The relationship between repetitive DNA and chromosomal bands in man

Physical fine mapping of the choroideremia locus using Xq21 deletions associated with complex syndromes

Characterization of several male-viable deletions and duplications with 20 random DNA probes has enabled us to subdivide the Xq21 region into seven discernible intervals. Almost all of the deletions spanning part of Xq21 are associated with choroideremia and mental retardation, with deafness being another common feature. The gene locus for choroideremia was assigned to interval 3 spanning the loci DXS95, DXS165, and DXS233. Genes for X-linked deafness and mental retardation were tentatively assigned to interval 2. Deletions of intervals 4 through 7 were not associated with any clinical abnormality. We have constructed a preliminary long-range restriction map of intervals 2 and 3 using field-inversion gel electrophoresis. The DXS232, DXS121, and DXS233 loci are located on the same SfiI fragment, whereas the DXS165 and DXS95 loci could not be linked to this cluster using SfiI and SalI.

Analysis of spreading of inactivation in eight X autosome translocations utilizing the high resolution RBG technique

Eight X autosome translocations were studied with replication banding to localize spreading of late replication into the autosomal segments. Partial spreading into the autosomal segment was seen in four translocations and no spreading of late replication was seen in four translocations. In those translocations with partial spreading of late replication into the autosomal segment, late replication did not always spread continuously from the X chromosome breakpoint throughout the autosome. Instead, it appeared to skip some bands and affect others. The data on the pattern of replication, taken to indicate also a spread of inactivation into these autosomal segments, correlated well with the clinical data in most cases and suggest that spreading of late replication is often incomplete and may be discontinuous.

Z-DNA immunoreactivity in fixed metaphase chromosomes of primates

Antibodies against Z-DNA bind to fixed metaphase chromosomes of man and Cebus albifrons (Platyrrhini, Primate). By indirect immunofluorescence and indirect immunoperoxidase techniques, a heavy staining is detected in some segments of chromosomes of C. albifrons. These segments correspond to R-band-positive heterochromatin, which has a high G + C-base content. Euchromatin of human and Cebus chromosomes show a weak and heterogeneous staining that consistently reproduces an R- and T-banding pattern in both species. Because chromosome homologies previously were demonstrated between these distantly related species by chromosome banding, our results suggest that Z-DNA has been conserved during the course of primate evolution.

Characterization of Giemsa dark- and light-band DNA

Using synchronized cultures of V79-8 Chinese hamster lung fibroblasts, we either alternately labeled early- and late-replicating DNA, or substituted one of these with bromodeoxyuridine to separate them in CsCl density gradients or to identify the bromodeoxyuridine-containing chromosome bands by fluorescence microscopy. The Giemsa light R bands were shown to replicate in the first half of S phase, and the dark G bands were shown to replicate in the last half of S phase. S phase was bimodal, with a distinct pause in the rate of DNA synthesis that separated the period of R-band DNA synthesis from that of G-band DNA synthesis. G-band DNA was found to be 3.2% richer in AT than R-band DNA. Surprisingly, G- and R-band DNA appeared equally transcriptionally active in that alternate labels in chromatin were digested with the same kinetics by DNAase I, and in reassociation experiments, total poly(A)+ RNA drove nick-translated G- and R-band DNA probes similarly. G- and R-band DNA also reassociated with identical kinetics, demonstrating that they contain equal proportions of all kinetic-complexity classes of sequences.

Non-random distribution of aberrations and identification with C- and G-bandings of the position of breakage points on Muntjac chromosomes induced by mitomycin c, bromodeoxyuridine and hydroxylamine

The analysis of chromosomes from muntjac after treatment of its lymphocyte cultures with 3 chemical mutagens having different base-pair affinities and modes of action, namely mitomycin C (MC), 5-bromodeoxyuridine (BUdR) and hydroxylamine hydrochloride (HA), with G- and C-band staining displayed non-random distribution of chemically specific damage points on them. The randomness of the involvement of each site on the chromosomes were examined by assuming an expected value calculated on the basis of its relative mitotic length. The observation revealed that a large fraction of MC-induced aberrations was preferentially located in the C-band positive constitutive heterochromatin, especially in the long "neck-like" centromeric region of the X-chromosome. On the chromosomal arms, the light G-bands were involved in aberrations either in proportion to or higher than that expected. When the cells were treated with BUdR, the dark G-bands on all the chromosomes of the complement were the preferred sites, displaying statistically significant higher numbers of aberrations. A single "hot-spot" for induced damage on 1 mid-q was also recorded. HA induced a very high frequency of damage in the secondary constriction regions of the chromosome pairs 1, X and Y2, and the frequency was slightly lower than this in the centromeres of 1, 2 and X chromosomes. The observation of specific distribution of damage points induced by the 3 chemicals lead to the suggestion that, though the effect of a chemical on chromosome segments depends on several factors, each being partially responsible for the end result, it is perhaps primarily depended by the chemical's base-pair affinity and mode of action.

