In situ hybridization technique to localize rRNA and mRNA in mammalian neurons

In situ hybridization provides a method for identifying cells that contain specific nucleic acid sequences. This report outlines an in situ hybridization procedure for mammalian neural tissue. The method maintains morphological quality and produces excellent specificity. Seven tritiated nucleic acid probes were examined: two ribosomal RNA probes, a control pBR322 plasmid probe, two probes encoding portions of the gene for oxytocin, one probe each encoding a portion of vasopressin glycoprotein, and neurophysin. Using cryostat-cut rat brain sections, rRNA probes labeled the cytoplasm of all cells and the nucleoli of larger neurons. The plasmid probe failed to produce a strong signal. Oxytocin and vasopressin probes appropriately labeled the cytoplasm of hypothalamic magnocellular neurons. Vasopressin parvocellular neurons were not identified by the current method, and the shorter length neurophysin probe failed to produce a signal. Methodological variables were examined by counting autoradiographic grains in cells. The longer oxytocin probe produced a stronger signal than the shorter oxytocin and vasopressin probes, and higher probe concentrations resulted in stronger signal. Hybridization could be abolished by tissue pretreatment with RNAse A, and longer exposure time increased signal strength. The outlined fixation steps with fresh-frozen tissue produced a superior signal compared to paraformaldehyde-perfused tissue.     

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.     

Computer assisted signal co-localization for simultaneous detection of antigen by immunohistochemistry and DNA by non-isotopic in situ hybridization

A method has been developed to co-localize signals for antigen and DNA using a desktop microcomputer system (computer assisted signal co-localization). Antigens were detected by standard immunohistochemical methods and DNA was detected by non-isotopic in situ hybridization (NISH). Using this method, NISH signals can be precisely located in cells with well-preserved morphology captured by computer. The removal of the first immunohistochemical reaction products and reagents eliminates possible interference with hybridization and non-specific binding to the probe; therefore the sensitivity of the original NISH method remains. The captured NISH signals can be converted to any other colour which contrasts with the immunostaining. We have used detection of Epstein-Barr virus (EBV) and keratins as a model system. This method is straightforward, and with necessary modifications, will be applicable to any type of combined immunohistochemistry and in situ hybridization technique for simultaneous detection of antigen and nucleic acids or two types of nucleic acids in the same cells.     

Anti-DNA.RNA sera

Summary The specificity of anti-nucleic acid antisera can immunocytochemically be evaluated with test systems which apply various nucleic acids immobilized to inert matrices. When using polyrA.polyrU as a model compoud for dsRNA, it is important to prevent the formation of the triple stranded form polyrA.(polyrU)₂.Anti-dsRNA antibodies which, when tested with the correct test system, proved to be present in an earlier described anti-DNA.RNA serum, could be removed by adsorption. By cytofluorometric comparison of the immunofluorescence signals obtained with the anti-dsRNA containing serum and the absorbed serum, it could be shown that the anti-dsRNA antibodies do not contribute to the specific signals measured after in situ hybridization.Repetitive incubations with the anti-DNA.RNA serum led to a considerable increase in immunofluorescence signal.This work was subsidized in part by Het Praeventiefonds, The Hague, The Netherlands     

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.     

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.     

Ultrastructural visualization of cytoskeletal mRNAs and their associated proteins using double-label in situ hybridization

We have been able to visualize cytoskeletal messenger RNA molecules at high resolution using nonisotopic in situ hybridization followed by whole-mount electron microscopy. Biotinated cDNA probes for actin, tubulin, or vimentin mRNAs were hybridized to Triton-extracted chicken embryo fibroblasts and myoblasts. The cells were then exposed to antibodies against biotin followed by colloidal gold-conjugated antibodies and then critical-point dried. Identification of mRNA was possible using a probe fragmented to small sizes such that hybridization of several probe fragments along the mRNA was detected as a string of colloidal gold particles qualitatively and quantitatively distinguishable from nonspecific background. Extensive analysis showed that when eight gold particles were seen in this iterated array, the signal to noise ratio was greater than 30:1. Furthermore, these gold particles were colinear, often spiral, or circular suggesting detection of a single nucleic acid molecule. Antibodies against actin, vimentin, or tubulin proteins were used after in situ hybridization, allowing simultaneous detection of the protein and its cognate message on the same sample. This revealed that cytoskeletal mRNAs are likely to be extremely close to actin protein (5 nm or less) and unlikely to be within 20 nm of vimentin or tubulin filaments. Actin mRNA was found to be more predominant in lamellipodia of motile cells, confirming previous results. These results indicate that this high resolution in situ hybridization approach is a powerful tool by which to investigate the association of mRNA with the cytoskeleton.     

