Detection of DNA sequences in nuclei in suspension by in situ hybridization and dual beam flow cytometry

Analysis of human chromosomes by imaging flow cytometry

Chromosomal analysis is traditionally performed by karyotyping on metaphase spreads, or by fluorescent in situ hybridization (FISH) on interphase cells or metaphase spreads. Flow cytometry was introduced as a new method to analyze chromosomes number (ploidy) and structure (telomere length) in the 1970s with data interpretation largely based on fluorescence intensity. This technology has had little uptake for human cytogenetic applications primarily due to analytical challenges. The introduction of imaging flow cytometry, with the addition of digital images to standard multi-parametric flow cytometry quantitative tools, has added a new dimension. The ability to visualize the chromosomes and FISH signals overcomes the inherent difficulties when the data is restricted to fluorescence intensity. This field is now moving forward with methods being developed to assess chromosome number and structure in whole cells (normal and malignant) in suspension. A recent advance has been the inclusion of immunophenotyping such that antigen expression can be used to identify specific cells of interest for specific chromosomes and their abnormalities. This capability has been illustrated in blood cancers, such as chronic lymphocytic leukemia and plasma cell myeloma. The high sensitivity and specificity achievable highlights the potential imaging flow cytometry has for cytogenomic applications (i.e., diagnosis and disease monitoring). This review introduces and describes the development, current status, and applications of imaging flow cytometry for chromosomal analysis of human chromosomes.

RNA Flow Cytometry Using the Branched DNA Technique

The systematic modulation of mRNA and proteins governs the complicated and intermingled biological functions of our cells. Traditionally, transcriptomic technologies such as DNA microarray and RNA-Seq have been used to identify, characterize, and profile gene expression data. These are, however, considered bulk methods as they are unable to measure gene expression at the single-cell level, unless the cells are pre-sorted. Branched DNA is a flow cytometry-based detection platform that has been developed recently to measure mRNA at the single-cell level. Originally adapted from microscopy, the current system has been modified to achieve compatibility with the detection of surface and intracellular antigens using monoclonal antibodies conjugated to fluorochromes, thus permitting simultaneous detection of mRNAs and proteins. The Branched DNA method offers a variety of advantages when compared to traditional or standard methods used for the quantification of mRNA, such as (a) the detection of specific mRNA on a per cell basis, (b) an alternate detection tool when the measurement of a protein is technically infeasible (i.e., no quality antibody exists) or the epitope is not assessable, and (c) correlate the analysis of mRNA with protein. Compared to earlier attempts at measuring nucleic acid by flow cytometry, the hybridization temperature applied in the Branched DNA assay is much lower, thus preserving the integrity of cellular structures for further characterization. It also has greatly increased specificity and sensitivity. Here, we provide detailed instruction for performing the Branched DNA method using it in a model system to correlate the expression of CD8 mRNA and CD8 protein by flow cytometry.

PNA-COMBO-FISH: From combinatorial probe design in silico to vitality compatible, specific labelling of gene targets in cell nuclei

Recently, advantages concerning targeting specificity of PCR constructed oligonucleotide FISH probes in contrast to established FISH probes, e.g. BAC clones, have been demonstrated. These techniques, however, are still using labelling protocols with DNA denaturing steps applying harsh heat treatment with or without further denaturing chemical agents. COMBO-FISH (COMBinatorial Oligonucleotide FISH) allows the design of specific oligonucleotide probe combinations in silico. Thus, being independent from primer libraries or PCR laboratory conditions, the probe sequences extracted by computer sequence data base search can also be synthesized as single stranded PNA-probes (Peptide Nucleic Acid probes) or TINA-DNA (Twisted Intercalating Nucleic Acids). Gene targets can be specifically labelled with at least about 20 probes obtaining visibly background free specimens. By using appropriately designed triplex forming oligonucleotides, the denaturing procedures can completely be omitted. These results reveal a significant step towards oligonucleotide-FISH maintaining the 3d-nanostructure and even the viability of the cell target. The method is demonstrated with the detection of Her2/neu and GRB7 genes, which are indicators in breast cancer diagnosis and therapy.

Simultaneous, Single-Cell Measurement of Messenger RNA, Cell Surface Proteins, and Intracellular Proteins

Nucleic acid content can be quantified by flow cytometry through the use of intercalating compounds; however, measuring the presence of specific sequences has hitherto been difficult to achieve by this methodology. The primary obstacle to detecting discrete nucleic acid sequences by flow cytometry is their low quantity and the presence of high background signals, rendering the detection of hybridized fluorescent probes challenging. Amplification of nucleic acid sequences by molecular techniques such as in situ PCR have been applied to single-cell suspensions, but these approaches have not been easily adapted to conventional flow cytometry. An alternative strategy implements a Branched DNA technique, comprising target-specific probes and sequentially hybridized amplification reagents, resulting in a theoretical 8,000- to 16,000-fold increase in fluorescence signal amplification. The Branched DNA technique allows for the quantification of native and unmanipulated mRNA content with increased signal detection and reduced background. This procedure utilizes gentle fixation steps with low hybridization temperatures, leaving the assayed cells intact to permit their concomitant immunophenotyping. This technology has the potential to advance scientific discovery by correlating potentially small quantities of mRNA with many biological measurements at the single-cell level.

FISHIS: fluorescence in situ hybridization in suspension and chromosome flow sorting made easy

The large size and complex polyploid nature of many genomes has often hampered genomics development, as is the case for several plants of high agronomic value. Isolating single chromosomes or chromosome arms via flow sorting offers a clue to resolve such complexity by focusing sequencing to a discrete and self-consistent part of the whole genome. The occurrence of sufficient differences in the size and or base-pair composition of the individual chromosomes, which is uncommon in plants, is critical for the success of flow sorting. We overcome this limitation by developing a robust method for labeling isolated chromosomes, named Fluorescent In situ Hybridization In suspension (FISHIS). FISHIS employs fluorescently labeled synthetic repetitive DNA probes, which are hybridized, in a wash-less procedure, to chromosomes in suspension following DNA alkaline denaturation. All typical A, B and D genomes of wheat, as well as individual chromosomes from pasta (T. durum L.) and bread (T. aestivum L.) wheat, were flow-sorted, after FISHIS, at high purity. For the first time in eukaryotes, each individual chromosome of a diploid organism, Dasypyrum villosum (L.) Candargy, was flow-sorted regardless of its size or base-pair related content. FISHIS-based chromosome sorting is a powerful and innovative flow cytogenetic tool which can develop new genomic resources from each plant species, where microsatellite DNA probes are available and high quality chromosome suspensions could be produced. The joining of FISHIS labeling and flow sorting with the Next Generation Sequencing methodology will enforce genomics for more species, and by this mightier chromosome approach it will be possible to increase our knowledge about structure, evolution and function of plant genome to be used for crop improvement. It is also anticipated that this technique could contribute to analyze and sort animal chromosomes with peculiar cytogenetic abnormalities, such as copy number variations or cytogenetic aberrations.

