Detection of small, single-copy genes on protein-G-banded chromosomes by electron microscopy.

A method for the detection by electron microscopy of chromosome banding after in situ hybridization of small, nonradioactive DNA sequences is described. Typical high-resolution G-banding is produced by adding 5-bromodeoxyuridine (BrdU) during the last part of the S-phase and by applying a monoclonal antibody against the BrdU-substituted chromosome segments, followed by the addition of protein G, but no further treatment. A protocol for in situ hybridization of small, single-copy biotinylated DNA sequences and their detection by immunogold tagging on banded chromosomes is also described. This combined approach permits high-resolution mapping of small DNA sequences and should be useful in discriminating between neighboring DNA fragments.     

BrdU related direct revelation of typical dynamic R- and G-banding with the use of monoclonal anti-BrdU antibody.

Pulse 5-bromodeoxyuridine (5-BrdU) incorporation during the last S-phase is known to produce R- or G-banded chromosomes after photolysis-plus-Giemsa (FPG) staining. The authors applied an immunological staining with monoclonal anti-BrdU antibody instead of the FPG protocol. The results offered banded chromosomes with an immunological typical R-banding (RBI) on the GBG cultivated cells (early pulse incorporation), and an immunological G-banding (GBI) on the RBG cultivated ones (late pulse incorporation). After a further FPG protocol following an immunological treatment, an inverted banding pattern became evident whereas a faint immunological staining remained. Thus the method superimposed a GBG-banding on the RBI-staining or a RBG on the GBI one. This allows a rapid and easy R and G double chromosomal identification on the same metaphase cell, using first the immunological banding then the classical FPG staining. The method allows a reproducible dynamic G-banding with an easy monitored late 5-BrdU pulse incorporation specially attractive in spontaneous dividing cells from bone marrow. This dynamic G-banding protocol should be extended to chorionic villi and malignant cells. Our data are in agreement with a connection between dynamic banding and chromosomal portions containing or not BrdU. The lack of an immunological staining after the FPG protocol has been noticed and assume the photolysis degradation-elution of the DNA in BrdU-substituted areas.     

Trypsin G- and C-banding for interchange analysis and sex identification in the chicken

The trypsin banding methods were applied to feather pulp and embryonic material of the chicken. Two contrasting types of chromosomal banding patterns were obtained by varying the duration of trypsin treatment. A short time treatment shows a G-banding pattern which has characteristic and distinctive bands along the chromosome arms. Prolonging the trypsin treatment causes the G-banding pattern to disappear, and only the centromeres and the W chromosome remained heterochromatic which is characteristic of the C-banding pattern. The application of the G-banding pattern analysis was used to identify regions of chromosomes involved in rearrangements. The simplified trypsin technique which produces the C-banding pattern makes it relatively easy to identify the W sex-chromosome and determine sex in avian species.     

Electron microscopy of gold-labeled human and equine chromosomes

We present an immunochemical technique for the detection of 5-bromo-2'-deoxyuridine (BrdU) incorporated discontinuously into the chromosomal DNA. A monoclonal anti-BrdU antibody and a protein A-gold complex were used to produce chromosome banding of human and equine chromosomes, specific for electron microscopy (EM). Well-defined bands, symmetry of sister chromatids, concordance between homologues, and band patterns similar to those observed by light microscopy facilitate chromosome identification and karyotyping. From prophase to late metaphase, chromosomes condense and bands appear to fuse. The fusion appears to be owing to chromatin reorganization. Our results underline the value of using immunogold reagents, which are ideal probes for antigen localization on chromosomes.     

