The effect of avidin-biotin interactions in detection systems for in situ hybridization.

The effect of avidin-biotin interactions in several detection systems for the non-radioactive in situ hybridization (ISH) technique was studied in a model system using a transitional cell carcinoma line and a biotinylated DNA probe. We performed fluorescence ISH to unravel the individual steps in a sensitive and frequently used amplification method which makes use of the alternating cytochemical detection layers of fluorescein isothiocyanate-conjugated avidin (AvFITC) and biotinylated goat anti-avidin (BioGAA) antibodies to detect the hybridized and biotinylated probe. Our experiments revealed that BioGAA antibodies bind with their antigen binding sites and not with their biotin moieties to avidin molecules that have already interacted with the DNA probe. The probable working mechanism of this amplification method is presented in a model. Furthermore, we used a peroxidase staining technique to compare with each other the sensitivity of several other detection systems in which avidin-biotin interactions play an important role, e.g., the avidin-biotinylated peroxidase complex (ABC) system. The experiments show that avidin molecules can not be efficiently used to interconnect two biotinylated molecular layers, since their introduction leads to firmly closed cytochemical networks. Such a closed network is already formed between the hybridized and biotinylated DNA probe and a first detection layer of avidin molecules, as appears from the finding that biotinylated molecules could hardly be coupled to these avidin molecules in a following detection layer. Therefore, the results presented here provide us with new insight into the molecular basis of cytochemical network formation. This will enable us to choose the proper procedures for increasing the sensitivity of ISH detection systems.     

Detection of viral infection and gene expression in clinical tissue specimens using branched DNA (bDNA) in situ hybridization.

In situ hybridization (ISH) methods for detection of nucleic acid sequences have proved especially powerful for revealing genetic markers and gene expression in a morphological context. Although target and signal amplification technologies have enabled researchers to detect relatively low-abundance molecules in cell extracts, the sensitive detection of nucleic acid sequences in tissue specimens has proved more challenging. We recently reported the development of a branched DNA (bDNA) ISH method for detection of DNA and mRNA in whole cells. Based on bDNA signal amplification technology, bDNA ISH is highly sensitive and can detect one or two copies of DNA per cell. In this study we evaluated bDNA ISH for detection of nucleic acid sequences in tissue specimens. Using normal and human papillomavirus (HPV)-infected cervical biopsy specimens, we explored the cell type-specific distribution of HPV DNA and mRNA by bDNA ISH. We found that bDNA ISH allowed rapid, sensitive detection of nucleic acids with high specificity while preserving tissue morphology. As an adjunct to conventional histopathology, bDNA ISH may improve diagnostic accuracy and prognosis for viral and neoplastic diseases.     

Amplification methods to increase the sensitivity of in situ hybridization: play card(s).

In situ hybridization (ISH) has proved to be an invaluable molecular tool in research and diagnosis to visualize nucleic acids in their cellular environment. However, its applicability can be limited by its restricted detection sensitivity. During the past 10 years, several strategies have been developed to improve the threshold levels of nucleic acid detection in situ by amplification of either target nucleic acid sequences before ISH (e.g., in situ PCR) or the detection signals after the hybridization procedures. Here we outline the principles of tyramide signal amplification using the catalyzed reporter deposition (CARD) technique, present practical suggestions to efficiently enhance the sensitivity of ISH with CARD, and discuss some applications and possible future directions of in situ nucleic acid detection using such an amplification strategy.     

Co-labeling using in situ PCR: a review.

In situ amplification permits the histological localization of low-copy DNA and RNA targets. However, in many instances it would be useful to know the specific phenotype of the target-containing cell or to ascertain the distribution of a different nucleic acid sequence in the same tissue section. This review describes a methodology that allows co-in situ localization of two nucleic acid targets or a DNA/RNA sequence and a protein in paraffin-embedded, formalin-fixed tissue. The key variable for detection of low-copy RNA targets by RT in situ PCR is optimal protease digestion to permit cDNA target-specific incorporation of the reporter nucleotide. This is achieved via inactivation of nonspecific DNA synthesis by overnight DNase digestion. The key variable for immunohistochemical localization of proteins is to determine the effect of protease digestion on the antigen-based signal intensity. Background for DNA targets by in situ hybridization or, for targets present in 1-10 copies per cell, PCR ISH is dependent primarily on probe concentration and the stringency of the post-hybridization wash. Radioactive 3H-labeled nucleotides permit an excellent distinction with colorimetric signals for co-localization, although two distinct chromogens can in many instances allow successful localization of two different targets.     

