Chromosomal localisation of DNA sequences in condensed and dispersed human chromatin.

The DNAs purified from condensed and dispersed human chromatin were used as templates for the in vitro synthesis of ³H-labelled complementary RNAs (cRNAs). These cRNAs were hybridised in situ to preparations of fixed human metaphase chromosomes which had previously been stained with quinacrine and photographed with fluorescent (UV) light. Autoradiographs of the hybridised chromosomes were stained and photographed and the results analysed by comparison of the fluorescence photographs with the autoradiographs. This method allowed positive identification of every chromosomal site of hybridisation and quantitative analysis of grain distribution over a number of metaphase spreads. The cRNA transcribed from condensed chromatin DNA (cRNA_C) hybridised mainly to a limited number of sites close to or including centromeric heterochromatin (C-bands) and also to the brightly fluorescent regions of the Y chromosome. Many of these C-band regions are known to contain satellite DNAs, indicating that the repeated DNA in the condensed chromatin fraction consists largely, if not entirely, of satellite sequences. The cRNA transcribed from dispersed chromatin DNA (cRNA_D) does not contain satellite DNAs and hybridised more generally over the chromosome arms. However, the main sites of hybridisation with cRNA_D included the C-bands in the Y chromosome and autosomes, i.e. those regions which bound cRNA_C. This suggests that nonsatellite repeated DNA sequences may be associated with satellite DNAs in the chromosomes. No general correlation between the distribution of either kind of cRNA and the overall level of quinacrine fluorescence in chromosomes or chromosome arms was detectable, nor could the dispersed fraction be equated with cytological euchromatin, since it hybridised in many sites which appear heterochromatic. However, there was a suggestion that some non-fluorescing Q-bands bound cRNA_D preferentially. The differences which were found between the distribution of the cRNAs from the two chromatin fractions may be associated with differences in genetic activity.     

The distribution of sequences complementary to human satellite DNAs I,II and IV in the chromosomes of chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus)

Human satellite DNAs I, II and IV were transcribed to yield radioactive complementary RNAs (cRNAs). These cRNAs were hybridised to metaphase chromosomes of man, chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus). The results of this in situ hybridisation were analysed quantitatively and compared with accepted chromosome homologies based on Giemsa banding patterns. The cRNA to satellite II (cRNAII) did not hybridise to chimpanzee chromosomes, although its hybridisation to chromosomes of gorilla and orang utan yielded more autoradiograph grains than hybridisation to human chromosomes, and cRNAIV hybridised to many chromosomes of gorilla and chimpanzee but was almost entirely restricted to the Y chromosome in orang utan. Most sites of hybridisation were located on homologous chromosomes in all four species, but there were a number of sites which showed no correspondence between satellite DNA location and chromosome banding patterns, and others where a given chromosomal location hybridised with different cRNAs in each species. These results are in contrast to those found for many transcribed DNA sequences, where the same sequence is usually located at homologous chromosome sites in different species, and appear to cast doubt on many proposed models of satellite DNA function.     

Specific arrangements of human satellite III DNA sequences in human chromosomes

DNA was extracted from various rodent-human somatic cell hybrids that contained single or a few human chromosomes. These DNAs were examined by a combination of restriction endonuclease digestion, gel electrophoresis, and filter hybridisation to radioactive satellite DNA probes following transfer of the denatured restriction fragments from a gel to a nitrocellulose filter. In this way the arrangement of sequences homologous to human satellite III were examined on human chromosomes 1, 7, 11, 15, 22 and X. It was found that the distribution of restriction endonuclease sites within satellite III DNA is different on different chromosomes.     

