苜蓿核糖体基因物理定位及染色体荧光分带

利用核糖体基因为探针对,二倍体和四倍体苜蓿(Medicago sativa)进行原位杂交,结果表明,45s在四倍体、二倍体种中总是以单位点位于核仁组织区,5s则有2～3个位点;以二倍体种的基因组DNA为探针的原位杂交表明,蓝花苜蓿(M.coerulea)和黄花苜蓿(M.falcata)均能与四倍体染色体进行杂交,仅杂交信号强弱的染色体数目有差别;荧光染料DAPI使苜蓿的染色体显示带纹,蓝花苜蓿的DAPI带与C-带基本一致.文章对四倍体苜蓿的可能来源进行了讨论.     

Nuclear protein matrix in giant nuclei from salivary glands of <Emphasis Type="Italic">Chironomus plumosus</Emphasis>

Polythene chromosomes from salivary glands of Chironomus plumosus were treated in situ in order to reveal residual nuclear protein matrix (NPM). It was shown that after the removal of H1-histones by 0.6 M NaCl the general morphology of chromosomes is preserved, revealing distinct banding pattern. Further treatment of chromosomes with 2 M NaCl and DNase completely disorganized the structure of chromosome bodies and patterns of banding. Preliminary treatment of salivary glands with 2 mM CuCl₂ resulted in stabilization of the structure of polythene chromosome in every stage of histone and DNA extractions. Stabilized chromosomes maintained their morphology and banding patterns observed by phase contrast or after the staining with Brilliant blue. Thus, after the removal of histones and DNA, stabilized chromosomes retain their morphological features, which depend on the presence of NMP. In stabilized polythene chromosomes, in spite of the absence of histones and DNA, topoisomerase IIα retains its localization, typical for untreated chromosomes.     

Simultaneous observation of quinacrine bands and silver grains on radiolabeled metaphase chromosomes

A procedure is described for quinacrine banding of radiolabeled metaphase chromosomes for autoradiography. The chromosomes can be labeled either in vivo or by in situ hybridization. The banding procedure involves treating the slides with RNase and formamide and staining in quinacrine. The slides are then processed for autoradiography. After development of the photoemulsion, the chromosomes can be karyotyped with UV light by their fluorescent banding patterns and the silver grains overlaying the chromosomes can be demonstrated by the addition of tungsten light. It is possible by careful manipulation of the visible light to simultaneously observe both fluorescent bands and silver grains. This technique should significantly increase the accuracy of chromosome identification after autoradiography and decrease the time and effort required for such analysis.     

Nucleolus organizer and N-band distribution in morphologic and fluorescence variants of human chromosomes

Summary Three cases of morphologic variants of human D- or G-group chromosomes have been studied by N- and Ag-AS banding techniques. The results confirm our previous findings about the localization of nucleolus organizers on the secondary constrictions of acrocentric chromosomes. Preliminary results on the distribution and number of N bands in D- and G-group chromosomes with morphologic and fluorescence variants are reported     

Chromosomal banding pattern and idiogram of the cotton rat,Sigmodon arizonae (Rodentia,Muridae)

A procedure for obtaining G-bands on chromosomes of mammals is outlined. The procedure was utilized in an investigation of the idiogram and banding pattern of the mitotic chromosomes of the cotton rat, Sigmodon arizonae. The diploid number of this species is 22, and each pair of homologues is easily separated on the basis of size, centromeric position, and banding pattern. The autosomes are represented by four pairs of large submetacentric chromosomes, three pairs of medium to small submetacentric chromosomes, two pairs of large subtelocentric chromosomes and one pair of small acrocentric chromosomes. The X chromosome is acrocentric and averages from 5.42% to 5.46% of the haploid female complement. The Y chromosome is a minute acrocentric and easily separated from the smallest acrocentric autosome. The usefulnes of Sigmodon arizonae as a laboratory animal for cytogenetic studies is substantiated.     