An improved method for chromosome banding after fluorescence in situ hybridization: Use of a tetramethylrodhamine-conjugated BrdU antibody

A method for high quality chromosome banding after in situ hybridization with biotinylated probes has been developed. Fluoresceine-conjugated avidin is used for probe detection, while chromosome banding is performed with a tetramethylrodhamine-conjugated anti-BrdU antibody. In this way probe localization and chromosome identification can be performed simultaneously simply by changing the incidental light wavelength.Abbreviations BAT BrdU antibody technique - DABCO 1,4 diazobicyclo-(2.2.2)octane - FITC fluorescein isothiocyanate - FPG fluorochrome plus giemsa - PHA phytohemagglutinin - RBA R-banding BrdU acridine - TRITC tetramethylrhodamine isothiocyanate     

Preparation of chromosome spreads for electron (TEM,SEM, STEM), light and confocal microscopy

In the past, ultrastructural studies on chromosome morphology have been carried out using light microscopy, scanning electron microscopy and transmission electron microscopy of whole mounted or sectioned samples. Until now, however, it has not been possible to use all of these techniques on the same specimen. In this paper we describe a specimen preparation method that allows one to study the same chromosomes by transmission, scanning-transmission and scanning electron microscopy, as well as by standard light microscopy and confocal microscopy. Chromosome plates are obtained on a carbon coated glass slide. The carbon film carrying the chromosomes is then transferred to electron microscopy grids, subjected to various treatments and observed. The results show a consistent morphological correspondence between the different methods. This method could be very useful and important because it makes possible a direct comparison between the various techniques used in chromosome studies such as banding, in situ hybridization, fluorescent probe localization, ultrastructural analysis, and colloidal gold cytochemical reactionsAbbreviations CLSM confocal laser scanning microscope - EM electron microscopy - kV kilovolt(s) - LM light microscope - SEM scanning electron microscope - STEM scanning-transmission electron microscope - TEM transmission electron microscope     

Scanning electron microscopy of the G-banded human karyotype

The chromosome structure of human metaphases was observed in the scanning electron microscope (SEM) after exposure to G-banding techniques for light microscopy (LM). Individual chromosomes showed an inherent specificity of quaternary coiling. Circumferential grooves along the chromatids demarcated the individual gyres of the coils, which were shown to correspond to the LM G-banding pattern. An increased number of quaternary coils was observed in prometaphase chromosomes, which were shown to be correlated with the high resolution LM bands. We propose that the observation of G-bands relies on LM visualization of quaternary structure by accumulation of Giemsa stain between the coils.     

Electron microscopic band-interband pattern of polytene chromosomes in Drosophila nasuta albomicans. 2. Salivary gland chromosome 2L.

The band-interband pattern (division 28-52) of salivary gland chromosome 2L in Drosophila nasuta albomicans was studied by light (LM) and electron microscopy (EM) using squash preparations and surface-spread polytene (SSP) chromosome preparations, respectively. LM and EM maps were complied. Based on the digitized EM patterns of five homologous SSP chromosomes a computerized EM chromosome map was plotted. The EM pattern analysis showed a total number of 479 chromosome bands with an almost 83% increase compared with the LM analysis of squash preparations. By extrapolation of the data from 39% of the polytene genome analysed so far in D. n. albomicans, a total number of 2,926 chromosome bands was calculated. This is almost the same number of bands as was calculated earlier for Drosophila hydei using the same SSP chromosome preparation technique. The data in the literature concerning variations in the number of chromosome bands in different Drosophila species, the various chromosome preparation techniques adopted, and the different criteria used for the EM pattern analyses, are discussed.     

Electron microscopic band-interband pattern of polytene chromosomes in Drosophila nasuta albomicans. 1. Salivary gland chromosome 2R

The band-interband pattern of salivary gland chromosome 2R in Drosophila nasuta albomicans (division 53-83) was studied by light (LM) and electron microscopy (EM) using squash preparations and surface-spread polytene (SSP) chromosome preparations, respectively. LM and EM maps were compiled. Based on the digitized EM patterns of five homologous SSP chromosomes a computerized chromosome map was plotted. The EM pattern analysis showed a total number of 662 chromosome bands with an almost 98% increase compared with the LM analysis of squash preparations. The majority (about 92%) of interband lengths in SSP chromosome 2R ranged between 0.25 and 0.64 microns, which equal about 0.8-2.1 kb of totally extended DNA or 2.5-6.4 kb of DNA, if a DNA packing ratio of 0.1 microns/kb is assumed for the interbands of SSP chromosomes.     

