Stewart J, Kozlowski P, Sowden M, Messing E, Smith H C
Department of Pathology and Laboratory Medicine, University of Rochester, 601 Elmwood Avenue, Rochester, NY 14642, USA.
Nucleic Acids Res. 1998 Feb 15;26(4):961-6. doi: 10.1093/nar/26.4.961.
A variety of techniques are currently available for detecting point mutations in DNA. These techniques are frequently not sensitive enough to be applied as quantitative assays in evaluation of relative occurrence of alleles in cases of polymorphism or when variations in allelic gene expression are being evaluated at the level of RNA. We report here the establishment of an iterative gap ligation (IGL) assay that is both quantitative and sensitive. The design of the assay is such that ligation of an upstream to a downstream primer across a single nucleotide gap will only occur if the gap is filled with a deoxynucleotide complementary to the wild-type or mutant sequence. Under conditions in which excess upstream primer saturates the template concurrently with limiting amounts of downstream primer quantitative ligation is absolutely dependent on provision of the appropriate gap filling nucleotide. When gap ligation occurs in a single incubation, or cycle, the amount of ligated product is a linear function of the relative amount of mutant sequence, with a sensitivity and detection limit of approximately 3% over a range of relative concentrations of 0-100%. When the reaction occurs over multiple cycles, or iterations, gap ligation becomes a non-linear function such that small changes in the relative proportions of alleles produce a disproportionately large amount of ligation. As a consequence, the sensitivity and limits of detection of the assay improve to 0.2% after only 8 cycles. The development of this assay provides a unique means of quantifying allelic polymorphisms in both DNA and RNA (after initial amplification by PCR or RT-PCR) and should be applicable to any experimental settings in which nucleic acids from tissues or mixed populations of cells are being evaluated.
目前有多种技术可用于检测DNA中的点突变。这些技术通常不够灵敏,无法作为定量分析方法用于评估多态性情况下等位基因的相对发生率,或在RNA水平评估等位基因表达变化时使用。我们在此报告一种既定量又灵敏的迭代缺口连接(IGL)分析方法的建立。该分析方法的设计是,只有当缺口被与野生型或突变序列互补的脱氧核苷酸填充时,上游引物与下游引物跨越单个核苷酸缺口的连接才会发生。在过量上游引物使模板饱和而下游引物数量有限的条件下,定量连接绝对依赖于提供合适的缺口填充核苷酸。当缺口连接在单个孵育或循环中发生时,连接产物的量是突变序列相对量的线性函数,在0-100%的相对浓度范围内,灵敏度和检测限约为3%。当反应在多个循环或迭代中发生时,缺口连接变成非线性函数,使得等位基因相对比例的微小变化会产生不成比例的大量连接。因此,仅经过8个循环后,该分析方法的灵敏度和检测限就提高到了0.2%。这种分析方法的开发提供了一种独特的手段,可用于定量DNA和RNA中的等位基因多态性(通过PCR或RT-PCR进行初始扩增后),并且应该适用于任何评估来自组织或细胞混合群体的核酸的实验设置。