Analysis of microRNA expression by in situ hybridization with RNA oligonucleotide probes

In situ hybridization is an important tool for analyzing gene expression and developing hypotheses about gene functions. The discovery of hundreds of microRNA (miRNA) genes in animals has provided new challenges for analyzing gene expression and functions. The small size of the mature miRNAs ( approximately 20-24 nucleotides in length) presents difficulties for conventional in situ hybridization methods. However, we have described a modified in situ hybridization method for detection of mammalian miRNAs in tissue sections, based upon the use of RNA oligonucleotide probes in combination with highly specific wash conditions. Here, we present detailed procedures for detection of miRNAs in tissue sections or cultured cells. The methods described can utilize either nonradioactive hapten-conjugated probes that are detected by enzyme-coupled antibodies, or radioactively labeled probes that are detected by autoradiography. The ability to visualize miRNA expression patterns in tissue sections provides an additional tool for the analyses of miRNA expression and function. In addition, the use of radioactively labeled probes should facilitate quantitative analyses of changes in miRNA gene expression.     

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.     

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.     

New tissue microarray technology for analyses of gene expression in frozen pathological samples

Tissue microarrays (TMAs) are widely used to analyze gene expression in multiple pathological samples on a single slide. Currently, most TMA slides are made by coring paraffin-embedded tissues and arraying them into a paraffin block, from which TMA sections are cut. However paraffin-based TMA technology may not be compatible with frozen clinical tissue samples, which have a higher quality of RNAs and proteins for preparing TMAs than paraffin-embedded tissue samples. In this study, we developed an alternative TMA technology that is applicable to a broader range of frozen tissue samples. Our method takes advantage of a newly developed array recipient block that can be used to array small tissue cores. After arraying tissue cores, the tissue block can be immediately sectioned on a cryostat microtome to make TMA slides. TMAs made using this method have well-defined array configurations and good tissue/cell morphology. Immunohistochemistry and in situ hybridization study also revealed well-preserved proteins and mRNAs on TMA slides. Our method significantly simplifies TMA preparation and assembly when frozen pathological tissues are used. Our technology provides an alternative tool for creating high-quality TMAs for the general research community to study gene expressions in pathological samples.     

Cellular resolution expression profiling using confocal detection of NBT/BCIP precipitate by reflection microscopy

The determination of gene expression patterns in three dimensions with cellular resolution is an important goal in developmental biology. However the most sensitive, efficient, and widely used staining technique for whole-mount in situ hybridization (WMISH), nitroblue tetrazolium (NBT)/5-bromo-4-chloro-3-indolyl phosphate (BCIP) precipitation by alkaline phosphatase, could not yet be combined with the most precise, high-resolution detection technique, confocal laser-scanning microscopy (CLSM). Here we report the efficient visualization of the NBT/BCIP precipitate using confocal reflection microscopy for WMISH samples of Drosophila, zebrafish, and the marine annelid worm, Platynereis dumerilii. In our simple WMISH protocol for reflection CLSM, NBT/BCIP staining can be combined with fluorescent WMISH, immunostainings, or transgenic green fluorescent protein (GFP) marker lines, allowing double labeling of cell types or of embryological structures of interest. Whole-mount reflection CLSM will thus greatly facilitate large-scale cellular resolution expression profiling in vertebrate and invertebrate model organisms.     

High-resolution in situ hybridization and TUNEL staining with free-floating brain sections.

We applied in situ hybridization and the TUNEL technique to free-floating (vibratomed) sections of embryonic and postnatal mouse CNS. Full-length cDNAs specific for oligodendrocyte- or astrocyte-specific genes were labeled with digoxigenin using the random primer method. With paraformaldehyde-fixed sections, the nonradioactive in situ hybridization method provides detection of individual, very small glial progenitor cells in embryonic development. Small, isolated cells expressing oligodendrocyte specific messages can be detected in the neuroepithelium at embryonic and postnatal stages. The technique can be completed within 3 days and is as sensitive as the radioactive method. Likewise, the TUNEL method using DAB as the chromogen on free-floating sections provides excellent resolution. These DAB-stained sections can be embedded in plastic and thin-sectioned to visualize the ultrastructure of apoptotic cells. Both in situ hybridization and TUNEL methods can be applied to the same section, the tissue embedded in plastic, and semithin sections cut. The high resolution obtained with this combined procedure makes it possible to determine whether brain cells expressing glia-specific messages are undergoing apoptosis.     