Dynamic G- and R-banding of human chromosomes for electron microscopy

Synchronized human lymphocytes were exposed to 5-bromo-2-deoxyuridine (BrdUrd) for incorporation in either G-or R-bands. The substituted bands were revealed by monoclonal anti-BrdUrd antibodies disclosed with either gold-labeled antibodies or with the protein A-gold complex. Sharp G-or R-banding, specific for electron microscopy (EM), was obtained. These banding patterns, referred to as GB-AAu (G-bands by BrdUrd using Antibodies and gold [Au]) and RB-AAu (R-bands by BrdUrd using Antibodies and gold [Au]), resemble dynamic band patterns (GBG and RBG) much more than they do morphologic band patterns (GTG and RHG). The G- and R- band patterns allow accurate chromosome identification and karyotyping. An actual karyotype of human GB-AAu-banded chromosomes at the 750 band level, photographed in the EM, is presented. The method produces excellent band separation and band contrast. Variations in band staining intensities were noted and correlated with BrdUrd enrichment. The C-band regions were positively stained after GB-AAu banding while they were negatively stained after RB-AAu banding. Telomeres appeared heterogeneous after GB-AAu banding suggesting that part of the telomeric bands might be late replicating.     

Karyotypic characterization of Iheringichthys labrosus (Pisces, Pimelodidae): C-, G- and restriction endonuclease banding

Various chromosomal banding techniques were utilized on the catfish, Iheringichthys labrosus, taken from the Capivara Reservoir. C-banding regions were evidenced in telomeric regions of most of the chromosomes. The B microchromosome appeared totally heterochromatic. The restriction endonuclease AluI produced a banding pattern similar to C-banding in some chromosomes; the B microchromosome, when present, was not digested by this enzyme and remained stained. G-banding was conspicuous in almost all the chromosomes, with the centromeres showing negative G-banding. When the restriction endonuclease BamHI was used, most of the telomeres remained intact, while some centromeres were weakly digested. The B chromosome was also not digested by this enzyme. The first pair of chromosomes showed a pattern of longitudinal bands, both with G-banding and BamHI; this was more evident with G-banding. This banding pattern can be considered a chromosomal marker for this population of I. labrosus.     

Different reactivity of Z-DNA antibodies with human chromosomes modified by actinomycin D and 5-bromodeoxyuridine

Summary Antibodies against Z-DNA react with fixed metaphase chromosomes of man and other mammals. Indirect immunofluorescence staining shows that chromosomal segments corresponding to R- and T-bands preferentially fix Z-DNA antibodies. In this work Z-DNA antibodies were used as a probe for DNA conformation in euchromatin of fixed human chromosomes whose condensation or staining were modified by actinomycin D (AMD) and by 5-bromodeoxyuridine (BrdU). Treatments with AMD and BrdU were performed to induce a G-banding by modification of chromosomal segments corresponding to R- and T-bands. Long BrdU treatments were used to induce asymmetrical and partially undercondensed chromosomes by substitution of thymidine in one or both DNA strand. Our results show a clear difference of Z-DNA antibodies reactivity after AMD or BrdU treatment. The G-banding obtained after AMD treatment is not reversed by Z-DNA antibodies staining since these antibodies bind very weakly to the undercondensed R-bands. On the other hand, the G-banding obtained by BrdU is completely reversed giving typical R-banding, as on untreated chromosomes. For asymmetrical chromosomes an R-, T-banding pattern is always observed but there is a decrease of the fluorescence intensity proportional to the degree of BrdU incorporation. We conclude that AMD treatment greatly disturbs Z-DNA antibodies binding suggesting a change in DNA conformation, whereas BrdU treatments do not suppress but only weaken the specific binding of Z-DNA antibodies on R- and T-bands. The direct involvement of thymidine substitution in DNA sequences recognized by Z-DNA antibodies is discussed.     