The Feulgen banded karyotype of the mouse: analysis of the mechanisms of banding

The chromosomes of the mouse have been identified by specific banding patterns revealed by the Feulgen stain. Comparison of the patterns of the Feulgen-stained karyotype with those of acetic-saline-Giemsa stain and quinacrinemustard-fluorescence demonstrates a high order of similarity among the three, with the localization of Feulgen dense bands and regions closely paralleling that of Giemsa dark and fluorescence bright bands. Since the stained substrate of the Feulgen reaction is known to be DNA, it is suggested that all three banding methods reveal the distribution of DNA or of some moiety that closely follows DNA distribution in metaphase chromosomes. The preparative procedure of the Feulgen banding method consists of a 15 to 20 minute exposure to PO₄ buffer at pH 10 and a prolonged (60–72 hrs) exposure to 12xSSC. Omission or curtailment of either step results in preparations with chromosome sets that are not karyotypable, although some stain differentiation is produced. HCl extraction prior to the preparative treatment blocks banding, but acid extraction following the preparative treatment, either that of the HCl hydrolysis of the Feulgen reaction of that of an almost fourfold extension of the standard hydrolysis time, does not obliterate bands already formed. By extrapolation from biochemical studies of chromatin, it is postulated that the localization of Feulgen dark and light stain, representing relative DNA densities, reflects the regional protein association of the DNA; the Feulgen dense regions may result from aggregation of a specific class of histones by the alkaline buffer with consequent condensation of the DNA bound to those histones; the Feulgen pale or negative regions may represent those in which non-aggregated proteins, histone and non-histone, have been solubilized in the saline incubation, rendering the DNA of those regions subject to diffusion or vulnerable to fragmentation in the Feulgen hydrolysis.     

Homologous chromosomes characteristics by sequential banding procedures in rainbow trout Oncorhynchus mykiss

The development of high resolution methods of chromosome banding helped the finding of homologous chromosomes, detecting chromosomal abnormalities, and assigning the gene loci to particular chromosomes in mammals. Unfortunately, small and numerous fish chromosomes do not show GC rich and GC poor compartments, this preventing the establishment of G banding pattern. The combination of techniques enabling the identification of constitutive heterochromatin (C-banding), heterochromatin resistant to restriction endonucleas, NOR bearing chromosomes (AgNO3 banding), or AT rich regions on chromosomes (DAPI banding) in sequential staining provides a better characteristic of fish chromosomes. In this work sequentially DAPI, DdeI, AgNO3 stained chromosomes of rainbow trout resulted in the characteristic banding pattern of some homologous chromosomes. Procedure of FISH with telomere probe and DAPI as a counterstaining fluorochrome visualized simultaneous hybridization signals and DAPI banding. Possibility of detection both FISH and DAPI signals can help in procedures of gene mapping on chromosomes.     

Enhanced resolution of specific chromosome and nuclear regions by reflectance laser scanning confocal microscopy

 DNA sequences digested by HaeIII and reconstructed by in situ nick translation employing digoxigenin-labelled nucleotides are usually revealed either by horseradish peroxidase or FITC fluorescence. To obtain a significant improvement in terms of resolution, sensitivity and specificity, colloidal gold has been used instead of FITC (as the reporter molecule) to reveal the labelled DNA. Colloidal gold and propidium iodide were visualised by employing the reflectance mode and the 488-nm laser line of a confocal laser scanning microscope. In chromosomes, the fluorescent reaction pattern showed diffuse areas of labelling in which it was impossible to identify any specific kind of banding along the arms. In some chromosomes and, in particular, 1 and 9, a C-negative banding due to the negativity of the centromeric areas was seen. A more accurate localisation on chromosomes, including telomeric regions, often organised in spot pairs that resembled an R-like banding, was detected using 1-nm colloidal gold. A fine labelling was also demonstrated in nuclei, especially at their peripheral heterochromatin. The non-fading properties of colloidal gold combined with visualisation by reflectance confocal laser scanning microscopy demonstrated the possibility of obtaining a higher spatial resolution than when using conventional fluorophores or higher laser wavelength. This improved way to study the localization of HaeIII digestion sites in single chromosomes and in interphase nuclei made the reaction a valuable tool for the detection of antigens or of specific DNA sequences in biological preparations. Accepted: 5 September 1996     

