Prototype sequence of bovine 1.720 satellite DNA

Bovine 1.720 satellite DNA (density in CsCl, 1.720 g/cm³) consists of a tandem array of 46 base-pair-repeat units without a detectable higher-order periodicity. About 80% of the satellite DNA is cleaved by AluI into a 46 base-pair fragment which has been isolated and sequenced. The sequence determined exhibits a very high homology to the 23 base-pair prototype sequence of bovine 1.706 satellite DNA (Pech et al., 1979) indicating a common origin of the two satellites. The 46 base-pairrepeat unit of the 1.720 satellite is composed of two related 23 base-pair sequences both of which are largely self-complementary. The entire 1.720 satellite DNA can be considered to be an imperfect palindrome.     

The primary structure of bovine satellite 1.715.

The primary structure of the 1402 bp repeat unit of bovine satellite 1.715 has been determined using a dimer inserted at the SalI site of plasmid pBR322 and cloned in E. coli. In contrast with bovine satellites 1.706, 1.720b and 1.711a, the 1.715 satellite has a complex sequence with no obvious internal short prototype repeat. The sequence consists however of repeats ranging in length from 6 to 13 nucleotides. In addition, the hexanucleotide, AGATGA, present in the prototype sequences of satellites 1.706, 1.720b and 1.711a, is found in satellite 1.715 in repeats as long as, or longer than, 8 nucleotides, establishing a homology link among those satellites on one hand and satellite 1.715 (and the related satellite 1.711b) on the other. In turn, this suggests a common evolutionary origin. A comparison of the maps for 15 restriction enzymes of cloned and uncloned satellite indicates very little sequence divergence among the repeat units of the latter, most of the differences being due to methylation.     

Apparent relatedness of the main component of ovine 1.714 satellite DNA to bovine 1.715 satellite DNA

The nucleotide sequence of the principal component of ovine 1.714 g/cm3 satellite DNA was determined from a monomeric fragment inserted at the BamHI site of pBR322 and cloned in Escherichia coli strain RR1. The 816-bp tandemly repeated sequence contains a number of small repeated sequences dispersed within it, one group of which forms a pentameric tandem repeat of a 13-bp segment (positions 548-612). A 20-bp region (60-79) shows an 85% homology with the reverse-complement of the sequence from 455 through 474. There are two regions of 67 bp (75-141) and 59 bp (755-813) which show greater than 70% homology with regions of bovine 1.715 g/cm3 satellite DNA (1402 bp; positions 1218-1284 and 1079-1137, respectively) while a 31-bp region (ovine 62-92, bovine 133-163) shows 80% homology. Quasi-correlation coefficients (Qr) were determined using the triplet numbers of the sheep satellite versus all sequences in the National Biomedical Research Foundation and EMBL nucleotide sequence data bases. Qr equals 0.85 for ovine 1.714 g/cm3 satellite versus bovine 1.715 g/cm3 satellite. The next highest Qr for a bovine satellite segment was 0.58. Thus, the ovine 1.714 g/cm3 and bovine 1.715 g/cm3 satellite appear demonstrably related. Taking into account that sheep and cattle diverged 18-20 million years ago, this suggests that the material may be functional and that its function is related to its sequence.     

Transgenerational transmission of bovine satellite DNA in transgenic mice

Genetical, cytogenetical and molecular analysis was made for 5 generations of mice transgenic for bovine satellite DNA (Sat). In all cases transgenic mice were generated by crosses of transgenic males and females with normal (CBA x C57B1) mice. No abnormalities in the founder development were noticed. A normal (near 50 %) ratio of transgenic and nontransgenic offsprings was observed in blastocysts. However, profound differences occurred in the rate of transgene bearing offsprings, depending on the sex of grandparents rather than of parents. The grandfather Sat transmission resulted in the appearance of 0-52.4 % transgenic grandchildren, whereas the grandmother transmission ended in the theoretically expected rate. This means that stabilization of transsatellite took place upon the female germ line transmission (a positive grandmother effect). It is essential that in hemizygous transsatellite mice Sat integration led to the occurrence of mammary tumors, inflammation of uterine horns, and infringement of mother care of transgenic females. Simultaneous FISH and G-banding showed Sat to be localized in the internal region of chromosome 12 near Pax 9 and Brms 11 genes. Commonly, these genes are implicated in tumorigenesis as their expression decreases. Thus, a kind of silencing effect of these genes' expression may be supposed.     

