Biotin and digoxigenin as labels for light and electron microscopy in situ hybridization probes: where do we stand?

European Society of Toxicologic Pathology (Pathology 2.0 Molecular Pathology Special Interest Group): Review of In Situ Hybridization Techniques for Drug Research and Development

In situ hybridization (ISH) is used for the localization of specific nucleic acid sequences in cells or tissues by complementary binding of a nucleotide probe to a specific target nucleic acid sequence. In the last years, the specificity and sensitivity of ISH assays were improved by innovative techniques like synthetic nucleic acids and tandem oligonucleotide probes combined with signal amplification methods like branched DNA, hybridization chain reaction and tyramide signal amplification. These improvements increased the application spectrum for ISH on formalin-fixed paraffin-embedded tissues. ISH is a powerful tool to investigate DNA, mRNA transcripts, regulatory noncoding RNA, and therapeutic oligonucleotides. ISH can be used to obtain spatial information of a cell type, subcellular localization, or expression levels of targets. Since immunohistochemistry and ISH share similar workflows, their combination can address simultaneous transcriptomics and proteomics questions. The goal of this review paper is to revisit the current state of the scientific approaches in ISH and its application in drug research and development.

Synthetic chemical ligands and cognate antibodies for biorthogonal drug targeting and cell engineering

A vast range of biomedical applications relies on the specificity of interactions between an antigen and its cognate receptor or antibody. This specificity can be highest when said antigen is a non-natural (synthetic) molecule introduced into a biological setting as a bio-orthogonal ligand. This review aims to present the development of this methodology from the early discovery of haptens a century ago to the recent clinical trials. We discuss such methodologies as antibody recruitment, artificial internalizing receptors and chemically induced dimerization, present the use of chimeric receptors and/or bispecific antibodies to achieve drug targeting and transcytosis, and illustrate how these platforms most impressively found use in the engineering of therapeutic cells such as the chimeric antigen receptor cells. This review aims to be of interest to a broad scientific audience and to spur the development of synthetic artificial ligands for biomedical applications.

Zinc-based fixation for high-sensitivity in situ hybridization: a nonradioactive colorimetric method for the detection of rare transcripts on tissue sections

Nonradioactive colorimetric in situ hybridization (NoRISH) has been widely applied to analyze gene expression at the single-cell level. Zinc fixation is time efficient and provides excellent tissue morphology. Furthermore, it improves the preservation of the RNA, facilitating the detection of rare transcripts or the identification of expressing cells scattered within a tissue. Here we present a rapid, highly sensitive NoRISH method that uses a zinc-salt-based fixative and is especially suitable for the study of genes expressed at low levels and/or in a small number of cells within a structure.

Endogenous biotin-binding proteins: an overlooked factor causing false positives in streptavidin-based protein detection

Biotinylation is widely used in DNA, RNA and protein probing assays as this molecule has generally no impact on the biological activity of its substrate. During the streptavidin-based detection of glycoproteins in Lactobacillus rhamnosus GG with biotinylated lectin probes, a strong positive band of approximately 125 kDa was observed, present in different cellular fractions. This potential glycoprotein reacted heavily with concanavalin A (ConA), a lectin that specifically binds glucose and mannose residues. Surprisingly, this protein of 125 kDa could not be purified using a ConA affinity column. Edman degradation of the protein, isolated via cation and anion exchange chromatography, lead to the identification of the band as pyruvate carboxylase, an enzyme of 125 kDa that binds biotin as a cofactor. Detection using only the streptavidin conjugate resulted in more false positive signals of proteins, also in extracellular fractions, indicating biotin-associated proteins. Indeed, biotin is a known cofactor of numerous carboxylases. The potential occurence of false positive bands with biotinylated protein probes should thus be considered when using streptavidin-based detection, e.g. by developing a blot using only the streptavidin conjugate. To circumvent these false positives, alternative approaches like detection based on digoxigenin labelling can also be used.

Digoxigenin-labeled in situ hybridization for the detection of Streptococcus suis DNA in polyserositis and a comparison with biotinylated in situ hybridization

The objective of this study was to develop digoxigenin-labeled in situ hybridization (ISH) for the detection of Streptococcus suis in naturally infected pigs with polyserositis and to compare it with biotinylated ISH. Digoxigenin-labeled hybridization signals for S. suis were observed in cells that had infiltrated the fibrous polyserositis and microcolonies in the blood vessels. Mock hybridization showed no hybridization signals for endogenous digoxigenin. Biotinylated hybridization signals for S. suis were observed in cells that had infiltrated the fibrous polyserositis. However, similar hybridization signals were also observed in the fibrous inflammatory area using mock hybridization for endogenous biotin. The present study demonstrated that digoxigenin-labeled ISH is a valuable diagnostic tool for specific detection of S. suis in polyserositic tissues without nonspecific reactions compared with biotinylated ISH.

