Binding of anti-nucleoside antibodies reveals different classes of DNA in the chromosomes of the kangaroo rat (Dipodomys ordii)

The binding of highly purified anti-nucleoside antibodies to fixed metaphase chromosomes of the kangaroo rat (Dipodomys ordii) revealed the presence of different classes of DNA in different regions of the chromosomes. To permit antibody binding, the chromosomal DNA was first made single-stranded by either ultraviolet irradiation, which denatures some classes of AT-rich DNA, or photo-oxidation, which denatures GC-rich DNA. The antibody binding patterns obtained matched the location of the different classes of satellite DNA in kangaroo rat chromosomes. After either denaturation method, anti-5-methylcytidine (anti-M) bound intensely only to the centromeric heterochromatic regions which are known to contain the GC rich, highly methylated HS-β satellite DNA of this species. The basic repeating unit of the HS-β sequence is 5′-ACACAGCGGG-3′ 3′-TGTGTCGCCC-5′ [4]. The binding of anti-M after UV irradiation is permitted by the production of pyrmidine (CC and TC) dimers in the right-hand portion of this repeating sequence, supporting the idea that the 5-methylcytosine residues are in this portion. After photo-oxidation, anti-cytidine (anti-C) and anti-adenosine (anti-A) also showed intense binding to the centromeric heterochromatin. In addition, these antibodies showed moderately intense binding to non-centromeric heterochromatic regions, which contain the relatively GC-rich HS-α and MS satellite DNAs. After UV irradiation, anti-A binding produced a banding pattern identical to the quinacrine (Q-band) pattern, with bright chromosome arms and very dull centromeric heterochromatic regions, while anti-C showed moderate binding in the centromeric regions and fairly even but weak binding elsewhere.The results have clarified the way in which anti-nucleoside antibodies react with chromosomal DNA. The reactivity of anti-A, anti-C and anti-M with the partially denatured HS-β satellite DNA supports the idea that antibody binding requires denaturation of a sequence perhaps no more than 5 base pairs long. In addition, it appears that it is not necessary to have more than one identical base in a row to permit antibody binding.     

5-Methylcytosine in heterochromatic regions of chromosomes: chimpanzee and gorilla compared to the human

Fixed metaphase chromosomes of gorilla and chimpanzee were UV-irradiated to produce regions of single-stranded DNA and then treated with antibodies specific for the minor DNA base 5-methylcytosine (5 MeC). An indirect immunofluorescence technique was used to visualize sites of antibody binding. In the gorilla six pairs of autosomes contained major fluorescent regions, indicating localized regions of highly methylated DNA. These corresponded, with the exception of chromosome 19, to the major regions of constitutive heterochromatin as seen by C-banding. The Y chromosome also contained a highly fluorescent region which was located just proximal to the intense Q-band region. In the chimpanzee no comparable concentrations of highly methylated DNA were seen. Smaller regions of intense 5 MeC binding were present on perhaps six chimpanzee chromosomes, including the Y. Five of these corresponded to chromosomes which were highly methylated in the gorilla.--There is diversity among the human, gorilla and chimpanzee in both the size and location of concentrations of 5 MeC, supporting the idea that satellite DNA evolves more rapidly than DNA in the remainder of the chromosome.     

The structural organization of mouse metaphase chromosomes

The binding of highly purified anti-nucleoside antibodies to mouse (Mus musculus) metaphase chromosomes was studied by an immunofluorescence technique. The chromosomal DNA was denatured by one of two selective denaturation procedures because these antibodies reacted with single stranded but not native DNA. After ultraviolet irradiation (UV), which produced single stranded regions primarily in AT rich DNA, the binding of antiadenosine (anti-A) produced a pattern of fluorescent bands similar to that produced by quinacrine (Q-bands). Additional foci of bright fluorescence were observed at the centrometric (C-band) regions, which are known to contain AT rich satellite DNA. After photooxidation, which produced single stranded regions in GC rich DNA, the binding of anti-A produced a fluorescent banding pattern similar to the R-banding pattern seen after thermal denaturation and staining with coriphosphine O. After photooxidation, R-band patterns were also obtained with anti-cytidine (anti-C) and anti-5-methylcytidine (anti-M). After either UV irradiation or photooxidation, anti-M, but not anti-C, showed intense binding to the C-band regions of mouse chromosomes. — These findings led to the following conclusions: (1) Antibody banding patterns reflect the presence of a class of AT rich, GC poor DNA in chromosome regions which show bright quinacrine fluorescence and in the regions that contain the AT rich satellite DNA. (2) The alternate, quinacrine dull regions contain a relatively GC rich class of DNA which appears to be more highly methylated than the AT rich DNA in the Q-bright bands, but not the AT rich satellite DNA in the Q-dull C-bands. (3) 5-Methylcytosine residues occur in a sequence of mouse satellite DNA that contains both adjacent pyrimidines and guanine residues. The basic repeating unit of mouse satellite DNA is known to contain the sequence 5-GAAAAATGA-3 (Biro et al., 1975). Therefore, assuming the antibodies used could detect single bases in denatured DNA, the methylated sequence in mouse satellite DNA      