Chromosomes in the flow to simplify genome analysis

Nuclear genomes of human, animals, and plants are organized into subunits called chromosomes. When isolated into aqueous suspension, mitotic chromosomes can be classified using flow cytometry according to light scatter and fluorescence parameters. Chromosomes of interest can be purified by flow sorting if they can be resolved from other chromosomes in a karyotype. The analysis and sorting are carried out at rates of 10(2)-10(4) chromosomes per second, and for complex genomes such as wheat the flow sorting technology has been ground-breaking in reducing genome complexity for genome sequencing. The high sample rate provides an attractive approach for karyotype analysis (flow karyotyping) and the purification of chromosomes in large numbers. In characterizing the chromosome complement of an organism, the high number that can be studied using flow cytometry allows for a statistically accurate analysis. Chromosome sorting plays a particularly important role in the analysis of nuclear genome structure and the analysis of particular and aberrant chromosomes. Other attractive but not well-explored features include the analysis of chromosomal proteins, chromosome ultrastructure, and high-resolution mapping using FISH. Recent results demonstrate that chromosome flow sorting can be coupled seamlessly with DNA array and next-generation sequencing technologies for high-throughput analyses. The main advantages are targeting the analysis to a genome region of interest and a significant reduction in sample complexity. As flow sorters can also sort single copies of chromosomes, shotgun sequencing DNA amplified from them enables the production of haplotype-resolved genome sequences. This review explains the principles of flow cytometric chromosome analysis and sorting (flow cytogenetics), discusses the major uses of this technology in genome analysis, and outlines future directions.

Overview of molecular testing in non-small-cell lung cancer: mutational analysis, gene copy number, protein expression and other biomarkers of EGFR for the prediction of response to tyrosine kinase inhibitors

Most patients with non-small-cell lung cancer (NSCLC) present with advanced disease. Current treatment paradigms are shifting from cytotoxic chemotherapies alone to single-agent and combination biological and targeted therapies. As patient responses to these therapies vary, predictive biomarkers will be an important facet of a patient's diagnostic workup in personalized medicine, as there is accumulating evidence that they may enable the prognostication and prediction of therapeutic response. Potential biomarkers for the selection of patients with NSCLC most likely to benefit from epidermal growth factor receptor (EGFR) tyrosine kinase inhibitors (TKIs), such as gefitinib and erlotinib, include mutations, gene copy number increase and single-nucleotide polymorphisms of the EGFR gene, EGFR protein expression and oncogenic mutation on the KRAS gene. Many techniques are available to assay for these biomarkers. In this review, we present the current weight of evidence for using these methods as biomarkers for anti-EGFR therapy in patients with NSCLC.

Basic preparative techniques for fluorescence in situ hybridization

This unit presents protocols for preparing human metaphase chromosome slides from peripheral blood lymphocytes, isolating interphase nuclei from lymphocytes and paraffin-embedded tissues, and preparing DNA fibers. The protocols are designed so that the resulting preparations are amenable to FISH. The methods correspond to a selection of the specimens that can be analyzed with FISH techniques, and the choice of sample preparation method is highly dependent on the molecular cytogenetics question being addressed.

Cellular image analysis and imaging by flow cytometry

Imaging flow cytometry combines the statistical power and fluorescence sensitivity of standard flow cytometry with the spatial resolution and quantitative morphology of digital microscopy. The technique is a good fit for clinical applications by providing a convenient means for imaging and analyzing cells directly in bodily fluids. Examples are provided of the discrimination of cancerous from normal mammary epithelial cells and the high-throughput quantitation of fluorescence in situ hybridization (FISH) probes in human peripheral blood mononuclear cells. The FISH application will be enhanced further by the integration of extended depth-of-field imaging technology with the current optical system.

Stratification of non-small cell lung cancer patients for therapy with epidermal growth factor receptor inhibitors: the EGFR fluorescence in situ hybridization assay

DNA fluorescence in situ hybridization (FISH) technology is used to study chromosomal and genomic changes in fixed cell suspensions and tissue block preparations. The technique is based on specific hybridization of small labeled DNA fragments, the probes, to complementary sequences in a target DNA molecule. Demand for FISH assays in formalin-fixed, paraffin-embedded tissues has been increasing, mainly in conditions in which diagnosis is not achieved in cell smears or tissue imprints, such as solid tumors. Moreover, the development of molecular targeted therapies in oncology has expanded the applicability of tests to predict sensitivity or resistance to these agents. The efficient use of tyrosine kinase inhibitors (TKI) of the epidermal growth factor receptor (EGFR) as therapeutical agents in advanced non-small cell lung cancer (NSCLC) depends on identification of patients likely to show clinical benefit from these specific treatments. The EGFR gene copy number determined by FISH has been demonstrated as an effective predictor of outcome from NSCLC patients to EGFR TKIs; however there are pending challenges for standardization of laboratory procedures and definition of the scoring system. This methodology article focuses on the EGFR FISH assay. It details the scoring system used in the studies conducted at the University of Colorado Cancer Center in which a significant association was found between increased EGFR copy numbers and clinical outcome to TKIs, and proposes interpretative guidelines for molecular stratification of NSCLC patients for TKI therapy.

In situ hybridisation for flow cytometry: a molecular method for monitoring stress-gene expression in hemolymph cells of oysters

In the present study, we developed a molecular method for flow cytometry to detect the effects of environmental factors on the stress-response in immunocompetent cells of the European flat oyster, Ostrea edulis. Stress-generating conditions were applied to individuals acclimated in the laboratory to environmental salinity and temperature. Oligonucleotidic probes were applied to quantify the expression of HSP/C70 or metallothionein genes. After a heat-stress, a response was reflected in hemocytes by an increased amount of HSP/C70 mRNA and quantitative changes in HSP/C70 protein expression. The technique of in situ hybridisation described here also allowed to quantify the expression of metallothionein mRNA in oysters exposed to a heavy metal-exposure. The detection of stress protein markers by using such quantitative methods could be applied in contamination studies in oysters and other bivalves where monitoring the status of hemolymph cells is required.