Analysis of the human karyotype using a reassociation technique

A characteristic banding pattern can be made visible in human chromosomes by a denaturating and renaturating procedure performed on cytological preparations. The banding pattern is characteristic of each chromosome pair, allowing easy identification of all human chromosomes. The method is likely to provide a useful tool in the identification of mammalian chromosomes and in the study of aberrations and variations in the chromosome set.     

Detection of a Single-Locus Gene on Channel Catfish Chromosomes by In-Situ Polymerase Chain Reaction

An in-situ polymerase chain reaction (ISPCR) procedure was applied to chromosomal localization of the gene, Ig H, encoding the immunoglobulin heavy chain of channel catfish (Ictalurus punctatus). Metaphase chromosomes were prepared by a replication banding procedure and subjected to ISPCR using biotin-labeled primers. The hybridization signals were detected with an avidin-fluorescein isothiocyanate (FITC)-based method, and chromosome bands revealed by simultaneous or sequential treatment methods. Standard fluorescent in-situ hybridization (FISH) was performed on chromosome preparations to compare with the ISPCR procedure. The Ig H gene was detected at the telomeric position of a chromosome with a relative length of 3.2 ± 0.2%. The Ig H-bearing chromosome detected by the FISH method was identical to that found by ISPCR procedure. Visibility of chromosome bands was reduced by heat and salt treatments and could not be analyzed after thermocycling. Therefore, specific identity of the chromosome bearing the Ig H gene remains unknown. Banding of fish chromosomes is difficult and poses a barrier for applying current molecular techniques to physical mapping of teleost genomes. Application of the ISPCR to chromosomal mapping is new for fish species and is only in initial stages of development for higher vertebrates.     

An improved method for chromosome-specific labeling of alpha satellite DNA in situ by using denatured double-stranded DNA probes as primers in a primed in situ labeling (PRINS) procedure.

An improved primed in situ labeling (PRINS) procedure that provides fast, highly sensitive, and nonradioactive cytogenetic localization of chromosome-specific tandem repeat sequences is presented. The PRINS technique is based on the sequence-specific annealing in situ of unlabeled DNA. This DNA then serves as primer for chain elongation in situ catalyzed by a DNA polymerase. If biotin-labeled nucleotides are used as substrate for the chain elongation, the hybridization site becomes labeled with biotin. The biotin is subsequently made visible through the binding of FITC-labeled avidin. Tandem repeat sequences may be detected in a few hours with synthetic oligonucleotides as primers, but specific labeling of single chromosomes is not easily obtained. This may be achieved, however, if denatured double-stranded DNA fragments from polymerase-chain-reaction products or cloned probes are used as primers. In the latter case, single chromosome pairs are stained with a speed and ease (1 h reaction and no probe labeling) that are superior to traditional in situ hybridization. Subsequent high-quality Q banding of the chromosomes is also possible. The developments described here extends the range of applications of the PRINS technique, so that it now can operate with any type of probe that is available for traditional in situ hybridization.     

Banding isolated metaphase chromosomes by a sequential fluorescent G/Q technique

Summary G/Q-banding is a new, rapid, fluorescent technique for banding isolated chromosomes that incorporates characteristics of both G- and Q-banding. G-bands, while easily characterized, are often inconsistent when using isolated chromosomes, and Q-bands, while reliable, fade rapidly under UV exposure, making prolonged observation and photography difficult. G/Q-banding combines these techniques to sequentially utilize quinacrine staining over Giemsa banding to produce slow-fading fluorescent G/Q-bands. The background fluorescence in G/Q preparations fades quickly under continued UV exposure, while the chromosomes remain brightly banded and can be observed and photographed for at least five minutes. G/Q-banding was extended to whole cell chromosome spreads and produced results identical to those obtained with isolated chromosomes. Whole cell karyotypes indicate that G/Q-bands generally correspond to Q-bands. Advantages of G/Q-banding as a unique and universal technique over current double-staining procedures are discussed.     