Hoechst 33258 banding of Drosophila nasutoides metaphase chromosomes

Hoechst 33258 banding of D. nasutoides metaphase chromosomes is described and compared with Q and C bands. The C band positive regions of the euchromatic autosomes, the X and the Y fluoresce brightly, as is typical of Drosophila and other species. The fluorescence pattern of the large heterochromatic chromosome is atypical, however. Contrary to the observations on other species, the C negative bands of the large heterochromatic chromosome are brightly fluorescent with both Hoechst 33258 and quinacrine. Based on differences in the various banding patterns, four classes of heterochromatin are described in the large heterochromatic chromosome and it is suggested that each class may correspond to an AT-rich DNA satellite.     

Molecular and cytological characterization of repetitive DNA sequences from the centromeric heterochromatin of <Emphasis Type="Italic">Sciara coprophila</Emphasis>

Sciara coprophila (Diptera, Nematocera) constitutes a classic model to analyze unusual chromosome behavior such as the somatic elimination of paternal X chromosomes, the elimination of the whole paternal, plus non-disjunction of the maternal X chromosome at male meiosis. The molecular organization of the heterochromatin in S. coprophila is mostly unknown except for the ribosomal DNA located in the X chromosome pericentromeric heterochromatin. The characterization of the centromeric regions, thus, is an essential and required step for the establishment of S. coprophila as a model system to study fundamental mechanisms of chromosome segregation. To accomplish such a study, heterochromatic sections of the X chromosome centromeric region from salivary glands polytene chromosomes were microdissected and microcloned. Here, we report the identification and characterization of two tandem repeated DNA sequences from the pericentromeric region of the X chromosome, a pericentromeric RTE element and an AT-rich centromeric satellite. These sequences will be important tools for the cloning of S. coprophila centromeric heterochromatin using libraries of large genomic clones.     

The staining of constitutive heterochromatin,and A-T and G-C rich DNA in lymphocytes and primary spermatocytes of the Chinese hamster

The staining of male Chinese hamster chromosomes at meiotic prophase with several banding techniques is described. C-banding results only occasionally in well-differentiated pachytene and diakinesis bivalents. Meiotic C-bands are small compared with those in somatic metaphase chromosomes. In mice C-bands mainly consist of highly repetitive satellite DNA, whereas in Chinese hamsters the majority of the DNA in C-bands is not or hardly repetitive. Especially in Chinese hamsters both the degree of chromatin despiralisation and the folding pattern of the chromatin drastically reduce the distinction of C-bands in late meiotic prophasc chromosomes. In contrast to the situation in mice, C-heterochromatin associations are never observed in Chinese hamster spermatocytes. It is assumed that the presence of satellite DNA rather than constitutive heterochromatin is the basis for the associations of the paracentromeric chromosome regions in mice. The location and behaviour of AT- and GC-rich DNA in Chinese hamster primary spermatocytes is studied with base-specific fluorochromes (H 33258 and Chromomycin A₃ for AT-and GC-rich DNA respectively), in combination with a pretreatment with base-specific non-fluorescent antibiotics (Actinomycin D and Netropsin for GC-and AT-rich DNA respectively). No indications are found for the clustering of AT-or GC-rich DNA in Chinese hamster pachytene nuclei. A comparison of banding patterns observed in somatic metaphases and in diakinesis gives some information about the partial homology of the X and Y chromosome. The results are conflicting. The short arm of the Y chromosome is homologous with a part of the X chromosome. According to the C-band pattern the long arm of the X chromosome is involved in the pairing with Y, whereas fluorescence banding patterns indicate that it is the short arm of X.     

