Linear dynamic range for signal detection in fluorescent differential display

We have determined the linear dynamic range in signal detection by Fluorescent Differential Display (FDD) using conditionally induced mRNA expression of the p53 tumor-suppressor gene as a control. By serial spiking of p53-induced RNA into that of non-induced RNA, we were able to quantitatively measure up to 100-fold change in p53 mRNA expression level. The linear dynamic range of signal detection per mRNA message was determined to be from 1000 up to 20,000 in fluorescence signal, in which the signals for the majority of mRNAs reside. Thus, FDD can be used to accurately quantify differences in mRNA expression among eukaryotic cells.     

Male specific genes from dioecious white campion identified by fluorescent differential display

Fluorescent differential display (FDD) has been used to screen for cDNAs that are differentially up-regulated in male flowers of the dioecious plant Silene latifolia in which an X/Y chromosome system of sex determination operates. To adapt FDD to the cloning of large numbers of differential cDNAs, a novel method of confirming the differential expression of these has been devised. FDD gels were Southern electro-blotted and probed with mixtures of individual cDNA clones derived from different FDD product ligation reactions. These Southern blots were then stripped and re-probed with further mixtures of individual cloned FDD products to identify the maximum number of recombinant clones carrying the true differential amplification products. Of 135 differential bands identified by FDD, 56 differential amplification products were confirmed; these represent 23 unique differentially expressed genes as determined by virtual Northern analysis and two genes expressed at or below the level of detection by virtual Northern analysis. These two low expressed genes show bands of hybridization on genomic Southern blots that are specific to male plants, indicating that they are derived from, or closely related to, Y chromosome genes.     

mRNA差异显示

分离差异表达的基因是研究生命调节过程的重要手段,mRNA差异显示技术是一种能成功分离差异表达基因的方法,文章对该方法的基本原理、方法步骤及其应用作了较为详细的介绍。     

限制性酶切片段差异显示及其应用

差异显示技术(DD)-PCR是一种研究基因表达差异的重要而应用广泛的方法,传统的差异显示法由于在PCR时采用Poly（T）引物和随机引物而导致较高的假阳性率和产物的近Poly(A)非编码区的大量扩增。改进后的限制性酶切片段差异显示技术(RFDD)-PCR采用ToqI酶切双链cDNA,连上特殊设计的接头,再用经特殊设计的特异性配对于接头的引物来扩增,因此能重点扩增编码区并能极大地消除假阳性率。由于扩增时引物就带有荧光或放射性核素标记,还使得差异显示条带的检测更为方便、灵敏。本简要介绍了该法的原理、步骤、应用及其优缺点。     

A protocol for differential display of mRNA expression using either fluorescent or radioactive labeling

Since its invention in the early 1990s, differential display (DD) has become one of the most commonly used techniques for identifying differentially expressed genes at the mRNA level. Unlike other genomic approaches, such as DNA microarrays, DD systematically detects changes in mRNA profiles among multiple samples being compared without the need of any prior knowledge of genomic information of the living organism being studied. Here, we present an optimized DD protocol with a fluorescent digital readout as well as traditional radioactive labeling. The resulting streamlined fluorescent DD process offers an unprecedented accuracy, sensitivity and throughput in comprehensive and quantitative analysis of eukaryotic gene expression. Results usually can be obtained within days using a limited number of primer combinations, but a comprehensive DD screen may take weeks or months to accomplish, depending on gene coverage required and the number of differentially expressed genes present within a biological system being compared.     

Cytokinin-induced gene expression in cultured green cells of Nicotiana tabacum identified by fluorescent differential display

The cell growth and plastid development of cultured green tobacco cells were maintained by the phytohormone cytokinin. After subculture into cytokinin-free medium, when cytokinin treatment was resumed, physiological changes induced by cytokinin were analyzed. Changes in chlorophyll biosynthesis and photosynthetic gene expression were observed 1 week after cytokinin induction, and changes in cell growth were observed 2 weeks after cytokinin induction. Two cytokinin-induced genes (cig) were isolated from these cells using the fluorescent differential display technique. Northern analysis confirmed that expression of these cig was induced by both natural and synthetic cytokinins. The expression of cig1 was also induced by abscisic acid, and its cDNA sequence was similar to the proline dehydrogenase gene. The expression of cig2 is specific to cytokinin and is not induced by other phytohormones. The amino acid sequence encoded by cig2 is similar to the GDP/GTP exchange factor eIF2B, which regulates translation initiation. The expression of these cig suggests a complex induction system involving cytokinin and other phytohormones.     

