mutations and 15 with heterozygous mutations (14.53%). Mitochondrial 12S rRNA gene mutation was found in 6 patients (5.13%). Targeted gene capture and high-throughput sequencing of 8 patients identified 4 further cases, including 1 with RDX gene 129_130del and 76_79del compound heterozygous mutations, 1 with OTOF gene 1274G>C homozygous mutation, 1 with SLC26A4 gene 919-2A>G and IVS16-6G>A compound heterozygous mutation, and 1 with SLC26A4 gene 919-2A>G and A1673T compound heterozygous mutation.
CONCLUSION
The frequency of mutation among patients with NSHL from north Jiangsu was 73.50%, and GJB2 gene was most commonly mutated.
China
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Connexins
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DNA Mutational Analysis
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DNA, Mitochondrial
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Hearing Loss
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genetics
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Humans
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Membrane Proteins
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Mutation
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Sulfate Transporters
7.A non-invasive method for detecting mitochondrial tRNA
Zhining TANG ; Xiaowen TANG ; Ling XUE ; Minxin GUAN
Journal of Southern Medical University 2021;41(1):151-156
OBJECTIVE:
To explore the feasibility of detecting maternal hereditary mitochondrial tRNA
METHODS:
We performed sequence analysis of mitochondrial DNA in blood samples from 2070 cases of maternal hereditary mitochondrial disease in the First Affiliated Hospital of Wenzhou Medical University, and identified 3 patients with m.15927G>A mutation.Buccal swabs and blood samples were obtained from the 3 patients (mutation group) and 3 normal volunteers (control group).After extracting whole genomic DNA from all the samples, the DNA concentration and purity were analyzed.The PCR products were subjected to dot blot hybridization, Southern blot hybridization, and DNA sequencing analysis to verify the feasibility of detecting m.15927G>A mutation using buccal swabs.
RESULTS:
There was no significant difference in DNA concentration extracted from buccal swabs and blood samples in either the mutation group or the control group (
CONCLUSIONS
Buccal swabs collection accurate is an accurate and sensitive method for the detection of m.15927G>A mutation.
DNA, Mitochondrial/genetics*
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Humans
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Mitochondria
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Mutation
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RNA, Transfer
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Sequence Analysis, DNA
8.Sequencing of mitochondrial DNA cytochrome oxidase subunit I gene in sarcosaphagous flies from 14 provinces in China.
Li YANG ; Jifeng CAI ; Jifang WEN ; Yadong GUO
Journal of Central South University(Medical Sciences) 2010;35(8):819-825
OBJECTIVE:
To detect the 278 bp region of gene of the cytochrome oxidase subunit I (COI) in mitochondral DNA (mtDNA) of sarcosaphagous flies, identify the species of sarcosaphagous flies, and provide reference for forensic application.
METHODS:
Samples were collected in Baotou and Chifeng of Inner Mongolia, Tianjin, Nanning, Fuzhou, Linyi of Shandong, Shijiazhuang, Yinchuan, Lanzhou, Huairou of Beijing, Xinxiang and Nanyang of Henan, Datong of Shanxi, Wuhu of Anhui, Quzhou of Zhejiang, Changsha, Zhuzhou and Yongzhou of Hunan. A total of 38 flies were randomly collected from rabbits, dogs and pigs which were set outdoors, then the flies' mitochondrial DNA (mtDNA) were extracted by the improved small insects DNA homogenate method. Amplification was conducted by Perkin-Elmer 9600 thermal cycler, then vertical non-denaturing 7% polyacrylamide gelectrophoresis. PCR products were purified using the nucleic acid purification kit. Sequences of both strands were obtained by direct sequence of the double-stranded PCR product using one of the PCR primers and the ABI PRISM big dye terminator cycle sequencing dit. Sequence reactions were electrophorsed on ABI Model 3730 DNA Sequencers. A UPGMA tree was contrasted using the maximum composite likelihood method in MEGA4.
RESULTS:
The 38 sarcosaphagous flies belonged to 3 families(Muscidae, Calliphoridae, and Sarcophagidae), 10 genuses (Musca Linnaeus, Hydrotaea Robineau-Desvoidy, Aldrichina Townsend, Hemipyrellia Townsend, Achoetandrus Bezzi, Protophormia Townsend, Chrysomya Robineau-Desvoidy, Lucilia Robineau-Desvoidy, Helicophagella Enderlein, and Boettcherisca Rohdendorf), and 12 species [Musca domestica (Linnaeus), Hydrotaea (Ophyra) capensis (Wiedemann), Lucilia caesar (Linnaeus), Lucilia illustris (Meigen), Aldrichina graham (Aldrich), Hemipyrellia ligurriens, Achoetandrus (Chrysomya) rufifacies (Macquary), Protophormia terraenovae (Robineau-Desvoidy), Chrysomya megacephala (Fabricius), Lucilia sericata (Meigen), Helicophagella melanura (Meigen), and Boettcherisca peregrine (Robineau-Desvoidy)].
CONCLUSION
The genus of the sarcosaphagous flies can be identified by 278 bp gene sequence analysis of CO I in mtDNA. This method is rapid, convenient and precise.