A polypeptide-DNA hybrid with selective linking capability applied to single molecule nano-mechanical measurements using optical tweezers

Many applications in biosensing, biomaterial engineering and single molecule biophysics require multiple non-covalent linkages between DNA, protein molecules, and surfaces that are specific yet strong. Here, we present a novel method to join proteins and dsDNA molecule at their ends, in an efficient, rapid and specific manner, based on the recently developed linkage between the protein StrepTactin (STN) and the peptide StrepTag II (ST). We introduce a two-step approach, in which we first construct a hybrid between DNA and a tandem of two STs peptides (tST). In a second step, this hybrid is linked to polystyrene bead surfaces and Maltose Binding Protein (MBP) using STN. Furthermore, we show the STN-tST linkage is more stable against forces applied by optical tweezers than the commonly used biotin-Streptavidin (STV) linkage. It can be used in conjunction with Neutravidin (NTV)-biotin linkages to form DNA tethers that can sustain applied forces above 65 pN for tens of minutes in a quarter of the cases. The method is general and can be applied to construct other surface-DNA and protein-DNA hybrids. The reversibility, high mechanical stability and specificity provided by this linking procedure make it highly suitable for single molecule mechanical studies, as well as biosensing and lab on chip applications.

A rapid and highly sensitive method of non radioactive colorimetric in situ hybridization for the detection of mRNA on tissue sections

Background

Non Radioactive colorimetric In Situ Hybridization (NoRISH) with hapten labeled probes has been widely used for the study of gene expression in development, homeostasis and disease. However, improvement in the sensitivity of the method is still needed to allow for the analysis of genes expressed at low levels.

Methodology/Principal Findings

A stable, non-toxic, zinc-based fixative was tested in NoRISH experiments on sections of mouse embryos using four probes (Lhx6, Lhx7, ncapg and ret) that have different spatial patterns and expression levels. We showed that Z7 can successfully replace paraformaldehyde used so far for tissue fixation in NoRISH; the morphology of the cryosections of Z7-fixed tissues was excellent, and the fixation time required for tissues sized 1 cm was 1 hr instead of 24 hr for paraformaldehyde. The hybridization signal on the sections of the Z7-treated embryos always appeared earlier than that of the PFA-fixed embryos. In addition, a 50–60% shorter detection time was observed in specimen of Z7-treated embryos, reducing significantly the time required to complete the method. Finally and most importantly, the strength of the hybridization signal on the sections of the Z7-treated embryos always compared favorably to that of the sections of PFA-fixed embryos; these data demonstrate a significant improvement of the sensitivity the method that allows for the analysis of mRNAs that are barely or not detected by the standard colorimetric NoRISH method.

Conclusions/Significance

Our NoRISH method provides excellent preservation of tissue morphology, is rapid, highly sensitive, and especially suitable to implement in the study of genes expressed at low levels and/or in sparse cells within a structure.

ISH-IEM: a sensitive method to detect endogenous mRNAs at the ultrastructural level

This protocol describes the combination of in situ hybridization (ISH) with cryo-immunolabeling methods to allow the simultaneous detection at the ultrastructural level of mRNAs and proteins. The procedure consists of five steps and takes 4-5 d: (i) acquisition of ultrathin frozen sections of chemically fixed tissues or cells; (ii) hybridization of the sections with digoxigenin (DIG) or biotin-labeled RNA probes; (iii) detection of the bound probe with antibodies and protein A-gold (PAG); (iv) labeling of proteins of interest (optional); and (v) visualization by transmission electron microscopy (immuno-electron microscopy (IEM)). This technique allows the simultaneous detection of endogenous/overexpressed/injected RNAs and proteins while preserving the cell ultrastructure. The protocol is also suitable for mRNA detection on semi-thin frozen sections in combination with immunofluorescence. The localization of targeted transcripts, such as gurken and oskar mRNA in the Drosophila oocyte, and of structural elements and proteins that mediate their localization have been revealed using this technique.