Distribution of gamma satellite DNA on the human X and Y chromosomes suggests that it is not required for mitotic centromere function

The bulk of the DNA found at human centromeres is composed of tandemly arranged repeats, the most abundant of which is alpha satellite. Other human centromeric repetitive families have been identified, one of the more recent being gamma satellite. To date, gamma satellite DNAs have been reported at the centromeres of human chromosomes 8 and X. Here, we show that gamma-X satellite DNA is not interspersed with the major DZX1 alpha-X block, but rather is organised as a single array of approximately 40-50 kb on the short-arm side of the alpha satellite domain. This repeat array is absent on two mitotically stable Xq isochromosomes. Furthermore, a related repeat DNA has been identified on the human Y chromosome. Fluorescence in situ hybridisation has localised this satellite DNA to the long arm side of the major DYZ3 alpha-Y domain, outside the region previously defined as that required for mitotic centromere function. Together, these data suggest that while blocks of highly related gamma satellite DNAs are present in the pericentromeric regions of both human sex chromosomes, this repeated DNA is not required for mitotic centromere function.     

A cloned repeated DNA sequence in human chromosome heteromorphisms

A sequence derived by ECoRI restriction of human satellite DNA III has been cloned in lambda gt WES. The cloned DNA was used as a template for in vitro synthesis of cRNA, which was hybridized in situ to preparations of human metaphase chromosomes with a range of heterochromatic polymorphisms. Most of the hybridization was found on chromosome 1, and the amount of hybridization was related to the size of the C-band on this chromosome. Hybridization to other chromosomes was not related to the C-band size, although hybridization of total satellite DNA is proportional to C-band size. Total satellite DNAs contain a mixture of sequences, some of which are predominantly located on only one pair of chromosomes. Hybridization in situ is able to discriminate between such chromosome-specific sequences and the bulk of satellite DNA. Further analysis of satellite DNAs may identify sequences specific for every chromosome pair.     

Satellite DNA of Anopheles stephensi liston (Diptera: Culicidae)

Four satellite DNAs in the Anopheles stephensi genome have been defined on the basis of their banding properties in Hoechst 33258-CsCl density gradients. Two of these satellites, satellites I and II, are visible on neutral CsCl density gradients as a light density peak forming approximately 15% of total cellular DNA. Hoechst-CsCl density gradient profiles of DNA extracted from polytene tissues indicates that these satellites are underreplicated in larval salivary gland cells and adult female Malpighian tubules and possibly also in ovarian nurse cells. The chromosomal location of satellite I on mitotic and polytene chromosomes has been determined by in situ hybridisation. Sequences complementary to satellite I are present in approximately equal amounts on a heterochromatic arm of the X and Y chromosomes and are also present, in smaller amounts, at the centromere of chromosome 3. A quantitative analysis of the in situ hybridisation experiments indicates that sequences complementary to satellite I at these two sites differ in their replicative behaviour during polytenisation: heterosomal satellite I sequences are under-replicated relative to chromosome 3 sequences in polytene larval salivary gland and ovarian nurse cell nuclei.     

The chromosomal localisation of human satellite DNA I

The major concentrations of human satellite DNA I (1.688 g/ml) have been localised on human chromosome preparations by the technique of in situ hybridisation using radioactive complementary RNA synthesised in vitro. Chromosomes were identified by prior study using quinacrine fluorescence microscopy. The satellite DNA is concentrated, mainly in centromeric constitutive heterochromatin, on many chromosomes but is especially obvious in the fluorescent distal segment of the Y chromosome.     

Localization of satellite DNAs in the chromosomes of the guinea pig

The in situ hybridization method has been used to investigate the localization of each of the three satellite DNAs present in the genome of the guinea pig. Purified fractions of the satellite DNAs were utilized as templates for synthesis of ³H-labeled complementary RNA (cRNA) by E. coli RNA polymerase, then each cRNA was hybridized to metaphase spreads of embryonic guinea pig cells. The cRNAs of all three satellite DNAs hybridized predominantly to the centromeric region of the chromosomes. The cRNAs of satellite DNAs II and III hybridized to all chromosomes except the Y chromosome. The cRNA of satellite DNA I did not hybridize to the Y chromosome nor to two pairs of small acrocentric chromosomes. Satellite II cRNA hybridized to the telomeric region of chromosomes 3 and 4.     

