Immunocytochemistry and in situ hybridization in the electron microscope: combined application in the study of virus-infected cells

The present review evaluates methods for electron microscopic immunocytochemistry and in situ hybridization, using post-embedding techniques and colloidal gold as a label. Special emphasis is given to double labeling immunocytochemistry and double in situ hybridization and to their combined application on the same specimen. Brief guidelines are presented for fixation, embedding media, the use of polyclonal and monoclonal antibodies and nucleic acid probes. Conditions for labeling and binding of antibody and nucleic acid probes to the target and protocols for direct and indirect immunodetection are discussed. Combinations of direct and indirect immunodetections in multiple labeling experiments are summarized.     

Conjugated polyelectrolytes for label-free DNA microarrays

Classical strategies for gene microarrays require labeling of probes or target nucleic acids with signaling molecules, a process that is expensive, time consuming and not always reliable. Bazan and colleagues showed that a nucleic acid-binding cationic conjugated polyelectrolyte can be used in label-free DNA microarrays based on surfaces modified with neutral peptide nucleic acid (PNA) probes. This technique provides a simple and sensitive method for DNA detection without the need for covalent labeling of target DNA.     

Preparation of horseradish peroxidase-labeled probes

The direct labeling of nucleic acid probes, with horseradish peroxidase (HRP) may be used in many membrane hybridization applications, including Southern blots, Northern blots, colony and plaque screening, PCR products detection/identification. This article describes the preparation method, which involves the labeling of a single-stranded nucleic acid probe with a positively charged HRP-parabenzoquinonepolyethyleneimine complex (labeling reagent). The associated hybridization and posthybridization protocols are relatively simple, which makes probes labeled directly with HRP particularly suitable for large scale screening, where tens or hundreds of blots are processed weekly.     

Radical-generating coordination complexes as tools for rapid and effective fragmentation and fluorescent labeling of nucleic acids for microchip hybridization

DNA microchip technology is a rapid, high-throughput method for nucleic acid hybridization reactions. This technology requires random fragmentation and fluorescent labeling of target nucleic acids prior to hybridization. Radical-generating coordination complexes, such as 1,10-phenanthroline-Cu(II) (OP-Cu) and Fe(II)-EDTA (Fe-EDTA), have been commonly used as sequence nonspecific "chemical nucleases" to introduce single-strand breaks in nucleic acids. Here we describe a new method based on these radical-generating complexes for random fragmentation and labeling of both single- and double-stranded forms of RNA and DNA. Nucleic acids labeled with the OP-Cu and the Fe-EDTA protocols revealed high hybridization specificity in hybridization with DNA microchips containing oligonucleotide probes selected for identification of 16S rRNA sequences of the Bacillus group microorganisms.We also demonstrated cDNA- and cRNA-labeling and fragmentation with this method. Both the OP-Cu and Fe-EDTA fragmentation and labeling procedures are quick and inexpensive compared to other commonly used methods. A column-based version of the described method does not require centrifugation and therefore is promising for the automation of sample preparations in DNA microchip technology as well as in other nucleic acid hybridization studies.     

Site-specific labeling of RNA with fluorophores and other structural probes

Site-specific probes provide a powerful tool for structure and function studies of nucleic acids, especially in elucidating tertiary structures of large ribozymes and other folded RNA molecules. Among many types of extrinsic labels, fluorophores are most attractive because they can provide structural information at millisecond time resolution, thus allowing real-time observation of structural transition during biological function. Methods for introducing fluorophores in RNA molecules are summarized here. These methods are robust and readily applicable to the labeling of other types of probes. However, as each case of RNA modification is unique, fine tuning of the general methodology is beneficial.     

Preparation of nonradioactive probes for in situ hybridization

In situ hybridization (ISH) enables the precise localization of RNA targets and provides an avenue to study the temporal and spatial patterns of expression of specific genes. ISH has evolved from being an esoteric technique to one that is routinely used by researchers in many areas of research. A major driving force has been the development of numerous nonisotopic labeling and signal detection methods. Historically, radioactive probes and autoradiography provided sensitivity that was unattainable with nonisotopic probes. But the long exposure times required for signal detection and the perceived dangers associated with radioactivity limit its use. Advances in nonisotopic detection systems have overcome many of the limitations associated with using radiolabeled probes. One of the most significant contributions from nonisotopic methods is the ability to discriminate between multiple nucleic acid sequences simultaneously.     

