Fluorescence in situ hybridization in paraffin tissue sections: pretreatment protocol

Fluorescence in situ hybridization has found wide application in the enumeration of gene and chromosome copy number both in isolated cells and in tissue sections. However, the technique has been less widely used than would be expected in formalin-fixed paraffin processed (archival) tissue. This article describes a method for assessing archival tissue sections, following pretreatment, before applying DNA probes, that gives consistent, reliable results.     

High-throughput analysis of gene expression on tissue sections by in situ hybridization

Genome-scale sequencing projects, high-throughput RNAi screens, systematic gene targeting, and system-biology-based network predictions all depend on a validation of biological significance in order to understand the relevance of a particular finding. Such validation, for the most part, rests on low-throughput technologies. This article provides protocols that, in combination with suitable instrumentation, make possible a semi-automated analysis of gene expression on tissue sections by means of in situ hybridization. Knowledge of gene expression localization has the potential to aid, and thereby accelerate, the validation of gene functions.     

Detection of altered retinoic acid receptor expression in tissue sections using in situ hybridization

Nuclear retinoid receptors mediate retinoid effects in controlling cell growth, differentiation, apoptosis, and carcinogenesis. Altered expression or activity of these receptors could abolish the retinoid signal transduction pathway and be associated with human carcinogenesis. In situ hybridization is a powerful tool for analyzing gene expression in formalin-fixed, paraffin-embedded tissue sections, especially for newly cloned genes or when no antibodies are available. Detection of altered retinoid receptor expression using in situ hybridization in premalignant and malignant tissues has provided important information about the roles of these receptors in cancer development and the response of these tissues to retinoid treatment. Among these receptors, altered expression of retinoic acid receptor-beta (RAR-beta) has been mostly detected in human cancers, including those of the head and neck, lung, esophagus, mammary gland, pancreas, and cervix. RAR-beta is thus currently used as a surrogate endpoint biomarker in different clinical prevention trials of various cancers.     

Computer-aided quantification of RNA levels detected by in situ hybridization of tissue sections.

A semi-automatic program, designed for non-computer scientists, was developed for quantification of RNA levels detected by in situ hybridization in heterogeneous tissues. A video camera was used to acquire microscopic images of autoradiographed tissue sections which are then digitized on a video monitor for semi-automated quantification of silver grains. We describe a data entry and analysis procedure for systematic quantification of RNA levels in which about 300 cells per tissue sample can be analysed within 10 min. When compared with visual counting, computer-aided quantification was found to be more objective and reliable, with the highest variation coefficient between individuals being 7.5% using computer-aided quantification, compared to 24% with manual counting of the same section areas. A comparative study of c-myc oncogene expression in 11 mammary adenocarcinomas from 3 independent experiments showed the good reproducibility of results using the computer-aided method, with an 18% maximum variation between experiments. The program, with its simple user-interface, reliability and rapidity, is convenient for measuring specific genetic expression levels in clinical studies requiring large numbers of specimens.     

In situ hybridization: use of 35S-labeled probes on paraffin tissue sections

The following protocol is for radioactive in situ hybridization detection of RNA using paraffin-embedded tissue sections on glass microscope slides. Steps taken to inhibit RNase activity such as diethyl pyrocarbonate (DEPC) treatment of solutions and baked glassware are unnecessary. The tissue is fixed using 4% paraformaldehyde, hybridized with (35)S-labeled RNA probes, and exposed to nuclear-track emulsion. The entire procedure takes 2-3 days prior to autoradiography. The time required for autoradiography is variable with an average time of 10 days. Parameters that affect the length of the autoradiography include: (1) number of copies of mRNA in the tissue, (2) incorporation of label into the probe, and (3) amount of background signal. Additional steps involved in the autoradiography process, including development of the emulsion, cleaning of the microscope slides, counterstaining of the tissue, and mounting coverslips on the microscope slides, are discussed. In addition, a general guide to the interpretation of the in situ results is provided.     

An efficient in situ hybridization protocol for multiple tissue sections and probes on miniaturized slides

To facilitate detection of gene activity in tissue sections we combined common protocols of in situ hybridization on tissue sections (TSISH) with the technique of whole-mount in situ hybridization (WMISH). Miniature glass slides for mounting tissue sections were cut from regular microscope slides and handled for in situ hybridization in laboratory-made 2-ml containers (baskets) similar to those originally used for WMISH on Drosophila embryos. A salient point of the method is the use of airtight reaction vessels placed in a dry thermostat for critical hybridization steps as this facilitates reproducible and stringent hybridization conditions which are difficult to achieve on tissue sections otherwise. The practicability of the method is illustrated on consecutive serial frozen sections of murine neonatal cerebellum hybridized for math1 and neuroD, two developmentally regulated genes with distinct expression patterns. For both genes excellent spatial resolution and a highly dynamic range of signal intensity was obtained. The approach enables simple processing of multiple probes, allows the efficient and economic use of small tissue samples and is amenable to automation.     

