Buoyant Density and Satellite Composition of DNA of Mouse Heterochromatin

Ten per cent of mouse DNA occurs as a satellite band with a buoyant density lighter than that of the main band¹. This satellite contains highly repetitious DNA^2,3. It has been shown that the amount of satellite is markedly increased in DNA isolated from the heterochromatin fraction of mouse nuclei⁴. Furthermore, in situ hybridization studies have shown that satellite DNA is localized to the pericentromeric heterochromatin of all the mouse chromosomes except the Y^5,6. These observations demonstrate an intimate association between mouse satellite DNA and heterochromatin and they raise the question: is all the DNA from mouse heterochromatin composed of satellite DNA or is a significant portion composed of non-satellite DNA?     

Locations of a Human Satellite DNA in Human Chromosomes

USING techniques for DNA/RNA or DNA/DNA hybridization in situ, Pardue and Gall¹ and Jones² made several significant discoveries on the chromosomal locations of the mouse satellite DNA: (1) this fraction of DNA is found in all chromosomes except the Y, (2) the cytological location of the satellite DNA is limited to the centromeric region of each chromosome and is probably absent in other regions and (3) the centromeric regions of all mouse chromosomes are hetero-chromatic.     

Satellite DNA specific to knob heterochromatin inCucumis metuliferus (Cucurbitaceae)

Buoyant density gradient analysis of nuclear DNA of fourCucumis species showed asymmetric profiles indicating the presence of satellite DNA sequences in the nuclear genome. A highly repeated satellite DNA sequence was isolated from the nuclear genome ofC. metuliferus under neutral CsCl gradients. The satellite DNA constitutes about 4.96% of total nuclear DNA and has 48.06% guanine plus cytosine content. The kinetic complexity of satellite DNA is 150 times smaller than T₄ phage DNA and the base sequence divergence is low.³H-labeled cRNA transcribed from satellite DNA hybridized clearly to six heterochromatic knobs of pachytene chromosomes. The knob heterochromatin can be distinguished by Giemsa C-banding of pachytene chromosomes. Restriction enzyme analysis and Southern blot hybridization indicated that the satellite DNA has a tandem arrangement and predominantly formed two bands of size 210 and 151 base pairs. Absence of knob satellite DNA ofC. metuliferus in the nuclear genomes ofC. melo, C. anguria andC. sativus showed thatC. metuliferus remains isolated within the genusCucumis.     

New Technique for Distinguishing between Human Chromosomes

A GIEMSA staining procedure that preferentially stains centromeric heterochromatin in mouse chromosomes has been described¹. This specificity was observed when fixed preparations were treated with sodium hydroxide to denature the DNA and then incubated in warm saline to allow annealing, in the presence of ³H-labelled single stranded satellite DNA or its complementary RNA. In this way mouse satellite DNA was located in the centromeric heterochromatin^1,2. It is known to consist of highly repetitive sequences³ and to anneal much more rapidly than non-repetitive DNA⁴. It seems probable, therefore, that the darker staining with Giemsa of these regions, after denaturation and annealing, indicates the presence of highly repetitive DNA.     

Nuclear DNA in normal and refed Amoeba proteus

Amoeba proteus synthesizes DNA in G2 phase of the cell cycle upon feeding after starvation. The characteristics of the DNA synthesized in G2 have been studied by microscope photometry of individual Feulgen-stained nuclei and by buoyant density centrifugation of nuclear DNA in CsCl. Amoeba nuclei were found to contain 42.8 pg of DNA. This DNA bands in CsCl at a density of 1.693 g/cm³ with a satellite at 1.714 g/cm³ which makes up 24% of nuclear DNA. DNA from whole cells has an additional non-nuclear satellite at 1.726 g/cm³. When cells are starved and re-fed with food labeled with [³H]thymidine, the DNA synthesized is predominantly the 1.714 satellite. The amount of DNA synthesized in G2 is small since there is no measurable difference in Feulgen dye binding to nuclei of starved vs starved and re-fed cells. The data suggest that refeeding induces a resumption of late S phase DNA synthesis, or the preferential synthesis of specific DNA sequences such as rRNA genes.     

The fluorescence localization of mouse satellite DNA in interphase nuclei

Nuclei from various mouse tissues exhibit a pattern of fluorescence characteristic of the cell type when stained with the fluorescent compound Hoechst 33258. When such preparations are hybridized in situ with ³H-RNA complementary to the A-T rich satellite of mouse, it is clearly seen that only the fluorescent regions of the nuclei contain the satellite DNA. Thus Hoechst 33258 allows the precise localization of satellite DNA at all stages of the mouse cell cycle.     

Separation of satellite DNA chromatin and main band DNA chromatin from mouse brain.

