Olerup O, Zetterquist H
Center for BioTechnology, Karolinska Institute, NOVUM, Huddinge, Sweden.
Tissue Antigens. 1992 May;39(5):225-35. doi: 10.1111/j.1399-0039.1992.tb01940.x.
In most PCR-based tissue typing techniques the PCR amplification is followed by a post-amplification specificity step. In typing by PCR amplification with sequence-specific primers (PCR-SSP), typing specificity is part of the amplification step, which makes the technique almost as fast as serological tissue typing. In the present study primers were designed for DR "low-resolution" typing by PCR-SSP, i.e. identifying polymorphism corresponding to the serologically defined series DR1-DRw18. This resolution was achieved by performing 19 PCR reactions per individual, 17 for assigning DR1-DRw18 and 2 for the DRw52 and DRw53 superspecificities. Thirty cell lines and 121 individuals were typed by the DR "low-resolution" PCR-SSP technique, TaqI DRB-DQA-DQB RFLP analysis and serology. The concordance between PCR-SSP typing and RFLP analysis was 100%. The reproducibility was 100% in 40 samples typed on two separate occasions. No false-positive or false-negative typing results were obtained. All homozygous and heterozygous combinations of DR1-DRw18 could be distinguished. Amplification patterns segregated according to dominant Mendelian inheritance. DNA preparation, PCR amplification and post-amplification processing, including gel detection, documentation and interpretation, were performed in 2 hours. In conclusion, PCR-SSP is an accurate typing technique with high sensitivity, specificity and reproducibility. The method is rapid and inexpensive. DR "low-resolution" typing by the PCR-SSP technique is ideally suited for analyzing small numbers of samples simultaneously and is an alternative to serological DR typing in routine clinical practice including donor-recipient matching in cadaveric transplantations.
在大多数基于聚合酶链反应(PCR)的组织分型技术中,PCR扩增之后是一个扩增后特异性步骤。在用序列特异性引物进行PCR扩增分型(PCR-SSP)时,分型特异性是扩增步骤的一部分,这使得该技术几乎与血清学组织分型一样快。在本研究中,设计了用于通过PCR-SSP进行DR“低分辨率”分型的引物,即识别与血清学定义的DR1-DRw18系列相对应的多态性。通过对每个个体进行19次PCR反应来实现这种分辨率,其中17次用于确定DR1-DRw18,2次用于确定DRw52和DRw53超特异性。通过DR“低分辨率”PCR-SSP技术、TaqI DRB-DQA-DQB限制性片段长度多态性(RFLP)分析和血清学对30个细胞系和121个个体进行了分型。PCR-SSP分型与RFLP分析之间的一致性为100%。在两次单独检测的40个样本中,重复性为100%。未获得假阳性或假阴性分型结果。可以区分DR1-DRw18的所有纯合和杂合组合。扩增模式按照显性孟德尔遗传进行分离。DNA制备、PCR扩增和扩增后处理,包括凝胶检测、记录和解读,在2小时内完成。总之,PCR-SSP是一种准确的分型技术,具有高灵敏度、特异性和重复性。该方法快速且成本低廉。通过PCR-SSP技术进行DR“低分辨率”分型非常适合同时分析少量样本,并且是常规临床实践中血清学DR分型的一种替代方法,包括尸体移植中的供体-受体匹配。