Cytofluorometry and visualisation of DNA base composition in the chromosomes of Drosophila melanogaster

The DNA base composition determined cytofluorometrically with the dyes CMA and DAPI in individual mitotic chromosomes of Drosophila melanogaster agrees very well with reference data obtained by hybridisation. Measurements in polytene chromosomes showed: (1) The base composition in the chromocenter, in chromosome 4 and bands X 1 and 3R 81 is lower than would be expected if they consisted of satellite DNAs only. (2) In the chromosome arms, bands with deviating base composition were found also where no satellite DNAs have been localized. With two visualisation methods — a photographic technique and image analysis — a complex pattern of base composition heterogeneity in the arms of the polytene chromosomes was established. In part this pattern may reflect the intercalary heterochromatin shown by weak point behaviour, ectopic pairing, and late replication.     

Characterisation of rye B chromosome DNA by DNA/DNA hybridisation

The DNAs of wheat and rye plants with rye B chromosomes have been compared with wheat, rye and oats DNAs by DNA/DNA hybridisation. The presence of DNA from B chromosomes made no significant difference to the proportion of repeated sequence DNA. The repeated sequence fractions of these cereal DNAs were quantitatively divided into eight different groups on the basis of the amount of DNA/DNA hybridisation occurring between the different DNAs. Rye A and B chromosomes contained similar proportions of three of the groups. These results, together with estimates of the thermal stabilities of all the renatured DNA duplexes suggest that rye B chromosome DNA is very similar to rye A chromosome DNA in the proportion and heterogeneity of its repeated sequences.     

Localisation of reiterated nucleotide sequences in Drosophila and mouse by in situ hybridisation of complementary RNA

The location of highly reiterated nucleotide sequences on the chromosomes has been studied by the technique of in situ hybridisation between the DNA of either Drosophila melanogaster salivary gland chromosomes or mouse chromosomes and tritium labelled complementary RNA (c-RNA) transcribed in vitro from appropriate templates with the aid of DNA dependent RNA polymerase extracted from Micrococcus lysodeikticus. The location of the hybrid material was identified by autoradiography after RNase treatment. — When Drosophila c-RNA, transcribed from whole DNA, was annealed with homologous salivary chromosomes in the presence of formamide the well defined labelling was confined to the chromocentre. With heat instead of formamide denaturation there was evidence of discontinuous labelling in various chromosome regions as well, apparently associated with banding. Xenopus ribosomal RNA showed no evidence of annealing to Drosophila chromosomes with the comparatively short exposure times used here. — When mouse satellite DNA was used as template the resulting c-RNA showed no hybridisation to Drosophila chromosomes but, when annealed with mouse chromosomes, the centromeric regions were intensely labelled. The interphase nuclei showed several distinct regions of high activity which suggested aggregation of centromeric regions of both homologous and non-homologous chromosomes. The results of annealing either c-RNA or labelled satellite DNA to homologous chromosomes were virtually indistinguishable. Incubation of Drosophila c-RNA with mouse chromosomes provided no evidence of localisation of grains. — It is inferred that both in mouse and Drosophila the centromeric regions of all chromosomes are enriched in highly reiterated sequences. This may be a general phenomenon and it might be tentatively suggested that the highly reiterated sequences play some role in promoting the close physical approximation of homologous and non-homologous chromosomes or chromosome regions to facilitate regulation of function.     

Characterization and chromosomal distribution of satellite DNA sequences of the water buffalo (Bubalus bubalis).

Satellite DNA sequences were isolated from the water buffalo (Bubalus bubalis) after digestion with two restriction endonucleases, BamHI and StuI. These satellite DNAs of the water buffalo were classified into two types by sequence analysis: one had an approximately 1,400 bp tandem repeat unit with 79% similarity to the bovine satellite I DNA; the other had an approximately 700 bp tandem repeat unit with 81% similarity to the bovine satellite II DNA. The chromosomal distribution of the satellite DNAs were examined in the river-type and the swamp-type buffaloes with direct R-banding fluorescence in situ hybridization. Both the buffalo satellite DNAs were localized to the centromeric regions of all chromosomes in the two types of buffaloes. The hybridization signals with the buffalo satellite I DNA on the acrocentric autosomes and X chromosome were much stronger than that on the biarmed autosomes and Y chromosome, which corresponded to the distribution of C-band-positive centromeric heterochromatin. This centromere-specific satellite DNA also existed in the interstitial region of the long arm of chromosome 1 of the swamp-type buffalo, which was the junction of the telomere-centromere tandem fusion that divided the karyotype in the two types of buffaloes. The intensity of the hybridization signals with buffalo satellite II DNA was almost the same over all the chromosomes, including the Y chromosome, and no additional hybridization signal was found in noncentromeric sites.     

