Comparison of sample preparation methods for ChIP-chip assays

A single chromatin immunoprecipitation (ChIP) sample does not provide enough DNA for hybridization to a genomic tiling array. A commonly used technique for amplifying the DNA obtained from ChIP assays is ligation-mediated PCR (LM-PCR). However; using this amplification method, we could not identify Oct4 binding sites on genomic tiling arrays representing 1% of the human genome (ENCODE arrays). In contrast, hybridization of a pool of 10 ChIP samples to the arrays produced reproducible binding patterns and low background signals. However the pooling method would greatly increase the number of ChIP reactions needed to analyze the entire human genome. Therefore, we have adapted the GenomePlex whole genome amplification (WGA) method for use in ChIP-chip assays; detailed ChIP and amplification protocols used for these analyses are provided as supplementary material. When applied to ENCODE arrays, the products prepared using this new method resulted in an Oct4 binding pattern similar to that from the pooled Oct4 ChIP samples. Importantly, the signal-to-noise ratio using the GenomePlex WGA method is superior to the LM-PCR amplification method.     

ChIP技术及其在基因组水平上分析DNA与蛋白质相互作用

染色质免疫沉淀(Chromatin immunoprecipitaion, ChIP)技术是分析细胞内生理状态下DNA结合蛋白与基因组DNA相互作用的技术。ChIP与高密度芯片(ChIP-chip)或高通量测序(ChIP-Seq)相结合能产生大量的研究数据, 在细胞的基因表达调控网络研究中发挥重要作用。文章主要介绍ChIP、ChIP-chip和ChIP-Seq的技术特点以及发展趋势, 重点讨论了ChIP-Seq数据分析方法及相关的应用实例。     

一种改良的启动子序列克隆的染色体步查法

利用染色体步行法,从已知DNA序列克隆侧翼未知序列是非常有效的方法之一,但由于所选用的特定限制性内切酶对目标基因组不能酶解成合适大小的片段,因而受PCR扩增能力的局限,往往扩增不出有效产物. 针对这一点,这里我们介绍一种简单有效的改良方法,它包括以下步骤：首先用不同的限制性内切酶(包括平末端和粘性末端) 酶解目标基因组DNA,接着,选择能将基因组酶切成弥散、分布均匀的限制性内切酶,如DraⅠ和HindⅢ,合成相对应的接头;然后,选择弥散的、分布均匀的限制性内切酶的酶解产物,构建成含相应接头的基因组DNA文库,用作PCR的模板;最后,用接头引物和特异引物,通过巢式PCR扩增目的片段,获得了理想的扩增效果.采用改进后的染色体步查法,有效地从较复杂的棉花核DNA中克隆出6个棉花启动子序列.     

ChIP-chip: considerations for the design, analysis, and application of genome-wide chromatin immunoprecipitation experiments

Chromatin immunoprecipitation (ChIP) is a well-established procedure to investigate interactions between proteins and DNA. Coupled with whole-genome DNA microarrays, ChIPS allow one to determine the entire spectrum of in vivo DNA binding sites for any given protein. The design and analysis of ChIP-microarray (also called ChIP-chip) experiments differ significantly from the conventions used for locus ChIP approaches and ChIP-chip experiments, and these differences require new methods of analysis. In this light, we review the design of DNA microarrays, the selection of controls, the level of repetition required, and other critical parameters for success in the design and analysis of ChIP-chip experiments, especially those conducted in the context of mammalian or other relatively large genomes.     

Multiple displacement amplification enables large-scale clonal analysis following retroviral gene therapy

Analysis of the fate of retrovirally transduced cells after transplantation is often hampered by the scarcity of available DNA. We evaluated a promising method for whole-genome amplification, called multiple displacement amplification (MDA), with respect to even and accurate representation of retrovirally transduced genomic DNA. We proved that MDA is a suitable method to subsequently quantify engraftment efficiencies by quantitative real-time PCR by analyzing retrovirally transduced DNA in a background of untransduced DNA and retroviral integrations found in primary material from a retroviral transplantation model. The portion of these retroviral integrations in the amplified samples was 1.02-fold (range 0.2, to 2.1-fold) the portion determined in the original genomic DNA. Integration site analysis by ligation-mediated PCR (LM-PCR) is essential for the detection of retroviral integrations. The combination of MDA and LM-PCR showed an increase in the sensitivity of integration site analysis, as a specific integration site could be detected in a background of untransduced DNA, while the transduced DNA made up only 0.001%. These results show for the first time that MDA enables large-scale sensitive detection and reliable quantification of retrovirally transduced human genomic DNA and therefore facilitates follow-up analysis in gene therapy studies even from the smallest amounts of starting material.