Detection of protein-DNA interaction with a DNA probe: distinction between single-strand and double-strand DNA-protein interaction

A simple, direct method for the detection of DNA-protein interaction was developed with electrochemical methods. Single-stranded DNA (ss-DNA) probes were prepared through the chemical bonding of an oligonucleotide to a polymer film bearing carboxylic acid groups, and double-stranded DNA (ds-DNA) probes were prepared through hybridization of the complementary sequence DNA on the ss-DNA probe. Impedance spectroscopy and differential pulse voltammetry (DPV) distinguished the interaction between the DNA probes with mouse Purbeta (mPurbeta), an ss-DNA binding protein, and with Escherichia coli MutH, a ds-DNA binding protein. Impedance spectra obtained before and after the interaction of DNA probes with these proteins clearly showed the sequence-specific ss-DNA preference of mPurbeta and the sequence-specific ds-DNA preference of MutH. The concentration dependence of proteins on the response of the DNA probes was also investigated, and the detection limits of MutH and mPurbeta were 25 and 3 microg/ml, respectively. To confirm the impedance results, the variation of the current oxidation peak of adenine of the DNA probe was monitored with DPV. The formation constants of the complexes formed between the probe DNA and the proteins were estimated based on the DPV results.     

通过荧光标记的凝胶阻滞技术分析Opaque2蛋白与ZmGRAS11启动子的结合位点

凝胶阻滞实验（electrophoretic mobility shift assay，EMSA）是研究蛋白质与核酸结合的一种关键实验技术。EMSA技术兴起以来，使用放射性同位素、生物素标记核酸探针的手段已经非常成熟，但这两种传统的标记技术分别具有放射性探针稳定性差和生物素检测步骤复杂等缺点。近年来，尽管荧光标记探针逐渐被应用于EMSA中，但是对于利用荧光标记探针的EMSA仍缺乏系统的报道。对荧光标记的EMSA技术流程进行了优化和系统总结；利用6-羧基荧光素（6-carboxy-fluoroscine，FAM）标记ZmGRAS11启动子探针，通过EMSA检测其与Opaque2蛋白的结合，明确了蛋白和探针的适宜比例为8∶1。对GCN4 motif序列碱基进行突变并利用EMSA分析Opaque2与ZmGRAS11启动子之间的结合位点，结果表明GCN4 motif的“TGAC”核心基序在ZmGRAS11启动子与Opaque2蛋白的结合中可能起到了关键作用。研究结果为进一步探究Opaque2-ZmGRAS11转录调控模块在玉米籽粒发育中的作用机理提供了数据支撑。     

Detection of protein–DNA interaction with a DNA probe: distinction between single-strand and double-strand DNA–protein interaction

A simple, direct method for the detection of DNA–protein interaction was developed with electrochemical methods. Single-stranded DNA (ss-DNA) probes were prepared through the chemical bonding of an oligonucleotide to a polymer film bearing carboxylic acid groups, and double-stranded DNA (ds-DNA) probes were prepared through hybridization of the complementary sequence DNA on the ss-DNA probe. Impedance spectroscopy and differential pulse voltammetry (DPV) distinguished the interaction between the DNA probes with mouse Purβ (mPurβ), an ss-DNA binding protein, and with Escherichia coli MutH, a ds-DNA binding protein. Impedance spectra obtained before and after the interaction of DNA probes with these proteins clearly showed the sequence-specific ss-DNA preference of mPurβ and the sequence-specific ds-DNA preference of MutH. The concentration dependence of proteins on the response of the DNA probes was also investigated, and the detection limits of MutH and mPurβ were 25 and 3 μg/ml, respectively. To confirm the impedance results, the variation of the current oxidation peak of adenine of the DNA probe was monitored with DPV. The formation constants of the complexes formed between the probe DNA and the proteins were estimated based on the DPV results.     

Combining sequence-specific probes and DNA binding dyes in real-time PCR for specific nucleic acid quantification and melting curve analysis

Currently, in real-time PCR, one often has to choose between using a sequence-specific probe and a nonspecific double-stranded DNA (dsDNA) binding dye for the detection of amplified DNA products. The sequence-specific probe has the advantage that it only detects the targeted product, while the nonspecific dye has the advantage that melting curve analysis can be performed after completed amplification, which reveals what kind of products have been formed. Here we present a new strategy based on combining a sequence-specific probe and a nonspecific dye, BOXTO, in the same reaction, to take the advantage of both chemistries. We show that BOXTO can be used together with both TaqMan probes and locked nucleic acid (LNA) probes without interfering with the PCR. The probe signal reflect formation of target product, while melting curve analysis of the BOXTO signal reveals primer-dimer formation and the presence of any other anomalous products.     