Chromosome markers in Mus musculus: Differences in C-banding between the subspecies M. m. musculus and M. m. molossinus

Quinacrine (Q-band) and centromeric heterochromatin (C-band) patterns of metaphase chromosomes of two subspecies of Mus musculus were compared. M. m. musculus (the laboratory mouse) and M. m. molossinus (a subspecies from Southeast Asia) had similar Q-band patterns along the length of the chromosomes, but differences were observed in the centromeric region of some chromosomes. The two subspecies had very different distributions of C-band material. Antibodies to 5-methylcytosine were bound to regions of the chromosome corresponding to the C-bands in each animal. These findings support the idea that satellite DNA, which is concentrated in the C-band region, changes more quickly than bulk DNA. The interfertility of these two subspecies permits the development of a musculus strain carrying normal marker chromosomes for genetic studies.     

The organization of DNA in the mitotic and polytene chromosomes of Sciara coprophila

The organization of DNA in the mitotic metaphase and polytene chromosomes of the fungus gnat, Sciara coprophila, has been studied using base-specific DNA ligands, including anti-nucleoside antibodies. The DNA of metaphase and polytene chromosomes reacts with AT-specific probes (quinacrine, DAPI, Hoechst 33258 and anti-adenosine) and to a somewhat lesser extent with GC-specific probes (mithramycin, chromomycin A₃ and anticytidine). In virtually every band of the polytene chromosomes chromomycin A₃ fluorescence is almost totally quenched by counterstaining with the AT-specific ligand methyl green. This indicates that GC base pairs in most bands are closely interspersed with AT base pairs. The only exceptions are band IV-8A3 and the nucleolus organizer on the X. In contrast, quinacrine and DAPI fluorescence in every band is only slightly quenched by counterstaining with the GC-specific ligand actinomycin D. Thus, each band contains a moderate proportion of AT-rich DNA sequences with few interspersed GC base pairs. — The C-bands in mitotic and polytene chromosomes can be visualized by Giemsa staining after differential extraction of DNA and those in polytene chromosomes by the use of base-specific fluorochromes or antibodies without prior extraction of DNA. C-bands are located in the centromeric region of every chromosome, and the telomeric region of some. The C-bands in the polytene chromosomes contain AT-rich DNA sequences without closely interspered GC base pairs and lack relatively GC-rich sequences. However, one C-band in the centromeric region of chromosome IV contains relatively GC-rich sequences with closely interspersed AT base pairs. — C-bands make up less than 1% of polytene chromosomes compared to nearly 20% of mitotic metaphase chromosomes. The C-bands in polytene chromosomes are detectable with AT-specific or GC-specific probes while those in metaphase chromosomes are not. Thus, during polytenization there is selective replication of highly AT-rich and relatively GC-rich sequences and underreplication of the remainder of the DNA sequences in the constitutive heterochromatin.     

Experimental condensation inhibition in constitutive and facultative heterochromatin of mammalian chromosomes

What drives the dramatic changes in chromosome structure during the cell cycle is one of the oldest questions in genetics. During mitosis, all chromosomes become highly condensed and, as the cell completes mitosis, most of the chromatin decondenses again. Only chromosome regions containing constitutive or facultative heterochromatin remain in a more condensed state throughout interphase. One approach to understanding chromosome condensation is to experimentally induce condensation defects. 5-Azacytidine (5-aza-C) and 5-azadeoxycytidine (5-aza-dC) drastically inhibit condensation in mammalian constitutive heterochromatin, in particular in human chromosomes 1, 9, 15, 16, and Y, as well as in facultative heterochromatin (inactive X chromosome), when incorporated into late-replicating DNA during the last hours of cell culture. The decondensing effects of 5-aza-C analogs, which do not interfere with normal base pairing in substituted duplex DNA, have been correlated with global DNA hypomethylation. In contrast, decondensation of constitutive heterochromatin by incorporation of 5-iododeoxyuridine (IdU) or other non-demethylating base analogs, or binding of AT-specific DNA ligands, such as berenil and Hoechst 33258, may reflect an altered steric configuration of substituted or minor-groove-bound duplex DNA. Consequently, these compounds exert relatively specific effects on certain subsets of AT-rich constitutive heterochromatin, i.e. IdU on human chromosome 9, berenil on human Y, and Hoechst 33258 on mouse chromosomes, which provide high local concentrations of IdU incorporation sites or DNA-ligand-binding sites. None of these non-demethylating compounds affect the inactive X chromosome condensation. Structural features of chromosomes are largely determined by chromosome-associated proteins. In this light, we propose that both DNA hypomethylation and steric alterations in chromosomal DNA may interfere with the binding of specific proteins or multi-protein complexes that are required for chromosome condensation. The association between chromosome condensation defects, genomic instability, and epigenetic reprogramming is discussed. Chromosome condensation may represent a key ancestral mechanism for modulating chromatin structure that has since been realloted to other nuclear processes.     

