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单突变和双突变小鼠睾丸癌易感性的增强子和抑制子

Enhancers and suppressors of testicular cancer susceptibility in single- and double-mutant mice.

作者信息

Lam Man-Yee Josephine, Youngren Kirsten K, Nadeau Joseph H

机构信息

Department of Genetics, Comprehensive Cancer Center and Center for Computational Genomics, Case Western Reserve University, Cleveland, OH 44106, USA.

出版信息

Genetics. 2004 Feb;166(2):925-33. doi: 10.1534/genetics.166.2.925.

DOI:10.1534/genetics.166.2.925
PMID:15020477
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1470739/
Abstract

Susceptibility to spontaneous testicular germ cell tumors (TGCTs), a common cancer affecting young men, shows unusual genetic complexity. Despite remarkable progress in the genetics analysis of susceptibility to many cancers, TGCT susceptibility genes have not yet been identified. Various mutations that are inherited as Mendelian traits in laboratory mice affect susceptibility to spontaneous TGCTs on the 129/Sv inbred genetic background. We compared the frequency of spontaneous TGCTs in single- and double-mutant mice to identify combinations that show evidence of enhancer or suppressor effects. The lower-than-expected TGCT frequencies in mice with partial deficiencies of TRP53 and MGF-SLJ and in 129.MOLF-Chr19 (M19) consomic mice that were heterozygous for the A(y) mutation suggest that either these genes complement each other to restore normal functionality in TGCT stem cells or together these genes activate mechanisms that suppress incipient TGCTs. By contrast, the higher-than-expected TGCT frequencies in Mgf(Sl-J)-M19 compound heterozygous mice suggest that these mutations exacerbate each other's effects. Together, these results provide clues to the genetic and molecular basis for susceptibility to TGCTs in mice and perhaps in humans.

摘要

睾丸生殖细胞肿瘤(TGCT)是一种常见于年轻男性的癌症,对其易感性表现出不同寻常的遗传复杂性。尽管在许多癌症易感性的遗传学分析方面取得了显著进展,但TGCT的易感基因尚未被确定。在实验室小鼠中,作为孟德尔性状遗传的各种突变会影响129/Sv近交遗传背景下自发性TGCT的易感性。我们比较了单突变和双突变小鼠中自发性TGCT的发生率,以确定显示增强或抑制作用证据的组合。TRP53和MGF-SLJ部分缺陷的小鼠以及对A(y)突变杂合的129.MOLF-Chr19(M19)染色体置换小鼠中TGCT发生率低于预期,这表明这些基因要么相互补充以恢复TGCT干细胞中的正常功能,要么这些基因共同激活抑制初期TGCT的机制。相比之下,Mgf(Sl-J)-M19复合杂合小鼠中TGCT发生率高于预期,这表明这些突变会加剧彼此的影响。总之,这些结果为小鼠以及可能在人类中TGCT易感性的遗传和分子基础提供了线索。

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