Detection of DNA sequences in Plasmodium berghei by means of in situ hybridization

Summary A non-radioactive in situ hybridization technique, used to map unique DNA sequences to plant chromosomes, has been adapted for the localization of specific DNA sequences in nuclei of Plasmodium berghei. After hybridization using probes labeled with biotin-11-dUTP, the formed DNA/DNA hybrids were detected by fluorescence microscopy using a specific double-layer antibody technique. Besides its high resolution, this procedure is characterized by a high sensitivity, allowing the detection of a unique sequence as small as 2.5 kb.     

In situ hybridization at the electron microscope level: hybrid detection by autoradiography and colloidal gold

In situ hybridization has become a standard method for localizing DNA or RNA sequences in cytological preparations. We developed two methods to extend this technique to the transmission electron microscope level using mouse satellite DNA hybridization to whole mount metaphase chromosomes as the test system. The first method devised is a direct extension of standard light microscope level using mouse satellite DNA hybridization to whole mount metaphase chromosomes as the test system. The first method devised is a direct extension of standard light microscope in situ hybridization. Radioactively labeled complementary RNA (cRNA) is hybridized to metaphase chromosomes deposited on electron microscope grids and fixed in 70 percent ethanol vapor; hybridixation site are detected by autoradiography. Specific and intense labeling of chromosomal centromeric regions is observed even after relatively short exposure times. Inerphase nuclei present in some of the metaphase chromosome preparations also show defined paatterms of satellite DNA labeling which suggests that satellite-containing regions are associate with each other during interphase. The sensitivity of this method is estimated to at least as good as that at the light microscope level while the resolution is improved at least threefold. The second method, which circumvents the use of autoradiogrphic detection, uses biotin-labeled polynucleotide probes. After hybridization of these probes, either DNA or RNA, to fixed chromosomes on grids, hybrids are detected via reaction is improved at least threefold. The second method, which circumvents the use of autoradiographic detection, uses biotin-labeled polynucleotide probes. After hybridization of these probes, either DNA or RNA, to fixed chromosomes on grids, hybrids are detected via reaction with an antibody against biotin and secondary antibody adsorbed to the surface of over centromeric heterochromatin and along the associated peripheral fibers. Labeling is on average ten times that of background binding. This method is rapid and possesses the potential to allow precise ultrastructual localization of DNA sequences in chromosomes and chromatin.     

Chromosomal localization of ceruoplasmin and transferrin genes in laboratory rats,mice and in man by hybridization with specific DNA probes

Fragments of the natural rat ceruloplasmin (Cp) gene and cDNA copies of rat Cp and transferring (Tf) mRNAs highly labelled by nick translation with ¹²⁵I-dCTP were used as specific probes for assignment of these genes to the metaphase chromosomes of rat, mouse and man by in situ hybridization. Both Cp and Tf genes were found to be syntenic in rodents, occupying with high probability the regions 9D and 9F1–3 in mice and 7q11–13 and 7q31–34 in rats respectively. The significant increase in silver grain count over chromosome 15 in rats after hybridization with both the Cp and Tf probes suggests the presence of a related pseudogene cluster on this particular chromosome and thus favours its partial homeology to chromosome 7. The localization of silver grains in metaphase chromosome of man indicates subregional assignment of the Tf gene to 3q21. Use of the rat Cp DNA probe does not indicate synteny of the Cp and Tf genes in man and suggests the existence of a related DNA sequence in 15q11–13. The potential and limitations of the in situ hybridization technique with heterologous DNA probes for gene mapping in mammalian species are discussed.     

18p− Syndrome: an unusual case and diagnosis by in situ hybridization with chromosome 18-specific alphoid DNA sequence

Summary A patient with an atypical clinical picture of 18p^– syndrome is described. By the in situ hybridization technique we localized the chromosome 18-specific cloned repetitive sequence to metaphase chromosomes of the patient. The predominant hybridization of the probe was found in pericentromeric regions of homologous chromosomes 18. The amount of pericentromeric DNA measured by in situ hybridization differed between homologous chromosomes; and the number of radioactive grains was statistically greater in the normal chromosome 18 than in the aberrant chromosome 18p^–. The results indicate that this probe may be useful in clinical cytogenetics for identification of aberrant chromosomes, localization of breakpoints, and studies of C-band DNA polymorphism of chromosome 18.     