Biolabeling with 2,4-dichlorophenoxyacetic acid derivatives: the 2,4-D tag

Many bioanalytic and diagnostic procedures rely on labels with which the molecule of interest can be tracked in or discriminated from accompanying like substances. Herein, we describe a new labeling and detection system based on derivatives of 2,4-dichlorophenoxyacetic acid (2,4-D) and anti-2,4-D antibodies. The 2,4-D system is highly sensitive with a K(D) of 7 x 10(-11) M for the hapten-antibody pair, can be used on a large variety of biomolecules such as proteins, peptides, carbohydrates, and nucleic acids, is not hampered by endogenous backgrounds because 2,4-D is a xenobiotic, and is robust because 2,4-D is a very stable compound that withstands the conditions of most reactions usually performed on biomolecules. With this unique blend of properties, the 2,4-D system compares favorably with its rivals digoxigenin (DIG)/anti-DIG and biotin/(strept)avidin and provides an interesting and powerful tool in biomolecular labeling.

An improved in situ hybridization method for the detection of fish pathogens

A fluorescent in situ hybridization (FISH) method was developed for detection of infectious pancreatic necrosis virus (IPNV) in paraffin-embedded tissues of Atlantic salmon, Salmo salar L. Several methods of probe labelling and detection were evaluated and found unsuitable for FISH because of tissue autofluorescence. Likewise, the use of avidin to detect biotin-labelled probe was obviated by the presence of endogenous biotin. An existing approach, using digoxigenin (DIG)-labelled probes and detection by anti-DIG antibody-labelled with alkaline phosphatase, was modified to use a fluorescent substrate, 2-hydroxy-3-naphthoic acid-2'-phenylanilide phosphate/4-chloro-2-methylbenzene diazonium hemi-zinc chloride salt (HNPP/Fast Red TR). This improved method allowed sensitive detection of IPNV target, without interference from autofluorescence or endogenous alkaline phosphatase. Furthermore, the reporter produces a discrete, non-fading signal, which is particularly suitable for analysis by confocal microscopy.

Pseudo-immunolabelling with the avidin-biotin-peroxidase complex due to the presence of endogenous biotin in the retina

Immunodetection techniques are dependent on enzyme-protein conjugates for the visualization of antigen-antibody complexes. One of the most widely used is the avidin-biotin-peroxidase complex (ABC) method. However, treatment of certain tissues with ABC reagents alone may result in high background, which is indicative for the presence of endogenous biotin or biotinylated proteins. In goldfish and salamander retinal sections, we observed a distinct staining pattern, presumably through binding of avidin to endogenous biotin in Müller cells. These findings summon for caution in the application of detection systems based on biotinylated antibodies or biotinylated DNA probes.

Cellular co-localization of intron-4 containing mRNA and HLA-G soluble protein in melanoma analyzed by fluorescence in situ hybridization

HLA-G5, -G6, and -G7 soluble isoforms of the immunosuppressive HLA-G molecule are produced from the splice variants of the primary HLA-G mRNA transcript containing intron-4 that encodes a specific 21 amino acids tail. In particular, HLA-G5 interacts with the inhibitory ILT2/4 and KIR2DL4 receptors that are expressed on immune cells. Acquisition of soluble HLA-G in the microenvironment may turn a HLA-G non-expressing cell into a HLA-G-bearing one. To address the question of how to distinguish cells that express soluble HLA-G generated by alternative splicing from those that have acquired HLA-G, we have developed a method capable of detecting intron-4 containing mRNA and protein in situ simultaneously. M8 melanoma cell line either transfected or not with HLA-G5 cDNA was analyzed by indirect immunofluorescence confocal microscopy using double staining with a HLA-G intron-4 digoxygenin labeled probe along with a monoclonal antibody directed against the 21 amino acid tail. The combined fluorescence in situ hybridization was also used on the HLA-G-positive choricarcinoma cell line JEG-3. This method would be helpful to follow-up bona fide HLA-G expression in a heterogeneous cell population and to elucidate the mechanisms underlying soluble HLA-G mediated immune modulation in physiological conditions such as pregnancy and pathophysiological situations such as cancer.