Use of fluorescent sequence-specific polyamides to discriminate human chromosomes by microscopy and flow cytometry

In this paper, we demonstrate the use of synthetic polyamide probes to fluorescently label heterochromatic regions on human chromosomes for discrimination in cytogenetic preparations and by flow cytometry. Polyamides bind to the minor groove of DNA in a sequence-specific manner. Unlike conventional sequence-specific DNA or RNA probes, polyamides can recognize their target sequence without the need to subject chromosomes to harsh denaturing conditions. For this study, we designed and synthesized a polyamide to target the TTCCA-motif repeated in the heterochromatic regions of chromosome 9, Y and 1. We demonstrate that the fluorescently labeled polyamide binds to its target sequence in both conventional cytogenetic preparations of metaphase chromosomes and suspended chromosomes without denaturation. Chromosomes 9 and Y can be discriminated and purified by flow sorting on the basis of polyamide binding and Hoechst 33258 staining. We generate chromosome 9- and Y-specific 'paints' from the sorted fractions. We demonstrate the utility of this technology by characterizing the sequence of an olfactory receptor gene that is duplicated on multiple chromosomes. By separating chromosome 9 from chromosomes 10-12 on the basis of polyamide fluorescence, we determine and differentiate the haplotypes of the highly similar copies of this gene on chromosomes 9 and 11.

Telomere analysis by fluorescence in situ hybridization and flow cytometry

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

Telomere length dynamics in human lymphocyte subpopulations measured by flow cytometry

To measure the average length of telomere repeats at chromosome ends in individual cells we developed a flow cytometry method using fluorescence in situ hybridization (flow FISH) with labeled peptide nucleic acid (PNA) probes. Results of flow FISH measurements correlated with results of conventional telomere length measurements by Southern blot analysis (R = 0.9). Consistent differences in telomere length in CD8+ T-cell subsets were identified. Naive and memory CD4+ T lymphocytes in normal adults differed by around 2.5 kb in telomere length, in agreement with known replicative shortening of telomeres in lymphocytes in vivo. T-cell clones grown in vitro showed stabilization of telomere length after an initial decline and rare clones capable of growing beyond 100 population doublings showed variable telomere length. These results show that flow FISH can be used to measure specific nucleotide repeat sequences in single cells and indicate that the very large replicative potential of lymphocytes is only indirectly related to telomere length.

Flow cytometric detection of EBV (EBER snRNA) using peptide nucleic acid probes

The application of peptide nucleic acid (PNA) probes for detection of Epstein-Barr Virus (EBV) snRNA in fixed cells is described. Fluorescein labelled PNA probes were used to detect EBER1 and EBER2 snRNA in Raji, Daudi and HS-Sultan cells. The fixation and permeabilization of cells were optimized. The optimal fixation was found to be 5% acetic acid plus 4% paraformaldehyde in PBS and the optimal permeabilization 0.5% Tween 20 in PBS whereas no proteolytic digestion was needed. The hybridization time needed with the PNA probes was only 1 h. When running mixed samples of Ramos (EBV neg.) Raji, Daudi and HS-Sultan (EBV pos.) cells in flow cytometry a strong fluorescence signal was seen in Raji, Daudi and HS-Sultan cells whereas no fluorescence signal was seen in the Ramos cells. In total 0.5% EBER positive Raji cells could easily be identified in a mixture of Raji and Ramos cells. The results were verified by fluorescence microscopy. It is concluded that PNA probes can be used for in situ hybridization in solution and the analysis can be done using flow cytometry or fluorescence microscopy. PNA probes therefore may facilitate and enhance the potential use of the in situ hybridization/flow cytometry combination.

Trisomy 12 in B-cell chronic lymphocytic leukemia: correlation with advanced disease, atypical morphology, high levels of sCD25, and with refractoriness to treatment

In situ hybridization was performed to study the clinical significance of trisomy 12 in fifty patients with B-cell chronic lymphocytic leukemia at various stages of disease. Trisomy 12 was detected in 12%-65% (median 53%) of the circulating neoplastic cells in seven out of 20 patients with advanced Binet stage C disease. In contrast, 22 patients with Binet stage A and eight patients with Binet stage B disease were found to be negative for trisomy 12. As occurrence of trisomy 12 was associated with the presence of B-symptoms and hepatosplenomegaly, its association with advanced disease was further considered. In addition, atypical morphology was a common finding in trisomic patients who also displayed higher serum levels of soluble CD25 than patients without trisomy at Binet stage C. No significant differences were detected in serum levels of soluble CD8 and of soluble CD23. No correlation with a lymphocyte doubling time of < 12 months, marked lymphadenopathy, or prior treatment was apparent. However, refractoriness to treatment was evident more frequently in trisomic than in non-trisomic patients (p < .05). In conclusion, trisomy 12 in B-cell chronic lymphocytic leukemia appears to occur predominantly in advanced and symptomatic disease with atypical morphology. It could indicate a high risk for treatment failure thus serving as a marker of poor prognosis in this disease.

Chromosome specific DNA hybridization in suspension for flow cytometric detection of chimerism in bone marrow transplantation and leukemia

Flow cytometry was used to measure the fluorescence intensity of nuclei that were subjected to fluorescent in situ hybridization in suspension with chromosome specific DNA probes. Paraformaldehyde-fixed nuclei were protein digested with trypsin and hybridized simultaneously with a biotin- and DIG labeled chromosome specific centromere probe. A number of probes were tested in the suspension hybridizations. The method yielded fluorescent hybridization signals that allow discrimination between Y chromosome positive and negative nuclei when analyzed by flow cytometry. The method is especially suited for analysis of bone marrow cells derived from patients who have received a sex-mismatched allogeneic bone marrow transplantation. Male leukemia cells with a trisomy for chromosome 8 were mixed with normal female cells and simultaneously hybridized in suspension with a DIG labeled probe specific for chromosome 8 and the biotin labeled Y chromosome probe. Y chromosome positive or negative nuclei were sorted onto microscope slides and subsequently classified as being leukemic or not by fluorescence microscopy, on the basis of the presence of a trisomy for chromosome 8. A 120-fold enrichment could be achieved when 300 Y positive nuclei were sorted from a mixture originally containing 0.5% leukemia cells. Given the specificity of the flow cytometry and FISH procedure, the combination of the two methods can reach a lower detection level of 1 per 250,000.

