常见的端粒基因沉默检测法受核苷酸代谢的影响。
A common telomeric gene silencing assay is affected by nucleotide metabolism.
机构信息
Cold Spring Harbor Laboratory, Cold Spring Harbor, NY 11724, USA.
出版信息
Mol Cell. 2011 Apr 8;42(1):127-36. doi: 10.1016/j.molcel.2011.03.007.
Abstract
Telomere-associated position-effect variegation (TPEV) in budding yeast has been used as a model for understanding epigenetic inheritance and gene silencing. A widely used assay to identify mutants with improper TPEV employs the URA3 gene at the telomere of chromosome VII-L that can be counterselected with 5-fluoroorotic acid (5-FOA). 5-FOA resistance has been inferred to represent lack of transcription of URA3 and therefore to represent heterochromatin-induced gene silencing. For two genes implicated in telomere silencing, POL30 and DOT1, we show that the URA3 telomere reporter assay does not reflect their role in heterochromatin formation. Rather, an imbalance in ribonucleotide reductase (RNR), which is induced by 5-FOA, and the specific promoter of URA3 fused to ADH4 at telomere VII-L are jointly responsible for the variegated phenotype. We conclude that metabolic changes caused by the drug employed and certain mutants being studied are incompatible with the use of certain prototrophic markers for TPEV.
摘要
端粒相关位置效应变异(TPEV)在 budding yeast 中被用作理解表观遗传遗传和基因沉默的模型。一种广泛用于鉴定 TPEV 异常突变体的常用方法是利用染色体 VII-L 端粒上的 URA3 基因,该基因可以用 5-氟乳清酸(5-FOA)进行反向选择。5-FOA 抗性被推断为 URA3 转录缺乏,因此代表异染色质诱导的基因沉默。对于两个与端粒沉默相关的基因 POL30 和 DOT1,我们表明 URA3 端粒报告基因检测方法不能反映它们在异染色质形成中的作用。相反,5-FOA 诱导的核糖核苷酸还原酶(RNR)失衡,以及与 ADH4 在端粒 VII-L 融合的 URA3 的特定启动子,共同导致了斑驳的表型。我们得出结论,所使用药物和某些正在研究的突变体引起的代谢变化与使用某些原养型标记物进行 TPEV 检测不相容。
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