Small nucleolar RNA is potential as a novel player in leukemogenesis and clinical application 被引量：2

导出

摘要 Lack of clarity of the mechanisms that underlie leukemogenesis obstructs the diagnosis,prognosis,and treatment of leukemia.Research has found that small nuclear RNA(snoRNA)plays an essential role in leukemia.These small non-coding RNAs are involved in ribosome biogenesis,including the 2'-O-methylation and pseudouridylation of precursor ribosomal RNA(pre-rRNA),and pre-rRNA splicing.Recently,many snoRNAs were found to be orphans that have no predictable RNA modification targets,but these RNAs have always been found to be located in different subcellular organelles,and they play diverse roles.Using high-throughput technology,snoRNA expression profiles have been revealed in leukemia,and some of the deregulated snoRNAs may regulate the cell cycle,differentiation,proliferation,and apoptosis in leukemic cells and confer drug resistance during leukemia treatment.In this review,we discuss the expression profiles and functions of snoRNAs,particularly orphan snoRNAs,in leukemia.It is possible that the dysregulated snoRNAs are promising diagnosis and prognosis markers for leukemia,which may serve as potential therapeutic targets in leukemia treatment.

作者 Li-Min Lin Qi Pan Yu-Meng Sun Wen-Tao Wang

机构地区 MOE Key Laboratory of Gene Function and Regulation

出处《Blood Science》 2021年第4期122-131,共10页 血液科学（英文）

基金 National Natural Science Foundation of China(82000168 and 31870818)。

关键词 2'-O-methylation Biomarkers Drug resistance LEUKEMIA SNORNA Targeted therapy

分类号 R73 [医药卫生—肿瘤]

引文网络
相关文献

参考文献1

1Xue-Yuan Dong,Peng Guo,Jeff Boyd,Xiaodong Sun,Qunna Li,Wei Zhou,Jin-Tang Dong.Implication of snoRNA U50 in human breast cancer[J].Journal of Genetics and Genomics,2009,36(8):447-454. 被引量：11

二级参考文献38

1Abdollahi, A., Pisarcik, D., Roberts, D., Weinstein, J., Cairns, P., and Hamilton, T.C. (2003). LOT1 (PLAGL1/ZAC1), the candidate tumor suppressor gene at chromosome 6q24-25, is epigenetically regulated in cancer. J. Biol. Chem. 278: 6041-6049.
2Basyuk, E., Coulon, V., Le Digarcher, A., Coisy-Quivy, M., Moles, J.P., Gandarillas, A., and Journot, L. (2005). The candidate tumor suppressor gene ZAC is involved in keratinocyte differentiation and its expression is lost in basal cell carcinomas. Mol. Cancer Res. 3: 483-492.
3Callahan, R., and Campbell, G. (1989). Mutations in human breast cancer: An overview. J. Natl. Cancer Inst. 81: 1780-1786.
4Cesari, R., Martin, E.S., Calin, G.A., Pentimalli, F., Bichi, R., McAdams, H., Trapasso, F., Drusco, A., Shimizu, M., Masciullo, V., D’Andrilli, G., Scambia, G., Picchio, M.C., Alder, H., Godwin, A.K., and Croce, C.M. (2003). Parkin, a gene implicated in autosomal recessive juvenile parkinsonism, is a candidate tumor suppressor gene on chromosome 6q25-q27. Proc. Natl. Acad. Sci. USA 100: 5956-5961.
5Devilee, P., van Vliet, M., van Sloun, P., Kuipers Dijkshoorn, N., Hermans, J., Pearson, P.L., and Cornelisse, C.J. (1991). Allelotype of human breast carcinoma: A second major site for loss of heterozygosity is on chromosome 6q. Oncogene 6: 1705-1711.
6Dong, J.T. (2001). Chromosomal deletions and tumor suppressor genes in prostate cancer. Cancer Metastasis Rev. 20: 173-193.
7Dong, J.T., Chen, C., Stultz, B.G., Isaacs, J.T., and Frierson, H.F., Jr. (2000). Deletion at 13q21 is associated with aggressive prostate cancers. Cancer Res. 60: 3880-3883.
8Dong, X.Y., Chen, C., Sun, X., Guo, P., Vessella, R.L., Wang, R.X., Chung, L.W., Zhou, W., and Dong, J.T. (2006). FOXO1A is a candidate for the 13q14 tumor suppressor gene inhibiting androgen receptor signaling in prostate cancer. Cancer Res. 66: 6998-7006.
9Dong, X.Y., Rodriguez, C., Guo, P., Sun, X., Talbot, J.T., Zhou, W., Petros, J., Li, Q., Vessella, R.L., Kibel, A.S., Stevens, V.L., Calle, E.E., and Dong, J.T. (2008). SnoRNA U50 is a candidate tumor-suppressor gene at 6q14.3 with a mutation associated with clinically significant prostate cancer. Hum. Mol. Genet. 17: 1031-1042.
10Dutrillaux, B., Gerbault-Seureau, M., and Zafrani, B. (1990). Characterization of chromosomal anomalies in human breast cancer. A comparison of 30 paradiploid cases with few chromosome changes. Cancer Genet. Cytogenet. 49: 203-217.

