Description of the Anser anser goose karyotype

The karyotype of the Italian goose originating from Anser anser was characterised on the basis of R and C bands. Chromosomal preparations obtained from an in vitro culture of blood lymphocytes were stained with the RBG and CBG techniques. The RBG technique enabled the analysis of the structure of nine pairs of chromosomes whereas the CBG technique - fourteen pairs ofchromosomes from the total ofeighty goose chromosomes. The morphology and the R and C banding patterns were described. The size and arrangement of the blocks of constitutive chromatin were determined. Ideograms of R and C banded patterns were drawn. The morphological structure of the analysed chromosomes was evaluated.     

Comparing the karyotype of the European domestic goose and the Asian goose on the basis of the karyotype of their interspecific cross-breed, using the RBG chromosome staining technique

The aim of the research was to compare the karyotypes of two goose species: the European domestic goose and the Asian goose on the basis of the karyotype of their interspecific cross-breed, using the RBG chromosome staining technique. The karyotype standard for Anseriformes has not been determined yet. The RBG technique is considered as one of the standard methods for analysing chromosomes. It is a dynamic method. The R bands appear during the cell growth cycle in the early S phase. The formation of the characteristic band configuration for each chromosome facilitates chromosome segregation and analysis. The mitotic chromosomes for experiments were obtained from an in vitro blood lymphocyte culture and stained according to the RBG technique. The first eight largest autosome pairs and the ZW sex chromosomes were analysed. No differences were found between the band patterns of the analysed chromosomes, except for the fourth autosome pair.     

Centromeric banding (C) of sequentially Q- and R-banded human chromosomes

Summary A modified C-banding technique is described that produces C bands on human chromosomes after sequential Q and R banding and retains good chromosome morphology. Despite the considerable exposure to UV light during sequential Q and R bandings, clear C bands could still be achieved. Employing the present technique, Q, R, and C polymorphisms can be recorded on a single metaphase.     

Production of C and T bands in human mitotic chromosomes after heat treatment

Summary A modified thermal denaturation of human chromosomes in Hanks' solution at 91°C produces highly contrasted C and T bands. This improved double-banding system is a good tool in the analysis of ring chromosomes, for which R banding is often inadequate, as it is exemplified.Service Prof. J. Battin     

Banding patterns in newt chromosomes by the giemsa stain

Specific banding patterns can be produced on the mitotic chromosomes of the newt species Triturus vulgaris meridionalis and T. italicus by using the Giemsa stain technique. These bands are most useful cytogenetic markers in karyotyping, since they facilitate identification of the individual elements of the complements. Evaluation of the shape of chromosomes as well as of the banding patterns produced by the Giemsa stain indicates that the karyotypes of T. vulgaris meridionalis and T. italicus are differentiated: hence the specific distinction of the two Salamandrids, still debated by taxonomists, appears supported by chromosome evidence. — Most of the bands seem to correspond to the heterochromatic tracts observable on mitotic chromosomes from embryos and larvae either untreated or submitted to cold treatment. Besides, the comparison of mitotic karyotypes and lampbrush maps shows that the bands located near the centromeric regions of mitotic chromosomes probably correspond to the so-called bars visible on either side of centromeres of lampbrush chromosomes, while some of the subterminal bands may correspond to the sphere.This work was financially supported by C. N. R., Roma.     

Heterochromatin patterns in triatomines of the genus Panstrongylus

Spermatogenesis was analysed by C-banding in two species of triatomines, Panstrongylus megistus and P. herreri. Both species revealed interstitial and terminal bands in the autosomes, which is a common pattern in Heteroptera. The terminal bands corroborated the hypothesis that in holocentric chromosomes the heterochromatin is preferentially located at the telomere. The sex chromosomes in P. herreri were totally heterochromatic in spermatogenesis, and in P. megistus the X chromosomes alternated between positive and negative banding.     

Equivalence of the total constitutive heterochromatin content by an interchromosomal compensation in the C band sizes of chromosomes 1, 9, 16, and Y in Caucasian and Japanese individuals

A quantitative analysis of C bands by densitometric measurements in chromosomes 1, 9, 16, and Y was conducted in Caucasians and Japanese living in Brazil. Sixty normal unrelated subjects (30 males and 30 females) were studied in each racial group. Caucasians presented C bands of chromosomes 1, 9, and 16 larger than Japanese, but, on average, only the difference for C bands of chromosome 9 was statistically significant. In the Japanese, the C band sizes of chromosomes Y were, on average, significantly larger than in the Caucasians. The mean C band size of chromosome 9 and the sum of the three pairs were significantly larger in Caucasian than in Japanese males. The total values of constitutive heterochromatin, sigma (1qh,9qh,16qh,Yq12), did not show significant difference between Caucasian and Japanese males. The relative C band sizes of chromosomes 1, 9, and 16 were, on average, similar in Caucasians and Japanese. No sex difference was found in both racial groups. As regards the heteromorphism, only the values of C bands of chromosome 9 were, on average, significantly larger in Caucasians than in Japanese. Partial inversions were detected only among the Caucasians.     