Detection and amplification systems for sensitive, multiple-target DNA and RNA in situ hybridization: looking inside cells with a spectrum of colors

In situ hybridization (ISH) is a powerful technique for localizing specific nucleic acid sequences (DNA, RNA) in microscopic preparations of tissues, cells, chromosomes, and linear DNA fibers. To date, a wide variety of research and diagnostic applications of ISH have been described, making the technique an integral part of studies concerning gene mapping, gene expression, RNA processing and transport, the three-dimensional organization of the nucleus, tumor genetics, microbial infections, and prenatal diagnosis. In this review, I first describe the ISH procedure in short and then focus on the currently available non-radioactive probe-labeling and cytochemical detection methodologies that are utilized to visualize one or multiple different nucleic acid targets in situ with different colors. Special emphasis is placed on the procedures applying fluorescence and brightfield microscopy, the simultaneous detection of nucleic acids and proteins by combined ISH and immunocytochemistry, and, in addition, on the recent progress that has been made with the introduction of signal amplification procedures to increase the detection sensitivity of ISH. Finally, a comparison of fluorescence, enzyme cytochemical, and colloidal gold silver probe detection systems will be presented, and possible future directions of in situ nucleic acid detection will be discussed. Accepted: 9 June 1999     

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.     

Telomere analysis by fluorescence in situ hybridization and flow cytometry.

Determination of telomere length is traditionally performed by Southern blotting and densitometry, giving a mean telomere restriction fragment (TRF) value for the total cell population studied. Fluorescence in situ hybridization (FISH) of telomere repeats has been used to calculate telomere length, a method called quantitative (Q)-FISH. We here present a quantitative flow cytometric approach, Q-FISHFCM, for evaluation of telomere length distribution in individual cells based on in situ hybridization using a fluorescein-labeled peptide nucleic acid (PNA) (CCCTAA)3probe and DNA staining with propidium iodide. A simple and rapid protocol with results within 30 h was developed giving high reproducibility. One important feature of the protocol was the use of an internal cell line control, giving an automatic compensation for potential differences in the hybridization steps. This protocol was tested successfully on cell lines and clinical samples from bone marrow, blood, lymph nodes and tonsils. A significant correlation was found between Southern blotting and Q-FISHFCMtelomere length values ( P = 0.002). The mean sub-telomeric DNA length of the tested cell lines and clinical samples was estimated to be 3.2 kbp. With the Q-FISHFCMmethod the fluorescence signal could be determined in different cell cycle phases, indicating that in human cells the vast majority of telomeric DNA is replicated early in S phase.     

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.     

Diagnostic nucleic acid hybridizations for infectious diseases

The use of nucleic acid hybridization techniques has expanded into many areas, including studies of gene structure and function, routine diagnosis of human, animal and plant diseases, and also forensic science. In situ hybridization is one of the techniques currently available for nucleic acid hybridization and has some distinct advantages compared with standard techniques such as dot-blot, Southern or Northern hybridization, in which the histological structure is lost during extraction of nucleic acids. On the other hand, immunohistochemical staining is one branch of histochemistry that has received considerable attention in recent years as a very sensitive method for localization of specific proteins and other antigenic macromolecules within tissues and cells. This technique has also been widely used for clinical diagnosis and in various fields of research in medical science and biology. Automation of colorimetric in situ hybridization and immunohistochemistry would greatly contribute to the ease of introducing these techniques for routine pathological diagnosis and would improve the reproducibility of the assay. In this review, author will describe the development of an automated method for in situ hybridization and immunohistochemical staining using an automatic machine for both procedures.     