Chromosome homology and heterochromatin in goat,sheep and ox studied by banding techniques

Peripheral blood lymphocyte metaphase chromosomes of three Bovoidean species have been studied using Quinacrine fluorescence and Giemsa banding techniques to give Q-, G-, and C-banding patterns. Q- and G-banding characteristics, coupled with chromosome length, enabled all of the chromosomes in each of the chromosome complements to be clearly distinguished, although some difficulties were encountered with the very smallest chromosomes. A comparison of G-banding patterns between the species revealed a remarkable degree of homology of banding patterns. Each of the 23 different acrocentric autosomes of the domestic sheep (2n=54) was represented by an identical chromosome in the goat (2n=60) and the arms of the 3 pairs of sheep metacentric autosomes were identical matches with the remaining 6 goat acrocentrics. A similar interspecies homology was evident for all but two of the autosomes in the ox (2n=60). This homology between sheep metacentric and goat acrocentric elements confirms a previously suggested Robertsonian variation. The close homology in G-banding patterns between these related species indicates that the banding patterns are evolutionarily conservative and may be a useful guide in assessing interspecific relationships. —The centromeric heterochromatin in the autosomes of the three species was found to show little or no Q-or G-staining, in contrast to the sex chromosomes. This lack of centromeric staining with the G-technique (ASG) contrasts markedly with results obtained with other mammalian species. However, with the C-banding technique these regions show a normal intense Giemsa stain and the C-bands in the sex chromosomes are inconspicuous. The amount of centromeric heterochromatin in the sheep metacentric chromosomes is considerable less than in the acrocentric autosomes or in a newly derived metacentric element discovered in a goat. It is suggested that the pale G-staining of the centromeric heterochromatin in these species might be related to the presence of G-Crich satellite DNA.     

In Situ Hybridization at the Electron Microscopic Level Using a Bromodeoxyuridine Labeled DNA Probe

A bromodeoxyuridine (BrdU) labeled DNA probe was used for in situ hybridization at the electron microscopic (EM) level. A BrdU labeled DNA probe was hybridized in situ to cryostat sections of paraformaldehyde fixed OCT compound embedded cultured HL-60 cells. After hybridization, some sections were incubated with FITC-conjugated anti-BrdU monoclonal antibody for fluorescence microscopy (FM). and others were embedded in Quetol for electron microscopy (EM). The ultrathin sections of Quetol-embedded specimens were incubated with the anti-BrdU monoclonal antibody and the immunoglobulin: gold colloid. In both FM and EM studies, the signals were concentrated in the rough endoplasmic reticulum. Moreover, some label was arranged from the nucleus to the cytoplasm at the EM level. Relatively simple methods using the BrdU labeled DNA probe for the detection of the defined nucleic acid sequence with reasonable tissue preservation and high resolution are described here. This method may be useful for developmental and disease related studies of specific mRNA in cells and tissues.     

Reversible differential decondensation of unfixed Chinese hamster chromosomes induced by change in calcium ion concentration of the medium

Differential decondensation of isolated unfixed Chinese hamster metaphase chromosomes was obtained by decreasing the calcium ion concentration in the surrounding medium. A banded appearance of the swollen chromosomes could be observed either directly by phase contrast microscopy or after glutaraldehyde fixation and staining. There was a gradual transition from homogeneously dense to banded and finally to extensively decondensed chromosomes. The patterns induced at different stages were similar to those observed on fixed chromosomes after standard banding procedures (i.e., G-, C-, C_d–, Ag-NOR-staining). Chromosome decondensation could be reversed by the addition of calcium ions to the medium. Ca⁺⁺-dependent reversible differential chromosome decondensation was not observed if the chromosomes were previously treated with 0.35 M NaCl. Chromosome regions which had incorporated BrdU into their DNA were more resistant to a decrease in calcium ion concentration than BrdU non-substituted regions.     

Immunological visualization of 5-methylcytosine-rich regions in Indian Muntjac metaphase chromosomes

Regions rich in 5-methylcytosine were localized in male metaphase chromosomes of the Indian muntjac deer (Muntiakus muntjak). Chromosomes were ultraviolet irradiated and subsequently photooxidized in the presence of methylene blue to induce maximum DNA denaturation. Following treatment with anti 5-methylcytosine antibody (anti 5-MeC), regions of antibody binding were visualized by an immunofluorescence or immunopreoxidase staining procedure. All chromosomes showed some level of antibody binding along their length and at centromeric regions, with intense binding evident in the centromere of chromosome 3 and the elongated centromeric "neck" of chromosome 3-X. The Y chromosome displayed low levels of antibody binding. The banding pattern observed with anti 5-MeC is the reverse of that obtained by quinacrine staining.     