Two human genes isolated by a novel method encode DNA-binding proteins containing a common region of homology

Two cDNAs encoding new DNA-binding proteins (Dbps) have been cloned using a human placenta lambda gt11 recombinant cDNA library and DNA fragments as probes. Hybrid proteins expressed by the lambda gt11 cDNA library were blotted onto nitrocellulose filters, and incubated with three different radio-labeled DNA probes containing the human epidermal growth factor (EGF) receptor enhancer or the human c-erbB-2 promoter. Two kinds of clones, named dbpA and dbpB, showed high affinities for the DNA probes. The comparison of the nucleotide and the deduced amino acid (aa) sequences between these two cDNAs indicated that 100 of 109 aa located in the central region of these two Dbps were identical. The dbpA and dbpB-coded proteins also had an affinity for other cDNA probes such as the human c-ski gene, but not for poly(dI-dC).poly(dI-dC), suggesting that the sequence(s) recognized by the dbpA and dbpB-coded proteins may occur frequently, or that these proteins bind to DNA non-specifically in a different manner from that of histones. A simple method, described in this paper, can be used to isolate cDNA clones encoding Dbps. Strategies used for the detection of sequence-specific and non-specific Dbps are discussed.     

A nonradioactive screening method for cloning genes encoding sequence-specific DNA binding proteins.

We have developed a novel nonradioactive screening method for cloning genes encoding sequence-specific DNA binding proteins. This method is derived from previously described protocols developed for the same purpose by using radioactively labeled DNA probes containing protein recognition sequences. This nonradioactive strategy relies upon the use of a small hapten, digoxigenin. Fusion proteins expressed from the recombinant bacteriophage lambda gt11/lambda ZAP are immobilized on nitrocellulose filters and probed with digoxigenin-labeled double-stranded DNA as a ligand. The specifically bound DNA probes can be detected through sequential incubations with antibody-enzyme conjugate and enzyme substrates. This technique has been successfully utilized to isolate several cDNA clones encoding DNA binding proteins.     

改造地高辛标记DNA和检测试剂盒用于凝胶阻滞实验的新方法

凝胶阻滞实验（gel retardation）,又称为电泳迁移率变动实验（Electrophoretic mobility shift assay,EMSA）,是研究蛋白和DNA相互作用的一种技术。传统的³²P标记探针的凝胶阻滞实验,具有很高的灵敏度,然而也有接触危险性的放射性同位素且不容易定量分析的缺点。最近利用非放射性标记的凝胶阻滞实验,已有很多成功的报导,该方法快捷,安全,灵活,但非放射性标记探针的凝胶阻滞试剂盒的费用却很高。在论文中,我们提供了一种改造地高辛标记DNA和检测试剂盒用于凝胶阻滞实验的新方法。首先将双链DNA探针末端引入EcoRI 粘性末端以便进行3′末端标记,然后利用价格比较便宜的地高辛标记DNA和检测试剂盒(DIG High Prime DNA Labeling and Detection Starter Kit II, Rohe) 进行探针标记和凝胶阻滞信号检测。经过多次实验参数的摸索,最终得到了成功的结果,为利用地高辛标记DNA和检测试剂盒进行凝胶阻滞实验提供了成功的例子和方法。      

Characterization of DNA sequence-common and sequence-specific proteins binding to cis-acting sites for cleavage of the terminal a sequence of the herpes simplex virus 1 genome.

The terminal 500-base-pair alpha sequence of the herpes simplex virus 1 genome contains signals for cleavage (Pac1 and Pac2) of unit-length DNA molecules from concatemers in unique stretches of sequences designated Ub and Uc, respectively, and a cis site for cleavage designated DR1. We report that nuclear extracts from infected cells contain factors which form two DNA-virus-specific protein complexes with components of the a sequence. Purification of the factors forming the V2 complex yielded a protein with an apparent molecular weight of 82,000 binding to DNA in a non-sequence-specific manner. Addition of Mg2+ to the purified protein-DNA probe mixture resulted in exonucleolytic degradation of the DNA. The protein was identified as the virus-specific DNase with monoclonal antibody specific for the viral enzyme. The purification of the proteins forming the V4 complex yielded two proteins with molecular weights of greater than 250,000 and 140,000 corresponding to infected cell protein 1 and to an as yet unidentified protein, respectively. These proteins formed two DNA sequence-common bands with a number of DNA probes and one sequence-specific band with probes containing both Pac2 and DR1 but not with probes containing either site alone or Pac1 and DR1. Since the DNA probe containing Pac2 and DR1 inserted into viral genome or into amplicons induced specific cleavage of the DR1 sequence whereas the nonreactive probes failed to induce the cleavage, the formation of this sequence-specific DNA-protein complex is significant and may reflect a DNA-protein interaction essential for cleavage. The possible role of the proteins identified in this study for the cleavage-packaging of viral DNA into capsids is presented.     