共引文献10

1魏炎,楚慧丽,关雅萍,王俊,毕经旺.小分子非编码RNAs在乳腺肿瘤中的作用机制[J].科技信息,2012(36):438-439.
2肖丙秀,夏天,郭俊明.核仁小RNA在肿瘤发生中的作用[J].中国生物化学与分子生物学报,2012,28(12):1087-1092. 被引量：2
3Tianzhi Huang,Angel Alvarez,Bo Hu,Shi-Yuan Cheng.Noncoding RNAs in cancer and cancer stem cells[J].Chinese Journal of Cancer,2013,32(11):582-593. 被引量：10
4徐斌,叶敏华,吕世刚,吴淼经,肖兵,范阳华,柴毅,祝新根.过表达SNORD47对U87-EGFRvIII胶质瘤细胞增殖和侵袭的影响[J].中华神经医学杂志,2017,16(6):547-552.
5胡江平,贺更生.核仁小RNA在肿瘤发生发展中的研究进展[J].癌症进展,2018,16(7):816-819.
6王晓琼,蔡志毅.长链非编码RNA ZFAS1在肿瘤中的研究进展[J].现代肿瘤医学,2019,27(3):537-540. 被引量：3
7马驰,焦振东.SNORA51在原发性肝细胞癌组织中的表达及临床意义[J].中国现代普通外科进展,2021,24(12):944-948.
8潘秀懿,苏征征,钟金晶,余婷,卫昱燕,许云屹,尹晓雪,郭小煜,张孟尼,聂玲,徐苗,龚静,陈铌,陈雪芹,周桥.肿瘤分子病理学中的调节性RNA[J].中国科学：生命科学,2022,52(11):1578-1602. 被引量：2
9丁翠玲,王鹏,王文.核仁小分子RNAs与癌症的研究进展[J].肿瘤防治研究,2015,42(1):86-89.
10Yi-Ting Tang,Xiao-Hui Xu,Xiao-Dong Yang,Jun Hao,Han Cao,Wei Zhu,Shu-Yu Zhang,Jian-Ping Cao.Role of non-coding RNAs in pancreatic cancer: The bane of the microworld[J].World Journal of Gastroenterology,2014,20(28):9405-9417.

引证文献2

1陈志国,盛静,赵著洋,阳莎,冯柳,吴宏博,唱凯,陈磊.外周血snoRNA单一及组合panel对原发性肝癌的诊断价值[J].国际检验医学杂志,2024,45(10):1267-1272.
2刘彦权,陈绍鹏,殷悦,沈建箴,曾敏娟.小核仁RNA SNORA63在急性白血病患者中的异常表达及其临床意义[J].中国实验血液学杂志,2024,32(4):979-986.

1Yang Xiong,Sen Hu,Hongyao Zhou,Hui Zeng,Xuan He,Dongni Huang,Xiaoyu Li.High-throughput 16S rDNA sequencing of the pulmonary microbiome of rats with allergic asthma[J].Genes & Diseases,2020,7(2):272-282. 被引量：4
2Yingchun Lyu,Yali Liu,Tao Cheng,Bingkun Guo.High-throughput characterization methods for lithium batteries[J].Journal of Materiomics,2017,3(3):221-229. 被引量：6
3Lifang Niu,Falong Lu,Taolan Zhao,Chunyan Liu,Xiaofeng Cao.The enzymatic activity of Arabidopsis protein arginine methyltransferase 10 is essential for flowering time regulation[J].Protein & Cell,2012,3(6):450-459. 被引量：2
4马驰,焦振东.SNORA51在原发性肝细胞癌组织中的表达及临床意义[J].中国现代普通外科进展,2021,24(12):944-948.
5Jing Yang,Ellen L.Weisberg.HSP70 and FLT3-ITD: Targeting chaperone systemto overcome drug resistance[J].Blood Science,2021,3(4):151-153. 被引量：1
6Wen-fang Li,Arin Herkilini,Yu Tang,Ping Huang,Guan-bin Song,Makoto Miyagishi,Vivi Kasim,Shou-rong Wu.The transcription factor PBX3 promotes tumor cell growth through transcriptional suppression of the tumor suppressor p53[J].Acta Pharmacologica Sinica,2021,42(11):1888-1899. 被引量：1
7许泽军,刘炜玮,王桂军,丁铲.环状RNA与病毒感染之间相互关系的研究进展[J].病毒学报,2021,37(6):1508-1514. 被引量：1
8SAETAN Wanida,YE Minghui,LIN Xinghua,LIN Xiaozhan,ZHANG Yulei,HUANG Yang,DU Tao,LI Guangli,TIAN Changxu.Comparative Transcriptome Analysis of Heart Tissue in Response to Hypoxia in Silver Sillago (Sillago sihama)[J].Journal of Ocean University of China,2021,20(4):949-958. 被引量：1
9Aleksander Prominski,Pengju Li,Bernadette A.Miao,Bozhi Tian.Nanoenabled Bioelectrical Modulation[J].Accounts of Materials Research,2021,2(10):895-906. 被引量：1
10Tai-Yong Wu,Jian Li,Hai-Jun Fu,Cai-Tong Cheng,Zhi Lv,Yi Feng.Research progress on methylation of osteosarcoma-related genes[J].Journal of Hainan Medical University,2021,27(24):61-65.

Blood Science

2021年第4期

浏览历史

内容加载中请稍等...

Small nucleolar RNA is potential as a novel player in leukemogenesis and clinical application 被引量：2

参考文献1

二级参考文献38

共引文献10

引证文献2

相关作者

相关机构

相关主题

浏览历史