Detection of two mRNA species at single-cell resolution by double-fluorescence in situ hybridization

Here we describe a fluorescence in situ hybridization protocol that allows for the detection of two mRNA species in fresh frozen brain tissue sections. This protocol entails the simultaneous and specific hybridization of hapten-labeled riboprobes to complementary mRNAs of interest, followed by probe detection via immunohistochemical procedures and peroxidase-mediated precipitation of tyramide-linked fluorophores. In this protocol we describe riboprobes labeled with digoxigenin and biotin, though the steps can be adapted to labeling with other haptens. We have used this approach to establish the neurochemical identity of sensory-driven neurons and the co-induction of experience-regulated genes in the songbird brain. However, this procedure can be used to detect virtually any combination of two mRNA populations at single-cell resolution in the brain, and possibly other tissues. Required controls, representative results and troubleshooting of important steps of this procedure are presented. After tissue sections are obtained, the total length of the procedure is 2-3 d.     

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.     

Detection of albumin mRNAs in rat liver by in situ hybridization: usefulness of paraffin embedding and comparison of various fixation procedures

Our aim was to define optimal conditions for efficient and reproducible albumin mRNA detection in rat liver by in situ hybridization. We used an albumin-specific [3H]-labeled cDNA probe with a specific activity of 6-8.10(6) cpm/microgram DNA. In situ hybridization is as efficient on paraffin sections as on cryostat sections for detecting albumin mRNAs. Perfusion fixation with a 4% paraformaldehyde solution results in homogeneous RNA retention within tissue blocks, in contrast with immersion fixation, which yields heterogeneous RNA preservation. Comparison of immersion fixation with three different fixatives (paraformaldehyde, ethanol-acetic acid, and Bouin's fixative) shows that the highest level of hybridization signal is obtained with paraformaldehyde. Ethanol-acetic acid and Bouin's fixative appear less efficient for albumin mRNA detection. Loss of mRNAs within liver tissue blocks over time is largely although not completely prevented by paraffin embedding.     

A simple method for coupling in situ hybridization and immunocytochemistry: application to the study of peptidergic neurons

We have devised a simple procedure for immunostaining of sections that have previously undergone autoradiographic visualization of mRNAs by in situ hybridization. Classical hybridocytochemistry techniques were performed first on cryostat sections of formaldehyde-fixed tissue. Standard methods were used for slide coating by emulsion dipping and for revelation, fixation, and coverslipping steps. The key to this method is the emulsion removal, or permeabilization, by a short trypsin incubation (0.2% for 20-30 sec) which facilitates the good access of antibodies used in a subsequent immunocytochemical technique to section epitopes. Usual immunofluorescence and immunoperoxidase procedures were successfully performed after this treatment. The immunoreactivity of several neuropeptides was well preserved after this procedure. In addition to its usefulness in our studies, this general method should be applicable to many other situations in which autoradiographic and immunocytochemical detections must be coupled.     

Adaptation of a non-radioactive in situ hybridization method to electron microscopy: detection of tenascin mRNAs in mouse cerebellum with digoxigenin-labelled probes and gold-labelled antibodies

In this study we describe a method for the detection of mRNAs at the ultrastructural level using a non-radioactive in situ hybridization method based on digoxigenin-labelled cRNA probes and gold-labelled digoxigenin-specific antibodies. We applied this protocol to an analysis of the expression of the extracellular matrix protein tenascin in the developing cerebellar cortex of the mouse. To gain an impression of the sensitivity attainable with digoxigenin-labelled probes, we first established at the light microscopic level that the hybridization signal obtained with the non-radioactive probe is as sensitive as that obtained with a ³⁵S-labelled probe. The non-radioactive hybridization protocol was then combined with electron microscopic post-embedding and immunogold detection techniques. Tenascinspecific, digoxigenin-labelled cRNA probes were hybridized to ultrathin sections of Lowicryl K4M-embedded tissue and the probe/target mRNA hybrids were detected using gold-labelled antibodies to digoxigenin. In agreement with the observations from in situ hybridization at the light microscopic level, specific labelling was observed in Golgi epithelial cells in the region of the Purkinje cell layer and cells in the internal granular layer, which could be identified as astrocytes by ultrastructural criteria. Labelling was detectable in association with free ribosomes and ribosomes of the rough endoplasmic reticulum. In addition, focal hybridization signals were occasionally found in the nucleus. No signal was observed in Golgi epithelial cells or astrocytes using sense or in any other cerebellar cell type using either sense or anti-sense probes. The described in situ hybridization technique uses ultrastructural criteria to associate the presence of a given mRNA species with a particular cell type. Additionally, it provides information about the target mRNA's subcellular distribution, thus offering the possibility to study intracellular transport of particular mRNAs.     

In situ localization of specific RNAs in developing fruit bodies of the basidiomyceteSchizophyllum commune

cDNA clones representing mRNAs abundantly expressed during fruiting ofSchizophyllum commune were used to detect the cellular localization of these mRNAs in freeze-microtome sections of developing fruit bodies. An 18 S rRNA clone was isolated and used as a probe for total RNA. Both RNA and DNA probes with different labels were found suitable but the procedure finally adopted involvedin situ hybridization with nick-translated biotinylated DNA probes. To permit the probes to permeate the cell walls it was necessary to treat the sections with RNasedepletedTrichoderma harzianum wall-lytic enzymes before hybridization. Hybridization at different developmental stages showed that the specific mRNAs were abundantly expressed in specific areas of the fruit bodies.     

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.     

