基于高分辨率熔解曲线检测MD肿瘤微卫星不稳定性

doi:10.11843/j.issn.0366-6964.2024.02.033

Abstract

Abstract: The study aimed to detect the presence of microsatellite instability (MSI) in Marek's disease (MD) tumors by high-resolution melting (HRM) method. Clinical samples were collected and diagnosed as Marek's disease by clinical signs, pathological anatomy, histopathology, PCR and sequencing. Muscle, liver, spleen, blood and tumor samples were collected from five affected chickens. DNA was extracted from the samples, and HRM assay was performed by using 15 pairs of primers for amplifying microsatellite DNA sequences. The difference melting curves of the normalization processing were obtained. The differences in the melting curves among samples were compared and analyzed for the presence of MSI in 15 microsatellite markers. The various clinical symptoms and pathological findings of the affected chickens were consistent with MD. The sequence of the viral meq gene had high homology with the virulent strain of MDV prevalent in China in recent years. HRM analysis showed that melting curves of PCR production were significantly different in muscle, liver, spleen, blood, and tumor samples. That is MSI phenomenon and MSI frequencies were different in chickens and microsatellites markers. There were 14,7,5,3 and one microsatellite markers presented MSI in five chickens respectively. The markers MCW0200 and MCW0220 presented MSI in all chickens' samples, however the markers ADL0158 had no MSI phenomenon in all chickens' samples. These microsatellite PCR amplification fragments differ in size were further demonstrated by nondenaturing polyacrylamide gel electrophoresis and sequencing analysis. There was an increase and decrease of microsatellite repeat units, and insertions or deletions of gene fragments in the sequences. The results suggest that the MSI phenomenon in MD tumors can be detected by HRM analysis, and HRM was a sensitive, accurate, simple and high-throughput method.

Key words: high-resolution melting, Marek's disease, microsatellite instability, tumor

CLC Number:

S857.4

SHI Zefeng, LI Lingxu, GUO Yiwen, LIAO Yun, SUN Zhaoyu, WANG Lairong, YANG Deji, YAO Dawei. Detection of Microsatellite Instability in Marek's Disease Tumor based on High-resolution Melting[J]. Acta Veterinaria et Zootechnica Sinica, 2024, 55(2): 759-769.