Rapid fluorescence in situ hybridization with repetitive DNA probes: quantification by digital image analysis

Fluorescence in situ hybridization (FISH) has become an important tool not only in cytogenetic research but also in routine clinical chromosome diagnostics. Here, results of a quantification of fluorescence signals after in situ hybridization with repetitive DNA probes are reported using a non-enzymatic hybridization technique working with a buffer system not containing any formamide or equivalent chemical denaturing agents. Following simultaneous denaturation of both cells and DNA probes, the renaturation time was reduced to less than 30 min. For one of the DNA probes reasonable FISH-signals were even achieved after about 30 s renaturation time. In addition, the number of washing steps was reduced drastically. As a model system, two repetitive DNA probes (pUC 1.77, D15Z1) were hybridized to human metaphase spreads and interphase nuclei obtained from peripheral blood lymphocytes. The probes were labelled with digoxigenin and detected by FITC-anti-digoxigenin. The hybridization time was reduced step by step and the resulting fluorescence signals were examined systematically. For comparison the pUC 1.77 probe was also hybridized according to a FISH protocol containing 50% formamide. By renaturation for 2 h and overnight two FISH signals per nucleus were obtained. Using shorter renaturation times, no detectable FISH signals were observed. Quantification of the FISH signals was performed using a fluorescence microscope equipped with a cooled colour charge coupled device (CCD) camera. Image analysis was made interactively using a commercially available software package running on a PC (80486). For the pUC 1.77 probe the major binding sites (presumptive chromosomes 1) were clearly distinguished from the minor binding sites by means of the integrated fluorescence intensity. For the two (pUC 1.77) or four (D15Z1) brightest spots on the metaphase spreads and in the interphase nuclei hybridized without formamide, integrated fluorescence intensity distributions were measured for different renaturation times (0.5, 15, 30 min). The intra-nuclear variation in the intensity of the two brightest in situ hybridization spots appeared to be slightly higher (CV between 16 and 32%) than the corresponding variation in the metaphase spreads (CV between 10 and 19%). For the D15Z1 probe FISH signals were detected after hybridization without formamide and 15 min and 30 min renaturation. Always four bright spots were visible and tentatively assigned on the metaphase spreads (presumptive chromosome 15 and 9). The intensity variation of each pair of homologues in a metaphase spread showed a CV of 14 or 15%, respectively, for the presumptive chromosome 15, and 8 or 9%, respectively, for the presumptive chromosome 9.

Flow-cytometric quantification in human gliomas of alpha satellite DNA sequences specific for chromosome 7 using fluorescence in situ hybridization

Cell suspensions prepared from freshly frozen tissue specimens were used to examine aberrations in the number of chromosome 7 signals in 10 human gliomas. Nuclear DNA was hybridized in vitro with an alpha satellite DNA probe specific for the centromeric regions of chromosome 7, using fluorescence in situ hybridization (FISH). The intensity of the fluorescence signal from the hybridized probe was measured, together with the nuclear DNA content, by flow cytometry. The mean probe fluorescence of all nuclei was compared to the mean copy number per nucleus found with microscopic scoring. Moreover, the mean probe fluorescence ratio of DNA aneuploid nuclei relative to DNA diploid nuclei (FISHa/FISHd) was calculated to determine how the numerical aberration of chromosome 7 signals contributes to the DNA ploidy of the sample. The results from the flow-cytometric analysis and from microscopic evaluation were compatible. One of four tumors with DNA diploidy had a higher average intensity of FISH signal and a broader coefficient of variation in FISH signal than normal brain tissue; this was shown to be due to the gain of chromosome 7 signals. Although FISHa/FISHd correlated with DNA indices (P < 0.01), there were some disparities, probably due to other complex genotypic associations involving several gains or losses of chromosomes. Thus gain of chromosome 7 in gliomas is related to both DNA ploidy change and chromosome specific gain. It is concluded that flow-cytometric quantification of FISH is useful in investigating numerical aberrations of chromosomes and nuclear DNA content simultaneously.

Interphase cytogenetic study of childhood acute lymphoblastic leukemia

We used the fluorescence in situ hybridization (FISH) technique and centromere-specific probes for chromosomes 1, 6, 8, 10, 12, 17, 18, X, and Y to investigate the presence and number of the respective chromosomes in interphase nuclei of 14 cases of childhood acute lymphoblastic leukemia (ALL) which were shown to be hyperdiploid by DNA flow cytometry irrespective of their cytogenetic pattern. Numerical anomalies for one or more chromosomes were detected in all 14 cases. The FISH results were compared with those obtained by conventional cytogenetic analysis. A hyperdiploid karyotype was evident in 5 cases, the others were either normal or lacking cytogenetic results because of technical failure. In the 5 cytogenetically hyperdiploid cases, 14 numerical abnormalities were observed with both techniques, whereas 4 numerical deviations were found only with FISH. In 9 other cases which had a DNA content indicating hyperdiploidy, 34 trisomies and 2 tetrasomies were detected by FISH analysis. Furthermore, in 1 case duplication of the Y chromosome and in 3 male cases duplication of the X chromosome were evident. Double-target FISH experiments in 2 patients allowed the correlation of numerical aberrations of 2 chromosomes in one and the same cell. By such analyses, detection of subpopulations of tumor cells was found to be relatively easy. Our results indicate that the FISH technique with chromosome-specific repetitive centromeric probes is a rapid, simple to use, and easy to interpret technique for the evaluation of numerical chromosomal aberrations in interphase nuclei of leukemias.

Detection of human papillomavirus DNA in CaSki and HeLa cells by fluorescent in situ hybridization. Analysis by flow cytometry and confocal laser scanning microscopy

CaSki and HeLa cell lines, isolated from human uterine carcinomas and containing integrated human papillomavirus (HPV) DNA type 16 and 18, respectively were used to evaluate the sensitivity of HPV-DNA detection on suspended cells by fluorescent in situ hybridization using flow cytometry and on corresponding cell deposits using confocal laser scanning microscopy (CLSM). HPV DNAs were detected in cell suspensions with biotinylated DNA probes and revealed with a three-step technique: a rabbit antibiotin antibody, a biotinylated goat anti-rabbit antibody and a streptavidin-fluorescein isothiocyanate complex. By flow cytometry, HPV DNA was detectable only in CaSki cells which contained about 600 copies of HPV DNA per cell. In HeLa cells, with only 20-50 copies of HPV DNA, flow cytometry could not detect HPV DNA, whereas CLSM permitted visualization of fluorescent labelling of HPV DNA hybrids. Furthermore, CLSM showed good preservation of cellular morphology and the nucleus was clearly recognizable after fluorescent in situ hybridization and counterstaining with propidium iodide. Moreover, this examination confirmed that the fluorescent foci were specifically confined to the cell nuclei.