Restriction endonuclease cleavage of satellite DNA in intact bovine nuclei

We have analyzed the efficiency with which specific nucleotide sequences within nucleosomes are recognized and cleaved by DNA restriction endonucleases. A system amenable to this sort of analysis is the cleavage of the bovine genome with the restriction endonuclease EcoRI. Bovine satellite I comprises 7% of the genome and is tandemly repetitious with an EcoRI site at 1400 base pair (bp) intervals within this sequence. The ease with which this restriction fragment can be measured permits an analysis of the accessibility of this sequence when organized in a nucleosomal array.Initial studies indicated that satellite I sequences are organized in a nucleosomal structure in a manner analogous to that observed for total genomic DNA. We then examined the accessibility of the EcoRI cleavage sites in satellite to endonucleolytic cleavage in intact nuclei. We find that whereas virtually all the satellite I sequences from naked DNA are cleaved into discrete 1400 bp fragments, only 33% of the satellite I DNA is liberated as this fragment from intact nuclei. These data indicate that 57% of the EcoRI sites in nuclei are accessible to cleavage and that cleavage can occur within the core of at least half the nucleosomal subunits. Analysis of the products of digestion suggests a random distribution of nucleosomes about the EcoRI sites of satellite I DNA.Finally, the observation that satellite sequences can be cleaved from nuclei to 1400 bp length fragments with their associated proteins provides a method for the isolation of specific sequences as chromatin. Using sucrose gradient velocity centrifugation, we have isolated a 70% pure fraction of satellite I chromatin. Nuclease digestion of this chromatin fraction reveals the presence of nucleosomal subunits and indicates that specific sequences can be isolated in this manner without gross disorganization of their subunit structure.     

Sequence and evolution of related bovine and caprine satellite DNAs: Identification of a short DNA sequence potentially involved in satellite DNA amplification

The satellite II DNAs of the domestic ox Bos taurus and sheep Ovis aries have been sequenced, and that of the domestic goat Capra hircus partially sequenced. All three are related, and consist of repeat units of about 700 base-pairs. There is no evidence of internal repetition within these repeat units. When matched for maximum homology, the goat and sheep sequences show 83% homology, whereas the ox and sheep sequences share only 70% homology. Factors contributing to the uncertainty of the exact homology between these sequences are discussed, but the results are nevertheless consistent with their progenitor sequence being present in the common ancestor of cattle and sheep. Goat satellite II DNA is shown to contain another, unrelated, tandemly repeated sequence, which is composed of 22 base-pair repeat units. Both this sequence and a region of ox satellite II share good homology with the 11 base-pair progenitor sequence of ox 1.706 g/cm³ satellite DNA. It is suggested that this shared sequence could play a role in bovine satellite DNA amplification.     

On the tertiary structure of satellite DNA.

The primary structure of the Citrus ichangensis satellite DNA repeating unit has been estimated. The repeat is 181 bp long and contains four pentanucleotides of adenine residues. Oligomer forms of the stDNA repeating unit were detected by a partial hydrolysis of the C ichangensis stDNA by BspI restriction endonuclease. Experiments on comparative mobility of oligomers in agarose and polyacrylamide gels evidenced a certain retardation of those in polyacrylamide gel indicating to a slight bend in the repeating unit. The BEN computer program [9] was employed to calculate the spatial positions of monomer and oligomer axes of the satellite DNA repeating unit of Citrus ichangensis, mouse and African green monkey, and to plot their two-dimensional projections. The bends in the monomer for higher oligomer form proved to result in a hypothetical solenoid-like structure, termed coiled double helix (CDH).     