References

[1] 崔治中, 苏帅, 罗俊, 等. 鸡马立克病毒的研究进展[J]. 微生物学通报, 2019, 46(7):1812-1826.
CUI Z Z, SU S, LUO J, et al. Progress in Marek's disease virus[J]. Microbiology China, 2019, 46(7):1812-1826.(in Chinese)
[2] 贺红娟, 陈尔飞, 雷蕾. 肿瘤发生与相关基因突变的关联[J]. 基因组学与应用生物学, 2015, 34(1):208-214.
HE H J, CHEN E F, LEI L. Association of tumorigenesis with the related gene mutation[J]. Genomics and Applied Biology, 2015, 34(1):208-214.(in Chinese)
[3] ARZIMANOGLOU I I, GILBERT F, BARBER H R K. Microsatellite instability in human solid tumors[J]. Cancer, 1998, 82(10):1808-1820.
[4] LOBBARDI R, PINDER J, MARTINEZ-PASTOR B. TOX regulates growth, DNA repair, and genomic instability in T-cell acute lymphoblastic leukemia[J]. Cancer Discov, 2017, 7(11):1336-1353.
[5] SPEAR T T, RILEY T P, LYONS G E, et al. Hepatitis C virus-cross-reactive TCR gene-modified T cells:a model for immunotherapy against diseases with genomic instability[J]. J Leukoc Biol, 2016, 100(3):545-557.
[6] CHANG A M V, CHIOSEA S I, ALTMAN A, et al. Programmed death-ligand 1 expression, microsatellite instability, epstein-barr virus, and human papillomavirus in nasopharyngeal carcinomas of patients from the Philippines[J]. Head Neck Pathol, 2017, 11(2):203-211.
[7] 王雅, 吕佳乐, 梁路, 等. MSI检测在胃癌治疗中的研究进展[J]. 胃肠病学和肝病学杂志, 2022, 31(6):691-695.
WANG Y, LYU J L, LIANG L, et al. Research progress of MSI detection in the treatment of gastric cancer[J]. Chinese Journal of Gastroenterology and Hepatology, 2022, 31(6):691-695.(in Chinese)
[8] 贾铮, 徐任, 张文新, 等. 高通量测序法微卫星不稳定性检测评价[J]. 分子诊断与治疗杂志, 2021, 13(10):1565-1568, 1573.
JIA Z, XU R, ZHANG W X, et al. Evaluation of microsatellite instability detection by high-throughput sequencing[J]. Journal of Molecular Diagnostics and Therapy, 2021, 13(10):1565-1568, 1573.(in Chinese)
[9] 王姣, 尤崇革. 高分辨率熔解曲线技术及应用新进展[J]. 兰州大学学报:医学版, 2016, 42(5):55-61.
WANG J, YOU C G. Application advances of high resolution melting technology[J]. Journal of Lanzhou University:Medical Sciences, 2016, 42(5):55-61.(in Chinese)
[10] 翟晓虎, 李翎旭, 陈小竹, 等. 肉中猪源性成分Real-time PCR定量检测技术[J]. 中国农业科学, 2023, 56(1):156-164.
ZHAI X H, LI L X, CHEN X Z, et al. Quantitative detection technology of porcine-derived materials in meat by Real-time PCR[J]. Scientia Agricultura Sinica, 2023, 56(1):156-164.(in Chinese)
[11] DENG X F, LI X D, SHEN Y, et al:The Meq oncoprotein of Marek's disease virus interacts with p53 and inhibits its transcriptional and apoptotic activities[J]. Virol J, 2010, 7:348.
[12] 毕研丽, 庄金秋, 王金良, 等. 双重PCR检测禽源生物制品中禽网状内皮组织增生症病毒和禽白血病病毒[J]. 畜牧与兽医, 2014, 46(4):74-78.
BI Y L, ZHUANG J Q, WANG J L, et al. Duplex PCR for the detection of REV and ALV in avian-derived biological products[J]. Animal Husbandry & Veterinary Medicine, 2014, 46(4):74-78.(in Chinese)
[13] ZHOU Z L, YAO D W, QIU Y, et al. Microsatellite instability in Marek's disease virus infected primary chicken embryo fibroblasts[J]. Virol J, 2012, 9:193.
[14] 马圣明, 滕蔓, 余祖华, 等. 马立克病病毒超强毒株GX0101感染宿主部分病毒基因表达水平及致病阶段分析[J]. 畜牧兽医学报, 2016, 47(8):1635-1644.
MA S M, TENG M, YU Z H, et al. The viral gene expression profiles and pathogenic phases of the disease caused by very virulent MDV strain GX0101[J]. Acta Veterinaria et Zootechnica Sinica, 2016, 47(8):1635-1644.(in Chinese)
[15] 马秀丽, 刘丽萍, 高月花, 等. 山东省农业科学院家禽研究所监测中心2022年第三季度检测数据统计分析[J]. 家禽科学, 2022(9):3-4.
MA X L, LIU L P, GAO Y H, et al. Statistical analysis of testing data of the monitoring center of poultry research institute of Shandong academy of agricultural sciences in the third quarter of 2022[J]. Poultry Science, 2022(9):3-4.(in Chinese)
[16] 李敏, 高延利, 石梦雅, 等. 黄羽肉鸡马立克氏病病毒强毒株GX18NNM4的分离鉴定及其致瘤基因meq的序列分析[J]. 中国家禽, 2021, 43(3):28-34.
LI M, GAO Y L, SHI M Y, et al. Isolation and identification of a highly virulent strain of Marek's disease virus in yellow-feather chicken and sequence analysis of the oncogenic gene meq[J]. China Poultry, 2021, 43(3):28-34.(in Chinese)
[17] KELES H, FIDAN A F, CIGERCI I H, et al. Increased DNA damage and oxidative stress in chickens with natural Marek's disease[J]. Vet Immunol Immunopathol, 2010, 133(1):51-58.
[18] LIAN X, BAO C Y, LI X Q, et al. Marek's disease virus disables the ATR-Chk1 pathway by activating[LL] STAT3[J]. J Virol, 2019, 93(9):e02290-18.
[19] 付煜, 杜小燕. 微卫星不稳定性与肿瘤的研究进展[J]. 肿瘤学杂志, 2012, 18(1):64-67.
FU Y, DU X Y. Research progress in microsatellite instability in cancer[J]. Journal of Chinese Oncology, 2012, 18(1):64-67.(in Chinese)
[20] 谭昌渊, 罗九甫, 任兆瑞. 高分辨率熔解曲线分析-分子诊断的新技术[J]. 生命科学研究, 2009, 13(3):268-271.
TAN C Y, LUO J F, REN Z R. High resolution melting-new method for molecular diagnosis[J]. Life Science Research, 2009, 13(3):268-271.(in Chinese)
[21] 毛旭华, 汤俊明, 乔国洪, 等. 高分辨率熔解曲线技术检测结直肠癌患者KRAS基因突变[J]. 中国肿瘤外科杂志, 2017, 9(5):296-299.
MAO X H, TANG J M, QIAO G H, et al. Detection of KRAS mutations in colorectal cancer patients by high resolution melting[J]. Chinese Journal of Surgical Oncology, 2017, 9(5):296-299.(in Chinese)
[22] REED G H, WITTWER C T. Sensitivity and specificity of single-nucleotide polymorphism scanning by high-resolution melting analysis[J]. Clin Chem, 2004, 50(10):1748-1754.

Detection of Microsatellite Instability in Marek's Disease Tumor based on High-resolution Melting

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