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.     

Cloning and characterization of a complex satellite DNA from Drosophila melanogaster.

The sequence organization of the 1.688 satellite DNA (density 1.688 g/cm³ in CsCl) has been investigated, and this satellite has been found to differ from the other D. melanogaster satellite DNAs in having a much greater sequence complexity. Purification of 1.688 satellite DNA by successive equilibrium density centrifugations yielded a fraction 77% pure. Segments of satellite DNA were isolated by molecular cloning in the plasmid vector pSC101. One recombinant plasmid contained a segment of 1.688 satellite DNA 5.8 kilobase pairs in size and was stable during propagation in E. coli. Recognition sites for restriction enzymes from Haemophilus aegyptius (Hae III), Haemophilus influenzae f (Hinf) and Arthrobacter luteus (Alu I) were mapped in the satellite DNA of this hybrid plasmid. The spacing of Hae III, Hinf and two Alu I sites at regular intervals of about 365 base pairs is strong evidence that the sequence complexity of this satellite DNA is 365 base pairs. Further evidence comes from the finding that both gradient-purified and cloned 1.688 satellite DNA renature with their Hae III sites in register. The Hae III and Hinf sites in gradient-purified satellite DNA have been shown by Manteuil, Hamer and Thomas (1975) and Shen, Wiesehahn and Hearst (1976) to be distributed at intervals of 365 base pairs and integral multiples thereof. These investigators proposed that some of the sites in an otherwise regular array have been randomly inactivated. Cloned satellite DNA provided a hybridization probe for sensitive studies of the arrangement of these recognition sites in gradient-purified satellite DNA. Some regions of satellite DNA were found to contain many fewer recognition sites than expected from the proposed models. These findings suggest that different regions of 1.688 satellite DNA may exhibit different arrangements of Hae III and Hinf recognition sites.     

Cleavage patterns of Drosophila melanogaster satellite DNA by restriction enzymes.

The five satellite DNAs of Drosophila melanogaster have been isolated by the combined use of different equilibrium density gradients and hydrolyzed by seven different restriction enzymes; Hae III, Hind II + Hind III, Hinf, Hpa II, EcoR I and EcoR II. The 1.705 satellite is not hydrolyzed by any of the enzymes tested. Hae III is the only restriction enzyme that cuts the 1.672 and 1.686 satellites. The cleavage products from either of these reactions has a heterogeneous size distribution. Part of the 1.688 satellite is cut by Hae III and by Hinf into three discrete fragments with M.W. that are multiples of 2.3 X 10(5) daltons (approximately 350 base pairs). In addition, two minor bands are detected in the 1.688-Hinf products. The mole ratios of the trimer, dimer and monomer are: 1:6.30 : 63.6 for 1.688-Hae III and 1 : 22.0 : 403 for 1.688-Hinf. Circular mitochondrial DNA (rho = 1.680) is cut into discrete fragments by all of the enzymes tested and molecular weights of these fragments have been determined.     

Different regions of a complex statellite DNA vary in size and sequence of the repeating unit.

The 1.688 g/cm³ satellite DNA of Drosophila melanogaster is composed primarily of 359 base-pair units repeated in tandem. Most of these units contain a single cleavage site for both HaeIII and HinfI restriction endonucleases; however, some units lack one or both sites. Previously we had shown that the distribution of HaeIII and HinfI endonuclease sites varies widely between different regions of 1.688 g/cm³ satellite DNA; for example, some regions contain HaeIII sites in every unit and other regions (>10,000 base-pairs) contain no HaeIII sites (Carlson &; Brutlag, 1977). We have now cloned molecules of 1.688 g/cm³ satellite DNA which lack HaeIII sites and have shown that the absence of sites is caused by sequence variation rather than base modification. This result indicates that regions of 1.688 g/cm³ satellite DNA with different distributions of restriction sites differ in the sequence of their repeating units. We also show that a large fraction of the satellite DNA which is not cleaved by HaeIII endonuclease still contains HinfI endonuclease sites (and AluI sites) spaced about 359 base-pairs apart. However, one cloned segment lacking HaeIII sites was found to contain 33 tandem copies of a novel 254 base-pair unit. Sequence analysis showed that this 254 base-pair unit is homologous to the 359 repeat except for a 98 base-pair deletion. These data suggest that both units have evolved from a common ancestor and that each has subsequently become amplified into separate tandem arrays.     

One of the copia genes is adjacent to satellite DNA in Drosophila melanogaster.