Karyomorphology of six taxa in Chrysanthemum sensu lato (Anthemideae) in Egypt and their genetic relationships by Giemsa C‐banding

Abstract Giemsa C‐banding was applied to the chromosome complements of six diploid species belonging to six genera in Chrysanthemum sensu lato (Anthemideae) distributed in Egypt. Four types of C‐banding distribution were observed in the taxa as follows: (i) negative C‐banding in Anacyclus monanthos (L.) Thell.; (ii) all bands in terminal regions in Achillea fragrantissima (Forssk.) Sch. Bip, which showed 32 bands on 18 chromosomes; (iii) all eight bands at centromeric regions on eight chromosomes in Matricaria recutita L.; and (iv) bands at terminal and centromeric regions in Brocchia cinerea Vis. (12 terminal and six centromeric bands on 12 chromosomes), Cotula barbata DC. (four terminal, six centromeric, and eight short arm bands on 16 chromosomes), and Glebionis coronaria (L.) Cass. ex Spach. (eight terminal on the short arms and four large bands in centromeric regions on 12 chromosomes).     

Distribution of Mitomycin C-induced damage in human chromosomes with special reference to regions of repetitive DNA

The distribution of gaps, breaks, exchanges and other effects induced by Mitomycin C on human chromosomes was analysed to examine the possibility of a correlation between chromosome lesions and regions of repetitive DNA. Homologous and non-homologous exchanges between chromosomes Nos. 1, 9 and 16, and also between and with the acrocentric chromosomes were more frequent than expected, but breaks and gaps appeared to be located randomly with regard to chromosome light and dark bands.     

Banding pattern observed in human chromosomes by the modified BSG technique

Summary A successful modification of the BSG technique to reveal C and R bands simultaneously in human chromosomes is described. Conventional air dried preparations were treated first with 0.1 N HCl for 30 min at room temperature, then denatured in freshly prepared 3% aqueous solution of Ba(OH)₂8H₂O for 10 min at 50°C. After rinsing, the slides were incubated for 1 h at 60°C in 2xSSC, and stained with Giemsa. The striking intense staining pattern could be observed in chromosome No. 19.The factors involved in the present technique were analyzed changing the concentrations of the reagents and the treatment time. It was evident that R, T and C bands correspond to a progressive destruction of the chromosome sructure mainly by the Ba(OH)₂8H₂O solution.     

Analysis of DNA replication patterns of human fibroblast chromosomes the replication map

Summary A replication map of human fibroblast chromosomes from two diploid human female fibroblast lines, 46,XX and 46,X, del (X)(q13), was determined using the fluorescent plus Giemsa (FPG) technique. Each chromosome was found to stain homogeneously dark when thymidine was incorporated for the entire S phase of that particular cell. As the duration of exposure to thymidine progressively decreased by increasing the incubation time in bromodeoxyuridine, the staining intensity of chromosomes decreased and, concurrently, gaps in the staining began to appear. These gaps coincide with R bands and represent the earliest areas to complete DNA synthesis. As these areas widen and increase in frequency, first Q and G bands appear, and finally C bands.Homologous X chromosomes were easily differentiated by either a comparison of the bands present or their staining intensity. The replication kinetics of the structurally abnormal heterocyclic X chromosome were very similar to those of the normal heterocyclic X chromosome. The X chromosome with deletion of a portion of the long arm was consistently late in replication.     

Localization of the gene-richest and the gene-poorest isochores in the interphase nuclei of mammals and birds

At a resolution of 850 bands, human chromosomes comprise two subsets of bands, the GC-richest H3⁺ and the GC-poorest L1⁺ bands, accounting for about 17 and 26%, respectively, of all bands. The former are a subset of the R bands and the latter are a subset of the G bands. These bands showed the highest and the lowest gene densities, respectively, as well as a number of other distinct features. Here we report that human and chicken interphase nuclei are characterized by the following features. (1) The gene-richest/GC-richest chromosomal regions are predominantly distributed in internal locations, whereas the gene-poorest/GC-poorest DNA regions are close to the nuclear envelope. (2) The interphase chromosomes seem to be characterized by a polar arrangement, because the gene-richest/GC-richest bands and the gene-poorest/GC-poorest bands are predominantly located in the distal and proximal regions, respectively, of chromosomes, and because interphase chromosomes are extremely long. While this polar arrangement is evident in the larger chromosomes, it is not displayed by the chicken microchromosomes and by some small human chromosomes, namely by chromosomes that are almost only composed by GC-rich or by GC-poor DNA. (3) The gene-richest chromosomal regions display a much more spread-out conformation compared to the gene-poorest regions in human nuclei. This finding has interesting implications for the formation of GC-rich isochores of warm-blooded vertebrates.     