Detection of DNA sequences in Plasmodium berghei by means of in situ hybridization

A non-radioactive in situ hybridization technique, used to map unique DNA sequences to plant chromosomes, has been adapted for the localization of specific DNA sequences in nuclei of Plasmodium berghei. After hybridization using probes labeled with biotin-11-dUTP, the formed DNA/DNA hybrids were detected by fluorescence microscopy using a specific double-layer antibody technique. Besides its high resolution, this procedure is characterized by a high sensitivity, allowing the detection of a unique sequence as small as 2.5 kb.     

Differential staining of human and murine chromatin in situ by hybridization with species-specific satellite DNA probes.

Human and murine chromatin was differentially labeled by hybridization with DNA probes that bind to species-specific satellite DNA. The targets for in situ hybridization were the mouse-specific major or gamma satellite DNA and the human alpha satellite DNA. These sequences typically are localized at or near the chromosome centromeres, and remain their tight localization throughout the cell cycle. DNA probes were synthesized in vitro by primer directed DNA amplification using the polymerase chain reaction. In typical applications like the differentiation of cells derived from chimeric animals or the characterization of chromosomes in somatic cell hybrids, the two DNA probes are differently labeled and detected using label-specific reagents that fluoresce at different wavelengths. The rapid technique for chromatin discrimination described here combines high specificity with unprecedented signal intensity.     

Cytological localization of fast renaturing and satellite DNA sequences inVicia faba

Summary DNA sequences reassociating within a Cot value of 1.8×10^–1 and those producing a light satellite in a CsCl density gradient were isolated fromVicia faba DNA and hybridizedin situ on squashes of roots of the same species. Silver grains were seen to be scattered over both the interphase nuclei and the metaphase chromosomes after hybridization with fast renaturing DNA sequences, indicating these are fairly regularly interspersed in theV. faba genome. Clustered labeling occurred after hybridization with satellite DNA sequences, indicating these are clustered in the genome. The localization of satellite DNA in chromosomes appeared to correspond closely to the position of the bright bands detectable after staining with quinacrine mustard. After hybridization with both DNA probes, labeling intensity over the nuclei of meristematic cells was higher than that over the nuclei of differentiating and/or differentiated cells. These results are discussed in relation to the structure of the cell nucleus, the mechanism of quinacrine banding and to previous data suggesting underrepresentation of nuclear repeated DNA sequences in differentiatingV. faba root cells.     

Location of ribosomal genes in CHO cells; in situ hybridization with a non-isotopic DNA probe on G-banded chromosomes.

A novel in situ hybridization technique using sulfonated probes is described. This non-radioactive approach, which employs chemically modified DNA and immunocytochemical procedures, is compatible with pre-G-banding and allows a rapid localization of the hybridized sequences on chromosomal spreads with a high spatial resolution. Using this technique we have localised the Chinese hamster ribosomal genes in the telomeric region of ten chromosomes, and among them in the subtelomeric q region of the Z5 chromosome. These results are discussed, the genetic markers confirming and locating the origin of Z group chromosomes by rearrangements of Chinese hamster chromosomes.     

Localization of single copy DNA sequences on G-banded human chromosomes by in situ hybridization

Recombinant lambda bacteriophage clone H3 containing a human DNA segment of 14.9 kb present in one or two copies per haploid genome was isolated. In situ hybridization to human metaphase chromosomes of the ³H-labeled cloned DNA resulted in highly significant labeling (53% of cells) of band p36 of chromosome 1, such that 22% of all chromosomal grains were located on this region. Hybridization was dependent upon the presence of dextran sulfate in the hybridization mixture and was not affected by repetitive DNA competitor. These results demonstrate localization of a single copy sequence on human metaphase chromosomes.     