Restriction enzyme analysis of satellite DNA components from the bovine genome

A restriction enzyme analysis was performed on satellite DNA components, isolated, as described in the preceding paper, from the bovine genome by a combination of Cs2SO4/BAMD and Cs2SO4/Ag+ density gradient centrifugation. Such an analysis has led to the unambiguous identification of eight satellite DNA components and to new information on their repeat units; this indicates that identical repeat lengths are shared by them, a fact strongly suggesting a common origin.     

A possible structure for calf satellite DNA I.

Calf satellite DNA I (p = 1.715) has been hydrolysed by a number or restriction endonucleases. It consists of a repeating unit of 1460 nucleotide pairs within which the sites of Eco R II Mbo I, Sac I, Alu I, Ava II and Hha I were localised in comparison with those of Eco R I and Hind II. The distribution of the Hpa II, Sac I, Hha I, Hinf I and Mbo II sites within calf satellite DNA I, as well as that of several restriction endonuclease sites within calf satellite DNA III (p = 1.705) allowed me to define subsatellite fractions. Furthermore, some of the sites of the CpG containing restriction enzymes Hpa II and Hha I are lacking. The possible implications of these results are discussed.     

Structure of 1.71 lb gm/cm(3) bovine satellite DNA: evolutionary relationship to satellite I

The Eco RI fragments from the 2600 bp repeating unit of 1.711b gm/Cm(3) bovine satellite DNA were cloned in pBR322. The structure of the repeat unit was determined and compared to bovine satellite I DNA (rho CsCl = 1.715 gm/cm(3)). All of the DNA in the 1402 bp repeat of satellite I is represented in the sequence of the 2600 bp 1.711b gm/cm(3) repeat. The difference between the two repeats is due to a 1200 bp piece of DNA (INS) residing in the middle of the 1.711b gm/cm(3) repeat. The INS is AT-rich and has some repetitive components; it bears only limited similarity to the structure of eukaryotic transposable elements. We propose that the 1.711b gm/cm(3) satellite DNA arose via the amplification of a 1.715 gm/cm(3) satellite repeat altered by a 1200 bp insertion of DNA.     

Demethylation of satellite I DNA during senescence of bovine adrenocortical cells in culture.

Over the finite proliferative life span of cultured bovine adrenocortical cells, satellite I DNA shows a progressive and extensive loss of methylation at CCGG sites. This was shown by Southern blotting after digestion with the methylation-sensitive enzyme HpaII alone, which provides a sensitive indicator of methylation loss, or digestion with the combination of EcoRI and HpaII, which provides a quantitative indication of loss of methylation. Bovine tissues, including adrenal cortex, all showed a much higher level of satellite methylation than cultured adrenocortical cells. After adrenocortical cells are placed in culture, some demethylation of satellite I is seen as early as 10 population doublings. By 80 population doublings, loss of satellite DNA methylation is extensive. The loss does not appear to prevent continued cell division, since an extended life span clone of bovine adrenocortical cells transfected with SV40 T antigen showed a similar pattern of extensive demethylation. Satellite demethylation has been reported in aging in vivo and the present cell culture system may provide an in vitro model for this form of genetic instability.     

Sequence analysis of bovine satellite I DNA (1.715 gm/cm3).

The 1402 bp Eco RI repeating unit of bovine satellite I DNA (rho CsCl = 1.715 gm/cm3) has been cloned in pBR322. The sequence of this cloned repeat has been determined and is greater than 97% homologous to the sequence reported for another clone of satellite I (48) and for uncloned satellite I DNA (49). The internal sequence structure of the Eco RI repeat contains imperfect direct and inverted repeats of a variety of lengths and frequencies. The most outstanding repeat structures center on the hexanucleotide CTCGAG which, at a stringency of greater than 80% sequence homology, occurs at 26 locations within the RI repeat. Two of these 6 bp units are found within the 31 bp consensus sequence of a repeating structure which spans the entire length of the 1402 bp repeat (49). The 31 bp consensus sequence contains an internal dodecanucleotide repeat, as do the consensus sequences of the repeat units determined for 3 other bovine satellite DNAs (rho CsCl = 1.706, 1.711a, 1.720 gm/cm3). Based on this evidence, we present a model for the evolutionary relationship between satellite I and the other bovine satellites.     

