Földes-Papp Zeno, Egerer Renate, Birch-Hirschfeld Eckhard, Striebel Hans-Martin, Demel Ulrike, Tilz Gernot P, Wutzler Peter
Clinical Immunology and Jean Dausset Laboratory, Graz University Medical School, Graz, Austria.
Mol Diagn. 2004;8(1):1-9. doi: 10.1007/BF03260041.
The detailed characterization of virus DNA is a challenge, and the genotyping that has been achieved to date has only been possible because researchers have sent a great deal of time and effort to do so. Instead of the simultaneous detection of hundreds of viruses on a single high-density DNA-chip at very high costs per chip, we present here an alternative approach using a well-designed and tailored microarray which can establish whether or not a handful of viral genes are present in a clinical sample.
In this study we applied a new concept of microarray-based, optimized and robust biochemistry for molecular diagnostics of the herpesviruses. For comparison, all samples were genotyped using standard procedures.
The biochemical procedure of a knowledge-based, low-density microarray was established based on the molecular diagnostics of human herpes viruses: herpes simplex virus (HSV) HSV-1, HSV-2, varicella zoster virus (VZV), Epstein-Barr virus (EBV), cytomegalovirus (CMV), and HHV-6. The study attempted to optimize parameters of microarray design, surface chemistry, oligonucleotide probe spotting, sample labeling and DNA hybridization to the developed DNA microarray. The results of 12 900 hybridization reactions on about 150 configured herpes virus microarrays showed that the established microarray-based typing procedure was reproducible, virus-specific and sufficiently sensitive with a lower limit of 100 viral copies per mL sample.
The developed method utilizes low-fluorescence background coverslips, epoxy surface chemistry, standardized oligonucleotide probe spotting, PCR-labeling with Cy3 of isolated DNA, array hybridization, and detecting of specific spot fluorescence by an automatic microarray reader. We expect the configured microarray approach to be the method for high-throughput associated studies on human herpes viruses.
病毒DNA的详细特征分析是一项挑战,迄今为止所实现的基因分型仅因为研究人员投入了大量时间和精力才得以实现。我们在此提出一种替代方法,并非在单个高密度DNA芯片上以极高的芯片成本同时检测数百种病毒,而是使用精心设计和定制的微阵列,它可以确定临床样本中是否存在少数病毒基因。
在本研究中,我们应用了一种基于微阵列的、经过优化且稳健的生物化学新概念,用于疱疹病毒的分子诊断。为作比较,所有样本均采用标准程序进行基因分型。
基于人类疱疹病毒的分子诊断,建立了一种基于知识的低密度微阵列的生化程序,这些病毒包括单纯疱疹病毒(HSV)-1、HSV-2、水痘带状疱疹病毒(VZV)、爱泼斯坦-巴尔病毒(EBV)、巨细胞病毒(CMV)和HHV-6。该研究试图优化微阵列设计、表面化学、寡核苷酸探针点样、样本标记以及与已开发的DNA微阵列的DNA杂交等参数。在约150个配置好的疱疹病毒微阵列上进行的12900次杂交反应结果表明,所建立的基于微阵列的分型程序具有可重复性、病毒特异性,且灵敏度足够高,每毫升样本的病毒拷贝下限为100个。
所开发的方法利用了低荧光背景盖玻片、环氧表面化学、标准化的寡核苷酸探针点样、用Cy3对分离的DNA进行PCR标记、阵列杂交以及通过自动微阵列读取器检测特定斑点荧光。我们期望配置好的微阵列方法成为用于人类疱疹病毒高通量相关研究的方法。
