Three-color fluorescence in situ hybridization for the simultaneous detection of multiple nucleic acid sequences

Quantification of inter- and intra-nuclear variation of fluorescence in situ hybridization signals

This study aims at the quantification of specific DNA sequences by using fluorescence in situ hybridization (ISH) and digital imaging microscopy. The cytochemical and cytometric aspects of a quantitative ISH procedure were investigated, using human peripheral blood lymphocyte interphase nuclei and probes detecting high copy number target sequences as a model system. These chromosome-specific probes were labeled with biotin, digoxigenin, or fluorescein. Quantification of the fluorescence ISH signals was performed using an epifluorescence microscope equipped with a multi-wavelength illuminator, and a cooled charge coupled device (CCD) camera. Specific image analysis programs were developed for the segmentation and analysis of the images provided by ISH. The fluorescence intensity distributions of the ISH spots showed large internuclear variation (CVs up to 65%) for the probes used. The variation in intensity was found to be independent of the probe, the type of labeling, and the type of immunocytochemical detection used. Variation in intensity was not caused primarily by the immunocytochemical detection method, since directly fluorescein-labeled probes showed similar internuclear variation. Furthermore, it was found that different white blood cell types, which harbor different degrees of compactness of the nuclear chromatin, showed the same variation. The intra-nuclear variation in intensity of the ISH spots on the two chromosome homologs within one nucleus was significantly smaller (approximately 20%) than the inter-nuclear variation, probably due to more constant local hybridization conditions. Due to the relatively small intranuclear variation, copy number polymorphisms of the satellite DNA sequence on chromosome 1 could readily be quantified.(ABSTRACT TRUNCATED AT 250 WORDS)

Specific metaphase and interphase detection of the breakpoint region in 8q24 of Burkitt lymphoma cells by triple-color fluorescence in situ hybridization

Triple fluorescence in situ hybridization with a plasmid DNA library from sorted human chromosomes 8 in combination with bacteriophage clones flanking the breakpoint in 8q24 of the Burkitt lymphoma cell line J1 was used for the specific delineation of this breakpoint in individual tumor cells. With this approach, tumor-specific breakpoints in translocation chromosomes can be detected at all stages of the cell cycle with high specificity.

Bicolor fluorescence in situ hybridization to intron and exon mRNA sequences

The technique of nonradioactive in situ hybridization has been used to visualize the DNA and mRNA expression of human cytomegalovirus (HCMV) immediate early antigen (IEA) in a transfected rat fibroblast cell line. Expression of the transfected HCMV immediate early DNA can be induced by a cycloheximide treatment and is S-phase-dependent. In addition to cytoplasmic mRNA localization, a nuclear RNA hybridization signal was found. In a substantial part of the cells the nuclear signal was in the form of a "track," possibly showing transport of IEA mRNA from the site of transcription to the cytoplasm. The use of PCR-generated intron- and exon-specific probes in a double hybridization revealed that intron and exon mRNA sequences coexist in the nuclear RNA signal. This shows the applicability of multiple-color fluorescence hybridization to obtain information about the site of pre-mRNA splicing in the nucleus. In addition, by combining the technique of in situ hybridization with an immunocytochemical procedure we illustrate the possibility of visualizing transcribed mRNAs simultaneously with their translation products.

Multicolor fluorescence in situ hybridization and pulsed field electrophoresis dissect CMT1B gene region

We have used multicolor fluorescence in situ hybridization of banded chromosomes to orient Fc gamma RII and clone 1054 on a single early metaphase chromosome band (1q22) representing about 2% of the physical map of chromosome 1 in the Charcot-Marie-Tooth (CMT1B) gene region. These two cloned fragments are on the same partially digested 900-kb MluI fragment detected by pulsed field gel electrophoresis. When applied to data from an earlier study, multicolor in situ hybridization results further refined the CMT1B genetic location from an 18 cM interval to a 6 cM interval and the physical map from 15% of chromosome 1 to 3% of chromosome 1. Occasionally the three Fc gamma RII immunoglobulin receptor genes within the 200-kb region are resolved in individual metaphase chromatids.