Ionizing radiation-induced instant pairing of heterochromatin of homologous chromosomes in human cells

Using fluorescence in situ hybridization with human band-specific DNA probes we examined the effect of ionizing radiation on the intra-nuclear localization of the heterochromatic region 9q12-->q13 and the euchromatic region 8p11.2 of similar sized chromosomes 9 and 8 respectively in confluent (G1) primary human fibroblasts. Microscopic analysis of the interphase nuclei revealed colocalization of the homologous heterochromatic regions from chromosome 9 in a proportion of cells directly after exposure to 4 Gy X-rays. The percentage of cells with paired chromosomes 9 gradually decreased to control levels during a period of one hour. No significant changes in localization were observed for chromosome 8. Using 2-D image analysis, radial and inter-homologue distances were measured for both chromosome bands. In unexposed cells, a random distribution of the chromosomes over the interphase nucleus was found. Directly after irradiation, the average inter-homologue distance decreased for chromosome 9 without alterations in radial distribution. The percentage of cells with inter-homologue distance <3 micro m increased from 11% in control cells to 25% in irradiated cells. In contrast, irradiation did not result in significant changes in the inter-homologue distance for chromosome 8. Colocalization of the heterochromatic regions of homologous chromosomes 9 was not observed in cells irradiated on ice. This observation, together with the time dependency of the colocalization, suggests an underlying active cellular process. The biological relevance of the observed homologous pairing remains unclear. It might be related to a homology dependent repair process of ionizing radiation induced DNA damage that is specific for heterochromatin. However, also other more general cellular responses to radiation-induced stress or change in chromatin organization might be responsible for the observed pairing of heterochromatic regions.     

Interchromosomal Effects of Heterochromatic Deletions on Recombination in DROSOPHILA MELANOGASTER

It is now known that partial deletions of the satellite sequences in X-chromosome heterochromatin result in a significant decrease in intrachromosomal recombination in the proximal region of the X chromosome of D. melanogaster (YAMAMOTO and MIKLOS 1978). It is important to ask then if the loss or gain of heterochromatin on the X also alters recombination in other chromosomes of the genome (interchromosomal effects). I have looked for such alterations by measuring recombination in chromosome 3. The results clearly indicate that the partial loss of X-chromosome heterochromatin not only decreases crossing over in the proximal region of the X chromosome itself, but also increases the frequency in chromosome 3, especially in the euchromatic regions around the centromere. Furthermore, the greater the deficiency of X heterochromatin, the higher is recombination in chromosome 3. This finding not only provides further evidence in support of the hypothesis that heterochromatin, in this case mainly composed of satellite DNA, regulates the recombination system, but it demonstrates that when the satellite content of one chromosome of the D. melanogaster genome is altered, there is an alteration in the crossover characteristics of other chromosomes in the same complement. If the amount of satellite DNA in a genome is being continuously altered, then one can predict that the recombination system is also being continually perturbed. Thus, the changing gene combinations produced indirectly by increases or decreases of heterochromatin are among the components available to organisms to break up or form new gene combinations upon which selection can act.     

Structure of DNA near long tandem arrays of alpha satellite DNA at the centromere of human chromosome 7.

The centromeric regions of human chromosomes contain long tracts of tandemly repeated DNA, of which the most extensively characterized is alpha satellite. In a screen for additional centromeric DNA sequences, four phage clones were obtained which contain alpha satellite as well as other sequences not usually found associated with tandemly repeated alpha satellite DNA, including L1 repetitive elements, an Alu element, and a novel AT-rich repeated sequence. The alpha satellite DNA contained within these clones does not demonstrate the higher-order repeat structure typical of tandemly repeated alpha satellite. Two of the clones contain inversions; instead of the usual head-to-tail arrangement of alpha satellite monomers, the direction of the monomers changes partway through each clone. The presence of both inversions was confirmed in human genomic DNA by polymerase chain reaction amplification of the inverted regions. One phage clone contains a junction between alpha satellite DNA and a novel low-copy repeated sequence. The junction between the two types of DNA is abrupt and the junction sequence is characterized by the presence of runs of A's and T's, yielding an overall base composition of 65% AT with local areas > 80% AT. The AT-rich sequence is found in multiple copies on chromosome 7 and homologous sequences are found in (peri)centromeric locations on other human chromosomes, including chromosomes 1, 2, and 16. As such, the AT-rich sequence adjacent to alpha satellite DNA provides a tool for the further study of the DNA from this region of the chromosome. The phage clones examined are located within the same 3.3-Mb SstII restriction fragment on chromosome 7 as the two previously described alpha satellite arrays, D7Z1 and D7Z2. These new clones demonstrate that centromeric repetitive DNA, at least on chromosome 7, may be more heterogeneous in composition and organization than had previously been thought.     

