High resolution DNA fiber-fish on yeast artificial chromosomes: direct visualization of DNA replication.

Fluorescent in situ hybridization (FISH) is a powerful, direct and sensitive technique with a wide resolution range that enables the simultaneous study of multiple targets, labelled in different colours. Spreading techniques, denoted here as 'Fiber-FISH', increase FISH-resolution to the DNA fiber, using decondensed nuclear DNA as hybridization target. FISH could be a powerful analytical tool for thorough physical examination of yeast artificial chromosomes (YACs) which are often chimaeric or contain internal deletions. However, with one exception restricted to meiotic yeast chromosomes, FISH has not been used successfully on yeast/YAC DNA. We have developed a fast and simple method that can be applied routinely for compositional and structural analysis of cosmid and YAC DNA in yeast. It enables precise localization and ordering of clones, resolves overlaps and distances and gives a detailed picture of the integrity and colinearity of both probe and target. The combination of high resolution, signal abundance and short yeast cell cycle allows direct visualization of replicating DNA fibers. In a 400 kb region of the human dystrophin gene, we identified two replication origins, demonstrating that human DNA cloned in yeast is capable of initiating its own replication.

Automated counting of in situ hybridization dots in interphase cells of leukemia samples.

Twenty-seven samples (cell cultures prepared for routine cytogenetics) of leukemia patients with known cytogenetic abnormalities were stained by in situ hybridization for interphase cytogenetics with centromere specific probes for chromosome Nos 4, 6, 7, 8, 9, 12, 17, 18, X and Y. The number of hybridization domains per nucleus was quantified using a semi-automated system developed in our laboratory. Results of this automated counting procedure (with and without verification of the counting results by the operator) were compared with conventional cytogenetic data and with visual scoring of the number of hybridization dots. The findings show that the system is capable of analysing 1000 cell nuclei in less than 30 min, including the necessary verification of the results by the operator. Automated counting and visual scoring were in good agreement. Conventional cytogenetics and interphase cytogenetics agreed in only 50% of the cases, confirming other studies showing that conventional cytogenetic results are not always representative for the majority of the cell population.

Rapid detection of human cytomegalovirus DNA in peripheral blood leukocytes of viremic transplant recipients by the polymerase chain reaction.

Peripheral blood leukocyte samples (n = 458) of 24 bone marrow transplant and 52 kidney transplant patients were examined weekly for the presence of human cytomegalovirus (HCMV) using an improved culture technique (DEAFF; detection of early antigen fluorescent foci). In total 5 (21%) bone marrow transplant and 11 (21%) kidney transplant patients developed a viremia. Patients' samples were investigated for the presence of HCMV DNA using an in vitro DNA amplification technique, the polymerase chain reaction (PCR). From the statistically evaluable viremic patients (n = 13), 110 blood samples were analyzed. In 5 of these patients, the DEAFF and PCR led to identical results. In 8 patients however the PCR was more sensitive, i.e. HCMV DNA was detected for a longer period of time. Applying statistical analysis using the McNemar test, this result was significant (P less than 0.05). The PCR applied on leukocyte samples did not detect HCMV DNA in viruric patients without viremia. Moreover, the current PCR never led to positive results with peripheral blood leukocyte samples of healthy seropositive or seronegative controls. Since the PCR can be performed in 6 hr, this technique will contribute to rapid detection of HCMV DNA in peripheral blood leukocytes and therefore to optimal clinical management of HCMV-infected transplant recipients.

DNA fiber-FISH staining mechanism.

Fluorescence in situ hybridization to DNA fibers (Fiber-FISH) is a high-resolution, wide-ranging physical DNA mapping method that finds increasing application in the study of pathological gene rearrangements. Here we present experiments designed to understand the nature of the discontinuous FISH signal patterns seen after Fiber-FISH. Use of a novel cisplatin-based chemical labeling method enabled us to produce intact biotin-labeled cosmid target DNA molecules. We monitored by immunofluorescence the fate of such cosmid targets during denaturation and hybridization. The same cosmid DNA labeled with digoxigenin by nick-translation was used to analyze the FISH probe signal distribution in a different color. The probe signals proved to be a subset of the target signals remaining after denaturation and hybridization. We argue that the discontinuity of probe signals in Fiber-FISH is mainly caused by loss of target DNA and limited accessibility due to in situ renaturation and attachment. Furthermore, we conclude that FISH sensitivity is determined by hybridization efficiency and not the ability to generate sufficient signal from small probes. (J Histochem Cytochem 48:743-745, 2000)

Detection of parvovirus B19 DNA in fetal tissues by in situ hybridisation and polymerase chain reaction.