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.     

In situ RNA hybridization using Technovit resin in Arabidopsis thaliana

A protocol is described for RNA in situ hybridization using thin sections prepared by Technovit resin. Technovit is a widely used resin for histological examinations. Since it does not require time-consuming processes such as removal of the resin and can be performed without high temperature treatment, a high resolution of sections could be possible compared to other resins and paraffin. Thin sections (approximately 4 m) were made from inflorescences of Arabidopsis thaliana embedded in Technovit 8100 resin, and in situ hybridization was performed using the protocol described in this article. Hybridization signals were observed using LEAFY and other genes as probes, showing that this resin can be used for in situ analysis. In our experiments, the most important factor for a successful in situ hybridization pattern was to optimize the RNase A concentration after hybridization. We routinely used RNase A at a concentration of 2–5 ng/ml, a concentration much lower than that used for paraffin embedding method. Thus, the use of the Technovit resin for plant tissue embedding results in a faster protocol and greater quality than allowed by paraffin sections.     

Improved method for making high-affinity sections of soft tissue embedded in polyethylene glycol (PEG): its use in screening monoclonal antibodies

This article describes improvements in the immunohistologic technique for embedding highly hydrated embryonic tissue in polyethylene glycol 1000 (PEG)--a water-soluble wax of melting point 39 degrees C--and compares the PEG sections with frozen and polyester-wax sections. The main improvement ensures that relatively large PEG sections (8 X 3 mm) stretch out and adhere well to slides: a coat of albumen and glycerine is dried onto the slides and a fresh coat applied just before use. The embedding, sectioning, and mounting procedures, which are considerably faster than those for wax processing, have been developed for screening monoclonal antibodies against the differentiated neural crest cells in the anterior eyes of 9-day-old chick embryos. PEG sections of such eyes were a little fragile, but showed good cellular detail, similar to or better than in wax sections and considerably better than in frozen sections. The responses of PEG sections to the antibodies were far stronger than those of wax and marginally better than those of frozen sections. In one experiment using 125I-labeled rabbit anti-mouse antibody on sections previously treated with antibodies or antisera, PEG sections bound about five times as much label as wax sections and approximately 30% more than frozen sections. The main limitation of the technique is that, because of the softness of PEG, it only works well for embedding a limited range of tissues. Such PEG sections may, however, be useful for in situ hybridization as well as for immunohistochemistry.     

Thin sectioning of slice preparations for immunohistochemistry

Many investigations in neuroscience, as well as other disciplines, involve studying small, yet macroscopic pieces or sections of tissue that have been preserved, freshly removed, or excised but kept viable, as in slice preparations of brain tissue. Subsequent microscopic studies of this material can be challenging, as the tissue samples may be difficult to handle. Demonstrated here is a method for obtaining thin cryostat sections of tissue with a thickness that may range from 0.2-5.0 mm. We routinely cut 400 micron thick Vibratome brain slices serially into 5-10 micron coronal cryostat sections. The slices are typically first used for electrophysiology experiments and then require microscopic analysis of the cytoarchitecture of the region from which the recordings were observed. We have constructed a simple device that allows controlled and reproducible preparation and positioning of the tissue slice. This device consists of a cylinder 5 cm in length with a diameter of 1.2 cm, which serves as a freezing stage for the slice. A ring snugly slides over the cylinder providing walls around the slice allowing the tissue to be immersed in freezing compound (e.g., OCT). This is then quickly frozen with crushed dry ice and the resulting wafer can be position easily for cryostat sectioning. Thin sections can be thaw-mounted onto coated slides to allow further studies to be performed, such as various staining methods, in situ hybridization, or immunohistochemistry, as demonstrated here.     

Investigation of Tissue Preparation Conditions for Non-radioactive In Situ Hybridization: Localization of Transforming Growth Factor-α Message in Rat Kidney

A non-radioactive method of in situ hybridization was used to localize transforming growth factor- mRNA in epithelial cells of collecting ducts and tubules in rat kidney tissue sections. The intensity and specificity of staining were assessed under a variety of tissue preparation conditions, including a direct comparison of paraffin against frozen sections. Under optimal conditions, both the signal strength and the cellular localization of the growth factor message were superior in paraffin sections. The staining method could also be used to localize the message in lung tissue, indicating that the procedure is generally applicable to other tissues. Our results indicate that the use of paraffin sections for non-radioactive in situ hybridization affords a number of advantages for the localization of specific messages in tissue sections.     

