High-performance liquid chromatography purification of 26-bp serial analysis of gene expression ditags results in higher yields,longer concatemers,and substantial time savings

In contrast to DNA chips, serial analysis of gene expression (SAGE) is not dependent on genes having been previously identified for their monitoring. Although useful, the method can be technically challenging, and particularly the last steps including concatenation and cloning may result in less than optimal results. We propose that many of the encountered problems can be attributed to the purification of the 26-bp ditags by polyacrylamide gel electrophoresis. Low yields, gel contaminants, potential exposure to degrading enzymes during handling and lengthy separation all disfavor the method. We introduce purification of 26-bp ditags by reverse-phase high-performance liquid chromatography (HPLC) using polystyrene/divinylbenzene columns and tetraethylammonium acetate buffer with acetonitrile as mobile phase. The method is fast and gives excellent results. Ditags purified by HPLC readily ligate to high-molecular-weight concatemers leading to their efficient cloning. The method should substantially facilitate the construction of SAGE libraries.     

Discarding duplicate ditags in LongSAGE analysis may introduce significant error

Background  

During gene expression analysis by Serial Analysis of Gene Expression (SAGE), duplicate ditags are routinely removed from the data analysis, because they are suspected to stem from artifacts during SAGE library construction. As a consequence, naturally occurring duplicate ditags are also removed from the analysis leading to an error of measurement.     

Substantially enhanced cloning efficiency of SAGE (Serial Analysis of Gene Expression) by adding a heating step to the original protocol.

The efficiency of the original SAGE (Serial Analysis of Gene Expression) protocol was limited by a small average size of cloned concatemers. We describe a modification of the technique that overcomes this problem. Ligation of ditags yields concatemers of various sizes. Small concatemers may aggregate and migrate with large ones during gel electrophoresis. A heating step introduced before gel electrophoresis breaks such contaminating aggregates. This modification yields cloned concatemers with an average size of 67 tags as compared to 22 tags by the original protocol. It enhances the length of cloned concatemers substantially and reduces the costs of SAGE.     

Generation of high-quantity and quality tag/ditag cDNAs for SAGE analysis

The serial analysis of gene expression (SAGE) technique is an important tool for genome-wide gene expression analysis. However, the requirement of a large amount of mRNA for the analysis and the difficulties in generating high-quality tag and ditag fragments for the construction of a SAGE library often interfere with the successful performance of the SAGE technique. We developed two procedures to solve these issues: (i) introducing low-cycle PCR amplification of the 3' cDNA before the BsmFI digestion of the 3' cDNAs and (ii) gel purifying the BsmFI-released tag fragments before ditag formation. These modifications provide a large quantity of initial 3' cDNAs and high-quality tags and ditags for the construction of SAGE libraries.     

From micrograms to picograms: quantitative PCR reduces the material demands of high-throughput sequencing

Current efforts to recover the Neandertal and mammoth genomes by 454 DNA sequencing demonstrate the sensitivity of this technology. However, routine 454 sequencing applications still require microgram quantities of initial material. This is due to a lack of effective methods for quantifying 454 sequencing libraries, necessitating expensive and labour-intensive procedures when sequencing ancient DNA and other poor DNA samples. Here we report a 454 sequencing library quantification method based on quantitative PCR that effectively eliminates these limitations. We estimated both the molecule numbers and the fragment size distributions in sequencing libraries derived from Neandertal DNA extracts, SAGE ditags and bonobo genomic DNA, obtaining optimal sequencing yields without performing any titration runs. Using this method, 454 sequencing can routinely be performed from as little as 50 pg of initial material without titration runs, thereby drastically reducing costs while increasing the scope of sample throughput and protocol development on the 454 platform. The method should also apply to Illumina/Solexa and ABI/SOLiD sequencing, and should therefore help to widen the accessibility of all three platforms.     

基因表达系列性分析技术及其应用

基因表达系列性分析（SAGE）是一种高通量的基因表达模式的研究技术,能够对特定细胞或组织中的大量转录本同时进行定量分析。本综述了SAGE技术的基本原理和实验流程以及近年来SAGE方法上的改进,同时介绍了该技术的一些应用研究实例和Internet上可资利用的SAGE数据库资源。     

Identification and prevention of a GC content bias in SAGE libraries

Serial Analysis of Gene Expression (SAGE) is becoming a widely used gene expression profiling method for the study of development, cancer and other human diseases. Investigators using SAGE rely heavily on the quantitative aspect of this method for cataloging gene expression and comparing multiple SAGE libraries. We have developed additional computational and statistical tools to assess the quality and reproducibility of a SAGE library. Using these methods, a critical variable in the SAGE protocol was identified that has the potential to bias the Tag distribution relative to the GC content of the 10 bp SAGE Tag DNA sequence. We also detected this bias in a number of publicly available SAGE libraries. It is important to note that the GC content bias went undetected by quality control procedures in the current SAGE protocol and was only identified with the use of these statistical analyses on as few as 750 SAGE Tags. In addition to keeping any solution of free DiTags on ice, an analysis of the GC content should be performed before sequencing large numbers of SAGE Tags to be confident that SAGE libraries are free from experimental bias.     

基因表达的系列分析方法研究进展

基因表达的系列分析（SAGE）是探讨组织或器官在不同条件下基因表达丰度以及差异表达的一种有效方法。本文介绍了SAGE方法的详细机理并且对SAGE方法学的改进进行了综述。     

强大的广谱基因表达分析技术——基因表达系列分析法

基因表达系列分析(serial analysis of gene expression,SAGE)是一项强大的数字化分析基因组整体表达模式的技术。它的诞生为定量、全局性地分析特定细胞内的基因表达情况提供了可能。本文介绍了SAGE技术的基本原理、最新进展和应用。