Varied patterns of DNA methylation change between different satellite regions in bovine preimplantation development

Global reduction of DNA methylation, a part of genome reprogramming processes, occurs in a gradual manner until before implantation and is recognized as a conserved process in mammals. Here, we reported that in bovine, satellite regions exhibited varied patterns of methylation changes when one-cell egg advanced to the blastocyst; a maintenance methylation was observed in satellite I sequences, a decrease in alpha satellites, and an increase in satellite II regions. Cloned embryos exhibited similar changes for DNA methylation in the satellite I and alpha. We also observed that the satellite I and alpha sequences were methylated more in inner cell mass region of the blastocyst whereas the satellite II showed selective demethylation in this region. Together, these findings point that individual satellite sequences carry their own methylation patterns under the pressure of global demethylation, suggesting that local methylation control system acts on the satellite regions in early bovine embryos.     

Mouse satellite DNA, centromere structure, and sister chromatid pairing

The experiments described were directed toward understanding relationships between mouse satellite DNA, sister chromatid pairing, and centromere function. Electron microscopy of a large mouse L929 marker chromosome shows that each of its multiple constrictions is coincident with a site of sister chromatid contact and the presence of mouse satellite DNA. However, only one of these sites, the central one, possesses kinetochores. This observation suggests either that satellite DNA alone is not sufficient for kinetochore formation or that when one kinetochore forms, other potential sites are suppressed. In the second set of experiments, we show that highly extended chromosomes from Hoechst 33258-treated cells (Hilwig, I., and A. Gropp, 1973, Exp. Cell Res., 81:474-477) lack kinetochores. Kinetochores are not seen in Miller spreads of these chromosomes, and at least one kinetochore antigen is not associated with these chromosomes when they were subjected to immunofluorescent analysis using anti-kinetochore scleroderma serum. These data suggest that kinetochore formation at centromeric heterochromatin may require a higher order chromatin structure which is altered by Hoechst binding. Finally, when metaphase chromosomes are subjected to digestion by restriction enzymes that degrade the bulk of mouse satellite DNA, contact between sister chromatids appears to be disrupted. Electron microscopy of digested chromosomes shows that there is a significant loss of heterochromatin between the sister chromatids at paired sites. In addition, fluorescence microscopy using anti-kinetochore serum reveals a greater inter-kinetochore distance than in controls or chromosomes digested with enzymes that spare satellite. We conclude that the presence of mouse satellite DNA in these regions is necessary for maintenance of contact between the sister chromatids of mouse mitotic chromosomes.     

Methylation of satellite DNA

The lower amount of 5 methylcytosine in DNA from bull sperm relative to DNA of other bovine tissues is a result of the absence of this minor base from several of the satellite DNAs in sperm. This applies particularly to the 1.715, 1.711b and 1.709 satellites and less so to the 1.706 and 1.711a satellites. Mouse sperm DNA is also partially undermethylated.     

Ribosomal DNA in a nuclear satellite of tomato

A satellite DNA of buoyant density 1.704 constitutes approximately 5%–6% of nuclear DNA isolated from cherry tomato leaves. Isolated satellite DNA exhibits a multi-component melting profile. Kinetic complexity measurements indicate that 37% of the satellite consists of repeating units of 10 ⁵ daltons, and 48% of it consists of repeating units of 5.5 x 10⁶ daltons. The latter component is identified as DNA coding for ribosomal RNA on the basis of its buoyant density, kinetic complexity, and abundance in nuclear DNA, 3.2% as determined by saturation hybridization measurements. Saturation studies show that the more rapidly reassociating component of the satellite does not code for 5S RNA. The question of genetic linkage between satellite components is not resolved by this study.     

Characterization of a species-specific satellite DNA of Drosophila buzzatii

The pBuM189 satellite DNA family was found to be species specific for Drosophila buzzatii . It consists of slightly AT-rich tandemly arranged repeats with a high copy number in the genome and shows a very high level of intraspecific sequence similarity. pBuM189 repeats cannot be detected in the genomes of closely related species such as Drosophila serido , Drosophila borborema and Drosophila koepferae . The data support the marginal systematic position of D. buzzatii within the buzzatii cluster of the Drosophila repleta group.