Characterization of human heterochromatin by in situ hybridization with satellite DNA clones

Biotinylated DNA from two satellite-related, repetitive DNA clones, pHuR 98 and pHuR 195 (specific for chromosomes 9 and 16, respectively), and from a Y-specific clone, pY-3.4A, were hybridized to human metaphase chromosomes using fluoresceinated avidin to detect binding. The chromosomes were simultaneously counterstained with distamycin-DAPI to identify the AT-rich heterochromatin of chromosomes 1, 9, 15, 16, and the Y chromosome. With this method, clear results were obtained under both normal and low stringency conditions, allowing hybridization between molecules sharing 80-85% and 60-65% identity, respectively. Thus, additional sites related to the probes could be identified. A close relationship was shown between the heterochromatin of chromosomes 1 and 16, both hybridizing with clone pHuR 195 under low stringency. Hybridization with clone pHuR 98 was highly specific for chromosome 9, even under low stringency. A relationship between chromosomes 9, 15, and the Y chromosome, however, was shown by hybridization with clone pY-3.4A. The chromosomal distribution of the three repetitive DNA clones used in this study, and data from the literature, are in accordance with the distribution of the heterochromatin types characterized by staining with different fluorescent dyes and dye combinations. Furthermore, our sequence data for clones pHuR 98 and pHuR 195 may explain the fluorescent properties on which the cytogenetic classification of the heterochromatin is based.     

Sister chromatid exchange and chromosome organization based on a bromodeoxyuridine Giemsa-C-banding technique (TC-Banding)

Hoechst 33258 fluorescent staining of bromodeoxyuridine substituted chromosomes provided a high resolution technique for following the segregation of replicated chromosomal DNA (Latt, 1973). Modifications have produced the same results after Giemsa staining (Wolff and Perry, 1975). Since this does not necessarily require Hoechst (Korenberg and Freedlander, 1975), we call this bromodeoxyuridine-Giemsa banding (BG-banding). We here describe a further modification which allows one to follow the T-rich strand of the AT-rich satellite DNA of C-band heterochromatin. We call this TC-banding. This technique was used to examine metacentric marker chromosomes found in mouse L-cells that contain many interstitial blocks of centromeric-type heterochromatin in each arm plus the usual two blocks of centromeric heterochromatin. One of the advantages of this technique for such chromosomes is that it is possible to distinguish first from second cell cycle sister chromatid exchange and unambiguously detect centromeric sister chromatid exchange. We found some chromosomes to have high rates of centromeric sister chromatid exchange. After one cycle in bromodeoxyuridine we could examine the satellite polarity of the heterochromatic DNA. Since there was no change in satellite polarity in any of the heterochromatic blocks, marker chromosomes could not have been formed by paracentric inversions, inverted insertions or inverted translocations. These results allow the formulation of several rules of chromosome organization.     

Pericentromeric regions containing 1.688 satellite DNA sequences show anti-kinetochore antibody staining in prometaphase chromosomes of Drosophila melanogaster

A striking characteristic of the centromeric heterochromatin of Drosophila melanogaster is that each chromosome carries different satellite DNA sequences. Here we show that while the major component of the 1.688 satellite DNA family expands across the centromere of the X chromosome the rest of the minor variants are located at pericentromeric positions in the large autosomes. Immunostaining of prometaphase chromosomes with the kinetocore-specific anti-BUB1 antibody reveals the transient presence of this centromeric protein in all the regions containing the 1.688 satellite.     

T antigen banding on chromosomes of simian virus 40 infected muntjac cells.