Detection of cytomegalovirus-infected cells by flow cytometry and fluorescence in suspension hybridisation (FLASH) using DNA probes labeled with biotin by polymerase chain reaction

A biotin-labeled DNA probe specific for the immediate early gene of the cytomegalovirus (CMV) strain AD 169 was generated with the polymerase chain reaction. Nucleic acid hybridisation was carried out with CMV-infected T-lymphoblastoid cells (MOLT-4) after 4 hr to 6 days of culture. Biotin molecules were made visible with streptavidin coupled with fluorescein. The fluorescence signal of the hybridised probe was measured by flow cytometry in the cell suspension. The number of CMV-positive cells was 7% at 4 hr, 8% after 28 hr, 18% after 2 days, 26% after 3 days, 91% after 4 days, 97% after 5 days, and 98% after 6 days. The first detection of CMV antigen (pp65) was possible with immunoenzymatic labeling by day 4, whereas CMV-DNA was detected by PCR after 4 hr. CMV-specific RNA could be detected in a similar way. The analysis of mononuclear peripheral blood leukocytes in a patient with active CMV infection showed 14.7% CMV DNA-positive cells at day 1 and 7% at day 8, as compared to 0.9% and 0.0% cells which were positive for CMV antigen (pp65) by immunoenzymatic labeling at day 1 and day 8, respectively. We conclude that flow cytometry and fluorescence in suspension hybridisation (FLASH) offers a new tool for analysing exactly and quantifying large numbers of cells for specific DNA or RNA and may be useful for other laboratory and clinical applications.

Sensitive detection of RNAs in single cells by flow cytometry

A rapid and sensitive fluorescent in situ hybridization method has been developed to probe RNA contents of individual cells by flow cytometry. Fixed cells in suspension were hybridized with 5' end-fluorophore-labeled oligodeoxynucleotides complementary to defined regions of the RNA of interest and analyzed by flow cytometry. With this method, we monitored combinations of histone H4 mRNA, 18S rRNA and 28S rRNA levels in synchronized HeLa S3 cells by multicolor analysis. A fluorescence signal equivalent to 1800 copies of histone H4 mRNA per cell was detected with signal-to-background ratio of 5.4. If non-specific binding of the fluorophore-labeled probe can be reduced, as few as 100 copies of mRNA of the size of H4 could be detected in individual cells by flow cytometry.

Flow cytometric measurement of rRNA levels detected by fluorescent in situ hybridization in differentiating K-562 cells

The flow cytometric detection of fluorescent in situ hybridization (FISH) performed on intact cells in suspension is a recently described method (Bauman et al. 1989). We studied the application of this method for monitoring cellular differentiation. The amount of rRNA which is taken for a good indicator of growth in size, the rate of protein synthesis and the G0 G1 transition was followed by FISH. For this purpose biotinylated single stranded RNA probes obtained by transcription from a 2.1 kb BglII-EcoRI fragment of the human 28S ribosomal RNA gene subcloned into plasmid pGEM2 were used. K-562 leukaemic cells, used as targets, were induced to differentiate by dimethyl sulfoxide, phorbol myristate acetate and hemin. In the last two cases the cell cycle analysis, growth kinetics, cellular morphology and immunophenotyping indicated differentiation into monocytic and erythroid direction, respectively. The differentiation was accompanied by a rapid increase followed by a decrease to the base level of rRNA. This was not observed in the uninduced exponentially growing control cells. Based on our results, we propose that the FC-FISH detection of the rRNA level is a valuable method to distinguish between cell subpopulations. We propose that using other probes, FC-FISH will become useful to monitor different cellular processes.

Denaturation behaviour of DNA-protein-complexes detected in situ in metaphase chromosomes in suspension by Hoechst 33258 fluorescence

The denaturation behaviour of DNA-protein complexes in metaphase chromosomes in suspension was analysed in situ by Hoechst 33258 fluorescence. The results indicate that due to the stability of the dye molecule and the product of the molecular extinction coefficient and the quantum yield at different temperatures, Hoechst 33258 is a suitable probe for the detection of double-stranded DNA. Thus, it is possible to monitor the concentration of double-stranded DNA in a suspension by measuring the total fluorescence intensity. The fluorescence denaturation profiles of DNA (calf thymus) were found to be comparable to absorption measurements. The decrease in fluorescence of metaphase chromosomes in suspension with increasing temperature may therefore be used to detect conformational changes of DNA in situ.

Interphase and metaphase resolution of different distances within the human dystrophin gene

Fluorescence in situ hybridization makes possible direct visualization of single sequences not only on chromosomes, but within decondensed interphase nuclei, providing a potentially powerful approach for high-resolution (1 Mb and below) gene mapping and the analysis of nuclear organization. Interphase mapping was able to extend the ability to resolve and order sequences up to two orders of magnitude beyond localization on banded or unbanded chromosomes. Sequences within the human dystrophin gene separated by less than 100 kb to 1 Mb were visually resolved at interphase by means of standard microscopy. In contrast, distances in the 1-Mb range could not be ordered on the metaphase chromosome length. Analysis of sequences 100 kb to 1 Mb apart indicates a strong correlation between interphase distance and linear DNA distance, which could facilitate a variety of gene-mapping efforts. Results estimate chromatin condensation up to 1 Mb and indicate a comparable condensation for different cell types prepared by different techniques.

Spatial topography of a pericentromeric region (1q12) in hemopoietic cells studied by in situ hybridization and confocal microscopy

A fluorescent in situ hybridization procedure with a chromosome 1-specific (1q12) repetitive satellite DNA probe was used to label the 1q12 regions of the chromosomes 1 in spherical and polymorphic hemopoietic cell nuclei. The entire procedure was performed in suspension to preserve nuclear morphology. The result was studied by three-dimensional analysis, as provided by a scanning laser confocal microscope. The 1q12 regions of chromosome 1 were measured to be closely associated with the nuclear envelope in isolated nuclei of unstimulated diploid human lymphocytes. The relative positions to each other in the periphery of these spherical nuclei could not be distinguished from a random distribution pattern. In the diploid and tetraploid polymorphic nuclei of cells of the promyelocytic leukemia cell line HL60 these pericentromeric sequences were also associated with the nuclear surface.