Gene mapping by chromosome spot hybridization

A method is described for the localization of cloned single-copy genes to flow-sorted chromosomes. Chromosomes were sorted directly onto nitrocellulose filters and the chromosomal DNA was subsequently hybridized with gene-specific radioactively labeled DNA probes. Mild aspiration of the filters during sorting was applied to collect the deflected chromosomes in a small spot. Sorting of 10,000-30,000 chromosomes was sufficient to detect gene-specific hybridization with single-copy DNA probes. Using this technique, we have sublocalized the human c-myb oncogene to 6q21-q23 by sorting translocated chromosomes with breakpoints in the q21 and q23 region of chromosome 6. Chromosome spot hybridization appears to be a rapid and simple method to assign cloned genes to chromosomes. Hybridization of an unlocalized gene probe to spots of chromosomes pre-enriched by velocity sedimentation can quickly narrow the choice of chromosomes which need to be sorted. Conversely, individual chromosomes in a flow karyotype can be identified by hybridizing sorted chromosomal DNA with chromosome-specific DNA probes.     

Localization polymorphism of EBV DNA genomes in the chromosomes of Burkitt lymphoma cell lines

The localization of Epstein-Barr virus (EBV) genomes in nuclei of the human lymphoblastoïd cell lines Raji, Jijoye, P₃HR-1, Daudi and Ramos was investigated by in situ hybridization with biotinylated EBV DNA probes. We found that all sites of hybridization were associated with the chromosomes. Only some of these sites were present on both chromatids and these had a non-random distribution; these sites could represent EBV sequences integrated at specific points on the chromosomes. The total mean site number corresponded with the number of viral DNA copies estimated in the different cell lines by other techniques, but the copy number was highly variable from cell to cell in a given line.     

Chromosomics: Detection of Numerical and Structural Alterations in All 24 Human Chromosomes Simultaneously Using a Novel OctoChrome FISH Assay

Fluorescence in situ hybridization (FISH) is a technique that allows specific DNA sequences to be detected on metaphase or interphase chromosomes in cell nuclei¹. The technique uses DNA probes with unique sequences that hybridize to whole chromosomes or specific chromosomal regions, and serves as a powerful adjunct to classic cytogenetics. For instance, many earlier studies reported the frequent detection of increased chromosome aberrations in leukemia patients related with benzene exposure, benzene-poisoning patients, and healthy workers exposed to benzene, using classic cytogenetic analysis². Using FISH, leukemia-specific chromosomal alterations have been observed to be elevated in apparently healthy workers exposed to benzene^3-6, indicating the critical roles of cytogentic changes in benzene-induced leukemogenesis. Generally, a single FISH assay examines only one or a few whole chromosomes or specific loci per slide, so multiple hybridizations need to be conducted on multiple slides to cover all of the human chromosomes. Spectral karyotyping (SKY) allows visualization of the whole genome simultaneously, but the requirement for special software and equipment limits its application⁷. Here, we describe a novel FISH assay, OctoChrome-FISH, which can be applied for Chromosomics, which we define here as the simultaneous analysis of all 24 human chromosomes on one slide in human studies, such as chromosome-wide aneuploidy study (CWAS)⁸. The basis of the method, marketed by Cytocell as the Chromoprobe Multiprobe System, is an OctoChrome device that is divided into 8 squares, each of which carries three different whole chromosome painting probes (Figure 1). Each of the three probes is directly labeled with a different colored fluorophore, green (FITC), red (Texas Red), and blue (Coumarin). The arrangement of chromosome combinations on the OctoChrome device has been designed to facilitate the identification of the non-random structural chromosome alterations (translocations) found in the most common leukemias and lymphomas, for instance t(9;22), t(15;17), t(8;21), t(14;18)⁹. Moreover, numerical changes (aneuploidy) in chromosomes can be detected concurrently. The corresponding template slide is also divided into 8 squares onto which metaphase spreads are bound (Figure 2), and is positioned over the OctoChrome device. The probes and target DNA are denatured at high-temperature and hybridized in a humid chamber, and then all 24 human chromosomes can be visualized simultaneously. OctoChrome FISH is a promising technique for the clinical diagnosis of leukemia and lymphoma and for detection of aneuploidies in all chromosomes. We have applied this new Chromosomic approach in a CWAS study of benzene-exposed Chinese workers^8,10.     