Comparative studies in two cases of testicular feminization syndrome, one with and the other without the fluorescent distal band q12 of the Y

In two patients with testicular feminization syndrome, one Yq12-positive and the other Yq12-negative, we compared phenotype, gonadal histology and ultrastructure, in vivo steroid response of the testes to the administration of exogenous gonadotropin during adrenal suppression, and of the adrenal gland to ACTH. The assumption that the constitutive Y heterochromatin could function as a regulator of steroid biosynthesis and metabolism, with or without effect at other levels, was not firmly supported by the observations reported here. However, further studies along this line may help elucidate the biologic role of this portion of the Y chromosome in humans.

Localization of sequences specifying messenger RNA to light-staining G-bands of human chromosomes

Total cytoplasmic polyadenylated RNA was isolated from the human lymphocyte cell line Wil2 by oligo(dT)-cellulose chromatography. Tritiated complementary DNA (cDNA) was transcribed from the RNA and used as a probe for in situ hybridization to metaphase chromosomes. The majority of G-negative or lightly staining bands were found to be preferential sites of hybridization.

Chromosomal localizations by in situ hybridization of the repetitious human DNA families and evidence of their satellite DNA equivalents

Four of the five major repetitious human DNA families have been mapped by the in situ hybridization technique at their TOPT values. Two of the lighter density DNA families have autoradiographic grain patterns over heterochromatic chromosomal regions that resemble those of known satellite DNAs. The two heaviest density DNA families have autoradiographic grain patterns of middle repetitious DNAs, with all chromosomes showing labelling. Some evidence suggests that one of these DNA families is concentrated in certain chromosomal regions. Both DNA families exhibit biphasic TOPT curves. The presence of two thermal stability classes of hybrids suggests sequence interspersion. By co-enrichment studies in Ag+-CS2SO4 gradients, evidence suggests the origin of the three lightest density renaturated human DNA families to be satellites I, II and III.

Reverse fluorescent chromosome banding with chromomycin and DAPI

Two DNA binding guanine-specific antibiotics, chromomycin A3 (CMA) and the closely related mithramycin (MM), were used as chromosome fluorescent dyes. Root-tip metaphase chromosomes of three plant species and human metaphase chromosomes were sequentially stained with CMA or MM and the DNA binding AT-specific fluorochrome 4'-6-diamidino-2-phenylindole (DAPI). In some cases a non-fluorescent counterstain was used as contrasting agent: methyl green in conjunction with CMA, and actinomycin D (AMD) in combination with DAPI.--In all three plant species, Vicia faba, Scilla siberica, and Ornithogalum caudatum, the nucleolus organiser regions and/or associated heterochromatin displayed very bright fluorescence with CMA and MM and, in general, heterochromatic segments (C-bands) which were bright with CMA and MM were pale with DAPI whereas segments which were dim with CMA and MM displayed very bright fluorescence with DAPI.--Human metaphase chromosomes showed a small longitudinal differentiation in CMA fluorescence, which was essentially the reverse of the banding pattern obtained with AMD/DAPI double-staining, but of lower contrast. The cma-banding pattern appears to be similar to the pattern found by R-banding procedures.