G-banding and chromosome structure

G-banding of chromosomes promises to be the most valuable technique for routine chromosome analysis due to its inherent simplicity, sensitivity, and stability of the material obtained. In the past, banding procedures have had several shortcomings in regard to efficiency and consistency of results. It is now possible to obtain good and consistent quality banding by using minor modifications of the standard technique, including the use of diluted Giemsa. This has eliminated the need of pre-treatment of the chromosome preparation, a point overemphasized in most of the work published so far. G-banding can also be observed using DNA (Feulgen) and histone (Alcian blue) stains. The results obtained by this simple technique suggest that banding represents a native conformational feature of chromosomes.     

Multiplex-FISH for pre- and postnatal diagnostic applications.

For >3 decades, Giemsa banding of metaphase chromosomes has been the standard karyotypic analysis for pre- and postnatal diagnostic applications. However, marker chromosomes or structural abnormalities are often encountered that cannot be deciphered by G-banding alone. Here we describe the use of multiplex-FISH (M-FISH), which allows the visualization of the 22 human autosomes and the 2 sex chromosomes, in 24 different colors. By M-FISH, the euchromatin in marker chromosomes could be readily identified. In cases of structural abnormalities, M-FISH identified translocations and insertions or demonstrated that the rearranged chromosome did not contain DNA material from another chromosome. In these cases, deleted or duplicated regions were discerned either by chromosome-specific multicolor bar codes or by comparative genomic hybridization. In addition, M-FISH was able to identify cryptic abnormalities in patients with a normal G-karyotype. In summary, M-FISH is a reliable tool for diagnostic applications, and results can be obtained in 相似文献   

Early replication banding reveals a strongly conserved functional pattern in mammalian chromosomes

One of the best documented autosomal linkage associations in man is on chromosome 1p and in the mouse on chromosome 4. On mitotic chromosomes this genetic homology is shown more clearly by early replication banding (RBG; induced by incorporation of 5bromodeoxyuridine (BrdU) in the second half of the S phase) than by structural banding (induced on prefixed chromosomes by denaturation, RFA, or trypsin, GTG). To analyse this phenomenon in more detail, 11 chromosomal regions in man and the domestic cat with known genetic homology were compared. In four chromosome pairs RBG and GTG banding show the same degree of homology. In seven chromosome pairs the homology is more pronounced by RBG than by GTG banding. RFA banding does not reveal the same extent of homology as does RBG banding. These results clearly show a difference between the structural banding pattern, RFA and GTG, and the replication banding pattern, RBG. The following conclusions can be drawn: in chromosomal regions with homologous functions the DNA replicates in the same temporal order. Early replication banding (RBG) reveals a functional pattern in these regions which has been more strongly preserved during evolution than the underlying chromosomal DNA. Differences in chromosomal banding are most prominent in the GTG banding pattern, whereas similarities are most apparent in the RBG banding pattern.     

Banding of human chromosomes with basic fuchsin

Summary In this paper a technique is described for the banding of human metaphase chromosomes with basic fuchsin. The main characteristics of the G-banding pattern obtained with this cationic triphenylmethane dye are:the secondary constriction regions of chromosomes Nos. 1 and 16 are strongly stained, especially in the latter one;the heterochromatic area of chromosome No. 9, usually negative with most other G-banding techniques, is clearly visible as an intensely stained band adjacent to the centromere;the chromosomal outline is often very distinct, facilitating the study of the telomeres; a number of chromosomal regions with bright Q fluorescence such as the polymorphic regions of the chromosomes Nos. 3, 4, and Y also stain strongly with basic fuchsin.The basic fuchsin technique combines therefore properties of G-, C-, and Q-banding methods and seems very suitable for use in e.g., family and linkage studies.Several triphenylmethanes closely related to basic fuchsin produce similar banding patterns. The band-producing ability is, however, diminished in those dyes which contain methylated amino groups. If the methyl groups are attached to the carbon atoms at the 3-positions in the phenyl rings, band formation seems unaffected.The way in which basic fuchsin and chromatin may interact as well as the possible mechanism(s) of band formation with this dye are discussed.