Interphase fluorescence in situ hybridization mapping: a physical mapping strategy for plant species with large complex genomes

The chromatin in interphase nuclei is much less condensed than are metaphase chromosomes, making the resolving power of fluorescence in situ hybridization (FISH) two orders of magnitude higher in interphase nuclei than on metaphase chromosomes. In mammalian species it has been demonstrated that within a certain range the interphase distance between two FISH sites can be used to estimate the linear DNA distance between the two probes. The intephase mapping strategy has never been applied in plant species, mainly because of the low sensitivity of the FISH technique on plant chromosomes. Using a CCD (charge-coupled device) camera system, we demonstrate that DNA probes in the 4 to 8 kb range can be detected on both metaphase and interphase chromosomes in maize. DNA probes pA1-Lc and pSh2.5·SstISalI, which contain the maize locia1 andsh2, respectively, and are separated by 140 kb, completely overlapped on metaphase chromosomes. However, when the two probes were mapped in interphase nuclei, the FISH signals were well separated from each other in 86% of the FISH sites analyzed. The average interphase distance between the two probes was 0.50 µm. This result suggests that the resolving power of interphase FISH mapping in plant species can be as little as 100 kb. We also mapped the interphase locations of another pair of probes, ksu3/4 and ksu16, which span theRp1 complex controlling rust resistance of maize. Probes ksu3/4 and ksu16 were mapped genetically approximately 4 cM apart and their FISH signals were also overlapped on metaphase chromosomes. These two probes were separated by an average of 2.32 µm in interphase nuclei. The possibility of estimating the linear DNA distance between ksu3/4 and ksu16 is discussed.     

Digoxigenated oligonucleotide probes specific for simple repeats in DNA fingerprinting and hybridization in situ

Summary A fast, reproducible and non-hazardous technique for non-isotopic DNA fingerprinting is presented. The method is based on digoxigenated oligonucleotides, which are specific for simple repetitive DNA sequences. The use of digoxigenin/ anti-digoxigenin detection avoids many drawbacks inherent in e.g. the biotin/streptavidin system which often causes a poor signal-to-background ratio. Synthesis and purification of digoxigenated oligonucleotides and their use in filter hybridization are described in detail. Hybridization patterns obtained with four different radioactively labeled oligonucleotides have been compared with those of the respective digoxigenated probes. When slightly less stringent hybridization conditions are applied for digoxigenated oligonucleotides than for those labeled with ³²P, the signal intensities are satisfying but additional minor bands occur as a result of the reduced strigency. With one explainable exception, these bands increase the information content of the fingerprint. In addition, hybridization of the digoxigenated (CAC)₅ probe has been performed in situ with human metaphase chromosomes. The hybridization patterns in many mitoses resemble R-bands.     

Detection of aneuploid human sperm by fluorescence in situ hybridization: evidence for a donor difference in frequency of sperm disomic for chromosomes 1 and Y.

Fluorescence in situ hybridization with repetitive-sequence DNA probes was used to detect human sperm disomic for chromosomes 1 and Y in three healthy men. Data on these same men had been obtained previously, using the human-sperm/hamster-egg cytogenetic technique, providing a cytogenetic reference for validating sperm hybridization measurements. Air-dried smears were prepared from semen samples and treated with DTT and lithium diiodosalicylate to expand sperm chromatin. Hybridization with fluorescently tagged DNA probes for chromosomes 1 (pUC177) or Y (pY3.4) yielded average frequencies of sperm with two fluorescent domains of 14.2 +/- 2.4/10,000 and 5.6 +/- 1.6/10,000 sperm, respectively. These frequencies did not differ statistically from frequencies of hyperploidy observed for these chromosomes with the hamster technique. In addition, frequencies of disomic sperm from one donor were elevated approximately 2.5-fold above those of other donors, for both chromosomes 1 (P = .045) and Y (P = .01), consistent with a trend found with the hamster technique. We conclude that fluorescence in situ hybridization to sperm chromosomes provides a valid and promising measure of the frequency of disomic human sperm.     

Chromosomal localization of the human proenkephalin and prodynorphin genes.

DNA probes derived from rat and human proenkephalin and prodynorphin genes have been used to localize these two opiate neuropeptide genes on human chromosomes. Hybridization of probes to Southern blots made with DNAs from a rodent-human somatic-cell hybrid panel indicates localization of proenkephalin to human chromosome 8 and of prodynorphin to human chromosome 20. In situ hybridization to metaphase chromosomes confirms these assignments and indicates regional localizations of proenkephalin to 8q23-q24 and of prodynorphin to 20p12-pter. A human genomic prodynorphin clone reveals a frequent two-allele TaqI polymorphism.     