A reexamination of the diploidlike meiotic behavior of polyploid cotton

Chromosome associations at pachytene, diakinesis, and metaphase I were analyzed in haploids of the allotetraploid G.hirsutwn, in the F1 hybrid between G.arboreum (A2) and G. raimondii (D5), and in the doubled hybrid 2(A2D2) in an effort to define more clearly the mechanism responsible for the diploidlike behavior of the natural allotetraploids. The mean number of bivalents per cell at pachytene, diakinesis, and MI were respectively 10.00, 7.40, and 0.80 for the haploids and 11.00, 9.50, and 5.82 for the A2D5 hybrid. The two pachytene means were not significantly different, but the two diakinesis means and the two MI means were significantly different.At early pachytene members of paired chromosomes were not equal in length, but at late pachytene both members were equal in length in most bivalents. It was particularly evident in the unpaired regions that one partner was much thicker or more deeply stained than its counterpart. Since A chromosomes are twice the size, have twice the amount of DNA, and contain greater amounts of repetitive DNA than D chromosomes, it was concluded that the bivalents consisted of A and D homoeologs. In order for the paired homoeologs to attain equality in length at late pachytene, it is presumed that the A chromosomes either started contracting before the D chromosomes or contracted at a faster rate. During the stages following late pachytene, the D chromosomes contracted at a faster rate than the A chromosomes resulting finally in a two-fold difference in the size of the A and D chromosomes at MI. It is assumed that this differential rate of contraction would limit intimate pairing attraction and chiasma formation between homoeologous chromosomes.We concluded that a gene control system analogous to that wheat and oats does not determine the diploidlike meiotic behavior of the natural allotetraploids of Gossypium. This is based on the high frequency of homoelogous pairs at pachytene in the haploids, on the strict homologous pairing in the synthetic 2(A2D5) hybrid, and on the roles repetitive DNA is assumed to have in regulating synapsis and chiasma formation and in structurally differentiating the A and D homoeologs.It was proposed that differences in genome chromosome size may determine whether a gene or non-gene control mechanism is required for regulating homologous pairing in allotetraploids.

The organization of repeated DNA sequences in the human genome

The arrangement of repetitive and non-repetitive DNA sequences was studied in the human genome. By Ag+-Cs2SO4 density gradient centrifugations of human DNA at different fragment size reannealed to different Cot values and c-RNA hybridization experiments, we have shown the presence of two repetitive DNA fractions, called fast and slow intermediate DNA, with different pattern of sequence organization. The fast intermediate DNA sequences (6% of the genome; CsCl density in renatured form: 1.703 g/ml) are in part clustered in fragments greater than 24,000 nucleotide pairs and in part in fragments ranging from 1,800 to 600 nucleotide pairs spaced with longer more complex sequences. The slow intermediate DNA sequences (30% of the genome; CsCl density in renatured form: 1.707 g/ml) appear to be finely interspersed with non-repetitive sequences. At a DNA fragment size of 600 nucleotide pairs only a third of the slow intermediate DNA sequences are free of unique sequences, while the other two thirds are still organized with unique sequences. It has also been shown that a great amount of the repetitive DNA sequence transcripts in heterogeneous nuclear RNA of HeLa cells are complementary to slow intermediate DNA sequences.

Chromosomes and DNA of Mus: terminal DNA synthetic sequences in three species

The DNA replication patterns of the terminal S phase of three species of Mus were analyzed by tritiated thymidine autoradiography. The centromeric heterochromatin of M. fulvidiventris is the latest component to finish DNA synthesis. The Y chromosome finishes replication earlier than the centromeric heterochromatin. The centromeric heterochromatin of M. musculus, on the other hand, is not the latest component to finish DNA synthesis. At the very late S phase, grains are found in the euchromatic arms instead of the heterochromatic areas. The "hot X" and the "hot Y" can be identified in the majority of, but not all, cases. The heterochromatic short arms of the autosomes in M. dunni finish DNA replication earlier than many areas in the euchromatic long arms and the heterochromatin of the sex chromosomes. This indicates that in M. dunni there are at least two types of heterochromatin. The late-replicating zones in the euchromatic long arms are distinctly banded. This banded grain pattern can be seen in all Mus species observed, but in M. dunni it is most exaggerated. Late-replicating chromosome segments can be demonstrated also by 2+ cycles of BUdR incorporation and Giemsa staining.

The G-banded prophase chromosomes of man

Using a simple G-banding technique developed in our laboratory, analysis of late prophases enables the visualization of approximately 1000 bands in the haploid set of human chromosomes. These bands have been classified according to the recommendations of the Paris Conference. The increased resolution offered by this technique is likely to be useful in the study of the structure and molecular organization of chromosomes and in identifying minute chromosome defects in birth defects and neoplasia.