Flow cytometric detection of beta-globin mRNA in murine haemopoietic tissues using fluorescent in situ hybridization

The novel method for flow cytometric detection of cellular RNA species in suspended cells by fluorescent in situ hybridization (FC-FISH) was applied in the evaluation of beta-globin expression in murine haemopoietic tissues. Normal murine bone marrow cells and regenerating bone marrow cells obtained after lethal irradiation and bone marrow transplantation as well as murine 15 d fetal liver were examined. Furthermore, spleens and bone marrow of phenylhydrazine-induced anaemic mice were studied. Biotinylated sense- and antisense single strand RNA probes, obtained by transcription of a 510 nucleotides murine beta-globin cDNA sequence subcloned into the pGEM1 plasmid were used as hybridization probes. For detection of the hybrids formed, avidin-FITC was used. Only the antisense beta-globin probe gave strongly positive fluorescence signals in a defined population of cells in each of the tissues examined, whereas the sense probe did not give signals higher than control samples. Melting characteristics of the hybrids showed the specificity of the in situ hybridization reaction. Forward light scatter distributions, reflecting cell size of the positive cells were as expected from erythroid cells. Within the erythrocyte subpopulation both beta-globin-negative and -positive cells were detected. The percentages of positive cells determined flow cytometrically correlated with the percentages observed in May-Grünwald/Giemsa stained preparations. Differences observed in fluorescence intensity between positive cells of different organs were no larger than about a factor of two, indicating a rather constant beta-globin mRNA content over the entire differentiation range. An exception was 15 d fetal liver, which was shown biochemically to contain about eight times more beta-globin RNA and which had a 2.4 times higher fluorescence intensity. We estimate that the sensitivity of the present method is such that as little as 500 copies per cell of a specific mRNA of 1 kb length would be detectable.

Fluorescent in-situ hybridization to detect cellular RNA by flow cytometry and confocal microscopy

A fluorescent in-situ hybridization procedure was developed which is suitable for detection of specific cellular RNA in cells fixed in suspension. The procedure was originally developed for analysis of single-cell suspensions by flow cytometry. The resulting fluorescent cells proved to have their 3-D morphology perfectly preserved. The spatial distribution of specific ribosomal RNA and messenger RNA could then be analysed by confocal microscopy of individual cells. In the hybridization procedure, biotinylated single-stranded RNA probes were used that were produced by transcription from cloned DNA fragments. Detection of poly-(A)+ RNA was performed with a poly-biotin-d(U)-tailed oligo-d(T) probe. Bound probe was detected using streptavidin-fluorescein isothiocyanate. For flow cytometry, nuclear DNA was counterstained with di-amidine-2-phenyl indol. Multi-parameter flow cytometry was used to quantify the fluorescence intensity, i.e. the hybridization signal, of thousands of cells. Confocal scanning microscopy on individual cells revealed the intracellular distribution of the target RNA. The distribution of ribosomal RNA and poly-(A)+ RNA mRNA in mouse bone marrow and the human leukaemia cell line HL60 cells was investigated. Ribosomal RNA was confined to the cytoplasm of the cells, although in many cells the nucleoli could also be distinguished. Poly-(A)+ RNA in HL60 cells was found both in the cytoplasm and nucleus. A granular cytoplasmic distribution was seen in part of these cells.

Flow cytometric quantification of human chromosome specific repetitive DNA sequences by single and bicolor fluorescent in situ hybridization to lymphocyte interphase nuclei

Fluorescent in situ hybridization allows for rapid and precise detection of specific nucleic acid sequences in interphase and metaphase cells. We applied fluorescent in situ hybridization to human lymphocyte interphase nuclei in suspension to determine differences in amounts of chromosome specific target sequences amongst individuals by dual beam flow cytometry. Biotinylated chromosome 1 and Y specific repetitive satellite DNA probes were used to measure chromosome 1 and Y polymorphism amongst eight healthy volunteers. The Y probe fluorescence was found to vary considerably in male volunteers (mean fluorescence 169, S.D. 35.6). It was also detectable in female volunteers (mean fluorescence 81, S.D. 10.7), because 5-10% of this repetitive sequence is located on autosomes. The Y probe fluorescence in males was correlated with the position of the Y chromosome cluster in bivariate flow karyotypes. When chromosome 1 polymorphism was studied, one person out of the group of eight appeared to be highly polymorphic, with a probe fluorescence 26% below the average. By means of fluorescent in situ hybridization on a glass slide and bivariate flow karyotyping, this 26% difference was found to be caused by a reduction of the centromere associated satellite DNA on one of the homologues of chromosome 1. The simultaneous hybridization to human lymphocyte interphase nuclei of biotinylated chromosome 1 specific repetitive DNA plus AAF-modified chromosome Y specific DNA was detected by triple beam flow cytometry. The bicolor double hybridized nuclei could be easily distinguished from the controls. When the sensitivity of this bicolor hybridization is improved, this approach could be useful for automatic detection of numerical chromosome aberrations, using one of the two probes as an internal control.

Non-isotopic RNA probes. Comparison between different labels and detection systems

Several studies have shown the use of non-radioactive labelled DNA probes for in situ hybridisation, mainly to identify cellular DNA. In this study mRNA in situ hybridisation was performed on rat pituitary with biotinylated complementary (c) RNA probes for rat prolactin and growth hormone (GH), and compared with radioactive 35S-radiolabelled probes. Biotinylated cRNA probes were labelled with either biotin-11-UTP or with allylamine-UTP, the latter method being able to produce a higher yield of labelled RNA. Different detection systems were tested, and hybridisation signal was seen in cells of anterior pituitary with both types of biotinylated probes. The signals were detected using either avidin-biotin-complex with peroxidase (ABC), peroxidase-anti-peroxidase (PAP) or gold-silver methods. ABC peroxidase detected using glucose oxidase-diaminobenzidine (DAB)-nickel solution appeared to be the best method for detecting labelled RNA probes, with very strong signal and low background. The biotinylated probes were comparable in sensitivity to the radiolabelled probes in detecting prolactin and GH mRNAs in the anterior lobe of the rat pituitary. These results indicate an alternative methods of labelling and detection of biotinylated probes which could have a potential role in research and diagnostic techniques.

