使用人类减数分裂基因对临床数据进行荟萃分析，确定了一组新的高度受限的癌症特异性标记基因。

Meta-analysis of clinical data using human meiotic genes identifies a novel cohort of highly restricted cancer-specific marker genes.

作者信息

Feichtinger Julia, Aldeailej Ibrahim, Anderson Rebecca, Almutairi Mikhlid, Almatrafi Ahmed, Alsiwiehri Naif, Griffiths Keith, Stuart Nicholas, Wakeman Jane A, Larcombe Lee, McFarlane Ramsay J

机构信息

North West Cancer Research Fund Institute, Bangor University, Bangor, LL57 2UW, UK.

出版信息

Oncotarget. 2012 Aug;3(8):843-53. doi: 10.18632/oncotarget.580.

DOI:10.18632/oncotarget.580

PMID:22918178

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3478461/

Abstract

Identifying cancer-specific biomarkers represents an ongoing challenge to the development of novel cancer diagnostic, prognostic and therapeutic strategies. Cancer/testis (CT) genes are an important gene family with expression tightly restricted to the testis in normal individuals but which can also be activated in cancers. Here we develop a pipeline to identify new CT genes. We analysed and validated expression profiles of human meiotic genes in normal and cancerous tissue followed by meta-analyses of clinical data sets from a range of tumour types resulting in the identification of a large cohort of highly specific cancer biomarker genes, including the recombination hot spot activator PRDM9 and the meiotic cohesin genes SMC1beta and RAD21L. These genes not only provide excellent cancer biomarkers for diagnostics and prognostics, but may serve as oncogenes and have excellent drug targeting potential.

摘要

识别癌症特异性生物标志物是新型癌症诊断、预后和治疗策略发展中持续面临的挑战。癌/睾丸（CT）基因是一个重要的基因家族，其表达在正常个体中严格限于睾丸，但在癌症中也可被激活。在此，我们开发了一种流程来识别新的CT基因。我们分析并验证了人类减数分裂基因在正常组织和癌组织中的表达谱，随后对一系列肿瘤类型的临床数据集进行荟萃分析，从而鉴定出一大批高度特异性的癌症生物标志物基因，包括重组热点激活因子PRDM9以及减数分裂黏连蛋白基因SMC1β和RAD21L。这些基因不仅为诊断和预后提供了出色的癌症生物标志物，还可能作为癌基因，具有出色的药物靶向潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1429/3478461/033dbc39144f/oncotarget-08-843-g001.jpg

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使用人类减数分裂基因对临床数据进行荟萃分析，确定了一组新的高度受限的癌症特异性标记基因。

Meta-analysis of clinical data using human meiotic genes identifies a novel cohort of highly restricted cancer-specific marker genes.

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