Attempts were made to detect human parvovirus B19-DNA by in situ hybridisation and the polymerase chain reaction in placental and fetal tissues from a case of intrauterine fetal death. In the in situ hybridisation experiments radioactive and non-radioactive (labelled with 2-acetyl-aminofluorene, AAF) DNA probes were used. B19-DNA was detectable in paraffin wax embedded fetal tissue from the liver, heart, lung, brain and thymus. The resolution with the AAF-labelled probes was higher than with the radiolabelled DNA. Parvovirus B19 DNA sequences were also detected in these tissues by an enzymatic in vitro amplification technique--the polymerase chain reaction. Amplification of a B19-DNA sequence before detection increases the rapidity and sensitivity of detection. The rapid, specific, and sensitive analysis of parvovirus B19 in normal and diseased tissues using these techniques may contribute considerably to determining the role of this virus as a risk factor in the outcome of pregnancy.

Detection of cytomegalovirus antigens and DNA in tissues fixed in formaldehyde.

Immunohistochemical techniques with monoclonal antibodies against cytomegalovirus (CMV) immediate early (IEA) and early antigens (EA), and in situ hybridisation, were used to detect CMV infection in routinely obtained, formaldehyde fixed and paraffin wax embedded tissues taken from bone marrow transplant patients, who had died form interstitial pneumonia. To improve the rates of detection of CMV-IEA and EA the wax embedded material was pretreated with 0.4% pepsin/HCl at 37 degrees C for 30 minutes. This pretreatment was also advantageous for in situ hybridisation. In the patients with histological evidence of CMV infection or positive viral culture from the lung tissue, or both, viral proteins and nucleic acids were detected in lung, as well as in other organs. Immunohistochemical techniques proved superior in heavily infected but necrotic tissues. In control patients (patients who had died from interstitial pneumonia without any evidence of CMV, or with no interstitial pneumonia at all) in situ hybridisation showed no positive signal, while immunohistochemical techniques showed only a few positive cells in lung tissue of one of nine patients. In addition to CMV-DNA analysis, formaldehyde-fixed, paraffin wax embedded tissue is amenable to immunohistochemical analysis with CMV monoclonal antibodies.

Rapid detection of human parvovirus B19 DNA by dot-hybridization and the polymerase chain reaction.

The results of a comparison of three DNA-detection methods for human parvovirus B19 DNA are described. The sensitivity of detection of virus from hybridization assays using 32P-radiolabeled DNA and RNA probes was compared with a method for enzymatically amplifying specific target DNA sequences (polymerase chain reaction). B19 virus DNA was detected using a radiolabeled DNA probe at serum dilutions of 10(-3), equivalent to approximately 3 pg of viral DNA. Using radiolabeled RNA probes even 0.3 pg of viral DNA was detectable. The polymerase chain reaction was more sensitive than the hybridization assays: 100 fg of viral DNA was easily detectable by electrophoresis on agarose and after subsequent hybridization with a radiolabeled probe approximately 10 fg of B19 DNA was detected. The sensitivity of the PCR, combined with the simplicity and reduced time scale, demonstrates the potential of this technique as an additional method for routine diagnosis of B19 infections.

Sample preparation and in situ hybridization techniques for automated molecular cytogenetic analysis of white blood cells.

With the advent of in situ hybridization techniques for the analysis of chromosome copy number or structure in interphase cells, the diagnostic and prognostic potential of cytogenetics has been augmented considerably. In theory, the strategies for detection of cytogenetically aberrant cells by in situ hybridization are simple and straightforward. In practice, however, they are fallible, because false classification of hybridization spot number or patterns occurs. When a decision has to be made on molecular cytogenetic normalcy or abnormalcy of a cell sample, the problem of false classification becomes particularly prominent if the fraction of aberrant cells is relatively small. In such mosaic situations, often > 200 cells have to be evaluated to reach a statistical sound figure. The manual enumeration of in situ hybridization spots in many cells in many patient samples is tedious. Assistance in the evaluation process by automation of microscope functions and image analysis techniques is, therefore, strongly indicated. Next to research and development of microscope hardware, camera technology, and image analysis, the optimization of the specimen for the (semi)automated microscopic analysis is essential, since factors such as cell density, thickness, and overlap have dramatic influences on the speed and complexity of the analysis process. Here we describe experiments that have led to a protocol for blood cell specimen that results in microscope preparations that are well suited for automated molecular cytogenetic analysis.

Methodologies for specific intron and exon RNA localization in cultured cells by haptenized and fluorochromized probes.