Animals
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China
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DNA, Mitochondrial
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genetics
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Electron Transport Complex IV
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classification
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genetics
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Forensic Medicine
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Genes, Insect
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Genes, Mitochondrial
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Larva
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genetics
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Phylogeny
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Sarcophagidae
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classification
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genetics
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Sequence Analysis, DNA
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Species Specificity
9.Quantitation and detection of deletion in tumor mitochondrial DNA by microarray technique.
Cheng-bo HAN ; Yu-jie ZHAO ; Fan LI ; Qun HE ; Jia-ming MA ; Yan XIN
Chinese Journal of Oncology 2004;26(1):10-13
OBJECTIVETo develop a method to rapidly quantitate and detect deletion of mitochondrial DNA (mtDNA) by microarray technique as a tool to study its relationship to tumorigenesis.
METHODSA modified PCR was used to amplify full length mtDNA sequence in two samples of normal human blood leukocytes and five samples of gastric cancerous tissues, which were simultaneously labeled with fluorescin. The amplified products were verified by polyacrylamide gel electrophoresis (PAGE) and silver staining. Then, 17 pairs of overlapping primers of mtDNA were designed and their PCR products were used as mitochondrial probes. They were spotted onto amino-slides as microarray and hybridized. Hybridization image was scanned with GeneTAC laser, mtDNA copy number was counted by ScanAnalyzer software.
RESULTSPAGE analysis showed that the designed probes were quite reasonable and strongly specific. The modified PCR method was efficient to amplify the whole mitochondrial genome with high-yield specific bands. The hybridizing spots were distinct, and background was clear. The signals of negative probes were close to those of background, and there was no significant difference between them (P > 0.05). The results were identical to those in the designed experiment. There were no significant differences between the results when the same sample of blood leucocytes or cancer tissues repeatedly examined with the same positive probes (P > 0.05), while there were significant differences when different types of samples were examined (P < 0.01). The hybridizing signals were stable and most of the data distributed in the range of mean +/- 2xSD.
CONCLUSIONThe method here reported can rapidly, correctly and massively determine whether there exist special deletion and/or quantitative changes of mtDNA in patients with tumors. It will be helpful for the study of the relationship between mtDNA alteration and tumor development.
DNA, Mitochondrial ; analysis ; genetics ; Electrophoresis, Polyacrylamide Gel ; Gene Deletion ; Humans ; Oligonucleotide Array Sequence Analysis ; methods
10.Diagnosis of mitochondrial disorders in children with next generation sequencing.
Zhimei LIU ; Fang FANG ; Email:13910150389@163.com. ; Changhong DING ; Weihua ZHANG ; Jiuwei LI ; Xinying YANG ; Xiaohui WANG ; Yun WU ; Hongmei WANG ; Liying LIU ; Tongli HAN ; Xu WANG ; Chunhong CHEN ; Junlan LYU ; Husheng WU
Chinese Journal of Pediatrics 2015;53(10):747-753
OBJECTIVETo explore the application value of next generation sequencing (NGS) in the diagnosis of mitochondrial disorders.
METHODAccording to mitochondrial disease criteria, genomic DNA was extracted using standard procedure from peripheral venous blood of patients with suspected mitochondrial disease collected from neurological department of Beijing Children's Hospital Affiliated to Capital Medical University between October 2012 and February 2014. Targeted NGS to capture and sequence the entire mtDNA and exons of the 1 000 nuclear genes related to mitochondrial structure and function. Clinical data were collected from patients diagnosed at a molecular level, then clinical features and the relationship between genotype and phenotype were analyzed.
RESULTMutation was detected in 21 of 70 patients with suspected mitochondrial disease, in whom 10 harbored mtDNA mutation, while 11 nuclear DNA (nDNA) mutation. In 21 patients, 1 was diagnosed congenital myasthenic syndrome with episodic apnea due to CHAT gene p.I187T homozygous mutation, and 20 were diagnosed mitochondrial disease, in which 10 were Leigh syndrome, 4 were mitochondrial encephalomyopathy with lactic acidosis and stroke like episodes syndrome, 3 were Leber hereditary optic neuropathy (LHON) and LHON plus, 2 were mitochondrial DNA depletion syndrome and 1 was unknown. All the mtDNA mutations were point mutations, which contained A3243G, G3460A, G11778A, T14484C, T14502C and T14487C. Ten mitochondrial disease patients harbored homozygous or compound heterozygous mutations in 5 genes previously shown to cause disease: SURF1, PDHA1, NDUFV1, SUCLA2 and SUCLG1, which had 14 mutations, and 7 of the 14 mutations have not been reported.
CONCLUSIONNGS has a certain application value in the diagnosis of mitochondrial diseases, especially in Leigh syndrome atypical mitochondrial syndrome and rare mitochondrial disorders.
Child ; DNA, Mitochondrial ; genetics ; High-Throughput Nucleotide Sequencing ; Homozygote ; Humans ; Leigh Disease ; Mitochondrial Diseases ; diagnosis ; Mitochondrial Encephalomyopathies ; Mutation ; Optic Atrophy, Hereditary, Leber ; Phenotype ; Point Mutation ; Sequence Analysis, DNA