Parallel processing data acquisition system for multilaser flow cytometry and cell sorting

This report describes the data acquisition electronics for a flow cytometer. The design differs from most instruments in that the signals from a large number of detectors are processed in parallel. Each of the input channels is capable of autonomously measuring and digitizing the fluorescence signals. The digitized values that belong to one particle are collected by digital circuitry and are presented as a compact data package on a special bus. In addition to the pulse values, the data package contains a time marker, information needed for sort decisions, and an error detection code. Specially designed electronic modules that read the information from the bus can take complex multiparameter sort decisions at a very high speed. All events can also be recorded as data lists by a computer. The lists can be used to reconstruct a sort or analysis run. The raw data lists can also be reduced to kinetic curves and/or (gated) multivariate histograms. As a result of the applied scheme of parallel pulse processing, the dead time of the system is independent of the number of parameters measured and the number and time separation of the excitation beams. The instrument has a cycle time of 5 microseconds, which corresponds to a throughput rate of 2 x 10(5) events/s. At this rate, the incidence of correlation errors is well below 1 in 10(8) analyzed particles. The system has proved to be reliable and convenient to use in a variety of experiments. Its high speed and low error rate make it well suited for high-resolution measurements, rare-event analysis, kinetic measurements, and high-speed cell sorting.

Detection of mRNA in flow-sorted cells

Cells were sorted onto nitrocellulose filters which were saturated with a lysing cocktail designed to preferentially immobilize cellular mRNA. After washing, these filters were incubated with 32P-labeled specific DNA probes. We used the phorbol ester/lipopolysaccharide (PMA + LPS) co-induction of IL-1 mRNA and CD13 expression in U937 cells to demonstrate the specificity of the technique. In addition we used the abundant expression of c-fos in U937 to demonstrate linearity. IL-1 beta mRNA is readily discernable autoradiographically from as few as 5,000 PMA + LPS-induced cells sorted onto a filter. With liquid scintillation counting we demonstrate good linearity of the c-fos quantitation over the range of 1,000 cells to 60,000 cells per filter target. The technique is easily adapted to any sorting flow cytometer and should prove useful to help correlate any flow cytometric cell phenotype with specific mRNA abundance.

In situ DNA-RNA hybridization using in vivo bromodeoxyuridine-labeled DNA probe

An in vivo 5'-bromodeoxyuridine (BrdUrd) labeled DNA probe was used for in situ DNA-RNA hybridization. BrdUrd was incorporated into plasmid DNA by inoculating E. coli with Luria-Bertani (LB) culture medium containing 500 mg/L of BrdUrd. After purification of the plasmid DNA, specific probes of the defined DNA fragments, which contained the cloned insert and short stretches of the vector DNA, were generated by restriction endonuclease. The enzymatic digestion pattern of the BrdUrd-labeled plasmid DNA was the same as that of the non-labeled one. BrdUrd was incorporated in 15%-20% of the total DNA, that is, about 80% of the thymidine was replaced by BrdUrd. Picogram amounts of the BrdUrd-labeled DNA probe itself and the target DNA were detectable on nitrocellulose filters in dot-blot spot and hybridization experiments using a peroxidase/diaminobenzidine combination. The BrdUrd-labeled DNA probe was efficiently hybridized with both single stranded DNA on nitrocellulose filters and cellular mRNA in in situ hybridization experiments. Through the reaction with BrdUrd in single stranded tails, hybridized probes were clearly detectable with fluorescent microscopy using a FITC-conjugated monoclonal anti-BrdUrd antibody. The in vivo labeling method did not require nick translation steps or in vitro DNA polymerase reactions. Sensitive, stable and efficient DNA probes were easily obtainable with this method.

Flow cytometric detection of ribosomal RNA in suspended cells by fluorescent in situ hybridization

A method using flow cytometry and fluorescent in situ hybridization (ISH) to detect RNA in cells is described. L1210 murine leukemia cells were fixed with 1% formaldehyde in HEPES buffered Hank's balanced salt solution (HH) followed by 70% ethanol. Endogenous RNAses were blocked by diethylpyrocarbonate treatment. Single-stranded sense and antisense RNA probes, labeled with biotin-11-UTP, were transcribed from a 2.1 kb 28S ribosomal RNA (rRNA) gene fragment subcloned into the pGEM2 plasmid. For good results, it was essential that the probes were degraded to 100-150 nucleotides before use. Hybridization was performed at 45 degrees C in 50% formamide, 5 x SSC, 0.5% SDS. Hybrids were detected with streptavidin-FITC by flow cytometry. Antisense rRNA probe signal was 100 times higher than the background. The hybrids were largely resistant to RNAse and melted at high temperature. The sense probe also gave a signal (5 times background), which was not RNAse resistant and was attributed to the presence of internal inverted repeats in the ribosomal RNA. When sufficient background reduction can be achieved, it is expected that as few as ten mRNA molecules per cell can be detected with the fluorescent in situ hybridization method.

Sorting of chromosomes by magnetic separation

Chromosomes were isolated from Chinese hamster x human hybrid cell lines containing four and nine human chromosomes. Human genomic DNA was biotinylated by nick translation and used to label the human chromosomes by in situ hybridization in suspension. Streptavidin was covalently coupled to the surface of magnetic beads and these were incubated with the hybridized chromosomes. The human chromosomes were bound to the magnetic beads through the strong biotin-streptavidin complex and then rapidly separated from nonlabeled Chinese hamster chromosomes by a simple permanent magnet. The hybridization was visualized by additional binding of avidin-FITC (fluorescein) to the unoccupied biotinylated human DNA bound to the human chromosomes. After magnetic separation, up to 98% of the individual chromosomes attached to magnetic beads were classified as human chromosomes by fluorescence microscopy.

Enzymatic production of single-stranded DNA as a target for fluorescence in situ hybridization

This study demonstrates that Exonuclease III (Exo III) can be used to produce sufficient single-stranded (ss)DNA in chromosomes and cells to allow in situ hybridization. In this study, all of the probes were modified with biotin and the probe binding was visualized with fluorescein-labeled avidin. Exo III digestion starting at naturally occurring breaks in methanol-acetic acid preparations produced enough ssDNA for strong hybridization when human genomic DNA was used to probe human chromosomes. Pretreatment with the endonucleases EcoRI, Hind III and BamHI was used to produce more sites for initiation of Exo III digestion when using a chromosome-specific repetitive probe specific to a small chromosomal subregion near the telomere of human chromosome 1(1p36). The fluorescence intensity following hybridization to Exo III-treated targets was roughly equal to that following hybridization to thermally denatured targets, but background fluorescence was lower.