Purification methods for the sequence-specific DNA-binding protein nuclear factor I (NFI)--generation of protein sequence information

The paper describes a potent purification method, preparative gel retention, for the purification of sequence-specific DNA-binding proteins. This procedure exploits the sequence-specific DNA-binding affinity of such proteins for their enrichment, comparable to recognition site DNA affinity chromatography. The method was employed to obtain a pure preparation of nuclear factor I (NFI) from porcine liver from which sequences of partial peptides could be obtained. Oligonucleotide probes derived from these amino-acid sequences were used to identify genomic and cDNA clones of NFI.     

Purification methods for the sequence-specific DNA-binding protein nuclear factor I (NFI) — Generation of protein sequence information

The paper describes a potent purification method, preparative gel retention, for the purification of sequence-specific DNA-binding proteins. This procedure exploits the sequence-specific DNA-binding affinity of such proteins for their enrichment, comparable to recognition site DNA affinity chromatography. The method was employed to obtain a pure preparation of nuclear factor I (NFI) from porcine liver from which sequences of partial peptides could be obtained. Oligonucleotide probes derived from these amino-acid sequences were used to identify genomic and cDNA clones of NFI.     

Detection of ubiquitin-proteasome enzymatic activities in cells: Application of activity-based probes to inhibitor development

Background: Synthetic probes that mimic natural substrates can enable the detection of enzymatic activities in a cellular environment. One area where such activity-based probes have been applied is the ubiquitin-proteasome pathway, which is emerging as an important therapeutic target. A family of reagents has been developed that specifically label deubiquitylating enzymes (DUBs) and facilitate characterization of their inhibitors. Scope of review: Here we focus on the application of probes for intracellular DUBs, a group of specific proteases involved in the ubiquitin proteasome system. In particular, the functional characterization of the active subunits of this family of proteases that specifically recognize ubiquitin and ubiquitin-like proteins will be discussed. In addition we present the potential and design of activity-based probes targeting kinases and phosphatases to study phosphorylation. Major conclusions: Synthetic molecular probes have increased our understanding of the functional role of DUBs in living cells. In addition to the detection of enzymatic activities of known members, activity-based probes have contributed to a number of functional assignments of previously uncharacterized enzymes. This method enables cellular validation of the specificity of small molecule DUB inhibitors. General significance: Molecular probes combined with mass spectrometry-based proteomics and cellular assays represent a powerful approach for discovery and functional validation, a concept that can be expanded to other enzyme classes. This addresses a need for more informative cell-based assays that are required to accelerate the drug development process. This article is part of a Special Issue entitled: Ubiquitin Drug Discovery and Diagnostics.     

Poly C binding protein, a single-stranded DNA binding protein, regulates mouse mu-opioid receptor gene expression

Previously, a single-stranded (ss) DNA element, polypyrimidine (PPy) element, was found to be important for the proximal promoter activity of mouse micro-opioid receptor (MOR) gene in a neuronal cell model. In this study, we identified the presence of unknown ssDNA binding proteins specifically bound to MOR ssPPy element in the mouse brain, implicating the physiological significance of these proteins. To identify the ssDNA binding proteins, yeast one-hybrid system with PPy element as the bait was used to screen a mouse brain cDNA library. The clone encoding poly C binding protein (PCBP) was obtained. Its full-length cDNA sequence and protein with molecular weight approximately 38 kDa were confirmed. Electrophoretic mobility shift analysis (EMSA) revealed that PCBP bound to ssPPy element, but not doubled-stranded, in a sequence-specific manner. EMSA with anti-PCBP antibody demonstrated the involvement of PCBP in MOR ssPPy/proteins complexes of mouse brain and MOR expressing neuroblastoma NMB cells. Functional analysis showed that PCBP trans-activated MOR promoter as well as a heterologous promoter containing MOR PPy element. Importantly, ectopic expression of PCBP in NMB cells up-regulated the expression level of endogenous MOR gene in vivo in a dose-dependent manner. Collectively, above results suggest that PCBP participates in neuronal MOR gene expression.