We have determined optimal conditions for the detection of mRNA sequences in cultured cells by nonradioactive in situ hybridization. For this purpose a number of different cell lines have been used: rat 9G cells for the detection of human cytomegalovirus immediate early mRNA, and HeLa as well as 5637 carcinoma cells for the detection of housekeeping gene mRNAs. Extensive optimization of fixation and pretreatment conditions revealed that most intense hybridization signals are obtained when cells are grown on glass microscope slides, fixed with a mixture of formaldehyde and acetic acid, pretreated with pepsin and denatured prior to hybridization. In addition, we also studied the potential of fluorochromized probes for the direct detection of multiple RNA sequences. The optimized in situ hybridization procedure revealed that immediate early mRNA transcripts are, in addition to a cytoplasmic localization, localized within nuclei of rat 9G cells. Double hybridization experiments showed that intron and exon sequences colocalize within the main nuclear signal. In addition, the presence of small, intron-specific, fluorescent spots scattered around the main nuclear signals indicates that intron sequences which are spliced out can be visualized. Additional information about the functioning of cells could be obtained by the detection of mRNA simultaneously with bromodeoxyuridine, incorporated during S-phase, or its cognate protein. The sensitivity of these methods is such that mRNAs of abundantly expressed housekeeping genes can be detected in a variety of cell lines with high signal to noise ratios.

Automated image cytometry for detection of rare, viral antigen-positive cells in peripheral blood.

A cell detection method based upon automated screening is described for recognition of low frequencies (1 in 100,000) of immuno-enzymatically labelled white blood cells in human peripheral blood. The used image cytometry instrumentation (LEYTAS) includes a wide-field, fully automated microscope (Autoplan) and a modular image analysis computer (MIAC), both from Leica, Wetzlar, Germany. The MIAC contains image boards for optimum use of mathematical morphology algorithms. Communication with the MIAC is via a personal computer. Programs for automated cell analysis have been written in C language. Main features of the system are fast analysis of large microscope fields including a count of all cells, selection of objects of interest (alarms), and display of digitally stored images of these alarms. We tested this system for the detection of white blood cells expressing antigen of cytomegalovirus (pp65) in 50 human blood smears from kidney transplant recipients. Immuno-enzymatic (peroxidase) staining was performed with DAB and counterstaining with hematoxylin. For determination of the sensitivity, a series of dilutions of a positive sample with a negative sample was performed. The lowest frequency detected was 1 antigen-positive cell/3 x 10(5) antigen-negative cells. Screening time was about 60 min for one million cells.

Non-radioactive in situ hybridization for the detection of cytomegalovirus infections.

Acetylaminofluorene (AAF) modified cytomegalovirus (CMV) DNA probes have been applied for the rapid detection of CMV genomes by non-radioactive in situ hybridization in routinely obtained pathological material. To establish proper protocols, AAF modified mouse satellite DNA and mouse liver were used to investigate the procedural variables. Among these were type and time of fixation, glass slide coating for improved tissue adherence, protease permeabilization of sections, type and time of denaturation and hybridization, probe concentration, post-hybridization washing conditions and immunocytochemical detection. This research has led to a user-friendly procedure which, in addition to cells displaying a cytopathological effect typical for CMV infection, detects with high sensitivity CMV carrying cells that show no histo-pathological alterations. It can be readily applied in routine clinical-diagnostic laboratories.

Automation of spot counting in interphase cytogenetics using brightfield microscopy.

In situ hybridization techniques allow the enumeration of chromosomal abnormalities and form a great potential for many clinical applications. Although the use of fluorescent labels is preferable regarding sensitivity and colormultiplicity, chromogenic labels can provide an excellent alternative in relatively simple situations, e.g., where it is sufficient to use a centromere specific probe to detect abnormalities of one specific chromosome. When the frequency of chromosomal aberrations is low, several hundreds or even thousands of cells have to be evaluated to achieve sufficient statistical confidence. Since manual counting is tedious, fatiguing, and time consuming, automation can assist to process the slides more efficiently. Therefore, a system has been developed for automated spot counting using brightfield microscopy. This paper addresses both the hardware system aspects and the software image analysis algorithms for nuclei and spot detection. As a result of the automated slide analysis the system provides the frequency spot distribution of the selected cells. The automatic classification can, however, be overruled by human interaction, since each individual cell is stored in a gallery and can be relocated for visual inspection. With this system a thousand cells can be automatically analyzed in approximately 10 min, while an extra 5-10 min is necessary for visual evaluation. The performance of the system was analyzed using a model system for trisomy consisting of a mixture of male and female lymphocytes hybridized with probes for chromosomes 7 and Y. The sensitivity for trisomy detection in the seeding experiment was such that a frequency of 3% trisomic cells could be picked up automatically as being abnormal according to the multiple proportion test, while trisomy as low as 1.5% could be detected after interaction.