Visualization of Chromosome Territories in Interphase Nuclei of Ovarian Nurse Cells in <Emphasis Type="Italic">Calliphora erythrocephala</Emphasis> Mg. (Diptera: Calliphoridae)

Analysis of localization of chromosomes 2, 3, and 6 of Calliphora erythrocephala Mg. in ovarian nurse cell nuclei with different chromatin structure has shown that the regions of DNA probe hybridization reduced with increasing chromatin compaction. Hybridization of DNA probes of chromosomes 3 and 6 to secondary reticular nuclei demonstrated that chromosomes retain their territories in the nuclei when the chromatin acquires a reticular structure. These results suggest regular organization of the chromosomal apparatus at all stages of the endomitotic cycle, including the stage of highly polyploid reticular nuclei. FISH of DNA probe of the chromosome 2 telomeric region to secondary reticular nuclei revealed a peripheral distribution of the signal. Zones of more intensive DNA probe hybridization have been distinguished. These zones probably are the regions of accumulation of telomeric and (or) centromeric chromosome regions.     

Localization of Human Ribosomal Gene DNA Probes on Barley Chromosomes

To estimate the possibility of plant genome mapping using human genome probes, the probes fluorescent in situ hybridization (FISH) of human 18S–28S rDNA (clon 22F9 from the LA-13NCO1 library) was carried out on chromosomes of the spring barleyHordeum vulgareL. As a control, wheat rDNA probe (clon pTa71) was taken. Hybridization of the wheat DNA probe revealed two major labelling sites on mitotic barley chromosomes 5I (7H) and 6I (6H), as well as several minor sites. With the human DNA probe, signals were detected in the major sites of the ribosomal genes on chromosomes 5I (7H) and 6I (6H) only when the chromosome preparations were obtained using an optimized technique with obligatory pepsin treatment followed by hybridization. Thus, this study demonstrates that physical mapping of plant chromosomes with human DNA probes that are 60 to 70% homologous to the plant genes is possible. It suggests principal opportunity for the FISH mapping of plant genomes using probes from human genome libraries, obtained in the course of the total sequencing of the human genomes and corresponding to the coding regions of genes with known functions.     

A combined PRINS-FISH technique for simultaneous localisation of DNA sequences on plant chromosomes

A novel approach for simultaneous localization of two DNA sequences on plant chromosomes is described. The approach is based on a combined use of primed in situ DNA labelling (PRINS) with fluorescent in situ hybridization (FISH). Traditionally, this has been done using FISH with two probes labelled by two different marker molecules. Compared to this method, the combined PRINS-FISH procedure is faster. Furthermore, because one of the DNA sequences is localized by PRINS with specific primers, only one labelled probe is needed. This revised version was published online in July 2006 with corrections to the Cover Date.     

USE OF REPEATED DNA SEQUENCES AS CYTOLOGICAL MARKERS

The majority of DNA that is found in most of the flowering plants appears to be non-coding DNA. Much of this excess DNA consists of nucleotide sequences which exist as multiple copies throughout the genome and are designated as repetitive sequences. Those sequences which are found in moderately high to high numbers of copies are observed to be of the greatest value as cytological markers. Moderately high copies may exist as sequences which are dispersed throughout the chromosomes of some species and not dispersed in other more distantly related species. By taking advantage of this characteristic and the technique of in situ hybridization with biotinylated probes, breakpoints of chromosomal translocations may be observed between species such as wheat and rye. Many of the high copy number repetitive sequences are organized in a tandem fashion in specific loci in the chromosome. Chromosomal identification may be accomplished by using the in situ hybridization technique. Upon in situ hybridization with a repetitive sequence isolated from Aegilops squarrosa, the patterns of the sites of hybridization allowed the D-genome chromosomes to be identified. The sequence was also observed only on the D-genome chromosomes of several polyploid species indicating its usefulness as a genome specific marker. Using this genome specificity, assessment of the orientation of the D-genome chromosomal segments of hexaploid wheat carrying the sequence during interphase and prophase of mitotic root tip cells was possible. Repetitive DNA sequences, therefore, provide cytological markers necessary for studies of chromosomal identification, genome allocation, and genome orientation. The use of biotin-labeled DNA probes allows the technique of in situ hybridization to be performed much more rapidly and with a greater degree of safety and reliability.