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.     

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.     

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.     

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 3, 4, 13–15, 21–22, and Y were studied in a population of 374 mentally retarded patients from diverse ethnic groups. A significant variation in the size of the Y chromosome was found among different racial groups, those of the Orientals and Filipinos being larger than those of the Caucasians or Polynesians. No other significant variation was found among the different racial groups, although suggestive differences were seen in bands 3 cen, 13p3, and 14p3. Band 13 cen/pl was significantly larger in the category of socio-familial retardation than in the other two categories. However, as the significance was at the 0.05% level and as this was the only heteromorphism whose distribution was different among the three categories of mental retardation, we assign little importance to this observation.     

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.     

Aspects of evaluation,significance, and evolution of human C-band heteromorphism

Summary The C-band heteromorphism may be evaluated in different forms. The results obtained from classification are easily influenced by subjective factors, and the conclusions of such types of data are acceptable only if they are well matched with a control. The length measurements is simple to obtain, and a quantitative presentation of the data, with correction for the contraction stage of the chromosomes, is considered the most effecient method to evaluate the C-band size heteromorphism. Excluding the acrocentrics, whose short arms present a complex heteromorphism, and the chromosome Y, whose variable C band is terminal, all others present C-band location heteromorphism except pair 16. It is possible to multiply the detectable heteromorphisms in some bands by using diverse staining methods. The present state of knowledge about the role of heterochromatin in the cell is analyzed, as is the effect of C-band variability on the phenotype, the reproductive fitness, and the individual viability. Although a great amount of data is available, no result can be considered definitive as yet. Aspects in which the use of C-band heteromorphisms are profitable are considered.     

Co-occurrences of polymorphic heterochromatin regions of chromosomes and effect on reproductive failure

Although the polymorphic heterochromatin regions of chromosomes (heteromorphisms) have been extensively studied for their phenotypic effects on humans, co-occurrences of chromosome 1, 9, 16 and Y heteromorphisms and of acrocentric variants have never been studied on humans with an objective scoring system. Here we compared the frequencies of individual heteromorphisms on a total of 602, 768 and 224 patients with the indications of infertility, recurrent miscarriage and in vitro fertilization (IVF) failure, respectively and on 272 controls. Then we examined whether there were significant co-occurrences between heteromorphisms within and between the groups. There were no statistically significant differences in the frequencies of heteromorphisms between the groups. Both statistically significant and non-significant correlations were observed within the non-acrocentric and certain acrocentric heteromorphisms in each group. When these co-occurrences were examined between the groups, a 2.2 fold increased risk of IVF failure in males in the presence of either chromosome 13 or chromosome 21 variants was observed (95 %CI:1.1–4.2). We conclude that the simultaneous manifestations of heteromorphisms have no effect on reproductive failure. There seems to be a correlation between the non-acrocentric heteromorphisms (1qh+, 9qh+, 16qh + and Yqh+/-), which might be the result of complex interactions of formation of these heterochromatin regions. The correlations observed between certain acrocentric chromosomes might be related to satellite association and nucleolus formation. The increased risk observed in males with IVF failure in the presence of either chromosome 13 or 21 variants should be interpreted cautiously due to the heterogeneity of the group.     

Y-chromosome length heteromorphisms in Delhi infants

One hundred and seventy normal male infants from Delhi were studied using the CBG technique to estimate Y-chromosome length heteromorphisms. The median class in Y/F [Y/F = total length of the Y chromosome/average total length of the F group chromosomes (19 and 20)] distribution was 0.75-0.79. The Y/F index in infants varied from 0.60 to 1.16 with a mean of 0.81 and a standard deviation of 0.09. A high incidence for very small (53.5 percent) and small (41.2 percent) categories of Y-chromosome length heteromorphisms was observed. Data were compared with other available reports; also possible mechanisms of the Y-chromosome length heteromorphisms and their role in ethnic/racial variation as well as in developmental disturbances are discussed. It is suggested there may be a need to redefine the long and short Y chromosome in a given population while studying different clinical disorders.     

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.     

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.     

鼷鹿云南亚种（Tragulus javanicus williamsoni）的核型分析

本文以染色体分带技术,发现鼷鹿云南亚种的染色体数目为2n=32。全部为双胃染色体,NF=64。所有染色体着丝点区分布有C带,多数染色体的端部或两端也有C带。某些染色体还有插入C带。Y染色体C带阳性,有一Ag-NORs。文章对鼷鹿云南亚种染色体独特的C带分布以及和核型进化的关系进行了讨论。     

C-band length variability and reproductive wastage

Summary The possible influence of total Y chromosome length and the C-band size variability of chromosomes 1, 9, 16, and Y, on reproductive wastage was investigated. One hundred couples with recurrent reproductive wastage and 106 control couples with at least two healthy children and no miscarriages were cytogenetically studied. Total Y chromosome length was evaluated as the Y/F index and the C-band size was analyzed quantitatively according to the linear measurement method of Baliek et al. (1977). The different degrees of mitotic contraction were corrected on the basis of the linear correlation found between heterochromatin and euchromatin length. Statistical comparison between results of Y chromosome from both samples demonstrated, in the test group, an increase in the mean value of the Y/F index, but the increase of Y C-band length did not reach significance. In addition mean values of C-band length on chromosomes 1, 9, and 16 in couples from the test group and especially those who had had two or more abortions, were lower than those in the controls. Among the latter the frequency of chromosomes included in the category of very large heterochromatin size is higher. However these length differences have been demonstrated only in specific subgroups, and in each one for a different chromosome. Our results indicated that Y chromosome length as well as C-band size variabilities are not directly related to reproductive wastage.     

