Modified differential display technique that eliminates radioactivity and decreases screening time

Several techniques are available that detect variations in gene expression between cellular populations. These include subtractive hybridization (SH), differential colony hybridization (DCH) and mRNA differential display, all based on the analysis of mRNA. The first two techniques, however, are limited because they require large amounts of mRNA for SH or several rounds of screening for DCH. Differential display overcomes both of these limitations. However, the conventional differential display technique is plagued by false positives and is labor intensive. The identification of genes that are truly differentially expressed, therefore, becomes a formidable task. We describe a modified differential display technique that overcomes the limitations of the conventional technique. This new technique eliminates a source of false positives, decreases the time required to screen a set of primers and reduces the use of radioactivity.     

Subtractive differential display: a modified differential display technique for isolating differentially expressed genes

Differential display (DD) is a novel PCR-based technique, very commonly used to study differentially expressed genes at the mRNA level. In this paper we report a modified version of this technique that we have used to study the differences between the mRNA population from brain tissue of adult and old rats. We have modified the technique to enhance reproducibility and reduce false positives and redundancy. It is fast and does not require any expensive or uncommon reagent. We choose to call it as subtractive differential display as it is a differential display performed over subtracted mRNA population. We have used this protocol successfully to clone a number of age-related differentially expressed sequences from rat brain that need to be sequenced to establish the gene identity.     

Microarray analysis of cytoplasmic versus whole cell RNA reveals a considerable number of missed and false positive mRNAs

With no known exceptions, every published microarray study to determine differential mRNA levels in eukaryotes used RNA extracted from whole cells. It is assumed that the use of whole cell RNA in microarray gene expression analysis provides a legitimate profile of steady-state mRNA. Standard labeling methods and the prevailing dogma that mRNA resides almost exclusively in the cytoplasm has led to the long-standing belief that the nuclear RNA contribution is negligible. We report that unadulterated cytoplasmic RNA uncovers differentially expressed mRNAs that otherwise would not have been detected when using whole cell RNA and that the inclusion of nuclear RNA has a large impact on whole cell gene expression microarray results by distorting the mRNA profile to the extent that a substantial number of false positives are generated. We conclude that to produce a valid profile of the steady-state mRNA population, the nuclear component must be excluded, and to arrive at a more realistic view of a cell''s gene expression profile, the nuclear and cytoplasmic RNA fractions should be analyzed separately.     

Rapid and Reliable Differential Display from Minute Amounts of Tissue: Mass Cloning and Characterization of Differentially Expressed Genes from Loblolly Pine Embryos

Performing RNA differential display analysis on small tissue samples is difficult since much RNA, the initial template for the reaction, is lost during conventional isolation procedures. We have developed a rapid method which employs oligo-dT beads to capture mRNA from cell lysates. Subsequent reactions are primed directly from the beads, thus RT and PCR reactions can be completed within a few hours of tissue harvest. This approach allows us to perform differential display on a single pine embryo. We describe strategies for distinguishing classes of co-migrating bands excised from differential display gels and outline a PCR-based method for confirming differential expression of large numbers of cloned bands in cases where RNA quantities are limiting.     

Isolation of developmentally regulated genes by differential display screening of cDNA libraries.

mRNA differential display RT-PCR has been extensively used for the isolation of genes differentially expressed between RNA populations. We have assessed its utility for the identification of developmentally regulated genes in plasmid cDNA libraries derived from individual tissues dissected from early mouse embryos. Using plasmid Southern blot hybridisation as a secondary screen, we are able to identify such genes and show by whole-mount in situ hybridisation that their expression pattern is that expected from the differential display profile.     

东亚砂藓取材部位对提取其总RNA及DDRT-PCR的影响

分别采用新鲜东亚砂藓植物体先端、基部及中部作为材料,采用改良的SDS法,提取及纯化三部分的总RNA。比较RNA产率、纯度及分析电泳图谱来确定适于东亚砂藓RNA分离的最佳部位。并运用mRNA差异显示方法比较了东亚砂藓不同部位的差异。实验结果显示,东亚砂藓植物体的先端适于其总RNA提取及mRNA差异显示的研究。     

mRNA差别显示技术分离草菇低温诱导基因*

本文报道采用改良的mRNA差别筛选法,通过选用3'锚定引物和18-25碱基的PCR随机引物组合,以琼脂糖凝胶电泳,EB显色替代聚丙烯酰胺凝胶电泳和放射自显影,对低温处理草菇(Volvariella volvacea)及正常草菇基因表达进行筛选、分析,结合RNA斑点杂交技术加以验证,分离得到70个草菇低温诱导DNA片段。     

mRNA差别显示技术分离草菇低温诱导基因

本文报道采用改良的mRNA差别筛选法,通过选用3'锚定引物和18-25碱基的PCR随机引物组合,以琼脂糖凝胶电泳,EB显色替代聚丙烯酰胺凝胶电泳和放射自显影,对低温处理草菇(Volvariella volvacea)及正常草菇基因表达进行筛选、分析,结合RNA斑点杂交技术加以验证,分离得到70个草菇低温诱导DNA片段。     