In situ detection of cytomegalovirus DNA in biopsies of AIDS patients using a hybrido-immunocytochemical assay

An in situ hybrido-immunocytochemical assay, with a digoxigenin-labelled probe, was used to show the presence of cytomegalovirus DNA in both paraffin and frozen sections from tissue blocks of 5 AIDS patients. The hybridization probe was constructed by using two different DNA fragments of the repeated sequences of the CMV genome. The CMV DNA probe hybridized in situ was immunocytochemically visualized by anti-digoxigenin Fab fragments labelled with alkaline phosphatase. This hybridization procedure proved to be sensitive, specific, and provided good resolving power. Thus, it might effectively be employed in immunohistological and virological laboratories for the diagnosis of CMV infections in AIDS patients; indeed it might even be applied further in the virological context.     

In situ detection of cytomegalovirus DNA in biopsies of AIDS patients using a hybrido-immunocytochemical assay

Summary An in situ hybrido-immunocytochemical assay, with a digoxigenin-labelled probe, was used to show the presence of cytomegalovirus DNA in both paraffin and frozen sections from tissue blocks of 5 AIDS patients. The hybridization probe was constructed by using two different DNA fragments of the repeated sequences of the CMV genome. The CMV DNA probe hybridized in situ was immunocytochemically visualized by anti-digoxigenin Fab fragments labelled with alkaline phosphatase. This hybridization procedure proved to be sensitive, specific, and provided good resolving power. Thus, it might effectively be employed in immunohistological and virological laboratories for the diagnosis of CMV infections in AIDS patients; indeed it might even be applied further in the virological context.     

Combination of immunocytochemistry and in situ hybridization in the same semi-thin sections: detection of Met-enkephalin and pro-enkephalin mRNA in the hypothalamic magnocellular dorsal nucleus of the guinea pig.

We describe a procedure for combining pre-embedding peroxidase immunocytochemistry with pre-embedding autoradiographic in situ hybridization in the same vibratome sections of paraformaldehyde-fixed brain tissue. The simultaneous detection of Met-enkephalin (Met-enk)-immunoreactive product and pro-enkephalin (PE) mRNA in neurons of the magnocellular dorsal nucleus (MDN) in the guinea pig hypothalamus was carried out as a model for this procedure. Vibratome slices were processed for Met-enk immunodetection followed by the incubation with a 45-base synthetic oligonucleotide complementary to PE mRNA labeled with 35S. Tissues were embedded in araldite, cut into semi-thin sections, and processed for autoradiography. Many neurons double labeled for Met-enk and PE mRNA were viewed in the MDN. The histological quality and the spatial resolution of both signals were optimized, since precise intracellular localization of hybridization sites was possible. This method allows simultaneous study of peptide immunoreactivity and mRNA expression levels in neurons within the same semi-thin sections. It may be useful for a variety of quantitative analyses, and might also be extended to ultrastructural analysis.     

In situ hybridization using PEG-embedded tissue and riboprobes: increased cellular detail coupled with high sensitivity

We describe a procedure for preparing tissue sections by embedding in polyethylene glycol for subsequent in situ hybridization analysis using single-stranded RNA probes. Improved tissue morphology is obtained as compared to frozen sections, and the embedding procedure is milder and faster than paraffin embedding. Sections as thin as 2 microns are readily cut from PEG-embedded brain tissue. A simplified hybridization protocol (Clayton et al.: Neuron 1:249, 1988) supports the detection of even low-abundance brain mRNAs (less than or equal to 10(-4) fractional mRNA mass). By employing high stringency washes in place of ribonuclease treatment after hybridization, cell RNA is retained for cresyl violet staining, and high signal:noise ratios are achieved. Solutions to problems with section mounting and adherence to glass slides are presented. The combination of improved morphology, high signal levels, and relative simplicity should make this procedure useful in a variety of applications.     

Simultaneous in situ detection of two mRNAs in the same cell using riboprobes labeled with biotin and 35S.

We used 35S-labeled and biotinylated cRNAs (riboprobes) to detect simultaneously two different mRNAs by in situ hybridization. In a first step we established the conditions under which each type of probe achieved the same high level of sensitivity. We then used these conditions to hybridize BHK cells infected with Theiler's virus, a murine picornavirus, with a mixture of a virus-specific biotinylated riboprobe and a 35S-labeled riboprobe specific for beta-actin mRNA. Both mRNAs could be detected in the same cell, although the sensitivity achieved by the radiolabeled probe was reduced by about 40% by the simultaneous hybridization with the biotinylated probe.     

In Situ Hybridization: Use of S-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 ³⁵S-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.     

Histochemical localization of messenger RNA coding for tyrosine hydroxylase: in situ hybridization with a single-stranded cDNA probe

The expression of tyrosine-hydroxylase (TH) gene was analysed in tissue sections of bovine adrenal glands, by in situ hybridization using a single-stranded cDNA probe. Tissue fixation and hybridization conditions were found that led to a specific and sensitive detection of TH.     

A two-step hybridization method for chemiluminescent detection of single copy genes.

We have developed a technique for the chemiluminescent detection of single copy genes that eliminates the high backgrounds and problems with probe labeling associated with existing methods. The procedure employs a primary hybridization of single-stranded probe DNA to immobilized target DNA, a secondary hybridization with a covalently cross-linked oligonucleotide-alkaline phosphatase conjugate, followed by incubation in the chemiluminescent substrate AMPPD and detection on x-ray film. The key to the success of this method is that the primary probe contains a region complementary to the target DNA as well as to the oligonucleotide sequence of the secondary probe-alkaline phosphatase conjugate. Here we report our results using the two-step hybridization procedure to detect single copy genes from genomic Southern blots.