Distribution of chromosomal polymorphisms in three subspecies of squirrel monkeys (genus Saimiri)

The presence of nucleolar organizer regions (NORs) and C-band polymorphisms has been examined in three subspecies of squirrel monkeys, Saimiri sciureus sciureus, S. boliviensis boliviensis, and S. boliviensis peruviensis. Pericentric inversions in chromosomes 15 and 16 were also examined in the three groups. Chromosome 15 was acrocentric in S. s. sciureus and submetacentric in S.b. boliviensis and S.b. peruviensis. Chromosome 16 was acrocentric in S.s. sciureus and S.b. boliviensis while being submetacentric in S.b. peruviensis. There was a significant difference in the distribution of the C-band polymorphisms on chromosomes 5 and 14 in the three groups, as determined by Chi-square analysis, while no difference was observed in the distribution of the NOR polymorphism on chromosome 2. The NOR polymorphism and the interstitial C-band polymorphism of chromosome 14 were found in all three groups; the C-band polymorphism of chromosome 5 was found only in S.s. sciureus. Twelve pedigreed families were examined. Pedigree analyses were consistent with codominant inheritance of each polymorphism. The results of these cytogenetic studies in squirrel monkeys are pertinent to genetic management and research protocols.     

Short rib-polydactyly syndrome,Majewski type,in two male siblings

Summary C-band polymorphisms of chromosomes 1, 9, and 16 were investigated in (1) 165 newborn infants, (2) 93 Down's syndrome patients, (3) 69 patients with acquired mental retardation, (4) 54 idiopathic patients, and (5) 48 idiopathics with multiple congenital malformations. The C-band size of chromosomes 1 and 9 showed a similar nonnormal distribution in all five groups. A significantly higher frequency of C bands, some of which were located on the short arm of chromosome 9, was observed in the groups of patients with Down's syndrome and with idiopathic mental retardation.     

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.     

C-band morphology of T(8;9)/8;9 in Blattella germanica

Summary Centromere position and each arm of the T(8;9)/8;9 quadrivalent at late pachytene can be recognized by C-banding. The chromosome 9 breakpoint lies immediately adjacent to the centromeric C-band; that of 8, in the general region of the centromere but the relationship to centromeric bands was not determined since the latter stain very faintly. Chromosome 9 differs from no. 8 in the presence of a complex series of intercalary bands, heavy centromeric bands and, overall, a larger amount of C-band material. Possible implications of these differences with respect to chromosome breakability and the nature and distribution of mutant loci are noted. Earlier identification of adjacent-1 and adjacent-2 metaphase I ring orientations, made on the basis of orientation pattern, was confirmed.     

Sister chromatid exchange points in the heterochromatin and euchromatin regions of Chinese hedgehog chromosomes

Summary The Chinese hedgehog has a diploid chromosome number of 48 in which there are eleven pairs of telo- or subtelocentric autosomes, twelve pairs of meta- or submetacentric autosomes, a metacentric X chromosome and a telocentric Y chromosome. The heterochromatin is almost completely distributed in five large distal segments of chromosomes nos. 9 to 12 and no. 18. There is no positive C-band in the centromeres of the chromosomes except for the X chromosome which has a small, weakly stained C-band in the centromere. In Chinese hedgehog cells 52.1% of SCEs are found at the junction between the euchromatin and the heterochromatin, 39.5% in the heterochromatin and 8.4% in the auchromatin. The SCE number per unit C-band is double the SCE number per unit euchromatin. The SCE rate in the heterochromatin or euchromatin regions is not proportional to their chromosome length and can be quite different between different pairs of the chromosomes. Our results indicate that there is a non-uniform distribution of the SCEs in the Chinese hedgehog cells.     

Patterns of exchange induced by mitomycin C in C-bands of human chromosomes. I. Relationship to C-band size in chromosomes 1, 9, and 16

Summary Frequencies of exchange were determined in C-bands of chromosomes 1, 9 and 16 in six normal males, and related to relative C-band area. Comparing these different chromosomes, more exchanges occurred on average in 9 than in 1 although their mean C-band sizes were similar. Chromosome 16 exchanges were fewer, both overall and relative to C-band area. Comparing the same chromosome between individuals, there was a positive correlation between relative frequency and band size in both 1-1 and 9-9 exchanges. No clear trend was observed for other exchange events.If homology is required for interchange, if cannot be dependent solely on overall C-band size. Perhaps certain DNA sequences, sensitive to mitomycin C damage, are located in part of each C-band, with less per unit area in chromosome 1 than in 9 and still less in chromosome 16.X- and U-type exchanges between chromosome 9s occurred in near equal frequencies in all individuals. If synapsis of specific, affected sequences is a pre-requisite for interchange, this observation suggests that the affected sequence in chromosome 9 is arranged in both orientations relative to the centromere.     

Minor chromosome variations and selected heteromorphisms in 200 unclassifiable mentally retarded patients and 200 normal controls

Summary Lymphocyte chromosome preparations from 200 mentally retarded children and 200 normal adult controls were analyzed by G-, Q-, and C-banding techniques for minor chromosome variations (G and Q) and selected heteromorphisms (G and C). Minor variations scored included inv(9), prominent or decreased short arms and/or satellite on acrocentric chromosomes, and 17ph. C heteromorphisms analyzed included those involving 1qh, 9qh, and 16qh regions. Length variations of Yq were scored on G-banded karyotypes. No significant differences in frequencies of scored minor variations or heteromorphisms were noted between the retarded and control populations.