Giemsa banding of meiotic chromosomes

Applying a Giemsa staining technique to the meiotic chromosomes of Anemone blanda demonstrates that Giemsa bands similar to those seen in the mitotic chromosomes are discernible at all the principal stages of meiosis. The bands are not a product of the Giemsa procedure since they can be seen in unstained preparations using phase-contrast optics as chromocentres in interphase nuclei and as condensed regions in prophase chromosomes. That the bands seem to be permanent features of the nucleus, whether it is dividing or otherwise is an important consideration for understanding their nature and function. Bands and chiasmata do not coincide indicating on the one hand that chiasmata are not responsible for differences in banding patterns and on the other hand that the conservation of bands is an indication that they are either inert regions or specialised regions with considerable adaptive significance. These alternatives can only be resolved by genetical studies of the banding phenomena.     

Photometric determination of the DNA distribution in the 24 human chromosomes

From five normal individuals the DNA content and the DNA arm ratios of the 24 metaphase chromosomes were determined by means of scanning densitometry of photographic negatives of Feulgen-stained metaphase preparations. The results showed high reproducibility of the measuring procedure. The obtained DNA values for the 24 chromosomes showed general correspondence between the individuals. No differences between males and females were found. The DNA arm ratios showed somewhat higher inter-individual variability, especially for the acrocentric chromosomes. Our data are in agreement with other data published so far, which were obtained with somewhat different techniques, indicating that the DNA content of the individual human chromosomes in general is highly constant. Attempts were made to distinguish chromosomes by their DNA content and DNA ratio. It appears that classification of chromosomes using these parameters cannot compete with classification according to the banding patterns. Determination of the total DNA content and DNA distribution along the metaphase chromosomes may, however, provide a frame of reference for cytochemical methods directed towards the localization and quantification of molecular properties of the chromosome.     

The banding pattern of the salivary gland chromosomes of Drosophila hydei

The banding pattern of the salivary gland chromosomes of D. hydei was investigated in the electron microscope. We compared the banding pattern of squashed chromosomes with non-squashed preparations and observed that the fixation and squash procedure we used does not introduce artificial changes in the banding pattern of the chromosome. An electron microscopic map was made of the banding pattern of the distal half of the second salivary gland chromosome. On the basis of the number of bands in this part of the second chromosome we calculated a total of about 3700 bands for the whole set of polytene chromosomes of D. hydei. Our data indicate a similar number of bands in the salivary gland chromosomes of evolutionary remote Drosophila species like D. hydei and D. melanogaster.     

The role of proteins in the production of different types of chromosome bands

Experiments have been carried out to try and answer two questions on the role of proteins in chromosome banding: firstly, what degree of protein extraction is required before banding can be produced; and secondly, to what extent are redistribution and reorganization of chromosomal components required for the production of banding. Partial extraction of all histones, and of a group of non-histones with molecular weights mainly between 50,000 and 70,000 appears to be necessary before G-, C- or R-banding can be produced. More extensive 'dehistonization' to produce chromosome scaffolds inhibits the production of all types of bands. Protein-protein and protein-DNA cross-linking inhibits all types of banding tested, the degree of inhibition being roughly related to the degree of cross-linking, but not apparently to the type of cross-linking. The results of both sets of experiments indicate that chromosome banding of all types is dependent on the prior loss from chromosomes of a specific set of proteins, and on some alteration of the arrangement of remaining chromosomal components during the banding procedure.     