Gene expression analysis in sections and tissue microarrays of archival tissues by mRNA in situ hybridization

Altered expression of genes in diseased tissues can prognosticate a distinct natural progression of the disease as well as predict sensitivity or resistance to particular therapies. Archival tissues from patients with a known medical history and treatments are an invaluable resource to validate the utility of candidate genes for prognosis and prediction of therapy outcomes. However, stored tissues with associated long-term follow-up information typically are formalin-fixed, paraffin-embedded specimen and this can severely restrict the methods applicable for gene expression analysis. We report here on the utility of tissue microarrays (TMAs) that use valuable tissues sparingly and provide a platform for simultaneous analysis of gene expression in several hundred samples. In particular, we describe a stable method applicable to mRNA expression screening in such archival tissues. TMAs are constructed from sections of small drill cores, taken from tissue blocks of archival tissues and multiple samples can thus be arranged on a single microscope slide. We used mRNA in situ hybridization (ISH) on >500 full sections and >100 TMAs for >10 different cDNAs that yielded >10,000 data points. We provide detailed experimental protocols that can be implemented without major hurdles in a molecular pathology laboratory and discuss quantitative analysis and the advantages and limitations of ISH. We conclude that gene expression analysis in archival tissues by ISH is reliable and particularly useful when no protein detection methods are available for a candidate gene.     

Enhancement of in situ hybridization to detect bovine herpesvirus 4 in paraffin sections

In situ hybridization (ISH) protocols including different pre-treatment regimes were developed and compared for their effects on detecting bovine herpesvirus 4 (BoHV-4) in formalin fixed, paraffin embedded tissue. Results were compared for the hybridization and background signal intensities, and cellular morphology. We found that optimum results were obtained using enzyme treatment-thermal cycling as a pre-treatment of ISH. The results showed that the combination of protease and thermal cycling would be recommended as a means of supplementing in situ hybridization methods, especially when using long-term formalin fixed, paraffin-embedded tissue.     

Fluorescence in situ hybridization on vibratome sections of plant tissues

This protocol describes the application of fluorescence in situ hybridization (FISH) to three-dimensionally (3D) preserved tissue sections derived from intact plant structures such as roots or florets. The method is based on the combination of vibratome sectioning with confocal microscopy. The protocol provides an excellent tool to investigate chromosome organization in plant nuclei in all cell types and has been used on tissues of both monocot and dicot plant species. The visualization of 3D well-preserved tissues means that cell types can be confidently identified. For example, meiocytes can be clearly identified at all stages of meiosis and can be imaged in the context of their surrounding maternal tissue. FISH can be used to localize centromeres, telomeres, repetitive regions as well as unique regions, and total genomic DNAs can be used as probes to visualize chromosomes or chromosome segments. The method can be adapted to RNA FISH and can be combined with immunofluorescence labeling. Once the desired plant material is sectioned, which depends on the number of samples, the protocol that we present here can be carried out within 3 d.     

In situ hybridization methods for the detection of somatostatin mRNA in tissue sections using antisense RNA probes

In situ hybridization studies with [32P] and [3H] labelled antisense RNA probes were undertaken to determine optimal methods of tissue fixation, tissue sectioning, and conditions of hybridization, and to compare the relative merits of the two different radioactive labels. The distribution of somatostatin mRNA in neurons of rat brain using a labelled antisense somatostatin RNA probe was employed as a model for these studies. The highest degree of sensitivity for in situ hybridization was obtained using paraformaldehyde fixation and vibratome sectioning. Optimal autoradiographic localization of mRNA was obtained within 7 days using [32P] labelled probes. However, due to the high energy emittance of [32P], precise intracellular localization of hybridization sites was not possible. [3H] labelled RNA probes gave more precise cellular localization but required an average of 18-20 days autoradiographic exposure. The addition of the scintillator, PPO, decreased the exposure time for the localization of [3H] labelled probes to seven days. We also report a method for combined in situ hybridization and immunocytochemistry for the simultaneous localization of somatostatin in mRNA and peptide in individual neurons.     

Multi-colour brightfield in situ hybridisation on tissue sections

 We describe the brightfield microscopical detection of multiple DNA target sequences in cell and tissue preparations. For this purpose, chromosome-specific DNA probes labelled with biotin, digoxigenin or fluorescein were simultaneously hybridised and detected by enzyme cytochemistry using two horseradish peroxidase (PO) reactions and one alkaline phosphatase (APase) reaction. For triple-colour detection on single cell preparations, the combination of the enzyme precipitates PO/diaminobenzidine (DAB, brown colour), APase/fast red (FR, red colour) and PO/tetramethylbenzidine (TMB, green colour) resulted in an accurate detection of DNA targets. Embedding of the preparations in a thin cross-linked protein layer further stabilised the enzyme reaction products. For in situ hybridisation on tissue sections, however, this detection procedure showed some limitations with respect to both the stability of the APase/FR and PO/TMB precipitates, and the sequence of immunochemical layers in multiple-target procedures. For this reason, the APase/FR reaction was replaced by the APase/new fuchsin (NF, red colour) reaction and the washing steps after the PO/TMB reaction were restricted to the use of phosphate buffer pH 6.0. Furthermore, to improve the efficiency of the ISH reaction, APase/NF was applied in an avidin-biotin complex detection system and, to avoid target shielding in the triple-target ISH, the third primary antibody was applied prior to the second enzyme cytochemical reaction. These adaptations resulted in stable, well contrasting brown, red and green coloured precipitates. After quick haematoxylin counterstaining, the tissue preparations were directly mounted in phosphate buffer and, optionally, embedded in the cross-linked protein layer. Accepted: 27 June 1997     

The use of UV light as a cross-linking agent for cells and tissue sections in in situ hybridization.