Fast and Non-Toxic In Situ Hybridization without Blocking of Repetitive Sequences

Formamide is the preferred solvent to lower the melting point and annealing temperature of nucleic acid strands in in situ hybridization (ISH). A key benefit of formamide is better preservation of morphology due to a lower incubation temperature. However, in fluorescence in situ hybridization (FISH), against unique DNA targets in tissue sections, an overnight hybridization is required to obtain sufficient signal intensity. Here, we identified alternative solvents and developed a new hybridization buffer that reduces the required hybridization time to one hour (IQFISH method). Remarkably, denaturation and blocking against repetitive DNA sequences to prevent non-specific binding is not required. Furthermore, the new hybridization buffer is less hazardous than formamide containing buffers. The results demonstrate a significant increased hybridization rate at a lowered denaturation and hybridization temperature for both DNA and PNA (peptide nucleic acid) probes. We anticipate that these formamide substituting solvents will become the foundation for changes in the understanding and performance of denaturation and hybridization of nucleic acids. For example, the process time for tissue-based ISH for gene aberration tests in cancer diagnostics can be reduced from days to a few hours. Furthermore, the understanding of the interactions and duplex formation of nucleic acid strands may benefit from the properties of these solvents.     

What's new: Ligation-based DNA diagnostics

A number of novel gene detection techniques all revolve around the ligation of synthetic nucleic acid probes. In such ligase-assisted gene detection reactions, specific DNA or RNA sequences are investigated by using them as guides for the covalent joining of pairs of probe molecules. The probes are designed to hybridize immediately next to each other on the target nucleic acid strand. Demonstration of ligated probes results in highly specific detection of and efficient distinction between similar sequence variants under standard reaction conditions. Accordingly, the principle has been applied in automated genetic screening procedures. Ligation reactions are also integral to a number of amplification procedures and they will be of value in an expanding range of genetic analyses.     

Detection protocols for biotinylated probes: optimization using multistep techniques.

Recent studies using biotinylated in situ hybridization (ISH) have utilized a wide range of detection protocols for the biotinylated hybrids, leading to conflicting reports in the literature regarding sensitivity. In this study we compared 11 different detection protocols for biotinylated ISH using a measles virus-specific RNA probe on formalin-fixed, paraffin-embedded central nervous system tissue infected with measles virus. Maximum sensitivity was achieved with five-step detection protocols incorporating the use of a monoclonal antibody to biotin. Single-step detection protocols were found to be insensitive, as shown by their failure to detect viral nucleic acid in infected white-matter cells. Only by increasing the number of steps in the detection protocols were these infected cells demonstrable. Unless pre-hybridization, hybridization, and detection protocols are optimized, the results obtained in pathogenicity studies using ISH could be misinterpreted, leading to false conclusions about nucleic acid distribution. This also applies to the ever-increasing use of ISH for diagnostic purposes.     

Single-copy gene detection using branched DNA (bDNA) in situ hybridization.

We have developed a branched DNA in situ hybridization (bDNA ISH) method for detection of human papillomavirus (HPV) DNA in whole cells. Using human cervical cancer cell lines with known copies of HPV DNA, we show that the bDNA ISH method is highly sensitive, detecting as few as one or two copies of HPV DNA per cell. By modifying sample pretreatment, viral mRNA or DNA sequences can be detected using the same set of oligonucleotide probes. In experiments performed on mixed populations of cells, the bDNA ISH method is highly specific and can distinguish cells with HPV-16 from cells with HPV-18 DNA. Furthermore, we demonstrate that the bDNA ISH method provides precise localization, yielding positive signals retained within the subcellular compartments in which the target nucleic acid sequences are localized. As an effective and convenient means for nucleic acid detection, the bDNA ISH method is applicable to the detection of cancers and infectious agents. (J Histochem Cytochem 49:603-611, 2001)     

Comparison of DNA and RNA quantification methods suitable for parameter estimation in metabolic modeling of microorganisms

Recent developments in cellular and molecular biology require the accurate quantification of DNA and RNA in large numbers of samples at a sensitivity that enables determination on small quantities. In this study, five current methods for nucleic acid quantification were compared: (i) UV absorbance spectroscopy at 260 nm, (ii) colorimetric reaction with orcinol reagent, (iii) colorimetric reaction based on diphenylamine, (iv) fluorescence detection with Hoechst 33258 reagent, and (v) fluorescence detection with thiazole orange reagent. Genomic DNA of three different microbial species (with widely different G+C content) was used, as were two different types of yeast RNA and a mixture of equal quantities of DNA and RNA. We can conclude that for nucleic acid quantification, a standard curve with DNA of the microbial strain under study is the best reference. Fluorescence detection with Hoechst 33258 reagent is a sensitive and precise method for DNA quantification if the G+C content is less than 50%. In addition, this method allows quantification of very low levels of DNA (nanogram scale). Moreover, the samples can be crude cell extracts. Also, UV absorbance at 260 nm and fluorescence detection with thiazole orange reagent are sensitive methods for nucleic acid detection, but only if purified nucleic acids need to be measured.     