A method for purifying sequences adjacent to satellite DNA in the heterochromatin of D. melanogaster is described. A cloned DNA segment containing part of a copia gene adjacent to 1.688 g/cm3 satellite DNA has been isolated. The copia genes compose a repeated gene family which codes for abundant cytoplasmic poly(a)-containing RNA (Young and Hogness, 1977; Finnegan et al., 1978). We have identified two major poly (A)-containing RNA species [5.2 and 2.1 kilobases (kb)] produced by the copia gene family. The cloned segment contains copia sequences homologous to the 5' end of RNA within 0.65 kb of the 1.688 satellite DNA sequences. Seven different cloned copia genes from elsewhere in the genome have also been isolated, and a 5.2 kb region present in five of the clones was identified as copia by heteroduplex analysis. In addition, three ususual copies of copia were found: a "partial" copy of the gene (3.7 kb) which has one endpoint in common with the 5.2 kb unit; a copia gene flanked on one side by a 1.6 kb sequence and on the other by the same 1.6 kb sequence in the inverted orientation; and a copia gene flanked only on one side by the same sequence.     

Sequence and sequence variation within the 1.688 g/cm3 satellite DNA of Drosophila melanogaster.

We have determined the complete nucleotide sequence of the monomer repeating unit of the 1.688 g/cm³ satellite DNA from Drosophila melanogaster. This satellite DNA, which makes up 4% of the Drosophila genome and is located primarily on the sex chromosomes, has a repeat unit 359 base-pairs in length. This complex sequence is unrelated to the other three major satellite DNAs present in this species, each of which contains a very short repeated sequence only 5 to 10 base-pairs long. The repeated sequence is more similar to the complex repeating units found in satellites of mammalian origin in that it contains runs of adenylate and thymidylate residues. We have determined the nature of the sequence variations in this DNA by restriction nuclease cleavage and by direct sequence determination of (1) individual monomer units cloned in hybrid plasmids, (2) mixtures of adjacent monomers from a cloned segment of this satellite DNA, (3) mixtures of monomer units isolated by restriction nuclease cleavage of total 1.688 g/cm³ satellite DNA. Both direct sequence determination and restriction nuclease cleavage indicate that certain positions in the repeat can be highly variable with up to 50% of certain restriction sites having altered recognition sequences. Despite the high degree of variation at certain sites, most positions in the sequence are highly conserved. Sequence analysis of a mixture of 15 adjacent monomer units detected only nine variable positions out of 359 base-pairs. Total satellite DNA showed only four additional positions. While some variability would have been missed due to the sequencing methods used, we conclude that the variation from one repeat to the next is not random and that most of the satellite repeat is conserved. This conservation may reflect functional aspects of the repeated DNA, since we have shown earlier that part of this sequence serves as a binding site for a sequence-specific DNA binding protein isolated from Drosophila embryos (Hsieh &; Brutlag, 1979).     

1.688 g/cm3 satellite‐related repeats: a missing link to dosage compensation and speciation

Despite the important progress that has been made on dosage compensation (DC), a critical link in our understanding of the X chromosome recognition mechanisms is still missing. Recent studies in Drosophila indicate that the missing link could be a family of DNA repeats populating the euchromatin of the X chromosome. In this opinion article, I discuss how these findings add a new fresh twist on the DC problem. In the following sections, I first summarize our understanding of DC in Drosophila and integrate these recent discoveries into our knowledge of the X chromosome recognition problem. Next, I introduce a model according to which, 1.688 g/cm³ satellite‐related (SR) repeats would be the primary recognition elements for the dosage compensation complex. Contrary to the current belief, I suggest that the DC system in Drosophila is not conserved and static, but it is continuously co‐evolving with the target SR repeats. The potential role of the SR repeats in hybrid incompatibilities and speciation is also discussed.     

Mitochondrial deoxyribonucleic acid from Tetrahymena pyriformis and its kinetic complexity

1. Mitochondrial DNA from Tetrahymena pyriformis strain T has a buoyant density (rho) of 1.685 compared with rho1.688 for whole cell DNA. Mitochondrial preparations from T. pyriformis strain W show an enrichment of a light satellite (rho1.686), although this is not obtained free from nuclear DNA (rho1.692). 2. T. pyriformis mitochondrial DNA renatures rapidly and the kinetics of this process indicate a complexity of approx. 3x10(7) daltons. 3. The base-pairing in the renaturation product is of a precise nature, since the ;melting' temperature (80.5 degrees C) is indistinguishable from that of the native DNA (80.5 degrees C). 4. Centrifugation of mitochondrial DNA in an alkaline caesium chloride density gradient gives two bands, implying the separation of the complementary strands.     

