Department of Legal Medicine, Asahikawa Medical University, Asahikawa, Japan.
Electrophoresis. 2013 Feb;34(3):448-55. doi: 10.1002/elps.201200215. Epub 2013 Jan 14.
Amplification/hybridization-based genetic analyses using primers containing locked nucleic acids (LNAs) present many benefits. Here, we developed a novel design for universal fluorescent PCR using LNAs. Universal fluorescent PCR generates intermediate nonlabeled fragments and final fluorescent fragments in a two-step amplification process that uses locus-specific primers with universal tails and universal fluorescent primers. In this study, a few standard nucleotides were replaced with LNAs only in the fluorescent universal primers. The sequence of the fluorescent universal primer significantly affected the amplification efficiency. For primers with three LNAs, the fluorescent primers with stable M13(-47) sequences provided the most efficient signal (approximately tenfold higher than the primers with M13(-21) sequences at lower Tm values). Moreover, AT-rich LNA substitutions in the fluorescent primers produced much lower amplification efficiencies than GC-rich substitutions. GC-rich LNAs produced greater differences in Tm values among primers, and resulted in the preferential production of fluorescently labeled amplicons. The specificity and sensitivity of LNA-containing fluorescent primers were assessed by genotyping eight STRs in Japanese individuals, and full STR profiles could be generated using as little as 0.25 ng of genomic DNA. The method permitted clear discrimination of alleles and represents sensitive STR genotyping at a reduced cost.
基于锁核酸(LNA)的引物的扩增/杂交遗传分析具有许多优点。在这里,我们开发了一种新的通用荧光 PCR 的 LNA 设计。通用荧光 PCR 在两步扩增过程中产生中间非标记片段和最终荧光片段,该过程使用具有通用尾巴和通用荧光引物的特异性引物。在这项研究中,仅在荧光通用引物中用 LNA 替换了几个标准核苷酸。荧光通用引物的序列显著影响扩增效率。对于具有三个 LNA 的引物,具有稳定 M13(-47)序列的荧光引物提供了最高的信号(在较低 Tm 值下,其信号比具有 M13(-21)序列的引物高约十倍)。此外,荧光引物中的富含 AT 的 LNA 取代产生的扩增效率比富含 GC 的取代低得多。富含 GC 的 LNA 在引物之间产生更大的 Tm 值差异,并导致荧光标记的扩增子优先产生。通过对日本个体的 8 个 STR 进行基因分型评估了含 LNA 的荧光引物的特异性和灵敏度,并且仅使用 0.25ng 的基因组 DNA 即可生成完整的 STR 图谱。该方法允许等位基因的清晰区分,并且代表了以降低成本进行敏感的 STR 基因分型。