Preparation of monosomal lines containing individual human 15, 21, and X chromosomes]

Sorting of human--mouse or human--hamster hybrid cells with particular human chromosomes was performed by in situ hybridization. Total human genomic DNA was heavily labelled with. H and hybridized to metaphase spreads from hybrid clone cells. The method allowed us to not only identify human chromosomes in hybrid cells but also to detect terminal translocations and insertions from 1-2 bands in length to large ones. Biochemical markers of some human chromosomes were analysed using electrophoretic technique in the clones selected. Cytogenetic analysis (G staining) of these clones was made to visualize human chromosomes. Total 99 initial hybrid human--hamster and 26 human--mouse clones were obtained. 53 clones were analysed by in situ hybridization, only one of them being monochromosomal; the latter contained human X chromosome on the background of Chinese hamster chromosomes. Two other monochromosomal clones containing particular 15 and 21 chromosomes, respectively, were obtained by more complicated way from human--mouse hybrid clones using back selection, repeated hybridization and passing through a number of subsequent subclonings.     

Characterization of extrachromosomal DNA in the flesh fly Sarcophaga bullata

The polytene pupal foot pad cells of the flesh fly Sarcophaga bullata contain numerous extrachromosomal DNA containing granules. We have determined both the origin and the nature of the DNA sequences present in these granules. Studies done with quinacrine staining of seven day old pupal foot-pad polytene nuclei showed that the granules fluoresced very brightly while the chromosomal bands to which the granules were attached did not. The only other highly fluroescent regions of the polytene karyotype were the centromeric heterochromatin of chromosomes C and E and several bands associated with the nucleolus of Chromosome A. When polytene nuclei were hybridized in situ with cRNA made from highly repetitive DNA, many of the granules positively labeled. Most of the label on these slides was concentrated on the centromeric heterochromatin of chromosomes C and E. Quinacrine staining of the foot-pad cells at very early stages of pupal development showed that when granules were present, they were always closely associated with the same two centromeric regions, those of chromosomes C and E. Since the highly repetitive DNA located in these centromeric regions is underreplicated, we conclude that the granules result from an extrusion process which takes place early during the polytenization of these cells. The chromosomal integrity of the centromeric heterochromatin of chromosomes C and E is apparently disrupted and repetitive sequences are dissociated from the chromosomes as DNA granules which then secondarily become associated with chromosomal bands throughout the nucleus.     

C-banded karyotypes of two Silene species with heteromorphic sex chromosomes.

Mitotic metaphase chromosomes of Silene latifolia (white campion) and Silene dioica (red campion) were studied and no substantial differences between the conventional karyotypes of these two species were detected. The classification of chromosomes into three distinct groups proposed for S. latifolia by Ciupercescu and colleagues was considered and discussed. Additionally, a new small satellite on the shorter arm of homobrachial chromosome 5 was found. Giemsa C-banded chromosomes of the two analysed species show many fixed and polymorphic heterochromatic bands, mainly distally and centromerically located. Our C-banding studies provided an opportunity to better characterize the sex chromosomes and some autosome types, and to detect differences between the two Silene karyotypes. It was shown that S. latifolia possesses a larger amount of polymorphic heterochromatin, especially of the centromeric type. The two Silene sex chromosomes are easily distinguishable not only by length or DNA amount differences but also by their Giemsa C-banding patterns. All Y chromosomes invariably show only one distally located band, and no other fixed or polymorphic bands on this chromosome were observed in either species. The X chromosomes possess two terminally located fixed bands, and some S. latifolia X chromosomes also have an extra-centric segment of variable length. The heterochromatin amount and distribution revealed by our Giemsa C-banding studies provide a clue to the problem of sex chromosome and karyotype evolution in these two closely related dioecious Silene species.     