Origin and Differentiation of a Sex Chromosome System in Parodon hilarii (Pisces, Parodontidae). Satellite DNA, G- and C-banding

A satellite DNA sequence of Parodon hilarii (named pPh2004) was isolated, cloned and sequenced. This satellite DNA is composed of 200 bp, 60% AT rich. In situ hybridization (FISH) results revealed that the satellite DNA pPh2004 is located in the terminal regions of several chromosomes, forming highly evident blocks in some and punctual marks in others. The comparison between the FISH and C-banding results showed that the location of this satellite DNA coincides with that of most terminal heterochromatins. However, some regions are only marked by FISH whereas other regions are only marked by C-banding. The possible existence of more than one satellite DNA family could explain these partial differences. The in situ hybridization with the satellite DNA and the G- and C-bandings confirmed the presence of a sex chromosome system of the ZZ/ZW type in P. hilarii, as well as the correct identification of the Z chromosome in the karyotype. This chromosome displays a segment of terminal heterochromatin in the long arm, similar to the segment observed in the short arm of the W chromosome, also showing a G-banding pattern similar to that of the short arm and part of the long arm of the W chromosome. A hypothesis on the origin of the W chromosome from an ancestral chromosome similar to the Z chromosome is presented.     

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.     

Alpha satellite DNAs on chromosomes 10 and 12 are both members of the dimeric suprachromosomal subfamily, but display little identity at the nucleotide sequence level

We have investigated the organization and complexity of alpha satellite DNA on chromosomes 10 and 12 by restriction endonuclease mapping, in situ hybridization (ISH), and DNA-sequencing methods. Alpha satellite DNA on both chromosomes displays a basic dimeric organization, revealed as a 6- and an 8-mer higher-order repeat (HOR) unit on chromosome 10 and as an 8-mer HOR on chromosome 12. While these HORs show complete chromosome specificity under high-stringency ISH conditions, they recognize an identical set of chromosomes under lower stringencies. At the nucleotide sequence level, both chromosome 10 HORs are 50% identical to the HOR on chromosome 12 and to all other alpha satellite DNA sequences from the in situ cross-hybridizing chromosomes, with the exception of chromosome 6. An 80% identity between chromosome 6- and chromosome 10-derived alphoid sequences was observed. These data suggest that the alphoid DNA on chromosomes 6 and 10 may represent a distinct subclass of the dimeric subfamily. These sequences are proposed to be present, along with the more typical dimeric alpha satellite sequences, on a number of different human chromosomes.     

Organization of the variant domains of α satellite DNA on human chromosome 21

The de novo creation of long, homogeneous, satellite DNA domains was postulated previously to occur by saltatory amplification. In this paper, pulsed field gel electrophoresis analysis of the α satellite DNA block organization of the human chromosome 21 supports this hypothesis. Double-dimension electrophoresis indicated that the variant copies of the basic α satellite repeat of chromosome 21 are organized in a single 3,150 Kblong domain. It was also established that the other satellite DNAs found in man (β, II, and III) are organized independently of the α satellite DNA block of the same chromosome. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

The organisation of repetitive sequences in the pericentromeric region of human chromosome 10.

Three satellite DNA families are present in the pericentromeric region of chromosome 10; the alpha satellite and two 5 bp satellite families defined here as satellites 2 and 3. Pulsed field gel electrophoresis (PFGE) demonstrates that these sequences are organised into five discrete arrays which are linked within a region of approximately 5.3 Megabases (Mb) of DNA. The alpha satellite is largely confined to a 2.2 Mb array which is flanked on its p arm side by two 100-150 kb satellite 3 arrays and on its q arm side by a 900 kb satellite 2 array and a further 320 kb satellite 3 array. This linear order is corroborated by fluorescent in situ hybridisation analyses. In total, these arrays account for 3.6 Mb of DNA in the pericentromeric region of chromosome 10. These data provide both physical information on sequences which may be involved in centromere function and a map across the centromere which has the potential to link yeast artificial chromosome (YAC) contigs currently being developed on both arms of this chromosome.     