Progresses and Applications of Fluorescence in Situ Hybridization

The techniques of in situ hybridization (ISH) are widely adopted for analyzing the genetic make-up and RNA expression patterns of individual cells. There are four main criterions for evaluating this technique, including detection sensitivity, resolution, capacity and specificity. This review focuses on a number of advances made over the last years in the fluorescence in situ hybridization (FISH). These advances can be catagorized into several branches as follows: (1) Multicolor-FISH (mFISH), including conventional mFISH, combinatorial FISH, ratio labelling FISH, multicolor chromosome painting and comparative genomic hybridization (CGH); (2) Extended DNA fiber-FISH (EDF-FISH), including quantitative DNA fiber mapping (QDFM), molecular combing (MC) and dynamic molecular combing (DMC); (3)In situ PCR-based FISH; (4) Bacterial (or yeast) artificial chromosome-FISH (BAC-FISH or YAC-FISH); (5) Tyramide signal amplification-FISH (TSA-FISH); (6) Polypeptide nucleic acid-FISH (PNA-FISH) and (7) padlock-FISH.     

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.     

Human papillomavirus detection by non isotopic in situ hybridization, in situ hybridization with signal amplification and in situ polymerase chain reaction

Classical in situ hybridization (ISH) with biotinylated probes makes it possible to detect and localize human papillomavirus (HPV) nucleic acid sequences in cytological and histological materials. This method is however of limited value in the detection of a few copies of the virus. Moreover the specificity of such a technique is not always convincing when ISH signals are small and/or of low intensity. Recently, much attention has been focused on the utility of the in vitro polymerase chain reaction (PCR) and especially on PCR-single strand conformation polymorphism (SSCP) to amplify small amounts of viral DNA with accurate hybrid specificity. But the latter method requires nucleic acid extraction and tissue destruction. Thus, correlation between the PCR results and histological findings is not possible. Hence, the aim of our current study was to apply to HeLa cells and cervical formalin-fixed and paraffin-embedded biopsies, a novel procedure of ISH signal amplification, the catalyzed signal amplification (CSA). Such a procedure is based on the deposition of streptavidin-horseradish peroxidase catalyzing the deposition of biotinylated tyramide molecules on the location of the probed target. The biotin accumulation is then detected with streptavidin peroxidase and diaminobenzidine. The results were compared with those obtained by direct and indirect in situ PCR. The catalysed signal amplification successfully increased the sensitivity and efficiency of ISH for the detection of rare sequences in HPV infected cells and histological materials. Such a method was found simpler and faster than in situ PCR and tissue morphology was better preserved.     

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).     

Quantification of inter- and intra-nuclear variation of fluorescence in situ hybridization signals.

This study aims at the quantification of specific DNA sequences by using fluorescence in situ hybridization (ISH) and digital imaging microscopy. The cytochemical and cytometric aspects of a quantitative ISH procedure were investigated, using human peripheral blood lymphocyte interphase nuclei and probes detecting high copy number target sequences as a model system. These chromosome-specific probes were labeled with biotin, digoxigenin, or fluorescein. Quantification of the fluorescence ISH signals was performed using an epifluorescence microscope equipped with a multi-wavelength illuminator, and a cooled charge coupled device (CCD) camera. Specific image analysis programs were developed for the segmentation and analysis of the images provided by ISH. The fluorescence intensity distributions of the ISH spots showed large internuclear variation (CVs up to 65%) for the probes used. The variation in intensity was found to be independent of the probe, the type of labeling, and the type of immunocytochemical detection used. Variation in intensity was not caused primarily by the immunocytochemical detection method, since directly fluorescein-labeled probes showed similar internuclear variation. Furthermore, it was found that different white blood cell types, which harbor different degrees of compactness of the nuclear chromatin, showed the same variation. The intra-nuclear variation in intensity of the ISH spots on the two chromosome homologs within one nucleus was significantly smaller (approximately 20%) than the inter-nuclear variation, probably due to more constant local hybridization conditions. Due to the relatively small intranuclear variation, copy number polymorphisms of the satellite DNA sequence on chromosome 1 could readily be quantified.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hybridization histochemistry or in situ hybridization in the study of neuronal gene expression

1. Currently popular techniques of in situ hybridization histochemistry for the detection of cellular nucleic acids (DNA or RNA) are reviewed. 2. The advantages of single stranded DNA or RNA probes are discussed, together with the advantages of radioactive versus non-radioactive detection of nucleic acid signal. 3. Improving techniques of non-radioactive labelling and the use of image analysis for quantitation of radioactive signals will greatly expand the use of in situ techniques which will become commonplace in the laboratory.