Behavior of polytene chromosomes of rhynchosciara angelae at different stages of larval development

Summary Polytene chromosomes in cells of salivary gland, Malpighian tubules and intestine of Rhynchosciara angelae are very favorable for study. The polytene chromosomes of the salivary gland are among the largest available for cytogenetics work. The ones in Malpighian tubules and in some parts of the intestine are as large and as favorable for cytological studies as the salivary chromosomes of many species of Drosophila.Two additional characteristics of Rhynchosciara make these flies excellent material for studies on the development of polytene chromosomes. 1.It is possible to observe the banding pattern of the polytene chromosomes at many stages of the larval life for at least 30 days before pupation, and 2. since the gregarious larvae develop simultaneously, one can sample the group at any stage desired. Sampling the group every day, it is possible to follow the development of the chromosomes as though one studied a single individual by observing it every day.We have followed in detail the behavior of the bands in two sections of chromosome B and in one section of chromosome C, at different stages of larval development. Some regions of the chromosomes which are represented by typical euchromatic bands at one stage of the larval development may develop in enormous bulbs, and later on may return to the banded stage again.The formation of the bulbs is not uniform in different sections of the same or of different chromosomes. In section 2 of chromosome B a certain locus swells enormously and then develops an enormous bulb, and later returns to the banded stage. At the point where the bulb was formed there is an accumulation of DNA, in amounts probably several times greater than before the bulb formation. In section 3 of chromosome B and section 3 of chromosome C the extra accumulation of DNA preceeds the formation of the bulb and is maintained during and after it. In the bulb formed in section 3 of chromosome C a single band seems to be responsible for the process.As shown by several authors, experimental evidence suggests that a gene is located within a band. The bulb formation in polytene chromosomes may then be morphological evidence of gene activities. This type of bulb formations and of return to the banded stage is a property of many chromosomes bands, during larval development. This type of behavior of many bands in polytene chromosomes is related to the process of nucleolus formation. However, this behavior may be found in almost all (if not in all) bands of the polytene chromosomes. If so, the behavior of the nucleolus organizer region is only a special case of this general process.The accumulation of DNA in different parts of the chromosome in cells of the same or of different tissues may be an argument against the theory of the constancy of the amount of DNA in all cells of a species. The bulb formations is not peculiar to R. angelae but occurs in several other Diptera.     

Estimation of chromosome number and size by pulsed-field gel electrophoresis (PFGE) in medically important Candida species.

The chromosomal DNAs of eight medically important Candida species, C. albicans, C. stellatoidea, C. tropicalis, C. parapsilosis, C. krusei, C. guilliermondii, C. kefyr and C. glabrata, were analysed by pulsed-field gel electrophoresis under various conditions. The corresponding bands in the gels were assigned by three kinds of DNA probe which hybridized to DNA of all the species: rDNA, TUB2 and PEP4. The best conditions for separating the chromosomal DNAs were investigated and the numbers and molecular sizes of the chromosome bands were determined for each species. The chromosomal DNAs of the species were separated into 5-14 bands ranging in size from 0.5 to 4.5 Mb. Based on the quantification of the chromosome band intensities using a laser fluorescent gel scanner, the chromosome numbers were estimated. The apparent average total number of chromosomes per cell was 16 for C. albicans, 16 for C. stellatoidea, 12 for C. tropicalis, 14 for C. parapsilosis, 8 for C. krusei, 8 for C. guilliermondii, 18 for C.kefyr, and 14 for C. glabrata; the total chromosomal DNA size of each species per cell was calculated at about 31 Mb, 33 Mb, 31 Mb, 26 Mb, 20 Mb, 12 Mb, 29 Mb and 14 Mb, respectively.     

牡丹染色体的Ag-NORs和Giemsa C带的研究

本文首次报道了紫斑牡丹和栽培牡丹5个重要品种的Ag-NORs和Giemsa C带带型。所有材料的核型组成均为2n=2x=10=6m+2sm+2st。多数材料具6个Ag-NORs,但在染色体上的分布位点不同。C带的差别主要表现在第1、2、3对染色体上。以上两种核学特征,具有品种的特异性。分带所显示的端(T)带和Ag-NORs的数目及分布基本一致。牡丹染色体的端带,本质上是N带;常规染色所显示的所谓随体,实际上是瑞部核仁组成区(NORs)。此外,对牡丹的细胞学研究技术进行了讨论。     

植物染色体G-带的初步研究

本文首次报道了川百台(Lilium davidii)、华山松(Pinus armardii)和七叶一枝花(Paris polyphylla)等植物染色体G-带研究结果。本试验的G-带与以往的C-带不同,C-带每条染色体上一般只有1-4条带,多分布在着丝点附近,而G-带则多达几十条,分布在整条染色体上,带纹清晰,前期染色体带呈颗粒状,中期染色体呈明显的带状,与哺乳动物染色体G-带很相似。G-带的数目取决于染色体浓缩的程度。前期染色体带纹数目是中期的三倍,接近人类高分辨带水平。对G-带带纹采用了自动光谱分析,波峰数值与带纹相符。作者同时介绍了胰酶法在植物染色体G-带中的应用。认为此方法既适合动物亦适用于植物。但植物G-带显示的关键可能不在胰酶法本身,而在合适的分裂时期及染色体处理技术。