Distribution of the rDNA and three classes of highly repetitive DNA in the chromatin of interphase nuclei of Arabidopsis thaliana

The distribution of the ribosomal RNA (rRNA) genes and three classes of highly repetitive DNA in the chromatin of interphase nuclei of Arabidopsis thaliana was studied for the first time through non-isotopic in situ hybridization and luminescence digital imaging microscopy. Each of the three classes of highly repetitive DNA exhibited a characteristic hybridization pattern, and one class was seen to be primarily localized on two chromocentres, which would allow it to distinguish a particular chromosome. The rDNA was consistently localized on the two largest chromocentres and on one or two smaller chromocentres. A limited number of nuclei exhibited more than four labelled chromocentres, indicative of either polypoidy or differential amplification of the rDNA. In nuclei where the nucleolus could be clearly observed, the nucleolar associated chromocentres (NACs) were seen to be labelled by the ribosomal DNA (rDNA) probe.

New evidence for tandem chromosome fusions in the karyotypic evolution of Asian muntjacs

A clone of highly repetitive DNA, designated C5, was isolated from DNA of female Chinese muntjac cells. The nucleotide sequence of this clone is 80%-85% homologous to that of the satellite IA clone and other highly repetitive DNA clones previously obtained from the Indian muntjac. Using C5 as a probe for in situ hybridizations to chromosome preparations of cells of both the Chinese and Indian muntjacs, we were able to show that these repeated sequences occur in centromeric heterochromatin of the chromosomes of both Chinese and Indian muntjac species. More significantly, non-random clusters of hybridization signals were detected on the arms of chromosomes of the Indian muntjac. These latter hybridization sites are postulated to be regions of interstitial heterochromatin and could be the remnants of centromeric heterochromatin from ancestral Chinese muntjac chromosomes. Our observations provide new supportive evidence for the tandem chromosome fusion theory that has been proposed for the evolution of the Indian muntjac karyotype.

Identification of the origin of centromeres in whole-arm translocations using fluorescent in situ hybridization with alpha-satellite DNA probes

We detected 2 patients with whole-arm translocations resulting in a derivative chromosome consisting of 18q and 21q. Because the breakpoints were near the centromere, classical cytogenetic techniques could not determine the centromeric origin of the derivative chromosomes. Using nonradioactive in situ hybridization with a chromosome 18 alpha-satellite DNA probe (D18Z1), the centromeres in the abnormal chromosomes were determined to be from chromosome 18. The abnormality in one patient resulted in monosomy 18p with a karyotype 45,XX, -18, -21, + der(18)t(18;21) (p11;q11)mat complement. The second patient with a 46,XX, -21, + der(18)t(18;21)(p11;q11) de novo karyotype had complete trisomy of 18q. In both cases the appropriate phenotype was observed.

In situ hybridization with fluoresceinated DNA

We have used fluorescein-11-dUTP in a nick-translation format to produce fluoresceinated human nucleic acid probes. After in situ hybridization of fluoresceinated DNAs to human metaphase chromosomes, the detection sensitivity was found to be 50-100 kb. The feasibility and the increase in detection sensitivity of microscopic imaging of in situ hybridized, fluoresceinated DNA with an integrating solid state camera for rapid cosmid mapping is illustrated. Combination of fluoresceinated DNA with biotinated and digoxigeninated DNAs allowed easy performance of triple fluorescence in situ hybridization. The potential of these techniques for DNA mapping, cytogenetics and biological dosimetry is briefly discussed.

The gene encoding human protective protein (PPGB) is on chromosome 20

Normal lymphocyte prometaphase chromosome spreads were hybridized in situ using single- and double-color fluorescence techniques. The results obtained with either the 1.8-kb protective protein cDNA or a 12-kb genomic fragment of the human protective protein gene as probe demonstrate that the PPGB gene is localized on the long arm of chromosome 20. This assignment was confirmed by hybridization with whole chromosome DNA libraries.

In situ hybridization banding of human chromosomes with Alu-PCR products: a simultaneous karyotype for gene mapping studies

Polymerase chain reaction products generated from a single Alu primer and human genomic DNA produce a distinct and highly reproducible R-banding pattern when hybridized to metaphase chromosome spreads. Individual chromosomes can be readily identified and karyotyped. Compared to conventional fluorescence banding on heat-denatured chromosomes, the in situ hybridization banding (ISHB) shows high contrast and definition. We demonstrate that this banding method can be employed effectively in double-labeling experiments for the rapid and simultaneous assignment of probes to specific chromosomal bands. Since virtually any fluorochrome can be used to delineate chromosomal bands, ISHB should provide added flexibility for multicolor mapping strategies.