Heterogeneity in telomere length of human chromosomes.

Vertebrate chromosomes terminate in variable numbers of T2AG3 nucleotide repeats. In order to study telomere repeats at individual chromosomes, we developed novel, quantitative fluorescence in situ hybridization procedures using labeled (C3TA2)3 peptide nucleic acid and digital imaging microscopy. Telomere fluorescence intensity values from metaphase chromosomes of cultured human hematopoietic cells decreased with the replication history of the cells, varied up to six-fold within a metaphase, and were similar between sister chromatid telomeres. Surprisingly, telomere fluorescence intensity values within normal adult bone marrow metaphases did not show a normal distribution, suggesting that a minimum number of repeats at each telomere is required and/or maintained during normal hematopoiesis.

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.

Fluorescence in situ hybridization using horseradish peroxidase-labeled oligodeoxynucleotides and tyramide signal amplification for sensitive DNA and mRNA detection.

We have used horseradish peroxidase-labeled 40 mer oligodeoxynucleotides (HRP-ODNs) specific for the human cytomegalovirus immediate early gene (HCMV-IE) and a novel dinitrophenol-tyramide signal amplification reagent (DNP-TSA plus) to evaluate their utility in fluorescence in situ hybridization (FISH). For DNA FISH, single or cocktails of HRP-ODNs were hybridized to metaphase chromosomes of rat 9G cells which, as determined by DNA fiber FISH, carry an integrated tandem repeat of 50-60 copies of the HCMV-IE gene. With one layer of DNP-TSA plus deposition and subsequent detection with a fluorochrome-conjugated antibody, four HRP-ODNs were needed to detect the HCMV-IE integration site. When employing two TSA amplification rounds, one HRP-ODN was sufficient for obtaining a strong signal of the integrated gene cluster, indicating that 50-60 HRP molecules can be detected with ease. In addition to DNA FISH, we report here the first use of HRP-ODN probes for mRNA detection by FISH. A single HRP-ODN and one DNP-TSA plus step resulted in clear visualization of the HCMV-IE gene transcripts in rat 9G cells induced for HCMV-IE expression by cycloheximide. Two TSA detection steps enhanced signal intensities even further. Parallel experiments with hapten-labeled ODN and cDNA probes and conventional detection methods illustrated the superiority of the HRP-ODN/TSA approach in DNA and RNA FISH.

An improved immunocytochemical method for the detection of human cytomegalovirus antigens in peripheral blood leucocytes.

A recently described immunoperoxidase method for the detection of nuclear human cytomegalovirus (HCMV) immediate early antigen (IEA) directly on peripheral blood leucocytes suffers from the drawback that the antigen is vulnerable to endogenous peroxidase inactivation procedures. To solve this problem a procedure is developed in which endogenous peroxidase is inactivated after binding and immobilization of the primary antibody with 4% formaldehyde. In combination with this procedure, three types of inactivation were investigated: glucose/glucose oxidase, hydrochloric acid and methanol/H2O2. Of these three, the first gives optimal results, especially in combination with methanol/acetic acid (20/1 v/v) as the primary fixative. This procedure results in preparations which allow for a more objective evaluation and enable automated examination using bright field microscopy. As a second improvement we developed a simple adherence method in order to diminish the risk of infection for the laboratory staff during processing of unknown blood samples. The protocol described shows great clinical potential for the diagnosis of HCMV infections.

Exon mapping by fiber-FISH or LR-PCR.

In this study we systematically assessed the sensitivity limits of fiber-FISH in model experiments. Exonic fragments and cDNAs with exon sizes of >/=200 bp could be mapped on their cognate cosmid. This positional fiber-FISH mapping was validated by long-range PCR. It is expected that these two independent mapping approaches will help to refine current available gene maps and show their applicability in fine mapping of sequence-tagged sites or expressed sequence tags. Also, they will be useful in resolving gene structures by mapping exon and intron locations.

Analysis of the monomeric alphoid sequences in the pericentromeric region of human chromosome 7.

To further define the structure of the pericentromeric region of human chromosome 7, we have identified and characterized a YAC clone (YAC 311.H5) containing the D7S1480 locus, which maps to the short arm near the centromere of this chromosome, by linkage in CEPH families and radiation hybrid analysis. This YAC contains two new blocks of alphoid DNA (named Z5 and Z6). Both Z5 and Z6 show monomeric structures and a lack of higher-order repeats, and, therefore, belong to suprachromosomal family type 4 (M1). The orientation of the two blocks and the physical distances over the region were defined by pulsed-field gel electrophoresis (PFGE) and fluorescence in situ hybridization on chromatin fibers (FiberFISH). A YAC contig spanning the centromeric region has been developed by STS content.