Constitutive heterochromatin distribution in monocentric and polycentric chromosomes

Monocentric chromosomes of Vicia faba (2n=12) and polycentric chromosomes of Luzula purpurea (2n=6) and L. multiflora (2n=36) were studied by the C-banding technique. C-positive regions exhibited a restricted distribution in V. faba nuclei and were located near the centromeres of the chromosomes. Each chromosome had both a characteristic number and distribution of C-positive regions permitting homologue identification. L. purpurea and L. multiflora C-bands were much more numerous than those of V. faba and were widely distributed throughout both nuclei and chromosomes. Three distinct constitutive heterochromatin distribution patterns were present in L. purpurea metaphase chromosomes permitting homologous chromosome identification. One of three C-band distribution patterns was also evident in L. multiflora chromosomes.     

Polymorphic patterns of heterochromatin distribution in guinea pig chromosomes

The chromosome complement and patterns of heterochromatin distribution (as demonstrated by the DNA d-r method) were studied from three different guinea pigs. Karyotype analyses showed that one of the females had a heteromorphic sex pair formed by a submetacentric X chromosome and a subterminal X chromosome originated by a shortening of the short arm (x-chromosome). The heterochromatin was mainly found in the pericentromeric areas of the autosomes and X chromosomes and in the short arm of pair 7. The Y chromosome exhibited a degree of heterochromatinization different from that of pericentromeric areas.—The analysis of the heterochromatin distribution in the X chromosomes showed that the smaller size of the heteromorphic x-chromosoine was probably due to a lack of heterochromatin in its short arm. Moreover, two out of the three animals studied had a heteromorphic pattern of heterochromatinization in the pair 21 characterized by heterochromatinization of the pericentromeric area in one chromosome and almost complete heterochromatinization of the other homologue.—It is suggested that most of the heterochromatin disclosed by the DNA d-r method is formed by repetitious DNA; and that the Y chromosome and perhaps some autosome regions in guinea pigs are formed by a type of heterochromatin with properties different from those of the constitutive and facultative heterochromatin (intermediate heterochromatin).Supported in part by NIH Grant 5-501-RR05672-02 and by NIH contract 70-2299.     

Parental origin of chromosomes in Down's syndrome

Summary The number of 21 chromosomes of 15 individuals with Down's syndrome and their parents were examined in an attempt to determine the parental origin of the extra number 21 chromosome and the stage of meiosis at which nondisjunction occurred. Chromosomes were stained with quinacrine hydrochloride and photographed; serial prints were made ranging from underexposed to overexposed. Twelve of the 15 families (80%) were informative: nondisjunction occurred in maternal meiosis I in eight (66.7%) families, in paternal meiosis I in two (16.7%) families, and in paternal meiosis II in two (16.7%) families. The production of serial exposures of chromosomes at the time of printing proved to be a valuable method of enhancing slight differences in short arm and satellite structure of the number 21 chromosomes and thereby increasing the number of informative families.     

Constitutive heterochromatin polymorphisms in human chromosomes identified by whole comparative genomic hybridization

Whole comparative genomic hybridization (W-CGH) is a new technique that reveals cryptic differences in highly repetitive DNA sequences, when different genomes are compared using metaphase or interphase chromosomes. W-CGH provides a quick approach to identify differential expansion of these DNA sequences at the single-chromosome level in the whole genome. In this study, we have determined the frequency of constitutive chromatin polymorphisms in the centromeric regions of human chromosomes using a whole-genome in situ cross-hybridization method to compare the whole genome of five different unrelated individuals. Results showed that the pericentromeric constitutive heterochromatin of chromosome 6 exhibited a high incidence of polymorphisms in repetitive DNA families located in pericentromeric regions. The constitutive heterochromatin of chromosomes 5 and 9 was also identified as highly polymorphic. Although further studies are necessary to corroborate and assess the overall incidence of these polymorphisms in human populations, the use of W-CGH could be pertinent and of clinical relevance to assess rapidly, from a chromosomal viewpoint, genome similarities and differences in closely related genomes such as those of relatives, or in more specific situations such as bone marrow transplantation where chimerism is produced in the recipient.     