Localizing DNA and RNA within nuclei and chromosomes by fluorescence in situ hybridization

The enormous potential of in situ hybridization derives from the unique ability of this approach to directly couple cytological and molecular information. In recent years, there has been a surge of success in powerful new applications, resulting from methodologic advances that bring the practical capabilities of this technology closer to its theoretical potential. A major advance has been improvements that enable, with a high degree of reproducibility and efficiency, precise visualization of single sequences within individual metaphase and interphase cells. This has implications for gene mapping, the analysis of nuclear organization, clinical cytogenetics, virology, and studies of gene expression. This article discusses the current state of the art of fluorescence in situ hybridization, with emphasis on applications to human genetics, but including brief discussions on studies of nuclear DNA and RNA organization, and on applications to clinical genetics and virology. Although a review of all of the literature in this field is not possible here, many of the major contributions are summarized along with recent work from our laboratory.

In situ hybridisation in perspective

In the introduction to this review two questions were posed: is the technology associated with ISH ready for general use, and will the method become an important investigative tool? With the exception of the demonstration of some single and low copy sequences, non-radioactive ISH is now sufficiently developed and simplified to make it a routine technique. It is also clear that ISH will continue to have an important research role. In diagnostic pathology the technique is already providing valuable information and the present decade should see the development of many more diagnostic applications.

Analysis of genes and chromosomes by nonisotopic in situ hybridization

Nonisotopic in situ hybridization is a powerful tool to analyze the organization of complex genomes. Current approaches utilizing this technique for the analysis of linear and spatial genome organizations are presented. Clinical applications of these approaches, which open new avenues for diagnosis of disease-related chromosomal changes, are also discussed.

Non-radioactive techniques for the labelling of nucleic acids

Non-radioactively labelled probes potentially have several advantages over radioactively labelled ones, such as increased stability and reduced hazard. As yet, no non-radioactive methods of labelling are as robust or produce as sensitive a probe as 32P. However, there are many options, some of which use approaches familiar to 32P users (nick translation, random priming, tailing). The majority of methods, whether enzymatic or chemical, direct or indirect, ultimately require the detection of an enzyme by a colourimetric or chemiluminescent substrate. Such detection can be achieved variously by direct visualisation (e.g. of a colourimetrically stained blot), by film, by microtitre plate reader or by CCD camera, depending on the choice of assay format and the degree of quantification required.

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.

Distribution of chromosome 18 and X centric heterochromatin in the interphase nucleus of cultured human cells

In situ hybridization of human chromosome 18 and X-specific alphoid DNA-probes was performed in combination with three dimensional (3D) and two dimensional (2D) image analysis to study the interphase distribution of the centric heterochromatin (18c and Xc) of these chromosomes in cultured human cells. 3D analyses of 18c targets using confocal laser scanning microscopy indicated a nonrandom disposition in 73 amniotic fluid cell nuclei. The shape of these nuclei resembled rather flat cylinders or ellipsoids and targets were preferentially arranged in a domain around the nuclear center, but close to or associated with the nuclear envelope. Within this domain, however, positionings of the two targets occurred independently from each other, i.e., the two targets were observed with similar frequencies at the same (upper or lower) side of the nuclear envelope as those on opposite sides. This result strongly argues against any permanent homologous association of 18c. A 2D analytical approach was used for the rapid evaluation of 18c positions in over 4000 interphase nuclei from normal male and female individuals, as well as individuals with trisomy 18 and Bloom's syndrome. In addition to epithelially derived amniotic fluid cells, investigated cell types included in vitro cultivated fibroblastoid cells established from fetal lung tissue and skin-derived fibroblasts. In agreement with the above 3D observations 18c targets were found significantly closer (P less than 0.01) to the center of the 2D nuclear image (CNI) and to each other in all these cultures compared to a random distribution derived from corresponding ellipsoid or cylinder model nuclei. For comparison, a chromosome X-specific alphoid DNA probe was used to investigate the 2D distribution of chromosome X centric heterochromatin in the same cell types. Two dimensional Xc-Xc and Xc-CNI distances fit a random distribution in diploid normal and Bloom's syndrome nuclei, as well as in nuclei with trisomy X. The different distributions of 18c and Xc targets were confirmed by the simultaneous staining of these targets in different colors within individual nuclei using a double in situ hybridization approach.