Alkaline phosphatase inhibitors as labels of DNA probes

A new approach to nucleic acid labeling was developed by preparing bifunctional reagents containing, in addition to the DNA-linking group, a competitive inhibitor of the chromogenic enzyme alkaline phosphatase. The nucleic acids labeled in such a way were able to bind themselves to the enzyme, whose activity was restored in the presence of a chromogenic substrate. Five phosphonic-acid-containing reagents were synthesized and coupled to linearized pBR322 plasmid DNA by different condensation methods. Eight probes thus obtained were assayed in a modified dot-blot detection procedure obtaining the best nucleic acid detection sensitivity of 25 pg. Finally, five of the above probes were tested in hybridization experiments, reaching sensitivity of 50 pg.     

Nanostructured luminescently labeled nucleic acids

Important and emerging trends at the interface of luminescence, nucleic acids and nanotechnology are: (i) the conventional luminescence labeling of nucleic acid nanostructures (e.g. DNA tetrahedron); (ii) the labeling of bulk nucleic acids (e.g. single‐stranded DNA, double‐stranded DNA) with nanostructured luminescent labels (e.g. copper nanoclusters); and (iii) the labeling of nucleic acid nanostructures (e.g. origami DNA) with nanostructured luminescent labels (e.g. silver nanoclusters). This review surveys recent advances in these three different approaches to the generation of nanostructured luminescently labeled nucleic acids, and includes both direct and indirect labeling methods.     

Effective and site-specific phosphoramidation reaction for universally labeling nucleic acids

Here we report efficient and selective postsynthesis labeling strategies, based on an advanced phosphoramidation reaction, for nucleic acids of either synthetic or enzyme-catalyzed origin. The reactions provided phosphorimidazolide intermediates of DNA or RNA which, whether reacted in one pot (one-step) or purified (two-step), were directly or indirectly phosphoramidated with label molecules. The acquired fluorophore-labeled nucleic acids, prepared from the phosphoramidation reactions, demonstrated labeling efficacy by their F/N ratio values (number of fluorophores per molecule of nucleic acid) of 0.02–1.2 which are comparable or better than conventional postsynthesis fluorescent labeling methods for DNA and RNA. Yet, PCR and UV melting studies of the one-step phosphoramidation-prepared FITC-labeled DNA indicated that the reaction might facilitate nonspecific hybridization in nucleic acids. Intrinsic hybridization specificity of nucleic acids was, however, conserved in the two-step phosphoramidation reaction. The reaction of site-specific labeling nucleic acids at the 5′-end was supported by fluorescence quenching and UV melting studies of fluorophore-labeled DNA. The two-step phosphoramidation-based, effective, and site-specific labeling method has the potential to expedite critical research including visualization, quantification, structural determination, localization, and distribution of nucleic acids in vivo and in vitro.     

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。     

DNA Probes: Applications of the Principles of Nucleic Acid Hybridization

Abstract

Nucleic acid hybridization with a labeled probe is the only practical way to detect a complementary target sequence in a complex nucleic acid mixture. The first section of this article covers quantitative aspects of nucleic acid hybridization thermodynamics and kinetics. The probes considered are oligonucleotides or polynucleotides, DNA or RNA, single- or double-stranded, and natural or modified, either in the nucleotide bases or in the backbone. The hybridization products are duplexes or triplexes formed with targets in solution or on solid supports. Additional topics include hybridization acceleration and reactions involving branch migration. The second section deals with synthesis or biosynthesis and detection of labeled probes, with a discussion of their sensitivity and specificity limits. Direct labeling is illustrated with radioactive probes. The discussion of indirect labels begins with biotinylated probes as prototypes. Reporter groups considered include radioactive, fluorescent, and chemiluminescent nucleotides, as well as enzymes with colorimetric, fluorescent, and luminescent substrates.     