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.     

Specific detection of RNA molecules by fluorescent in situ hybridization in living cells

The antisense therapeutic strategy makes the assumption that sequence-specific hybridization of an oligonucleotide to its target can take place in living cells. The present work provides a new method for the detection of intracellular RNA molecules using in situ hybridization on living cells. The first step consisted in designing nonperturbant conditions for cell permeabilization using streptolysin O. In a second step, intracellular hybridization specificity was evaluated by incorporating various types of fluorescently labeled nucleic acid probes (plasmids, oligonucleotides). Due to its high expression level, the 28S ribosomal RNA was retained as a model. Results showed that: (1) no significant cell death was observed after permeabilization; (2) on living cells, 28S RNA specific probes provided bright nucleoli and low cytoplasmic signal; (3) control probes did not lead to significant fluorescent staining; and (4) comparison of signals obtained on living and fixed cells showed a colocalization of observed fluorescence. These results indicate the feasibility of specific hybridization of labeled nucleic acid probes under living conditions, after a simple and efficient permeabilization step. This new detection method is of interest for investigating the dynamics of distribution of various gene products in living cells, under normal or pathological conditions.Abbreviations PI propidium iodide - SLO streptolysin O     

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.     

Immunological elimination of infected cells as the candidate mechanism for tumor protection in polyomavirus-infected mice.

The uniformly lethal development of mammary tumors in polyomavirus-infected adult female nude mice was prevented by adoptive cell transfer of polyomavirus-immune splenocytes or peritoneal cells. Transferred immune cells also lowered the growth rate of emerging tumors. The induction of other relatively less frequent tumors of the skin and bone was decreased as well. Using in situ hybridization of whole-body sections as well as hybridization of nucleic acids from the mammary glands, we show for the first time that transferred immune cells, but not normal cells, virtually eliminated virus signal in the whole mouse and in the mammary glands. Since infected and tumorous mammary glands produce very little infectious virus, it appears that a major mechanism mediating the prevention of polyomavirus oncogenesis involves the immunological elimination of nonproductively and persistently infected cells.     

LNA flow–FISH: A flow cytometry–fluorescence in situ hybridization method to detect messenger RNA using locked nucleic acid probes

We present a novel method using flow cytometry–fluorescence in situ hybridization (flow–FISH) to detect specific messenger RNA (mRNA) in suspended cells using locked nucleic acid (LNA)-modified oligonucleotide probes. β-Actin mRNA was targeted in whole A549 epithelial cells by hybridization with a biotinylated, LNA-modified probe. The LNA bound to β-actin was then stained using phycoerythrin-conjugated streptavidin and detected by flow cytometry. Shifts in fluorescence signal intensity between the β-actin LNA probe and a biotinylated, nonspecific control LNA were used to determine optimal conditions for this type of flow–FISH. Multiple conditions for permeabilization and hybridization were tested, and it was found that conditions using 3 μg/ml of proteinase K for permeabilization and 90 min hybridization at 60 °C with buffer containing 50% formamide allow cells containing the LNA-bound mRNA to be detected and differentiated from the control LNA with high confidence (< 14% overlap between curves). This combined method, called LNA flow–FISH, can be used for detection and quantification of other RNA species as well as for telomerase measurement and detection.     

Hybridocytochemistry as a tool for the investigation of chromatin organization

The study of nuclear components in cells and tissues has resulted in a wealth of information with regard to the role of chromatin in cellular processes. Here, a survey is given of procedures which allow the cytochemical investigation of nucleic acid present in microscopic preparations of cells, nuclei or metaphase chromosomes. Special attention is given to recent developments in hybridocytochemistry (in situ hybridization) which facilitate microscopic identification and localization of specific nucleotide sequences within the total amount of nucleic acids present. Some of the potentialities and limitations of these in situ hybridization methods are discussed.