降低mRNA差异显示技术假阳性率的一种方法

为了探讨降低mRNA差异显示技术假阳性率的方法 ,进一步提高此技术的可靠性 ,提取了手术切除肝癌及非癌肝组织成对标本的总RNA ,逆转录获得cDNA片段 ,以mRNA差异显示方法筛选差异表达基因 ,选取较明显的一条差异表达条带 ,行进一步PCR扩增 .分别对PCR产物及其经TA克隆后随机挑选的 6个单克隆质粒DNA进行序列分析 ,并通过GenBank BLAST数据库进行序列的同源性比较 ,以Northern杂交予以来源确认 .自 72 0余条扩增条带中共选出 2 8条差异条带 .序列分析及同源性比较表明 ,所选择条带的PCR产物为一可能的新基因片段 ;而随机选择的 6个TA克隆质粒DNA中 ,有 4个为同一已知基因片段 ,一个为另一已知基因片段 ,一个为一可能的新基因片段 .同源性比较表明 ,PCR产物直接测序所得序列与TA克隆质粒DNA的 6个片段不具同源性 .结果表明 ,mRNA差异显示条带可能由 1条以上分子量相似的片段构成 ,直接对PCR产物行序列分析并以其为探针进行Northern杂交 ,是导致出现假阳性片段的原因之一 .将PCR产物进行TA克隆 ,对单克隆质粒DNA进行序列分析并以其为探针进行Northern杂交 ,可能是解决此问题的一种较好方法 .     

用DDRT-PCR方法克隆小鼠精子发生早期相关基因的EST

为了避免差异显示技术中的放射性污染 ,并用之于筛选、克隆精子发生早期的相关基因 ,分离纯化了小鼠的原始精原细胞及B型精原细胞 ,提取其总RNA ,逆转录获得cDNA ,以荧光差异显示方法筛选差异表达基因。利用斑点杂交技术对差异片段进行快速鉴定以排除假阳性。选取 16条差异显著的片段做克隆测序 ,通过Gen Bank/Blast比较 ,有 7个片段属于新的EST ,且均表现为在B型精原细胞中表达强度高于原始精原细胞。提交Gen Bank获得注册号。从中选取较有意义的 3条基因片段通过半定量RT PCR方法进一步验证其表达特征。和传统的差异显示方法比较 ,文中所采用的mRNA差异显示技术可快速排除假阳性结果 ,避免同位素标记带来的放射性污染。结果表明所获得的 7个新EST均表现为B型精原细胞中高表达 ,这些表达升高的基因可能与其后精子发生过程中的一系列特殊现象 (如减数分裂、变态成形 )有关 ,为生精细胞的分化做物质上的准备。     

Differential display

Characterization of regulated gene expression in eukaryotic cells is essential for studying cell growth and differentiation as well as for understanding the molecular mechanisms of diseases. Differential display was developed for such comparative studies by allowing a systematic and nonbiased screening for molecular differences at the level of mRNA expression between or among different cells or tissues. The essence of the method is to amplify messenger RNA 3′ termini using a pair of anchored oligo-dT primer and a short primer with an arbitrary sequence. The amplified cDNAs labeled with radioisotope are then distributed on a denaturing polyacrylamide gel and visualized by autoradiography. Side-by-side comparison of mRNA species from two or more related samples allows identification of both up- and downregulation genes of interest. Some of the most recent improvements have been incorporated into this general protocol for differential display.     

荧光标记mRNA差异显示技术

目的：应用荧光标记的ｍＢＮＡ差异显示技术。方法：提取未经过／经过ＩＦＮ－ＬＰＳ处理的三组人单核细胞系Ｕ９３７的总ＲＮＡ并以此为模板,采用荧光标记的锚定引物,通过逆转录、差异显示ＰＣＲ反应,经５．６％变性聚丙烯酰胺凝胶电泳分离差异条带,回收后将其再扩增。结果：三组样本的ＤＤ－ＰＣＲ产物电泳显示长３００ｂｐ￣２．０ｋｂ不等的扩增片段,条带清晰、明亮,背景低,各样本相互间的差异不仅呈有无的变化,亦表现出     

原核细胞mRNA差异显示技术的引物设计

由于原核细胞mRNA3'端不存在ploy(A)结构,因而原核细胞DDRT-PCR引物设计不同于真核细胞。尽管不能根据oligo(dT)设计引物,但利用全基因中高度分散重复的短序列或回文序列却能有效克服mRNA分子结构的影响,最大限度地扩增全长cDNA;并且这2种引物设计方法还可以提高RNA指纹图谱的重复性,降低反应的假阳性,从而为原核细胞DDRT-PCR引物设计提供新的思路。