DNA probes: applications of the principles of nucleic acid hybridization.

Nucleic acid hybridization with a labeled probe is the only practical way to detect a complementary target sequence in a complex nucleic acid mixture. The first section of this article covers quantitative aspects of nucleic acid hybridization thermodynamics and kinetics. The probes considered are oligonucleotides or polynucleotides, DNA or RNA, single- or double-stranded, and natural or modified, either in the nucleotide bases or in the backbone. The hybridization products are duplexes or triplexes formed with targets in solution or on solid supports. Additional topics include hybridization acceleration and reactions involving branch migration. The second section deals with synthesis or biosynthesis and detection of labeled probes, with a discussion of their sensitivity and specificity limits. Direct labeling is illustrated with radioactive probes. The discussion of indirect labels begins with biotinylated probes as prototypes. Reporter groups considered include radioactive, fluorescent, and chemiluminescent nucleotides, as well as enzymes with colorimetric, fluorescent, and luminescent substrates.     

Enhanced chemiluminescence for the detection of membrane-bound nucleic acid sequences: advantages of the Amersham system.

A range of nonradioactive nucleic acid labeling and detection systems have been developed that enable the user to label probes directly with enzyme molecules or indirectly with hapten-derivatized nucleotides. Horseradish peroxidase is used for the direct labeling procedures due to the ease of chemical modification and the relative thermal and chemical stability of this enzyme. Horseradish peroxidase has also been conjugated to a high-specificity antifluorescein antibody for detection of hapten (fluorescein)-labeled hybrids. Enhanced chemiluminescence is a light-emitting process optimized for the detection of low levels of horseradish peroxidase on membrane supports. Results are obtained as hard copy images on x-ray film.     

Oligonucleotide derivatives in the hybridization analysis of nucleic acids: II. Isothermal signal amplification in DNA analysis by minisequencing

An isothermal amplification of a reporter signal during the analysis of the hybridization of nucleic acids was studied by limited probe extension (minisequencing). The intensity of the reporter signal was shown to increase due to the multiple enzymatic labeling of the probes during consecutive hybridization with one DNA template in both the homophase and heterophase assays using various detection methods: radioisotope or fluorescent labeling or enzyme-linked assay. The kinetic scheme of the process was proposed and the kinetic parameters for each step were evaluated. It was shown that the signal intensity correlated with the physicochemical characteristics for probe/DNA and product/DNA complexes. The maximum intensity was observed at the minimal difference between the thermodynamic stability of these complexes, provided that the reaction temperature was close to their melting temperature values; increasing or decreasing the reaction temperature led to a decrease in the amount of the reporting product. The signal intensity is significantly reduced when the analyzed DNA contains single-nucleotide discrepancies. The limited probe extension assay is useful not only for the detection of analyzed DNA, but also for its quantitative characterization.     

Locked nucleic acid flow cytometry-fluorescence in situ hybridization (LNA flow-FISH): a method for bacterial small RNA detection