Simultaneous identification and banding of human chromosome material in somatic cell hybrids

We have developed a method that identifies human chromosomes in human x hamster somatic cell hybrids and simultaneously bands these same metaphases. Other methods generally require separate slides for banding and detection of human chromosome material, making the precise characterization of human material difficult. Our procedure involves denaturing metaphase chromosomes, followed by in situ hybridization of biotinylated whole human DNA. Fluoresceinated avidin is then bound to the biotinylated DNA, staining the human chromosomes yellow-green when excited with UV light. Chromosome banding is achieved by staining the slides with DAPI and actinomycin D. The fluorescein and DAPI excite maximally at 488 and 355 nm and emit at 520 and 450 nm, respectively. This permits identification of the human material at one excitation wavelength and visualization of the banding patterns at another wavelength. With this procedure, we have successfully identified both intact and broken human chromosomes, as well as human material involved in human x hamster translocations. The results indicate that this procedure is more accurate and considerably more rapid than previous methods and can be routinely employed for the cytogenetic analysis of human x rodent hybrids.     

A comparative study on the effect of various detergents in human chromosome G-banding prior to tryptic digestion

The effect of treatment of chromosomes with various detergents prior to tryptic banding was investigated. The pre-treatment improved the resolution of banding for most of the chromosomes. The effectiveness of the detergents varied greatly. The number of chromosome pairs with optimal banding found after the use of different detergents was as follows: 19 of the possible 23 for emulphogene, 15 for Nonidet, 9 for Triton X-100, 10 for Tween 40, 4 for Tween 80, 4 for DOC and 18 for SDS compared to 3 for trypsin without using detergent. Optimal banding was as defined by the Paris Conference (1971) map. The improvement of banding was shown to be due to detergent-induced changes in the chromosomal proteins. When the chromosomes were treated first with trypsin followed by the detergent no improvement of chromosomal banding was observed. The detergents showed a degree of specificity towards individual chromosomes; certain chromosomes were found to be better banded with a particular detergent. Pretreatment of chromosomes with a combination of two detergents — simultaneously or consecutively — was found not to be additive. After such treatment the chromosome bands were disrupted. Pretreatment with different detergents sometimes changed the topography of chromosome banding, i.e., the relative location of the bands from the centromere. These findings suggest that the proteins attached to the DNA of the chromosomes were removed or loosened from different sites by the various detergents. — For chromosomes 8, 9, 20 and X, additional bands not reported previously were detected.On sabbatical leave from the Weizman Institute of Science, Rehovot, Israel     

Nuclear protein matrix from giant nuclei of Chironomus plumosus determinates polythene chromosome organization

Giant nuclei from salivary glands of Chironomus plumosus were treated in situ with detergent, 2 M NaCl and nucleases in order to reveal residual nuclear matrix proteins (NMP). It was shown, that preceding stabilization of non-histone proteins with 2 mM CuCl2 allowed to visualize the structure of polythene chromosomes at every stage of the extraction of histones and DNA. Stabilized NPM of polythene chromosomes maintains their morphology and banding patterns, which is observed by light and electron microscopy, whereas internal fibril net or residual nucleoli are not found. In stabilized NPM of polythene chromosomes, topoisomerase IIalpha and SMC1 retain their localization that is typical of untreated chromosomes. NPM of polythene chromosomes also includes sites of DNA replication, visualized with BrDU incubation, and some RNA-components. So, we can conclude that structure of NPM from giant nuclei is equal to NPM from normal interphase nuclei, and that morphological features of polythene chromosomes depend on the presence of NMP.     

Characterization of G-banded chromosomes of the Indian muntjac and progression of banding patterns through different stages of condensation

Muntjac prophase and metaphase chromosomes were G-banded following methotrexate-mediated synchronization of peripheral lymphocytes. Bands and subbands were characterized from prophase through metaphase, and the progression of band patterns from late prophase to mid-metaphase was analyzed. Extended prophase chromosomes exhibited more bands and subbands, a number of which became fused with each other, giving rise to fewer and thicker bands in the condensed metaphase chromosomes. It appeared that the dark bands condensed relatively more than the light bands. Precise delineation of the bands and subbands on extended prophase chromosomes and the usage of a proposed banding pattern nomenclature should aid in better detection and localization of induced chromosomal rearrangements with this extremely useful experimental material.