Three-dimensional reconstruction of pericentromeric (1q12) DNA and ribosomal RNA sequences in HL60 cells after double-target in situ hybridization and confocal microscopy

A fluorescent in situ hybridization procedure was applied to simultaneously label intranuclear pericentromeric (1q12) sequences of the chromosomes 1 and cytoplasmic ribosomal RNA sequences in whole cells of the promyelocytic HL60 cell line. For this purpose biotinated chromosome 1-specific (1q12) repetitive satellite DNA and 28S ribosomal ssRNA probes were used. 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 intracellular positions of both cytoplasmic rRNA and intranuclear centromere 1 DNA could easily be distinguished. This approach could be useful as a framework for the study of the 3-D localization of genes and gene transcripts.

Multiple fluorescence in situ hybridization

A method for multiple fluorescence in situ hybridization is described allowing the simultaneous detection of more than three target sequences with only three fluorescent dyes (FITC, TRITC, AMCA), respectively emitting in the green, red, and blue. This procedure is based on the labeling of (DNA) probes with more than one hapten and visualisation in multiple colors. The possibility to detect multiple targets simultaneously is important for prenatal diagnosis and the detection of numerical and/or structural chromosome aberrations in tumor diagnosis. It may form the basis for an in situ hybridization based chromosome banding technique.

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.

Inorganic phosphors as new luminescent labels for immunocytochemistry and time-resolved microscopy

A new strongly luminescent marker consisting of inorganic crystals is described for time-resolved microscopy. These crystals, known as phosphors, show delayed luminescence, unlike prompt fluorescent labels such as FITC, TRITC and phycobiliproteins, and are therefore potentially suitable for time-resolved microscopy. The luminescence of these phosphors is strong and non-fading in comparison to FITC/TRITC, and not significantly influenced by pH or temperature. The phosphor yttriumoxisulfide activated with europium emits maximally at 620 nm with a typical half life-time of approximately 700 musec, upon excitation with near ultraviolet light (360 nm). Phosphors for immunocytochemical staining were made by ball milling and were stabilized in suspension with polycarboxylic acids. Proteins such as avidin, protein A or immunoglobulins were allowed to adsorb to the surface of the phosphors. The immunocytochemical properties of the conjugates were evaluated in a model system of latex beads with defined surface antigens and in a cellular system containing fixed human lymphocytes or erythrocytes. Specific cytochemical staining was observed in suspension as well as on glass slides. A specially constructed time-resolved microscope was used to suppress the fast decaying fluorescence, thereby permitting visualization of the specific, slowly decaying luminescence of the phosphor label without the necessity of integration. Finally, the use of multiple phosphors with different kinetic and spectral characteristics for multiparameter studies is indicated.

Direct nonradioactive in situ hybridization of somatic cell hybrid DNA to human lymphocyte chromosomes

Biotinylated DNA from various human-rodent hybrids was hybridized to human lymphocyte spreads after preannealing of the repeated sequences with sonicated total human DNA. Fluorescent labeling was achieved by successive treatments with fluorescein-labeled avidin and biotinylated antiavidin antibody. The use of labeled total DNA from hybrids with known chromosome composition permits the fluorescent staining-("painting") of specific chromosomes, or parts thereof, in human lymphocyte metaphases. Alternatively, the human chromosome content of cell hybrids with unknown chromosome composition is directly assessed from the labeling pattern of human lymphocyte spreads using the total hybrid DNA as probe.

Rapid metaphase and interphase detection of radiation-induced chromosome aberrations in human lymphocytes by chromosomal suppression in situ hybridization

Chromosomal in situ suppression (CISS)-hybridization of biotinylated phage DNA-library inserts from sorted human chromosomes was used to decorate chromosomes 1 and 7 specifically from pter to qter and to detect structural aberrations of these chromosomes in irradiated human peripheral lymphocytes. In addition, probe pUC1.77 was used to mark the 1q12 subregion in normal and aberrant chromosomes 1. Low LET radiation (60Co-gamma-rays; 1.17 and 1.33 MeV) of lymphocyte cultures was performed with various doses (D = 0, 2, 4, 8 Gy) 5 h after stimulation with phytohaemagglutinin. Irradiated cells were cultivated for an additional 67 h before Colcemid arrested metaphase spreads were obtained. Aberrations of the specifically stained chromosomes, such as deletions, dicentrics, and rings, were readily scored after in situ hybridization with either the 1q12 specific probe or DNA-library inserts. By the latter approach, translocations of the specifically stained chromosomes could also be reliably assessed. A linear increase of the percentage of specifically stained aberrant chromosomes was observed when plotted as a function of the square of the dose D. A particular advantage of this new approach is provided by the possibility to delineate numerical and structural chromosome aberrations directly in interphase nuclei. These results indicate that cytogenetic monitoring of ionizing radiation may be considerably facilitated by CISS-hybridization.