Detection of two different mRNAs in a single section by dual in situ hybridization: a comparison between colorimetric and fluorescent detection

We have compared the performance of two methods designed to simultaneously detect two different mRNAs within a single brain section by dual ISH. Specific mRNA riboprobes labeled with biotin and digoxigenin were simultaneously hybridized and visualized using either brightfield or fluorescence microscopy. For brightfield visualization, the biotin-labeled riboprobe was detected with a peroxidase chromogen, whereas, an alkaline phosphatase substrate was used for the detection of the digoxigenin-labeled riboprobe. Dual fluorescent ISH involved the detection of the biotin-labeled riboprobe with an Alexa((R))488-conjugated streptavidin followed by the visualization of the digoxigenin-labeled riboprobe with the red fluorescent substrate HNPP. The dual ISH protocols presented here offer sensitive methods to detect the expression of two mRNAs of interest, with both colorimetric and fluorescent ISH each having its strengths and limitations. For example, dual colorimetric ISH has proven to be particularly useful to study the distribution of two mRNAs in different brain nuclei, whereas, dual fluorescent ISH has provided better results when studying the co-localization of two different mRNAs in single neurons. The comprehensive step-by-step procedure is presented, together with a troubleshooting section in which the advantages and limitations of these procedures are reviewed in depth. Moreover, alternative protocols for dual ISH were also compared to those presented here.

Nonisotopic detection of microRNA using digoxigenin labeled RNA probes

MicroRNAs (miRNAs) are an important class of endogenously derived, small approximately 22 nucleotide noncoding regulatory RNAs that have recently become implicated in development, cell regulation and cancers of various tissues. Here we report a nonisotopic Northern analysis method for miRNA detection using 3'-digoxigenin (DIG)-labeled RNA oligo probes. Northern blot analysis was performed using miRNA or total RNA fractions extracted from human leukemic cell lines, and blots were hybridized with either 32P- or DIG-labeled RNA probe for miR-181, miR-155 or miR-16. A labeled probe for U6 small nuclear RNA served as an internal control. The use of DIG-labeled RNA probes was equally sensitive compared to 32P-labeled probes in detecting miRNA quantities as low as 50 ng. The ability to use nonisotopic methods and yet obtain sensitive and reliable results offers an advantage to investigators who prefer to avoid isotopes.

Dendrimer FISH detection of single-copy intervals in acute promyelocytic leukemia

Acute promyelocytic leukemia (AML-M3) is characterized by a translocation between chromosomes 15 and 17 [t(15;17)]. The detection of t(15;17) at the single cell level, is commonly done by fluorescence in situ hybridization (FISH) using recombinant locus specific genomic probes greater than 14 kilobases kb in length. To allow a more thorough study of t(15;17), we designed small (0.9-3.6 kb), target-specific, single-copy probes from the human genome sequence. A novel detection approach was evaluated using moieties possessing more fluorophores, DNA dendrimers (up to 375 fluorophores per dendrimer). Two detection approaches were evaluated using the dendrimers: (1) dendrimers modified with anti-biotin antibodies for detection of biotinylated bound probes, and (2) dendrimers modified with 45-base long oligonucleotides designed from the single-copy probes, for direct detection of the target region. The selectivity of the probes was confirmed via indirect labeling with biotin/digoxigenin by nick translation, with detection efficiencies between 50 and 90%. Furthermore, the scFISH probes were successfully detected on metaphase cells with anti-biotin dendrimer conjugates and on interphase cells with 45-base modified dendrimers. Our results bring up the possibility to detect target regions of less than 1 kb, which will be a great contribution to high-resolution analysis of genomic sequences.

A high-resolution, double-labeling method for the study of in vivo red blood cell aging

BACKGROUND

Red blood cell (RBC) senescence is a process that has received considerable study, yet remains poorly understood. This has been primarily due to the difficulty in isolating a RBC cohort of narrowly distributed, well-defined age. Biotin labeling has previously been used to produce an identifiable cell cohort of known mean age; however, the variability of RBC age within the cohort is relatively large for most of its existence. Treatments typically employed on animal subjects to reduce this variability can perturb erythropoiesis and result in abnormal RBC aging.

STUDY DESIGN AND METHODS

The objective of this study was to improve on the traditional in vivo biotinylation method by introducing a chemically distinct, second labeling step. In this case, digoxigenin was used to label cells 1 to 2 days before the injection of biotin.

RESULTS

It was shown, in the rat, that two identifiable subpopulations of labeled RBCs can be followed over time: a broad, double-labeled cohort and a narrow, single-labeled cohort, the latter consisting of only those cells created between the first and second labeling steps. The utility of this technique was demonstrated by observing the age-dependent exposure of phosphatidylserine in the single-labeled RBCs.

CONCLUSION

Its capacity to generate a cohort of narrowly distributed age, without the adverse effects associated with animal treatment, should make this a useful method for the study of RBC senescence.