Radiosensitivity of chromosomes in lymphocytes from Down's syndrome patients

A study was made of the yield of chromosome aberrations in gamma-irradiated G0 peripheral blood lymphocytes from 6 patients with different forms of Down's syndrome. The doses used were from 0.25 to 3.0 Gy. Seven healthy donors of different age made the control group. There was a significant increase in the yield of chromosome exchanges in lymphocytes from all the patients as compared to control. The spontaneous level of chromosome aberrations and the frequency of radiation-induced fragments did not differ from the control values. The yield of exchanges in diploid and trisomic cells from patients with the mosaic form of Down's syndrome did not change significantly as the time of cultivation was raised. The origin of DNA repair defects leading to the increased chromosome radiosensitivity in Down's syndrome is discussed.     

Meiotic chromosomes in a female with primary trisomic Down's syndrome

Summary We report the first analysis of chromosomes at the first meiotic metaphase in a non-mosaic female with primary 21-trisomic Down's syndrome. A 21-univalent and a high chiasma number were found. These findings are discussed in comparison with the observations on normal subjects and on meiosis in Down's syndrome males.     

Fluorescent heterochromatin staining in primate chromosomes

Recently, in addition to quinacrine staining, fluorochrome techniques have been developed which brilliantly stain other heterochromatic regions. Two of these staining techniques are Distamycin/DAPI (DA/DAPI) and D287/170. We stained the chromosomes of all species of great apes and 14 species of primates (48 individuals) using these three fluorochrome techniques. Only african apes and man show brilliant quinacrine staining while, man and all the great apes show brilliant DA/DAPI staining and only species belonging to the hominoidea (including the siamang) showed bright D287/170 staining. In the lower primates a medium level of DA/DAPI fluorescence was found in some species with large amount of pericentromeric heterochromatin. Brilliant DA/DAPI staining could represent a derived trait linking all great apes and humans, while D287/170 may link all hominoidea. Fluorochrome staining is believed to be correlated with some satellite DNA sequences. However, data available on the chromosome location of satellite DNAs in non-human primates were derived from buoyant density fractions resulting in cross hybridization and now are not considered reliable. Before making any correlation between fluorochrome staining and satellite DNAs in non human primates there is need of data onin situ hybridization with cloned DNA sequences on primate chromosomes. These data would help clarify the evolution and relationship of satellite DNAs and heterochromatin in primates.     

Distribution of constitutive heterochromatin in mammalian chromosomes

Using a special staining technique, a survey of the chromosomes of many mammalian species showed that constitutive heterochromatin is present in all cases and that the heterochromatin pattern appears to be specific and consistent or each chromosome and each taxon. Usually heavy heterochromatin is found in the centromeric areas, but terminal heterochromatin is not uncommon. Occasionally interstitial heterochromatin bands occur. In some species, such as the Syrian hamster and Peromyscus, many chromosome arms are completely heterochromatic.Supported in part by Research Grant GB-13661 from the National Science Foundation.     

Constitutive heterochromatin and transposable elements in Drosophila melanogaster

Several families of transposable elements (TEs), most of them belonging to the retrotransposon catagory, are particularly enriched in Drosophila melanogaster constitutive heterochromatin. The enrichment of TE-homologous sequences into heterochromatin is not a peculiar feature of the Drosophila genome, but appears to be widespread among higher eukaryotes. The constitutive heterochromatin of D. melanogaster contains several genetically active domains; this raises the possibility that TE-homologous sequences inserted into functional heterochromatin compartments may be expressed. In this review, I present available data on the genetic and molecular organization of D. melanogaster constitutive heterochromatin and its relationship with transposable elements. The implications of these findings on the possible impact of heterochromatic TEs on the function and evolution of the host genome are also discussed. This revised version was published online in August 2006 with corrections to the Cover Date.