通过荧光差异显示PCR法分离水稻中由ABA调节的基因

脱落酸（ABA）在植物种子发育以及植物地外源环境因子（如逆境,胁迫等）反应过程中起着重要的作用,对其调节基因的分离将有助于了解其相关信号传导途径及作用机制。通过荧光差异显示PCR法我们由水稻中分离了部分ABA调节的cDNA片段,在所分离克隆的17个片段中,有14个片段被ABA诱导（2,4,8,12h),有2个片段被ABA抑制（8h),测序及序列分析表明这些片段可能分别编码与植物光合作用（7）,信号传导（1）,转录调控（2）,代谢（6）相关的蛋白或未知蛋白（1）而且其表达可能受到ABA的调节或ABA参与了其作用,对其中可能编码α/β水解酶折叠蛋白,酪氨酸磷酸酶,液泡H^ -ATPase的mRNA进行的RT－PCR和Northern blot分析,确证了ABA对它们表达的调节作用。在此基础上对FDD－PCR技术及ABA作用的可能机制进行了讨论。     

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.     

mRNA差异显示条件的优化

运用优化的mRNA差异显示技术分离受内生真菌诱导的差异基因。优化差异显示条件表现在增如指定引物和随机引物的长度、改变PCR参数和再扩增程序、运用银染显色等。应用这些条件共获得7个阳性差异片段。用未优化的PCR程序1筛选35条差异带,得到3个两端均为随机引物的差示片段。而用优化的PCR程序2,52条差异带中得到9条只能用锚定引物和随机引物才能扩增出的片段。地高辛标记的反向-Northern鉴定为阳性后进行克隆和测序。PCR方法1所得的3个差示片段均无开放的阅读框。PCR程序2得到7个差异表达的基因中,2个为已知基因,5个为未知基因。因此可运用优化的差显技术分离差异表达的基因。     

A decade of differential display

It has been 10 years since the invention of differential display (DD), a conceptually simple methodology that allows the detection and identification of differentially expressed genes. In the past decade, the number of publications describing successful applications of DD has outnumbered those using any other competing methodologies, including subtractive hybridization, representational difference analysis, serial analysis of gene expression, and DNA microarrays. This review will provide a glimpse of the current progress made in DD technological development, refinement, and automation. Excellent examples of DD applications in studying a variety of biological problems, in such diverse biological systems as bacteria, yeast, flies, plants, and higher mammals, are presented to provide a roadmap for those who would like to pursue a fruitful gene "fishing" expedition. Some of the fundamental differences between DD and DNA microarrays are also discussed.     

Isolation of rice genes possibly involved in the photoperiodic control of flowering by a fluorescent differential display method

To better understand the molecular mechanisms of the photoperiodic regulation of rice, a short-day plant, we isolated 27 cDNAs that were differentially expressed in the photoperiod-insensitive se5 mutant from approximately 8,400 independent mRNA species by the use of a fluorescent differential display (FDD). For this screening, we isolated mRNAs at five different time points during the night and compared their expression patterns between se5 and the wild type. Of 27 cDNAs isolated, 12 showed diurnal expression patterns often associated with genes involved in the determination of the flowering time. In se5, expression of nine cDNAs was increased. Five of these cDNAs were up-regulated under SD, suggesting that they may promote flowering under SD. They included genes encoding a cDNA containing a putative NAC domain, the fructose-bisphosphate aldolase, and a protease inhibitor. Expression of three cDNAs was decreased in se5 but not photoperiodically regulated. These cDNAs included a rice homolog of Arabidopsis GIGANTEA (GI), lir1, and a gene for myo-inositol 1-phosphate synthase, all of which were previously shown to be under the control of circadian clocks. The expression patterns of the rice homolog of GI, OsGI, were similar to those of the Arabidopsis GI, suggesting the conservation of some mechanisms for the photoperiodic regulation of flowering between these two species.     

Identification of the cDNA of differentially expressed genes in the transition zone of cucumber seedlings by fluorescent differential display.

Cucumber seedlings have potential to develop two pegs on the transition zone between the hypocotyl and root. Seedlings grown in a horizontal position suppress the development of the peg on the upper side of the transition zone in response to gravity. To understand how the response to gravity suppresses peg formation, we screened cucumber mRNAs to identify the mRNA in the non-peg side that accumulates more than in the peg side. For screening, we determined conditions of fluorescent differential display (FDD). Then, we carried out FDD and found 4 cDNA bands that repeatedly showed stronger intensity in the non-peg side than the peg side. We isolated one of these RT-PCR products. Northern blotting showed the pattern of its mRNA accumulations corresponding to the results of FDD.     

Cloning oncogenic ras-regulated genes by differential display

The coordinated regulation of gene expression is a key cellular function that specifies cell characteristics as well as controls normal physiological processes of the organism. Deregulation of this gene expression leads to a variety of abnormal conditions such as cancer. The ras oncogene is one of the most frequently found mutations in various types of human cancer. The mutated Ras protein constitutively elicits multiple mitogenic signals to the nucleus to alter gene expression of target genes that are involved in a broad range of normal cellular functions. Thus the identification of these genes may provide an important tool toward the understanding of these pathogenic processes. As a first step to reveal these processes at the molecular level and to dissect the key pathway employed by oncogenic Ras protein, we have looked for its target genes in rodent model cell lines using the differential display method. Our initial screening has isolated a number of genes either up- or downregulated by oncogenic ras activation. Although the functional analyses of these genes in terms of ras-mediated cell transformation will be the major challenge, differential display has come to be a very efficient tool that helped us move to the next step. In this short report, we focus primarily on the technical aspects of differential display and experimental designs used in this study.