Chromosomal heteromorphisms in Delhi infants. III. Qualitative analysis of C-band inversion heteromorphisms of chromosomes 1, 9, and 16

Qualitative analysis of C-band heteromorphisms was carried out in 200 infants (100 males and 100 females) in Delhi, India. Partial inversions minor and half inversions were observed as modal levels for chromosomes 1 and 9 in both sexes. No chromosome 16 with a C-band inversion was observed in the present investigation. A significantly higher incidence of percent inversions for chromosomes 1 and 9 was observed in males than in females. The frequency of heterozygous inversion level combinations for chromosome pairs 1 and 9 were remarkably higher than homozygous combinations both in males and females. Our results are compared with the other reported studies, and the possible role of these heteromorphisms in ethnic/racial variation and in developmental disturbances are discussed.     

Heteromorphism of chromosome 1, 9 and 16 homologs in persons living in regions differing in the level of longevity

Regional and age-related peculiarities of chromosomal polymorphism are established as a result of studies in C-band heteromorphism of chromosomes 1, 9 and 16 in the long-lived subjects, their relatives and population groups of the Abkhaz and Ukrainian Republics. Heteromorphism frequencies of chromosomes 1 and 9 homologs are higher in the Abkhaz as compared with the Ukrainian Republic. Age-related differences as to the degree of expression of chromosome 9 C-band heteromorphism are found: in the Abkhaz Province the frequency of variants with a high heteromorphism degree increases with age, while in the Ukrainian one--with a low heteromorphism degree.     

A new approach in recognition of heterochromatic regions of human chromosomes by means of restriction endonucleases.

The heteromorphisms of C-band regions of human chromosomes are evaluated by means of restriction endonucleases AluI, DdeI, MboI, and RsaI. Every chromosome exhibits heteromorphic markers of the C-band regions except chromosome 8. Each enzyme was found to be highly characteristic in its staining profile, a result that clearly suggests the diversity of heterochromatin. The inherent C-band-region heterochromatin variability that is revealed by these enzymes provides a valuable tool in identifying markers as compared with other previously described techniques.     

A cytogenetic survey of an institution for the mentally retarded

Summary Heteromorphisms of chromosomes 1,9, and 16 were studied by C-banding in a population of 403 mentally retarded individuals from diverse ethinic groups. A significant difference in the distribution of heteromorphisms was found among the different racial groups. The Orientals had a larger C-band on chromosome 1 and a smaller C-band on chromosome 9 than the other racial groups while the Caucasians had a larger C-band on chromosome 9. The Oriental group also had a significantly greater proportion of inverted C-band. No differences were found in the distribution of C-band heteromorphisms among different etiologic categories of mental retardation.     

Anatomy of human genome by restriction endonucleases Alul, Ddel, Haelll, Hinfl, Mobol and Rsal, and their application in clinical cytogenetics

The application of restriction endonucleases Alul, Ddel, Haelll, Hinfl, Mbol and Rsal in clinical cytogenetics is described. The extensive inherent heterogeneity of heterochromatin in the C-band regions revealed by these enzymes provides a valuable tool for describing the origin of trisomies and abnormal chromosomes in humans. The heteromorphic markers identified by these enzymes have tremendous potential in clinical cytogenetics. Unlike the CBG technique, slides can be stained immediately after preparation providing a rapid diagnosis. Characteristic bands induced by each enzyme in the human complement are discussed in detail. Comparative analysis of the present data, with those described earlier, revealed certain discrepancies including chromosomes 19 and 20 by Alul, chromosomes 4, 5, 8 and 22 by Mbol and chromosomes 12 and 20 by Rasl. These controversies are examined in the light of heteromorphisms, technical variables and chromosome identification.     

Human chromosomal heteromorphisms in Delhi newborns. II. Analysis of C-band size heteromorphisms in chromosomes 1, 9 and 16

Quantitative analysis of C-band size heteromorphisms in chromosomes 1,9 and 16 was carried out in 200 Delhi newborns (100 males and 100 females). The percent size heteromorphisms for chromosomes 1,9 and 16 showed nonsignificant differences between the sexes. Homozygous size level combinations showed higher incidence than the heterozygous combinations for all the three chromosome pairs studied in both sexes. Our results are compared with other reported studies and the possible role of these heteromorphisms in ethnic/racial variation and in developmental disturbances is discussed.     