Induction of a heat shock gene (hsp 70) in rabbit retinal ganglion cells detected by in situ hybridization with plastic-embedded tissue

Elevation of body temperature by 2–3°C induces a 2.7 kilobase hsp70 mRNA species in the rabbit retina within 1 hr. In situ hybridization with thin sections derived from plastic-embedded tissue permitted a higher level of resolution of retinal cell types compared to procedures which involved the use of frozen tissue sections. A prominent induction of hsp70 mRNA in retinal ganglion cells was observed when an hsp70 riboprobe was utilized for in situ hybridization. These results indicate that this neuronal cell type responds rapidly to fever-like body temperatures by inducing one of the major heat shock genes.     

Effect of the storage period of paraffin sections on the detection of mRNAs by in situ hybridization.

In this study we evaluated whether storing non-deparaffinized sections can affect the detection of specific mRNAs by radioactive in situ hybridization (ISH). Using a standard ISH protocol, we hybridized serial sections of paraffin blocks stored for different periods of time with (33)P-labeled riboprobes specific for rat Type III collagen and matrix metalloproteinase-2 (MMP-2). Signal intensities were evaluated using a phosphorimager and by blinded microscopic examination. For slides hybridized with the Type III collagen riboprobe, signal intensities measured with the phosphorimager or evaluated by microscopic examination were negatively correlated with the storage period of the sections. For slides hybridized with the MMP-2 riboprobe, differences in signal intensity could be detected, albeit inconsistently, with the phosphorimager, although microscopic examination consistently indicated stronger signals in freshly sectioned slides compared to slides stored for 2 weeks or more. We concluded that it was preferable to use recently prepared sections for trying to locate mRNAs in paraffin-embedded tissues by ISH. In addition, our results suggest that quantifying signal intensity using a phosphorimager is feasible for abundant mRNAs or when large differences in expression are anticipated.(J Histochem Cytochem 49:927-928, 2001)     

Detection of tissue-specific gene expression using an in situ hybridization method of histoblotting

A version of in situ hybridization on the histological sections that is used for screening specific mRNA in tissues in proposed. Sections of the frozen tissue samples are prepared on the cryostatic microtome, placed on nitrocellulose filters and hybridized with labelled DNA-probes under the conditions of RNA blot hybridization. The proposed method ("histoblotting") was used to study the distribution of actin and alpha-phetoprotein mRNA genes in tissues of 15 and 21-day rat embryos. The possibility of studying mRNA (by hibridizations) and protein (by immunoenzyme staining) and making histological analysis simultaneously by histoblotting is demonstrated.     

Development of an automatic machine for in situ hybridization and immunohistochemistry.

An instrument for the automation of in situ hybridization and immunohistochemistry has been developed. This machine is capable of analyzing 20 microscope glass slides via all of the steps required for colorimetric in situ hybridization or immunohistochemistry. The slides are placed specimen-side down on a specialized Teflon slide-holder set in the reaction chamber of the machine. The system uses a unique type of capillary action between the slide and the holder. The holder has two small holes and is designed to apply, incubate and sequentially add and remove reagents from the slide surface. The system performs the complete processes of in situ hybridization and immunohistochemistry from dewaxing to colorization. Some applications were carried out using this instrument. Cultured cells infected with cytomegalovirus, adenovirus, or herpes simplex virus were hybridized with homologous biotinylated probes, and showed strong purple signals with alkaline phosphatase in the presence of nitroblue tetrazolium and 5-bromo-4-chloro-3-indolyl phosphate. Automatic in situ hybridization using other colorimetric detection systems (e.g., peroxidase-labeled probes/diaminobenzidine/H2O2) was also examined in cells infected with Chlamydia trachomatis and in paraffin-embedded hepatic tissue sections from patients with hepatitis. For conventional immunohistochemical staining, formalin-fixed and paraffin-embedded tissues were used. Glial fibrillary acidic protein and gamma-immunoglobulins were detected automatically in human brain white matter and tonsillar tissues, respectively, as peroxidase-based reddish signals. The intensity of staining was equal to that achieved by manual methods.