Somatic pairing of chromosome 1 centromeres in interphase nuclei of human cerebellum

Interphase nuclei isolated from paraffin-embedded tissue of four normal brains were hybridized with biotinated repetitive DNA probes specific for the (peri)centromeric regions of chromosomes 1 and 7. Hybridization results were visualized with a peroxidase-DAB system after which the number of specific signals per nucleus was counted using bright field microscopy. Using the probe specific for chromosome 7 (p7t1), both the cerebral and the cerebellar samples showed 2 spots in 82% and 83%, respectively, of the nuclei. In situ hybridization with the chromosome 1 probe (pUC1.77) showed two spots in 69% of the cerebral nuclei. In cerebellar samples, hybridization with pUC1.77 resulted in only one large spot per nucleus in 82% of the cells. The average spot size in nuclei with one signal was about 1.6 times as large as that in nuclei with two signals. These observations suggest that the single large spot in the cerebellar cells is not the result of monosomy of chromosome 1 but that it reflects somatic pairing of the two chromosome 1 centromeres. Based on the size and the fraction of nuclei with one large spot, the small granular neuron is the most likely candidate. The difference between cerebral and cerebellar samples indicates that this somatic pairing of chromosome 1 is a cell-type-dependent phenomenon.

Detection of chromosome aberrations in interphase tumor nuclei by nonradioactive in situ hybridization

In a blind study, chromosome aberrations in tumor cells were analyzed by conventional cytogenetic techniques (G banding) and nonradioactive in situ hybridization with chromosome-specific probes. The material was obtained directly from patients with hematologic diseases and from colon tumor derived cell lines. The cytogenetic data obtained with G banding were in accord with those obtained by in situ hybridization to metaphase chromosomes. Most importantly, in situ hybridization to interphase nuclei gave reliable results and even allowed detection of cell subpopulations that were not detected by analyzing metaphase chromosomes. Furthermore, in retrospect, even structural aberrations could be detected in interphase nuclei; abnormal cells with either an i(1q) or a translocation der(1)t(1;7) could be identified. Our results show that the application of in situ hybridization in combination with routine cytogenetic techniques offers significant advantages for cytogenetic analysis of solid tumors and hematologic malignancies.

Improved detection and quantification of the (immuno) peroxidase product using reflection contrast microscopy

Reflection contrast microscopy (RCM) is a sensitive tool to detect minor amounts of precipitated diaminobenzidine (DABox) in immunoperoxidase stained specimens. One of the main issues in immunocytochemistry is the ongoing need for more sensitive and quantitative techniques. Therefore we applied RCM, using a new simple model system, to methods previously described for increased sensitivity in immunocytochemistry with bright field microscopy. Addition of imidazole was found the most sensitive method and addition of Nickel and Cobalt ions gave the most enhanced colour intensity. Variation of the enzyme reaction parameters yielded a continuous increase in reflection with time. This was then discussed in view of other model studies of peroxidase kinetics. A quantitative relationship between the amount of peroxidase and the reflection of DABox was observed, indicating that quantitative immunoperoxidase studies with RCM are feasible. In situ hybridization (ISH) was then used as a useful biological model for RCM to test the optimal conditions for DAB staining found in the model system (high concentrations of DAB and peroxidase and 2 h incubation time). There was no background staining in the model system, also after prolonged incubation time. The ISH experiments showed that the contrast (ratio) between specific signal and chromosome background did not increase in time, whereas only the use of high avPO concentrations yielded the highest contrast.

Two colour DNA in situ hybridization for the detection of two viral genomes using non-radioactive probes

Methods for the simultaneous detection of two virus types in cytological preparations or tissue sections by non-radioactive in situ hybridization were investigated. As a model system, CaSki cells, which have human papilloma virus type 16 (HPV16) DNA integrated in their cellular genome, were in vitro infected with Herpes simplex virus 2 (HSV2). DNA probes for both viruses were labeled with biotin, acetylaminofluorene (AAF), and transaminated-sulfonated cytosine (TS-modified). Best results were obtained when a mixture of biotinated and haptenized DNA probes (AAF- or TS-modified) was used for hybridization. The biotinated hybrid was demonstrated with a streptavidin-biotinated alkaline phosphatase staining reaction, whereas the haptenized hybrid was visualized by an indirect peroxidase method. Visualisation of both viral DNAs in the same cell was possible by a combination of biotinated HPV16 DNA and haptenized HSV2 DNA.