The chromosomal location of human satellite DNA III

In situ hybridisation of radioactive complementary RNA has been used to localise the chromosomal distribution of human satellite DNA III. This DNA is found to be concentrated in paracentromeric heterochromatin mainly on chromosome 9 and in minor concentrations on chromosomes chiefly of the D and G groups.     

Behaviour of sex chromosome associated satellite DNAs in somatic and germ cells in snakes

Sex chromosome associated satellite DNAs isolated from the snakes Elaphe radiata (sat III) (Singh et al., 1976) and Bungarus fasciatus (Elapidae) (minor satellite) are evolutionarily conserved throughout the suborder Ophidia. An autosome limited satellite DNA (B. fasciatus major satellite) is not similarly conserved. Both types of satellites have been studied by in situ hybridisation in various somatic tissues and germ cells where it has been observed that the W sex chromosome remains condensed in interphase nuclei. In growing oocytes however, the W chromosome satellite rich heterochromatin decondenses completely whilst the autosomal satellite rich regions remain condensed. Later, the cycle is reversed and the W chromosome condenses whilst the autosomal satellite regions decondense. In a primitive snake (Eryx johni johni) where the sex chromosomes are not differentiated and where there is no satellite DNA specific to them, these phenomena are absent. — The differential behaviour of autosomal and sex chromosome associated satellite DNAs is discussed in the light of gene regulation.     

Origin of human chromosome 2 revisited

Similarities in chromosome banding patterns and hornologies in DNA sequence between chromosomes of the great apes and humans have suggested that human chromosome 2 originated through the fusion of two ancestral ape chromosomes. A lot of work has been directed at understanding the nature and mechanism of this fusion. The recent availability of the human chrornosome-2-specific alpha satellite DNA probe D2Z and the human chromosome-2p-specific subtelomeric DNA probe D2S445 prompted us to attempt cross-hybridization with chromosomes of the chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orangutan (Pongo pygmaeus) to search for equivalent locations in the great apes and to comment on the origin of human chromosome 2. The probes gave different results. No hybridization to the chromosome-2-specific alpha satellite DNA probe was observed on the presumed homologous great ape chromosomes using both high-stringency and low-stringency post-hybridization washes, whereas the subtelomeric-DNA probe specific for chromosome 2p hybridized to telomeric sites of the short arm of chromosome 12 of all three great apes. These observations suggest an evolutionary difference in the number of alpha satellite DNA repeat units in the equivalent ape chromosomes presumably involved in the chromosome fusion. Nevertheless, complete conservation of DNA sequence of the subtelomeric repeat sequence D2S445 in the ape chromosomes is demonstrated.     

Satellite DNA and evolution of sex chromosomes

The satellite DNA (satellite III) which is mainly represented in the female of Elaphe radiata (Ophidia, Colubridae) has been isolated and its buoyant density has been determined (=1.700 g cm^–3). In situ hybridisation of radioactive complementary RNA of this satellite DNA with the chromosomes of different species has revealed that it is mainly concentrated on the W sex chromosome and its sequences are conserved throughout the sub-order Ophidia. From hybridisation studies these sequences are absent from the primitive family Boidae which represents a primitive state of differentiation of sex chromosomes. Chromosome analysis and C-banding have also revealed the absence of heteromorphism and of an entirely heterochromatic chromosome in the species belonging to the primitive family and their presence in the species of highly evolved families. It is suggested that the origin of satellite DNA (satellite III) in the W chromosome is the first step in differentiation of W from the Z in snakes by generating asynchrony in the DNA replication pattern of Z and W chromosomes and thus conceivably reducing the frequency of crossing-over between them which is the prerequisite of differentiation of sex chromosomes. Presence of similar sex chromosome associated satellite DNA in domestic chicken suggests its existence in a wider range of vertebrates than just the snakes.     