In situ detection of specific gene expression during and immediately after transcription at electron microscopic level

In situ hybridization (ISH) is a widely applied technique used for visualizing specific nucleic acid sequences at chromosomal, cytologic, and histologic levels. It sometimes fails, however, to demonstrate precise cell identity, early stages of gene expression and variants of alternative splicing because of its limited resolution. To overcome this shortcoming, we have developed an improved ISH technique at the electron microscopic (EM) level by conducting en bloc hybridization before embedding (pre-embedding) and immuno-EM detection after ultra-thin sectioning (post-embedding). We applied this technique to demonstrate both the dynamic expression of interleukin (IL)-6 mRNA immediately after lipopolysaccharide (LPS) treatment, and the static expression of osteonectin mRNA in a differentiating osteoblastic cell linage. Tissue samples were diced into 1mm cubes, fixed with 4% paraformaldehyde, and then successively hybridized en bloc with the digoxigenin (DIG)-labeled single-stranded probe measuring 200-300 bp with the aid of microwave treatment. After washing, for EM observation, the cubes were embedded in epon for ultra-thin sectioning, and a gold-colloid-labeled anti-DIG antibody was used for post-embedding immuno-EM; some of the cubes was directly incubated with anti-DIG antibody and developed en bloc for stereoscopic and light microscopic observation. IL-6 mRNA during and immediately after transcription was demonstrated in the nuclei of the alveolar macrophages and in neutrophils of mouse lung tissue as early as 15 min after LPS treatment, which was of better sensitivity than that by Northern blot or nuclear run-on techniques. Moreover, in mouse calvaria tissue, osteonectin mRNA both in the nucleus and the cytoplasm was observed in a differentiating osteoblastic cell linage in a differentiation-specific manner. This technique is useful in identifying specific cell types during and immediately after transcribing specific mRNA based on ultrastructural morphology.

Controlled three-dimensional immobilization of biomolecules on chemically patterned surfaces

We used electron-beam lithography to fabricate chemical nanostructures, i.e. amino groups in aromatic self-assembled monolayers (SAMs) on gold surfaces. The amino groups are utilized as reactive species for mild covalent attachment of fluorescently labeled proteins. Since non-radiative energy transfer results in strong quenching of fluorescent dyes in the vicinity of the metal surfaces, different labeling strategies were investigated. Spacers of varying length were introduced between the gold surface and the fluorescently labeled proteins. First, streptavidin was directly coupled to the amino groups of the SAMs via a glutaraldehyde linker and fluorescently labeled biotin (X-Biotin) was added, resulting in a distance of approximately 2 nm between the dyes and the surface. Scanning confocal fluorescence images show that efficient energy transfer from the dye to the surface occurs, which is reflected in poor signal-to-background (S/B) ratios of approximately 1. Coupling of a second streptavidin layer increases the S/B-ratio only slightly to approximately 2. The S/B-ratio of the fluorescence signals could be further increased to approximately 4 by coupling of an additional fluorescently labeled antibody layer. Finally, we introduced tetraethylenepentamine as functional spacer molecule to diminish fluorescence quenching by the surface. We demonstrate that the use of this spacer in combination with multiple antibody layers enables the controlled fabrication of highly fluorescent three-dimensional nanostructures with S/B-ratios of >20. The presented technique might be used advantageously for the controlled three-dimensional immobilization of single protein or DNA molecules and the well-defined assembly of protein complexes.

Inter- and Intramolecular Fluorescence Quenching of Organic Dyes by Tryptophan

Steady-state and time-resolved fluorescence measurements were performed to elucidate the fluorescence quenching of oxazine, rhodamine, carbocyanine, and bora-diaza-indacene dyes by amino acids. Among the natural amino acids, tryptophan exhibits the most pronounced quenching efficiency. Especially, the red-absorbing dyes ATTO 655, ATTO 680, and the oxazine derivative MR 121 are strongly quenched almost exclusively by tryptophan due to the formation of weak or nonfluorescent ground-state complexes with association constants, K(ass.), ranging from 96 to 206 M(-1). Rhodamine, fluorescein, and bora-diaza-indacene derivatives that absorb at shorter wavelengths are also quenched substantially by tyrosine residues. The quenching of carbocyanine dyes, such as Cy5, and Alexa 647 by amino acids can be almost neglected. While quenching of ATTO 655, ATTO 680, and the oxazine derivative MR121 by tryptophan is dominated by static quenching, dynamic quenching is more efficient for the two bora-diaza-indacene dyes Bodipy-FL and Bodipy630/650. Labeling of the dyes to tryptophan, tryptophan-containing peptides, and proteins (streptavidin) demonstrates that knowledge of these fluorescence quenching processes is crucial for the development of fluorescence-based diagnostic assays. Changes in the fluorescence quantum yield of dye-labeled peptides and proteins might be used advantageously for the quantification of proteases and specific binding partners.