Intensity heteromorphisms of human chromosome 15p by DA/DAPI technique

Summary We suggest that the short arms of human chromosome 15 (15p) exhibit intensity heteromorphisms by DA/DAPI technique. A method for classification of variable intensities is proposed. The different intensities can be classified into at least five classes. They are: negative, pale, medium, intense, and brilliant. Therefore we suggest that 15p is not always positive by DA/DAPI technique. The present findings reveal that the heteromorphism on 15p is far greater than previously thought.     

Evidence for a highly differentiated sex chromosome heteromorphism in the salamander Necturus maculosus (Rafinesque)

The mitotic chromosomes of the neotenic (sensu Gould, 1977, and Alberch et al., 1979) salamander Necturus maculosus (Rafinesque) have been examined using a C-band technique to demonstrate the distribution of heterochromatin. The C-banded mitotic chromosomes provide evidence of a highly differentiated XY male/XX female sex chromosome heteromorphism, in which the X and Y chromosomes differ greatly in size and morphology, and in the amount and distribution of C-band heterochromatin. The X chromosome represents one of the largest biarmed chromosomes in the karyotype and is indistinguishable from similar sized autosomes on the basis of C-band heterochromatin. The Y chromosome, on the other hand, is diminutive, morphologically distinct from all other chromosomes of the karyotype, and is composed almost entirely of C-band heterochromatin. The discovery of an X/Y chromosome heteromorphism in this species is consistent with the observation by King (1912) of a heteromorphic spermatogenic bivalent. Karyological and phylogenetic implications are discussed.     

A high-resolution C-banding technique

A high-resolution C-banding technique is described. The major advantages of this method are its simplicity and reliability. Because this technique allows the recognition of unusual C-band heteromorphisms, it can be very useful in population cytogenetic studies.     

C-bands and chiasma distribution inScilla amoena,S. ingridae,andS. mischtschenkoana (Hyacinthaceae)

An effect of C-band pattern and polymorphism on chiasma distribution in pollen meiosis was recently demonstrated inScilla siberica. A further meiotic banding study has been performed in the alliesS. amoena, S. ingridae, andS. mischtschenkoana in order to analyze the effect, if any, of their specific C-band patterns and cytochemically different heterochromatin types on recombination. No clear evidence for a preferential formation of chiasmata adjacent to homozygous intercalary heterochromatin and no consistent reduction of chiasma frequency near strongly heterozygous intercalary heterochromatin blocks, as observed inS. siberica, could be found. Terminal C-band heteromorphism is suspected to cause distal chiasma defaults. The results suggest once more that there is no uniform effect of heterochromatin on crossover distribution.     

Variability of C-banding patterns in Japanese quail chromosomes.

Observations were made of the C-banding patterns in several cells from 182 Japanese quail embryos to detect presence of stable variants. Each of the eight largest autosomes contains a C-band at the centromeric region. The short arm of autosome 8 is C-band positive, as is the entire W chromosome. The Z chromosome consistently contains an interstitial C-band in the long arm and a less prominent one in the short arm. Distinct variants of chromosome 4 and the Z chromosome were observed. In the Z chromosome a C-band at the terminal region of the short arm was markedly elongated in some embryos. Likewise, the short arm of chromosome 4 was much more prominent in one or both of the homologues in some embryos. Most of the microchromosomes contain a prominent C-band. The heteromorphisms are useful chromosome markers to detect the origins of heteroploidy in early embryos.     