Chromosomal localization of complex and simple repeated human DNAs

Complex repeating restriction multimers and a simple AT rich satellite isolated with Hoechst 33258 (<= 0.5% of the human genome) were localized by in situ hybridization to human chromosomes. The complex repeats were clustered at the centromeres, consonant with their integration in tandem arrays at these loci; these sequences were very prominent on chromosomes 7, 10 and 19, sites not previously identified with any specific human repeated sequence. The Hoechst simple satellite labelled predominantly the long arms of the Y chromosome. Although this simple satellite and the complex restriction multimers did not hybridize with each other, and did not contain detectable ribosomal sequences, both isolates additionally labelled the nucleolus organizing regions (NORs) of acrocentric chromosomes. —The possible relationship of complex and simple repeated DNAs, and their assignment to specific chromosomal domains, is discussed.     

Absence of satellite III DNA in the centromere and the proximal long-arm region of human chromosome 14: analysis of a 14p- variant.

Cytogenetic methods and molecular probes derived from the centromere and short arm of chromosome 14 were used to investigate the structural properties of a chromosome 14 variant. Results of GTL, CBG, Ag-NOR, and non-banded Giemsa staining of the chromosomes suggested the complete absence of the short arm and possibly a large part of the centromere. Negative in situ hybridisation with an alpha satellite III probe confirmed the absence of the arm; the detection of normal amounts of alpha satellite DNA, however, indicated retention of the centromeric domain. The natural occurrence of a human acrocentric variant lacking a short arm was thus established. Within the detection limits of the methods used, the results demonstrate that satellite III DNA is not essential for normal centromeric activity and allow us to exclude the presence of this satellite DNA within the centromere and proximal long-arm region of human chromosome 14.     

Satellite DNA associated with heterochromatin in Rhynchosciara

The DNA of Rhynchosciara hollaenderi was examined using isopycnic centrifugation in neutral CsCl. Two low density minor bands (collectively termed satellite DNA) were detected in addition to the main band DNA. Main band DNA has a buoyant density of 1.695 g/cm³. The larger of the two minor bands has a buoyant density of 1.680 g/cm³ while the smaller of the two minor bands has a buoyant density of about 1.675 g/cm³. Thermal denaturation studies have confirmed the presence of the two minor classes of DNA.—The satellite and main band DNAs were isolated in relatively pure form and were transcribed in vitro using DNA-dependent RNA polymerase from Escherichia coli. Annealing of the two complementary RNAs (cRNAs) with main band and satellite DNA was examined using filter hybridization techniques.—The chromosomal distribution of the satellite DNA was determined by in situ molecular hybridization of satellite-cRNA with Rhynchosciara salivary gland chromosomes. Satellite-cRNA hybridized with the centromeric heterochromatin of each of the four chromosomes (A, B, C, and X) and with certain densely staining bands in the telomere regions of the A and C chromosomes. Main band-cRNA annealed with many loci scattered throughout the chromosomes including areas containing satellite DNA.     

The location of DNA homologous to human satellite III DNA in the chromosomes of chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus)

Radioactive RNA with sequences complementary to human DNA satellite III was hybridised in situ to metaphase chromosomes of the chimpanzee (Pan troglodytes), the gorilla (Gorilla gorilla) and the orangutan (Pongo pygmaeus). A quantitative analysis of the radioactivity, and hence of the chromosomal distribution of human DNA satellite III equivalent sequences in the great apes, was undertaken, and the results compared with interspecies chromosome homologies based upon Giemsa banding patterns. In some instances DNA with sequence homology to human satellite III is present on the equivalent (homologous) chromosomes in identical positions in two or more species although quantitative differences are observed. In other cases there appears to be no correspondence between satellite DNA location and chromosome homology determined by banding patterns. These results differ from those found for most transcribed DNA sequences where the same sequence is located on homologous chromosomes in each species.