The case for extending storage and secretion functions of human mast cell granules to include synthesis

Ultrastructural studies using standard procedures have for years indicated close associations of ribosomes and secretory granules in human mast cells. These descriptive studies have informed new studies, using established and new ultrastructural methods based on different principles, designed to investigate the possible role of RNA metabolism in secretory granules of human mast cells. In aggregate, these studies indicate human mast cell secretory granule associations with ribosomes, the protein synthetic machine of cells, with ribosomal proteins, with RNA, with poly(A)-positive mRNA and with various long-lived, or short-lived, uridine-rich, and poly(A)-poor RNA species with key roles in RNA processing and splicing. These studies indicate that secretory-storage granules in human mast cells may also be synthetic granules.

Spectroscopic study and evaluation of red-absorbing fluorescent dyes

The spectroscopic characteristics (absorption, emission, and fluorescence lifetime) of 13 commercially available red-absorbing fluorescent dyes were studied under a variety of conditions. The dyes included in this study are Alexa647, ATTO655, ATTO680, Bodipy630/650, Cy5, Cy5.5, DiD, DY-630, DY-635, DY-640, DY-650, DY-655, and EVOblue30. The thorough characterization of this class of dyes will facilitate selection of the appropriate red-absorbing fluorescent labels for applications in fluorescence assays. The influences of polarity, viscosity, and the addition of detergent (Tween20) on the spectroscopic properties were investigated, and fluorescence correlation spectroscopy (FCS) was utilized to assess the photophysical properties of the dyes under high excitation conditions. The dyes can be classified into groups based on the results presented. For example, while the fluorescence quantum yield of ATTO655, ATTO680, and EVOblue30 is primarily controlled by the polarity of the surrounding medium, more hydrophobic and structurally flexible dyes of the DY-family are strongly influenced by the viscosity of the medium and the addition of detergents. Covalent binding of the dyes to biotin and subsequent addition of streptavidin results in reversible fluorescence quenching or changes in the relaxation time of other photophysical processes of some dyes, most likely due to interactions with tryptophan residues in the streptavin binding site.

Tuning ligand affinity, specificity, and folding stability of an engineered lipocalin variant -- a so-called 'anticalin' -- using a molecular random approach

Anticalins are prepared by reshaping the ligand pocket of a natural lipocalin via protein engineering in order to recognize a prescribed ligand. In this manner, the anticalin DigA with specificity for digoxigenin was previously derived from the bilin-binding protein (BBP), a natural lipocalin from Pieris brassicae. The four peptide loops that form its ligand-binding site were randomized and a cognate variant was selected from the resulting library. Here, we propose a concept for improving the ligand-binding properties of this anticalin in an in vitro affinity maturation process by step-wise randomization of restricted areas of the loop region. Following selection on digoxigenin-binding activity via phage display and colony screening, several DigA variants were thus obtained. The recombinant proteins were thoroughly characterized in terms of ligand affinity and specificity, secondary structure and thermal stability against unfolding. The variant DigA16/19, which carries several new mutations, exhibits clearly improved affinity for digoxigenin, with K(D)=12.4 nM. Hence, it is suitable as a sensitive reagent in biochemical detection experiments, especially when produced as a functional fusion protein with alkaline phosphatase as reporter enzyme. In addition, DigA16/19 possesses enhanced ligand specificity and recognizes part of the linker that was used for fixing the steroid group to a carrier protein. Finally, the digoxigenin-binding anticalins appear to have high physico-chemical stability, with T(m) values in the 70 degrees C range. Our present findings support the notion that anticalins provide a useful class of compact and robust ligand-receptor proteins that can be tailored for practical demands.