On the mode of evolution of alpha satellite DNA in human populations

Summary The hypothesis that highly reiterated satellite DNAs in present-day populations evolve by molecular mechanisms that create, by saltatory amplification steps, new long arrays of satellite DNA, and that such long arrays are used for homogenization purposes, has been tested both in mouse and in humans. In mouse, the data obtained are consistent with this hypothesis. This was tested in more detail on chromosomes 13 and 21 of the human genome. A Centre d'Etudes du Polymorphisme Humain family, which in some individuals exhibits strong supplementary DNA bands following TaqI restriction endonuclease digestion and conventional gel electrophoresis, was analyzed by pulse field gel electrophoresis following restriction by BamHI. The supplementary bands on chromosome 13 (18 times the basic alpha satellite DNA repeat) and on chromosome 21 (a 9.5-mer) segregated with centromeric alpha satellite DNA blocks of 5 and 5.3 megabases, respectively. These are by far the largest alpha satellite block lengths seen in all chromosome 13 and chromosome 21 centrometric sequences so far analyzed in this manner. The possibility that these supplementary alpha satellite sequences were created in single individuals by saltatory amplification steps is discussed in light of our own data and that published by others. It is proposed that deletion events and unequal cross-overs, which both occur in large satellite DNA arrays, contribute to the homogenization of size and sequence of the alpha satellite DNA on most chromosomes of humans.     

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.     

Labeling of the centromeric region on human chromosome 8 by in situ hybridization

Summary Probe DNA that binds preferentially to the centromeric region of human chromosomes 8 was synthesized. Alpha satellite probe DNA molecules were selectively amplified from sorter-purified human chromosomes 8 by in vitro DNA amplification using the polymerase chain reaction (PCR). Probe labeling was performed during PCR by incorporation of biotinylated deoxyuridine. In situ hybridization of unpurified probe DNA comprised of alpha satellite monomer and higher molecular weight DNA fragments with metaphase chromosome spreads showed binding to the centromeric regions of numerous chromosomes. However, blocking with unlabeled total human alphoid DNA dramatically reduced crosshybridization to chromosomes other than 8. Under these conditions, the degenerate probe DNA allowed unambiguous visualization of domains occupied by centromeric DNA of chromosome 8 in metaphase spreads and interphase cell nuclei, thus greatly facilitating the detection of numerical chromosome aberrations in tumor cells. In situ hybridization of size-fractionated alpha satellite DNA identified the monomeric fraction as the major cause of crosshybridization. Alpha satellite dimers and higher molecular weight DNA fragments showed relatively high specificity for human chromosomes 8.     

Evidence for structural heterogeneity from molecular cytogenetic analysis of dicentric Robertsonian translocations.

Most Robertsonian translocations are dicentric, suggesting that the location of chromosomal breaks leading to their formation occur in the acrocentric short arm. Previous cytogenetic and molecular cytogenetic studies have shown that few Robertsonian translocations retain ribosomal genes or beta-satellite DNA. Breakpoints in satellite III DNA, specifically between two chromosome 14-specific subfamilies, pTRS-47 and pTRS-63, have been indicated for most of the dicentric 14q21q and 13q14q translocations that have been studied. We have analyzed the structure of 36 dicentric translocations, using several repetitive DNA probes that localize to the acrocentric short arm. The majority of the translocations retained satellite III DNA, while others proved variable in structure. Of 10 14q21q translocations analyzed, satellite III DNA was undetected in 1; 6 retained one satellite III DNA subfamily, pTRS-47; and 3 appeared to contain two 14-specific satellite III DNA sub-families, pTRS-47 and pTRS-63. In 10/11 translocations involving chromosome 15, the presence of satellite III DNA was observed. Our results show that various regions of the acrocentric short arm, and, particularly, satellite III DNA sequences, are involved in the formation of Robertsonian translocations.     

Satellite DNA I in chromatin loops of rat pachytene chromosomes and in spermatids

Biotinylated rat satellite DNA I probe p93-50 was used to visualize the chromatin of surface-spread rat pachytene chromosomes. Fluorescein isothiocyanate (FITC)-conjugated avidin produces a beaded fluorescence pattern along the chromatin loops that insert in the centromeric region of the synaptonemal complex (SC), the paired cores of homologous chromosomes. The number of fluorescent beads ranges from zero for centromeres without satellite DNA I homologous to probe p 93-50, to several hundred for satellite-rich centromeric regions. For the chromosomes that can be identified, the relative amount of satellite DNA is chromosome specific. No satellite DNA I was detected at the non-centromeric ends of the chromosomes or interstitially. DNase-digested nuclei or isolated SCs did not have detectable amounts of satellite DNA in the centromeric regions of the chromosomes or in the residual SCs. The fate of the satellite DNA was followed during spermiogenesis. In the round spermatid the centromeric regions, which appear to be attached to the nuclear envelope, are still distinct and have converging loops of fluorescent chromatin. At later stages there are fewer but still bright fluorescent patches. Satellite DNA I is still detectable in the mature sperm head. These results demonstrate the organization of satellite DNA I in the chromatin loops at the centromeric regions, and they forecast the analysis of chromosome organization in unprecedented detail with a variety of probes in surface spreads of meiotic prophase chromosomes.