Quantitative analysis of C bands in chromosomes 1, 9, and 16 of Brazilian Indians and Caucasoids

Summary Densitometric C-band measurements in chromosomes 1, 9, and 16 of 394 Indians and 40 Caucasoids living in Brazil are reported. No significant intratribal variability in the average length of these regions was observed, and the intertribal variation showed no consistent patterns. But the Caucasoids always presented lower means. The relative C-band sizes of these three chromosomes, however, were very similar in Indians and Caucasoids. The indices of heteromorphism displayed analogous results; only in chromosome 16 are they dissimilar in these two ethnic groups. An unexpected sex difference was observed in the C-band sizes of this chromosome, females uniformly presenting higher averages than males. Centromeric heterochromatin appeared in 6% and 9% respectively of the short arms of chromosomes 1 and 9 among the Caucasoids, while among the Indians its prevalence was 2% in both chromosomes.     

Chromosome heteromorphisms in the gorilla karyotype. Analyses with distamycin A/DAPI, quinacrine and 5-azacytidine

The chromosomes of one male and three female gorillas were extensively studied with various regional banding methods. The chromosomes were stained with the fluorescent dyes quinacrine mustard and distamycin A/DAPI (DA/DAPI), which label different subsets of heterochromatin in the chromosome complement. Furthermore, lymphocyte cultures were treated with the cytidine analog 5-azacytidine (5-azaC). The 5-azaC-induced undercondensations were found in most of the DA/DAPI-bands as well as in many telomeric C-bands. The karyotype of the gorilla exhibits a considerable number of heterochromatin variants. Of the different types of heteromorphisms noted, the most striking is that involving the short arm regions of chromosomes 12 to 16 and 23 (satellite stalk regions) and the paracentromeric heterochromatin of chromosomes 17 and 18. There also are numerous heteromorphic C-bands localized in the telomeric regions of homologous chromosome arms. In comparison, only few heteromorphisms occur between C-bands in the centromeric and pericentromeric regions of homologs. Finally, a variability in the fluorescence intensity of quinacrine-bright satellites in the short arms of chromosomes 12 to 16, 22, and 23 is observed.     

Cytogenetic studies using Q-band polymorphisms in patients with AML receiving marrow from like-sex donors

Summary After bone marrow transplantation (BMT), it is important to monitor the bone marrow and lymphoid cell populations of the recipient to document engraftment. When donor and recipient are of unlike sex, the sex chromosomes serve as a useful marker to determine cellular origin. When donor and recipient are of like sex, autosomal heteromorphisms can be used to identify the origin of cells in metaphase. Using Q-banding, we found that 17 of 20 patient/donor pairs (85%) examined showed at least one chromosome heteromorphism that distinguished between recipient and donor cells with certainty. Five of the patients were followed up after BMT in order to document engraftment. Donor metaphases could be detected in the marrow within two weeks of BMT when the graft was successful. Chimaerism was detected in the lymphocyte population even when the graft persisted. In a case of graft failure, donor cells did not persist in the marrow, and the lymphocyte population did not convert to donor type. These studies demonstrate that autosomal heteromorphisms are useful in the study of myeloid and lymphoid chimaeric states after BMT.     

白鱀豚的核型及其C－带核型的研究

采用常规的白细胞培养技术及ＢＳＧＣ－带技术分析了白豚的核型、Ｃ－带核型。结果是：白豚的染色体数目２ｎ＝４４,其核型由１２条中部着丝点染色体、１８条亚中部着丝点染色体、４条亚端部着丝点染色体、８条端部着丝点染色体和２条性染色体所组成。染色体臂数（ＮＦ）雌性为７６,雄性为７５。Ｃ－带异染色质呈现出很深的着色区,主要分布在染色体臂上,着丝点区则几乎没有。Ｃ－带异染色质的量约为总染色质量的１２％。这一结果表明白豚与海生豚类的核型、Ｃ－带核型有较明显的相似性。     

Human chromosomal heteromorphisms in american blacks

Summary One hundred normal American Blacks (B) were studied by sequential QFQ and RFA banding techniques in order to estimate the type and frequency of heteromorphisms. Color heteromorphisms were classified into one of six colors by RFA and intensity variation into one of five levels by QFQ. The data are compared with a previously studied Caucasian population (C). The frequencies of QFQ and RFA heteromorphisms were significantly higher in the Black than in the Caucasian population. No racial difference was noted for chromosome 21 by QFQ, while RFA demonstrated a clear difference. It is concluded that the maximum characterization of racial differences of human chromosomal heteromorphisms was far greater by RFA than with QFQ. The present study suggests differences in QFQ and RFA heteromorphisms among the two races.     