A sensitive non-radioactive in situ hybridization method for the detection of chicken IgG gamma-chain mRNA: a technique suitable for detecting of variety of mRNAs in tissue sections

We established a sensitive non-radioactive in situ hybridization (ISH) method for the detection of chicken IgG gamma-chain mRNA in paraffin sections. RNA probes were transcribed in vitro from cloned chicken IgG CH1 nucleotide sequences with SP6/T7 RNA polymerases in the presence of DIG-UTP. These probes were used for hybridization and were immunodetected using anti-DIG antibodies conjugated to horseradish peroxidase. The immunoreactive products were visualized with DAB-H(2)O(2). IgG gamma-chain mRNA-expressing cells were localized in both the spleen and oviductal tissues. This method demonstrated an excellent sensitivity since the ISH signal was clear and the background was negligible. We found that in the spleen IgG gamma-chain mRNA-expressing cells were present mainly in the red pulp, whereas in the oviduct they appeared mainly in the mucosal stroma and not in the mucosal epithelium.

Ultrastructural cytochemical, immunocytochemical and in situ hybridization methods with polyuridine probes detect mRNA in human mast cell granules

Mature human mast cells are classical secretory cells that are filled with secretory-storage granules but are poorly endowed with visible free or membrane-bound cytoplasmic ribosomes. We recently reported close associations of ribosomes and various components essential to RNA metabolism in and close to human mast cell granules using multiple ultrastructural imaging methods. In view of these findings and an increased awareness of RNA sorting and localization to specific subcellular sites and organelles, we used human mast cells purified from non-tumour portions of lung samples resected at surgery for carcinoma and ultrastructural methods to investigate this further. Poly(U) probes were used to detect direct en grid binding, and radiolabelled as well as non-radiolabelled poly(U) probes were used in in situ hybridization protocols to detect poly(A)-positive pre-mRNA and mRNA in nuclear, cytoplasmic and granular compartments of mature human mast cells. Negative controls verified specificity of label; expected nuclear and cytoplasmic locations of poly(A)-positive RNA served as positive controls for each sample. These findings lend support to the hypothesis that site-specific synthesis in secretory-storage granules may occur in secretory cells.

A novel type of receptor protein, based on the lipocalin scaffold, with specificity for digoxigenin

We demonstrate that the bilin-binding protein, a member of the lipocalin family of proteins, can be structurally reshaped in order to specifically complex digoxigenin, a steroid ligand commonly used for the non-radioactive labelling of biomolecules. 16 amino acid residues, distributed across the four loops which form the binding site of the bilin-binding protein, were subjected to targeted random mutagenesis. From the resulting library the variant DigA16 was obtained by combined use of phage display and a filter-sandwich colony screening assay, followed by in vitro affinity maturation. DigA16 possesses strong binding activity and high specificity for the digoxigenin group, with a K(D) of 30.2(+/-3.6) nM. The derivative compound digitoxigenin is bound even more tightly, with a K(D) of 2.0(+/-0.52) nM, whereas the steroid glycoside ouabain is not recognized at all. Fusion proteins between DigA16 and alkaline phosphatase were constructed and shown to retain both the digoxigenin-binding function and enzymatic activity, irrespective of whether the enzyme was fused to the N or the C terminus of the bilin-binding protein variant. Our findings suggest that the lipocalin scaffold can be generally employed for the construction of specific receptor proteins, so-called "anticalins", which provide a promising alternative to recombinant antibody fragments.

Detection of different mRnas expressed in the thyro-parathyroid complex of the rat by in situ hybridization using digoxigenin-labelled oligonucleotide probes

The effects have been examined of different methods and regimens for tissue fixation, preservation, permeabilization and immunostaining of different mRNAs detected by in situ hybridization in paraffin-embedded samples. The three main hormone mRNAs expressed in the thyro-parathyroid glands, namely thyroglobulin, calcitonin and parathyroid hormone mRNAs, were chosen as the target nucleic acid sequences to be detected using digoxigenin-labelled probes. Our results suggest that chemical fixation and permeabilization of tissue samples are restrictive steps. Thus, paraformaldehyde fixation provides excellent signal intensities and non-detectable background levels whereas routine formalin and Bouin's solution give unsatisfactory results. A clear linear correlation was also found between signal intensity and proteinase K permeabilization. Moreover, the optimization of immunohistochemical steps, such as anti-digoxigenin antibody concentration and colour development times, enhance the intensity and specificity of hybrid signals. Furthermore, our results show that, in contrast to some data in the literature, paraffin-embedded tissue is suitable for detection of mRNAs by in situ hybridization. It gives equivalent intensities of specific signal and superior histological and cellular resolutions when compared to cryopreserved tissue.

