Stevens Aaron J, Kennedy Martin A
Department of Pathology, University of Otago , Christchurch, New Zealand.
Biochemistry. 2017 Jul 25;56(29):3691-3698. doi: 10.1021/acs.biochem.7b00480. Epub 2017 Jul 10.
The promoter of the human imprinted gene MEST is differentially methylated with respect to the parent of origin and contains several non B-DNA motifs that are capable of forming G-quadruplexes. These factors can contribute to a consistent allelic dropout (ADO) of the maternally methylated DNA during polymerase chain reaction (PCR) analysis of such gene regions. Here, we directly investigate the cause of allelic dropout by applying fluorescent techniques to visualize polymerase amplification and arrest during PCR of differentially methylated DNA templates. We demonstrate that polymerase arrest corresponds to previously characterized G-quadruplex-forming motifs at the MEST promoter region and occurs at equivalent sites on both methylated and nonmethylated DNA templates. However, during PCR, polymerase arrest can be observed on the methylated template for several cycles longer than on the nonmethylated template, and this results in an amplification lag and a lower yield of full length amplicons. We demonstrate that this delay in amplification is sufficient to cause complete ADO during PCR, providing a mechanistic basis for the previously observed genotyping error at this locus.
人类印记基因MEST的启动子在亲本来源方面存在差异甲基化,并且包含几个能够形成G-四链体的非B-DNA基序。在对此类基因区域进行聚合酶链反应(PCR)分析期间,这些因素可能导致母本甲基化DNA出现一致的等位基因脱失(ADO)。在此,我们通过应用荧光技术来可视化差异甲基化DNA模板PCR过程中的聚合酶扩增和停滞,直接研究等位基因脱失的原因。我们证明,聚合酶停滞与MEST启动子区域先前表征的G-四链体形成基序相对应,并且在甲基化和非甲基化DNA模板的等效位点处发生。然而,在PCR过程中,甲基化模板上观察到的聚合酶停滞比非甲基化模板上的持续时间长几个循环,这导致扩增滞后和全长扩增子产量降低。我们证明,这种扩增延迟足以在PCR期间导致完全的ADO,为该位点先前观察到的基因分型错误提供了机制基础。