Fluorescence in situ hybridization (FISH) is a powerful technique that is used to detect and localize specific nucleic acid sequences in the cellular environment. In order to increase throughput, FISH can be combined with flow cytometry (flow-FISH) to enable the detection of targeted nucleic acid sequences in thousands of individual cells. As a result, flow-FISH offers a distinct advantage over lysate/ensemble-based nucleic acid detection methods because each cell is treated as an independent observation, thereby permitting stronger statistical and variance analyses. These attributes have prompted the use of FISH and flow-FISH methods in a number of different applications and the utility of these methods has been successfully demonstrated in telomere length determination, cellular identification and gene expression, monitoring viral multiplication in infected cells, and bacterial community analysis and enumeration. Traditionally, the specificity of FISH and flow-FISH methods has been imparted by DNA oligonucleotide probes. Recently however, the replacement of DNA oligonucleotide probes with nucleic acid analogs as FISH and flow-FISH probes has increased both the sensitivity and specificity of each technique due to the higher melting temperatures (T(m)) of these analogs for natural nucleic acids. Locked nucleic acid (LNA) probes are a type of nucleic acid analog that contain LNA nucleotides spiked throughout a DNA or RNA sequence. When coupled with flow-FISH, LNA probes have previously been shown to outperform conventional DNA probes and have been successfully used to detect eukaryotic mRNA and viral RNA in mammalian cells. Here we expand this capability and describe a LNA flow-FISH method which permits the specific detection of RNA in bacterial cells (Figure 1). Specifically, we are interested in the detection of small non-coding regulatory RNA (sRNA) which have garnered considerable interest in the past few years as they have been found to serve as key regulatory elements in many critical cellular processes. However, there are limited tools to study sRNAs and the challenges of detecting sRNA in bacterial cells is due in part to the relatively small size (typically 50-300 nucleotides in length) and low abundance of sRNA molecules as well as the general difficulty in working with smaller biological cells with varying cellular membranes. In this method, we describe fixation and permeabilzation conditions that preserve the structure of bacterial cells and permit the penetration of LNA probes as well as signal amplification steps which enable the specific detection of low abundance sRNA (Figure 2).     

Comparison of different labeling methods for the production of labeled target DNA for microarray hybridization

Different labeling methods were studied to compare various approaches to the preparation of labeled target DNA for microarray experiments. The methods under investigation included a post-PCR labeling method using the Klenow fragment and a DecaLabel DNA labeling kit, the use of a Cy3-labeled forward primer in the PCR, generating either double-stranded or single-stranded PCR products, and the incorporation of Cy3-labeled dCTPs in the PCR. A microarray that had already been designed and used for the detection of microorganisms in compost was used in the study. PCR products from the organisms Burkholderia cepacia and Staphylococcus aureus were used in the comparison study, and the signals from the probes for these organisms analyzed. The highest signals were obtained when using the post-PCR labeling method, although with this method, more non-specific hybridizations were found. Single-stranded PCR products that had been labeled by the incorporation of a Cy3-labeled forward primer in the PCR were found to give the next highest signals upon hybridization for a majority of the tested probes, with less non-specific hybridizations. Hybridization with double-stranded PCR product labeled with a Cy3-labeled forward primer, or labeled by the incorporation of Cy3-labeled dCTPs resulted in acceptable signal to noise ratios for all probes except the UNIV 1389a and Burkholderia genus probes, both located toward the 3' end of the 16S rRNA gene. The comparison of the different DNA labeling methods revealed that labeling via the Cy3-forward primer approach is the most appropriate of the studied methods for the preparation of labeled target DNA for our purposes.     

A streptavidin paramagnetic-particle based competition assay for the evaluation of the optical selectivity of quadruplex nucleic acid fluorescent probes

Although quadruplex nucleic acids are thought to be involved in many biological processes, they are massively overwhelmed by duplex DNA in the cell. Small molecules, able to probe quadruplex nucleic acids with high optical selectivity, could possibly achieve the visualization of these processes. The aim of the method described herein is to evaluate quickly the optical selectivity of quadruplex nucleic acid probes, in isothermal conditions, using widely available materials, small quantities of oligonucleotides and virtually any kind and quantity of biological competitor. The assay relies on the use of streptavidin-coated paramagnetic particles and biotinylated quadruplex forming oligonucleotides, allowing a quick and easy separation of the quadruplex target from the competitor. In the present study, two quadruplex nucleic acids (the DNA and RNA human telomeric repeats) have been used as targets while a duplex DNA oligonucleotide, total DNA, total RNA, another quadruplex nucleic acid and a protein have been used as competitors. The optical selectivity of various probes, displaying different photophysical properties and binding selectivities, has been successfully examined, allowing the identification of a best candidate for further cell microscopy experiments. This assay allows a quick and reliable assessment of the labeling properties of a quadruplex binder in cellular environment conditions. It is an interesting alternative to gel electrophoresis experiments since it is performed in solution, has a well-resolved separation system and allows easy quantifications.