Freeze-drying allows double nonradioactive ISH and antigenic labeling

Because tissue freeze-drying is an excellent way to preserve antigenic conformation, we have tested the feasibility of this technique to reveal nonradioactive in situ hybridization (ISH) of tissue mRNA. We have compared mRNA detection after different methods of tissue preservation, freeze-drying, cryosectioning, and formaldehyde or methanol fixation. Our results show that nonradioactive ISH is more sensitive for tissues preserved by freeze-drying than for other tissue preparations. We have demonstrated that freeze-drying allows combination of ISH and immunohistochemistry for simultaneous detection of mRNA and antigen because with this technique of tissue preservation ISH does not affect the sensitivity or the amount of the detected antigens. This work underscores the fact that tissue freeze-drying is an easy, convenient, and reliable technique for both ISH and immunohistochemistry and achieves excellent structural conditions for nonradioactive detection.

Ultrastructural localization of beta-actin and amphoterin mRNA in cultured cells: application of tyramide signal amplification and comparison of detection methods

We describe a nonradioactive preembedding in situ hybridization protocol using digoxigenin-labeled RNA probes and tyramide signal amplification to increase the sensitivity of detection. The protocol is sensitive enough for electron microscopic localization of endogenous messenger RNAs encoding beta-actin and amphoterin. Three visualization methods were compared: diaminobenzidine enhanced by nickel, Nanogold enhanced by silver and gold toning, and fluorescently labeled tyramides. Diaminobenzidine and Nanogold can be used in both light and electron microscopy. The nickel-enhanced diaminobenzidine was the most sensitive visualization method. It is easy to accomplish but a drawback is poor spatial resolution, which restricts its use at high magnifications. Nanogold visualization has considerably better spatial resolution and is therefore recommended for electron microscopy. Fluorescent tyramides, especially TRITC-tyramide, offer a good detection method for fluorescence and confocal microscopy. The methods were used to localize amphoterin and beta-actin mRNAs in motile cells. Both mRNAs were found in the soma and cell processes. In double labeling experiments, beta-actin mRNA localized to filamentous structures that also contained ribosomal proteins. Especially in the cortical cytoplasm, beta-actin mRNA was associated with actin filaments. Direct localization to microtubules was only rarely seen. (J Histochem Cytochem 47:99-112, 1999)

Intracellular virus DNA distribution and the acquisition of the nucleoprotein core during African swine fever virus particle assembly: ultrastructural in situ hybridisation and DNase-gold labelling

African swine fever virus (ASFV) is a large complex icosahedral double-stranded DNA virus that replicates in the cytoplasm of susceptible cells. Assembly of new virus particles occurs within the perinuclear viroplasm bodies known as virus factories. Two types of virus particle are routinely observed: "fulls," which are particles with an electron-dense DNA-containing nucleoid, and "empties," which consist of the virus protein and membrane icosahedral shell but are without the incorporation of the virus genome. The objective of this study was to understand ASFV morphogenesis by determining the distribution of intracellular viral DNA in the virus factory and during virus particle assembly. The ultrastructural localisation of DNA within ASFV-infected cells was achieved using two complementary methods: with an ASFV-specific DNA probe to the major capsid protein (p73) gene (B646L) hybridised in situ or through detection of all forms of DNA (viral and cellular) with gold-labelled DNase. Conditions for in situ hybridisation at the electron microscopic level were optimised for infected cells in two Lowicryl resins (K4M and HM20) and using two nonradioactive probe labels (digoxygenin and biotin). The morphological data indicate that the viral DNA, perhaps from specialised storage sites within the factory, begins to condense into a pronucleoid and is then inserted, at a single vertex, into an "empty" particle. Further maturation of the viral particle, including closure of the narrow opening in the icosahedron, gives rise to "intermediate" particles, where the nucleoprotein core undergoes additional consolidation to produce the characteristic mature or "full" virions. The site of particle closure may represent a "weak point" at one vertex, but the mechanisms and structures involved in the packaging and release of the virus genome via such a port are yet to be determined.

Staining of the midbody by an anti-digoxin-specific antibody

Using RNA in situ hybridization to reveal cytoplasmic localization patterns of mRNAs in cultured cells, we noted unexpected staining of a cytoplasmic component in telophase cells. Control experiments revealed that the anti-digoxin-specific antibody was responsible for this staining. Because the staining was observed only at a position where both daughter cells are still connected, we identified the stained component as the midbody. This was confirmed by double staining of cells with anti-digoxin and anti-alpha-tubulin antibodies. We concluded that anti-digoxin-specific antibody shows crossreactivity with a component present in the midbody.