Selection and separation of X- and Y- chromosome-bearing mammalian sperm

Preselection of the gender of offspring is a subject that has held man's attention since the beginning of recorded history. Most scientific hypotheses for producing the desired sex of offspring address separation of X- and Y-bearing sperm, and most have had limited, if any success. Eight of these hypotheses and their experimental verifications are discussed here. Three hypotheses are based on physical characteristics of sperm, one on supposed differences in size and shape, another on differences in density, and a third on differences in surface charge. There has been no experimental verification of differences based on size and shape, and the results from attempts to verify separation of X- and Y-bearing sperm based on density have been mixed. Electrophoresis may provide a method for separating X- and Y-bearing sperm, but it is currently unproven and would be of little practical utility, since sperm motility is lost. A fourth hypothesis employs H-Y antigen to select preimplantation embryos. This method reliably produces female offspring, but does not permit the selection of male offspring and does not work on sperm. There are two applications of the theory that X- and Y-bearing sperm should be separable by flow fractionation. Flow fractionation using thermal convection, counter-streaming sedimentation, and galvanization is highly promoted by its originator but has not gained wide acceptance due to lack of independent confirmation. Flow fractionation by laminar flow is said to provide up to 80% enrichment of both X- and Y-bearing sperm; however, this method also has not been confirmed by other workers or tested in breeding trials. The sixth theory discussed is that of separation through Sephadex gel filtration. This method may provide enrichment of X-bearing sperm, but, again, other experimenters have not been able to adequately confirm the enrichment. The best-known approach to sperm separation is that employing albumin centrifugation, yet even with this method, not all researchers have been able to confirm a final fraction rich in Y sperm, and trials in animals have given contradictory results. The most reliable method for separating X- and Y-bearing sperm is use of flow cytometric and flow sorting techniques. These techniques routinely separate fractions with a purity greater than 80% and can be above 90%. Unfortunately, these methods do not always work for human samples. Furthermore, as with electrophoretic approaches, the methods identify and separate only chemically fixed sperm and provide limited biological applications.(ABSTRACT TRUNCATED AT 400 WORDS)

Rapid interphase and metaphase assessment of specific chromosomal changes in neuroectodermal tumor cells by in situ hybridization with chemically modified DNA probes

Repeated DNAs from the constitutive heterochromatin of human chromosomes 1 and 18 were used as probes in nonradioactive in situ hybridization experiments to define specific numerical and structural chromosome aberrations in three human glioma cell lines and one neuroblastoma cell line. The number of spots detected in interphase nuclei of these tumor cell lines and in normal diploid nuclei correlated well with metaphase counts of chromosomes specifically labeled by in situ hybridization. Rapid and reliable assessments of aneuploid chromosome numbers in tumor lines in double hybridization experiments were achieved, and rare cells with bizarre phenotype and chromosome constitution could be evaluated in a given tumor cell population. Even with suboptimal or rare chromosome spreads specific chromosome aberrations were delineated. As more extensive probe sets become available this approach will become increasingly powerful for uncovering various genetic alterations and their progression in tumor cells.

Fluorescence in situ hybridization to interphase cell nuclei in suspension allows flow cytometric analysis of chromosome content and microscopic analysis of nuclear organization

Fluorescence hybridization to interphase nuclei in liquid suspension allows quantification of chromosome-specific DNA sequences using flow cytometry and the analysis of the three-dimensional positions of these sequences in the nucleus using fluorescence microscopy. The three-dimensional structure of nuclei is substantially intact after fluorescence hybridization in suspension, permitting the study of nuclear organization by optical sectioning. Images of the distribution of probe and total DNA fluorescence within a nucleus are collected at several focal planes by quantitative fluorescence microscopy and image processing. These images can be used to reconstruct the three-dimensional organization of the target sequences in the nucleus. We demonstrate here the simultaneous localization of two human chromosomes in an interphase nucleus using two probe labeling schemes (AAF and biotin). Alternatively, dual-beam flow cytometry is used to quantify the amount of bound probe and total DNA content. We demonstrate that the intensity of probe-linked fluorescence following hybridization is proportional to the amount of target DNA over a 100-fold range in target content. This was shown using four human/hamster somatic cell hybrids carrying different numbers of human chromosomes and diploid and tetraploid human cell lines hybridized with human genomic DNA. We also show that populations of male, female, and XYY nuclei can be discriminated by measuring their fluorescence intensity following hybridization with a Y-chromosome-specific repetitive probe. The delay in the increase in Y-specific fluorescence until the end of S-phase in consistent with the results recorded in previous studies indicating that these sequences are among the last to replicate in the genome. A chromosome-17-specific repetitive probe is used to demonstrate that target sequences as small as one megabase (Mb) can be detected using fluorescence hybridization and flow cytometry.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection of proopiomelanocortin mRNA by in situ hybridization, using a biotinylated oligodeoxynucleotide probe and avidin-alkaline phosphatase histochemistry

A synthetic 24-mer oligodeoxynucleotide complementary to the region of proopiomelanocortin (POMC) mRNA that codes for the MSH core sequence (alpha MSH/ACTH[4-11]), was synthesized and labelled in the 3'-end by use of terminal transferase. Probes tailed with either [3H]- or biotin-labelled nucleotides could be used for in situ hybridization studies. Biotinylated probes, hybridized to mouse and rat pituitary sections, were detected by avidin-alkaline phosphatase or streptavidin-alkaline phosphatase procedures and development in 5-bromo-4-chloro-3-indolyl phosphate (BCIP)-nitroblue tetrazolium (NBT). Proteinase K pretreatment of sections produced a drastic enhancement of the signal obtained, particularly in strongly fixed, paraffin-embedded material. The non-radioactive in situ hybridization technique compared favourably to radioactive in situ hybridization in terms of rapidity and precision of the localization. Controls involved deletion of the probe to prove that other components of the reaction sequence did not yield stain, digestion with RNase to prove that tissue RNA was necessary to bind the probe, prehybridization (blocking) with unlabelled probe to prove that the biotinylated probe reacted with its anti-sense region and not its tail and Northern blotting to show that the probe reacted with only one species of pituitary RNA, having the size of mouse pituitary POMC mRNA. In addition, adrenalectomy, known to increase anterior lobe POMC levels, resulted in both increased numbers and increased intensity of positive corticotroph-like cells. Synthetic oligodeoxynucleotides labelled with biotin appear to constitute attractive reagents for in situ hybridization studies when supported by appropriate control procedures.