UV cross-linking is introduced as a novel method to stabilize tissue on microscopic slides and to immobilize target molecules in biological material for in situ hybridization. UV illumination dramatically improves the stability of tissue sections and isolated cells on slides coated with gelatin/poly-lysine. Even during prolonged high-stringency washes, specimens remain firmly attached to the support layer. At the same time, the signal intensity is increased significantly whereas background levels remain as low as without UV illumination. These results indicate that while target RNAs and other molecules in the biological material are covalently cross-linked with their nearest neighbor molecules, tissues nonetheless remain penetrable, and target molecules remain accessible. We expect that this simple and efficient technique will find widespread applications in in situ hybridization methodology.     

Sensitive nonradioactive detection of mRNA in tissue sections: novel application of the whole-mount in situ hybridization protocol.

The relative insensitivity of nonradioactive mRNA detection in tissue sections compared to the sensitive nonradioactive detection of single-copy DNA sequences in chromosome spreads, or of mRNA sequences in whole-mount samples, has remained a puzzling issue. Because of the biological significance of sensitive in situ mRNA detection in conjunction with high spatial resolution, we developed a nonradioactive in situ hybridization (ISH) protocol for detection of mRNA sequences in sections. The procedure is essentially based on the whole-mount ISH procedure and is at least equally sensitive. Increase of the hybridization temperature to 70C while maintaining stringency of hybridization by adaptation of the salt concentration significantly improved the sensitivity and made the procedure more sensitive than the conventional radioactive procedure. Thicker sections, which were no improvement using conventional radioactive ISH protocols, further enhanced signal. Higher hybridization temperatures apparently permit better tissue penetration of the probe. Application of this highly reliable protocol permitted the identification and localization of the cells in the developing heart that express low-abundance mRNAs of different members of the Iroquois homeobox gene family that are supposedly involved in cardiac patterning. The radioactive ISH procedure scarcely permitted detection of these sequences, underscoring the value of this novel method.     

Aminoalkylsilane-treated glass slides as support for in situ hybridization of keratin cDNAs to frozen tissue sections under varying fixation and pretreatment conditions

Summary Attempts to investigate the cellular localization of keratin mRNAs byin situ hybridization with specific [³⁵S]-labelled cDNA probes to mouse epithelia have been seriously impeded by the uncontrollable detachment of frozen tissue sections on conventionally coated glass slides (i.e. those coated with egg white, gelatine, collagen). Similarly, a variety of other coating and attachment devices have proved to be unsatisfactory or impracticable for large scale investigations. These difficulties were completely overcome andin situ hybridization was possible after a short immersion of the glass slides in a 2% solution of 3-aminopropyltriethoxysilane in acetone. This treatment provides the glass surface with aminoalkyl groups which are apparently able to react covalently with aldehyde or ketone functions of frozen tissue sections. The resulting firm adhesion of the sections enabled us to investigate the influence of different fixation and prehybridization procedures on the quality of thein situ hybridization. It was found that especially harsh prehybridization, involving hydrochloric acid, heat and proteinase K treatment, drastically reduces the morphological integrity of the sections, thus rendering a reliable assignment of the label difficult. In contrast, a mild prehybridization, consisting mainly of a rehydration of the sections in phosphate-buffered saline and equilibration in 0.1 M glycine, leaves the morphology intact and leads to a highly efficient and specificin situ hybridization.     

The use of fluorescence in situ hybridization (FISH) on paraffin-embedded tissue sections for the study of microchimerism

We describe here a simple and versatile method of fluorescence in situ hybridization (FISH) on paraffin-embedded tissue sections with specific application in the study of microchimerism, that is, the presence of intact foreign cells within an individual. This is accomplished through the use of X and Y chromosome-specific probes to identify the presence of male nuclei within a tissue section from a female, and vice versa. This technique requires only minor modification if at first the hybridization does not yield fluorescent signals of high quality. Analysis of a wide variety of tissue types is possible with this method, and multiple tissue types from one or more individuals can be processed in the same hybridization reaction. This robust FISH method has been used successfully in our laboratory to investigate fetal cell microchimerism in the following paraffin-embedded tissue types: skin, lung, thyroid, adrenal gland, lymph node, heart, spleen, liver, pancreas, kidney, and intestine.