Chromosomes were prepared from mitotic munjac cells 48 to 72 h after infection with SV40 virus. When stained for SV40 T antigen by indirect immunofluorescence, all chromosomes within an infected cell were fluorescent, indicating the presence of T antigen. Furthermore, the chromosomes were not uniformly stained but appeared to have regions of high and low fluorescence intensity. A variety of controls showed that the banding patterns are specific and highly reproducible and may indeed reflect the binding sites of T antigen. The bright, fluorescent bands T antigen were found to correspond to bands visualized by trypsin-Giesma staining (G-bands) and also by quinacrine staining (Q-bands). Current knowledge of chromosome banding indicates that Q-bands reflect the distribution of AT-rich regions along the chromosome. From the DNA sequence of SV40, it is known that one of the T antigen binding sites contains AT-rich sequences; thus, T antigen banding might be due to the base-specific binding of T antigen to chromatin. In addition, these bands have been implicated as centers for chromosome condensation and units in control of DNA replication. While the functional significance of T antigen binding has yet to be determined, the SV40-muntjac system provides an unusual opportunity to study the interaction of a known regulatory protein with mammalian chromosomes.     

Studies of He-T DNA sequences in the pericentric regions of Drosophila chromosomes

He-T DNA is a complex set of repeated DNA sequences with sharply defined locations in the polytene chromosomes of Drosophila melanogaster. He-T sequences are found only in the chromocenter and in the terminal (telomere) band on each chromosome arm. Both of these regions appear to be heterochromatic and He-T sequences are never detected in the euchromatic arms of the chromosomes (Young et al. 1983). In the study reported here, in situ hybridization to metaphase chromosomes was used to study the association of He-T DNA with heterochromatic regions that are under-replicated in polytene chromosomes. Although the metaphase Y chromosome appears to be uniformly heterochromatic, He-T DNA hybridization is concentrated in the pericentric region of both normal and deleted Y chromosomes. He-T DNA hybridization is also concentrated in the pericentric regions of the autosomes. Much lower levels of He-T sequences were found in pericentric regions of normal X chromosomes; however compound X chromosomes, constructed by exchanges involving Y chromosomes, had large amounts of He-T DNA, presumably residual Y sequences. The apparent co-localization of He-T sequences with satellite DNAs in pericentric heterochromatin of metaphase chromosomes contrasts with the segregation of satellite DNA to alpha heterochromatin while He-T sequences hybridize to beta heterochromatin in polytene nuclei. This comparison suggests that satellite sequences do not exist as a single block within each chromosome but have interspersed regions of other sequences, including He-T DNA. If this is so, we assume that the satellite DNA blocks must associate during polytenization, leaving the interspersed sequences looped out to form beta heterochromatin. DNA from D. melanogaster has many restriction fragments with homology to He-T sequences. Some of these fragments are found only on the Y. Two of the repeated He-T family restriction fragments are found entirely on the short arm of the Y, predominantly in the pericentric region. Under conditions of moderate stringency, a subset of He-T DNA sequences cross-hybridizes with DNA from D. simulans and D. miranda. In each species, a large fraction of the cross-hybridizing sequences is on the Y chromosome.     

Mapping Simple Repeated DNA Sequences in Heterochromatin of Drosophila Melanogaster

Heterochromatin in Drosophila has unusual genetic, cytological and molecular properties. Highly repeated DNA sequences (satellites) are the principal component of heterochromatin. Using probes from cloned satellites, we have constructed a chromosome map of 10 highly repeated, simple DNA sequences in heterochromatin of mitotic chromosomes of Drosophila melanogaster. Despite extensive sequence homology among some satellites, chromosomal locations could be distinguished by stringent in situ hybridizations for each satellite. Only two of the localizations previously determined using gradient-purified bulk satellite probes are correct. Eight new satellite localizations are presented, providing a megabase-level chromosome map of one-quarter of the genome. Five major satellites each exhibit a multichromosome distribution, and five minor satellites hybridize to single sites on the Y chromosome. Satellites closely related in sequence are often located near one another on the same chromosome. About 80% of Y chromosome DNA is composed of nine simple repeated sequences, in particular (AAGAC)(n) (8 Mb), (AAGAG)(n) (7 Mb) and (AATAT)(n) (6 Mb). Similarly, more than 70% of the DNA in chromosome 2 heterochromatin is composed of five simple repeated sequences. We have also generated a high resolution map of satellites in chromosome 2 heterochromatin, using a series of translocation chromosomes whose breakpoints in heterochromatin were ordered by N-banding. Finally, staining and banding patterns of heterochromatic regions are correlated with the locations of specific repeated DNA sequences. The basis for the cytochemical heterogeneity in banding appears to depend exclusively on the different satellite DNAs present in heterochromatin.     

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.