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.     

Banding patterns of the chromosomes of man and the chimpanzee

Summary A comparison of the banding patterns of the chromosomes of man (Homo sapiens) and the chimpanzee (Pan troglodytes) using G (Giemsa) and Q (quinacrine) banding techniques shows that the differences between the karyotypes of the two species are the result of a few simple structural rearrangements, which include one centric fusion, five pericentric inversions, one paracentric inversion and the absence of one secondary constriction.

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Zusammenfassung Ein Vergleich der Bandenmuster der Chromosomen des Menschen (Homo sapiens) und des Schimpansen (Pan troglodytes) bei Anwendung der G(Giemsa)- und Q(Quinacrin)-Bandentechnik zeigt, daß die Unterschiede zwischen den Karyotypen beider Species das Ergebnis einiger weniger einfacher Umstrukturierungen sind, nämlich einer zentrischen Fusion, 5 perizentrischen Inversionen, einer parazentrischen Inversion und des Fehlens einer sekundären Konstriktion.

     

Heterochromatic differentiation in barley chromosomes revealed by C- and N-banding techniques

Summary Heterochromatin distribution in barley chromosomes was investigated by analyzing the C- and N-banding patterns of four cultivars. Enzymatic maceration and air drying were employed for the preparation of the chromosome slides. Although the two banding patterns were generally similar to each other, a clear difference was observed between them at the centromeric sites on all chromosomes. Every centromeric site consisted of N-banding positive and C-banding negative (N⁺ C^–) heterochromatin in every cultivar examined. An intervarietal polymorphism of heterochromatin distribution was confirmed in each of the banding techniques. The appearance frequencies of some bands were different between the two banding techniques and among the cultivars. The heterochromatic differentiation observed is discussed with respect to cause.     

Analysis of replication patterns in chromosomes of normal Chinese hamster and its cell lines

Replication patterns of the normal male Chinese hamster chromosomes and the three cell lines CHW, 1102 and 1103, were determined using fluorescent, plus Giemsa or acridine orange, techniques. The individual chromosomes or chromosomal segments were consistent in the replication patterns of normal Chinese hamster chromosomes and all the transformed cell lines. Late DNA replication was regularly identified in the long arm of the X chromosome, the entire Y chromosome, the short arms of chromosomes 6 and 7, and the paracentromeric regions of chromosomes 8, 9 and 10. A similar consistency was demonstrated in the large late replicating areas of chromosomes X and Y. Each cell line had specific marker chromosomes by which the cell line was identified and their replication patterns have been described. The chromosome analysis in cell line 1103 indicated that chromosomes 2, 3, 8 and 9 were more stable than others, of which chromosome 2 was extremely stable. The markers M4 and M5 in cell line 1103 are very interesting. The cytogenetic behaviour of marker M4 indicated a new phenomenon of translocation by simple association. The marker chromosome M5 indicated that inactivation spread to the early replicating distal region. These cell lines are very useful tools for studying replication patterns and providing a basic understanding of mammalian cytogenetics.     

Banding patterns in Drosophila melanogaster polytene chromosomes correlate with DNA-binding protein occupancy

The most enigmatic feature of polytene chromosomes is their banding pattern, the genetic organization of which has been a very attractive puzzle for many years. Recent genome-wide protein mapping efforts have produced a wealth of data for the chromosome proteins of Drosophila cells. Based on their specific protein composition, the chromosomes comprise two types of bands, as well as interbands. These differ in terms of time of replication and specific types of proteins. The interbands are characterized by their association with active chromatin proteins, nucleosome remodeling, and origin recognition complexes, and so they have three functions: acting as binding sites for RNA pol II, initiation of replication and nucleosome remodeling of short fragments of DNA. The borders and organization of the same band and interband regions are largely identical, irrespective of the cell type studied. This demonstrates that the banding pattern is a universal principle of the organization of interphase polytene and non-polytene chromosomes.     

Banding patterns of the chromosomes of Nycticebus coucang (Boddaert, 1785).

Q, G and C banding studies of the chromosomes of Nycticebus coucang permitted the identification of all pairs in the complement. The X was a long submetacentric, the Y a rather long metacentric. All members of the complement were non-acrocentrics. The differences between the 2n = 52 and the 2n = 50 karyotypes described in this species may be due to a centric translocation mechanism.     

Banding patterns of the chromosomes of Presbytis cristatus pyrrhus and P. obscurus

The G- and Q-bands and the location of the nucleolar organizer regions (NOR) in the chromosomes of Presbytis obscurus and the Q- and C-bands of P. cristatus pyrrhus are described. Their chromosomes are compared to those of Macaca mulatta and to other Cercopithecidae and Hylobatidae. The origin of the two different banding patterns of pair no. 1 in our specimen of P. cristatus pyrrhus is discussed.     

Banding patterns on lampbrush chromosomes of Triturus marmoratus (Amphibia Urodela) by the Giemsa stain

Lampbrush chromosome preparations from the newt species Triturus marmoratus have been submitted to a banding procedure by using a Giemsa stain technique (C-banding) as well as variants of the method. Centromeres, most of telomeres, the nucleolus organizing region and some segments along the chromosome axes appear to be differently stained. The centromere positions have been indicated on the maps of the lampbrush complement of the species. The possible relationships between banding and chromosome structure and organization are briefly discussed.     

Banding patterns of the chromosomes ofCercopithecus neglectus: Comparison withMiopithecus talapoin andErythrocebus patas

The G, Q, and C bands and the location of the nucleolar organizing regions (NORs) of the chromosomes of two male Cercopithecus neglectusare described. The diploid number of the species is 2n =62. Comparison with the karyotypes of Miopithecus talapoin (2n =54), and Erythrocebus patas (2n =54)showed the presence of total banding homeology for only 10 chromosome pairs.     

Effect of Hoechst 33258 on Chinese hamster chromosomes

Cells of the Chinese hamster strain C-125 were treated for different time intervals with H 33258, a bibenzimidazole derivative. The same compound was used to stain fixed cells of the same strain. — H 33258 induced in cells in culture specific areas of reduced spiralization on the metaphase chromosomes of some cells. These probably correspond to DNA segments rich in A-T bases interspersed along the chromosomes. Probably H 33258 acts during S period of cell cycle. — The banding obtained by staining with H 33258 is similar to that induced by quinacrine dihydrochloride but shows a better resolution.