Satellite III DNA: Regions of extreme endonuclease resistance and interindividual polymorphism in the Mb size range

Southern analysis of within-gel digested and restricted human cells has revealed very large Satellite III restriction fragments which show clear inter-individual length polymorphism. The Mb and sub-Mb length of these fragments indicate that they arise from regions of heterochromatin which contain homogeneous Satellite III sequences of peculiar resistance to common endonucleases. Based on sequence alone, such regions would be little digested by endonuclease digestion of chromatin in metaphase, regardless of its method of preparation. Polymorphic regions such as these might be expected to stain as part of the C-banding seen in endonuclease treated metaphase chromosomes, and may in part account for inter-individual C-band heteromorphisms.     

Molecular cytogenetic evidence for amplification of chromosome-specific alphoid sequences at enlarged C-bands on chromosome 6.

We have characterized variant centromeric regions of chromosome 6 segregating in two families. The heteromorphism, 6ph+, stains negatively with G- and Q-banding and darkly with C-banding. The variant C-band regions measure two to three times the length of their homologues. The centromeric regions of the variant chromosome 6 and its homologue are not significantly elongated by adding 5-azacytidine to culture. We determined that the amount of the alphoid centromeric repeat 308 (DZ61), which is chromosome 6 specific, is amplified two- to threefold in the genomes of individuals with the 6ph+ variants. In situ hybridization localized the increase in 308 repeats to the 6ph+ region. These results suggest an association between amplification of chromosome-specific alphoid sequences and enlargement of specific C-band regions.     

Sex chromosome-autosome translocations in the leaf-nosed bats, family Phyllostomidae. I. Mitotic analyses of the subfamilies Stenodermatinae and Phyllostominae

Mitotic analyses using RBA- and C-banding were performed on Stenodermatine bats with X-autosome (XY1Y2) and X- and Y- autosome (neo-XY) translocations. RBA-banded metaphases of females revealed differential replication of the inactive X chromosome. An early replicating band comprises the short arm of the X, and an intermediate replicating band is located interstitially on the long arm. The early replicating short arm has a homologous counterpart either in the form of a free autosome (the Y2) or as part of the Y. Both the "autosomal" short arm of the X and its homologue fused to the Y are C-band negative and behave autonomously from the remainder of the sex chromosomes. They are separated from X and Y chromatin by centromeric heterochromatin which presumably acts as a barrier. The intermediate replicating region of the long arm of the X is also present in the subfamily Phyllostominae. In both subfamilies this region lacks a homologous counterpart. However, it may also represent a translocated autosome which, unlike the short arm of the X, is not separated from the inactive X by centromeric heterochromatin. Its intermediate replication time may represent a retarded replication due to its juxtaposition to late replicating X chromatin. These data are discussed in light of the theory of the evolution of sex chromosome heteromorphism, specifically as it applies to mammals.     

Characterization of a rare short arm heteromorphism of chromosome 22 in a girl with down-syndrome like facies

Chromosomal heteromorphisms are described as interindividual variation of chromosomes without phenotypic consequence. Chromosomal polymorphisms detected include most regions of heterochromatin of chromosomes 1, 9, 16 and Y and the short arms of all acrocentric chromosomes. Here, we report a girl with Down-syndrome such as facies and tremendously enlarged short arm of a chromosome 22. Fluorescence in situ hybridization (FISH) with a probe specific for all acrocentric short arms revealed that the enlargement p arms of the chromosome 22 in question contained exclusively heterochromatic material derived from an acrocentric short arm. Parental studies identified a maternal origin of this heteromorphism. Cryptic trisomy 21 of the Down-syndrome critical region was excluded by a corresponding FISH-probe. Here, we report, to the best of our knowledge, largest ever seen chromosome 22 short arm, being ~×1.5 larger than the normal long arm.