Using restriction endonucleases which preferentially digest mouse main band DNA and leave satellite DNA intact, we have isolated highly purified chromatin fractions containing only mouse satellite or main band DNA. Following the digestion of mouse brain nuclei with EndoR Alu I, main band DNA chromatin is selectively extracted with 10mM Tris, 10mM EDTA. Satellite DNA chromatin is subsequently extracted from the nuclear pellet with Tris-3M urea and further purified on sucrose gradients. Chromatin extracted from digested nuclei with Tris-EDTA contains only main band DNA and has a molecular weight lower than 2 x 10(6). Chromatin fractions obtained from the lower regions of sucrose gradients of the Tris-Urea extracts contain 40--95% satellite DNA and have a molecular weight of 6 to 8 x 10(6). Both the satellite DNA and main band DNA chromatins contain all five histones and have a protein to DNA ratio of 1.3 to 1.     

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.     

High-affinity microtubule protein-higher organism DNA complexes. Many-fold enrichment in repetitive mouse DNA sequences comprised of satellite DNAs

We have examined aspects of the interaction of cycled microtubule protein preparations with ³⁵S-labeled mouse DNA tracer in a competition system with unlabelled competitor E. coli or mouse DNA. The nitrocellulose filter binding assay was used to measure interaction by scintillation counting. DNA molecular weight affected the levels of filter retained ³⁵S-labelled mouse tracer DNA. Filter retention levels increased if ³⁵S-labelled mouse DNA tracer size was increased, and the filter binding level decreased if competitor DNA size was increased. There was a sizeable, reproducible difference in the ³⁵S-labelled mouse DNA tracer binding level of about 1% when E. coli or mouse DNA competitors were compared. Mouse DNA more effectively competed with ³⁵S-labelled mouse DNA for microtubule protein binding than did E. coli DNA, suggesting that a small class of higher-organism DNA sequences interacts very strongly with microtubule protein. From other studies we know this to be the MAP fraction (Marx, K.A. and Denial, T. (1984) in The Molecular Basis of Cancer (Rein, R., ed.), Alan R. Liss, New York, in the press; and Villasante, E., Corces, V.G., Manso-Martinez, R. and Avila, J. (1981) Nucleic Acids Res. 9, 895–908). We find that this difference in competitor DNA strength is qualitatively similar under high-stringency conditions (0.5 M NaCl, high competitor [DNA]) we developed for examining high-affinity complexes. Under high-stringency conditions we isolated 1.2% and 0.6% of ³⁵S-labelled mouse DNA at 4200 and 350 bp respective sizes as nitrocellulose filter bound DNA-protein complexes. At both molecular weights these high-affinity DNA sequences, isolated from the filters, were shown to be significantly enriched in repetitive DNA sequences by S₁ nuclease solution reassociation kinetics. The kinetics are consistent with about a 4-fold mouse satellite DNA enrichment as well as enrichment in other repetitious DNA sequence classes. The high molecular weight filter-bound DNA samples were sedimented to equilibrium in CsCl buoyant density gradients and found to contain primarily mouse satellite DNA density sequences (1.691 g/cm³) with some minor fractions at other density positions (1.670, 1.682, 1.705, 1.740, 1.760 g/cm³) similar to those observed by our laboratory in previous investigations of micrococcal nuclease-resistant chromatin (Marx, K.A. (1977) Biochem. Biophys. Res. Commun. 78, 777–784). That the high-affinity microtubule-bound DNA was some 3–5-fold enriched in mouse satellite sequences was demonstrated by its characteristic BstNI restriction enzyme cleavage pattern     

Absence of satellite DNA synthesis during meiotic prophase in mouse and human spermatocytes

Mouse spermatocytes were labelled in situ with ³H-thymidine at successive stages of meiosis. Isolated mouse as well as human spermatocytes were similarly labelled under in vitro conditions. DNA synthesis was followed either by tracking radioactivities in Cs₂SO₄ gradients or by measuring reassociation kinetics. Mouse satellite DNA and the 3 satellites of human DNA are labelled during S-phase but not during pachytene. In the mouse genome, there is a preferential labelling of regions containing foldbacks (human spermatocytes were not analyzed in this respect). The absence of detectable pachytene synthesis in satellite DNA is consistent with genetic evidence on the absence of crossing-over in constitutive heterochromatin.     

Sequence organization and cytological localization of the minor satellite of mouse.

A complete 120 bp genomic consensus sequence for the mouse minor satellite has been determined from enriched L929 centromeric sequences. The extensive sequence homology existing between the major and minor satellite suggests an evolutionary relationship. Some sequences flanking the minor satellite has also been identified and they provide insight into centromeric DNA organization. Isotopic in situ hybridization analysis of the minor satellite to mouse L929 and Mus musculus metaphase spreads showed that this repetitive DNA class is localized specifically to centromeres of all chromosomes of the karyotype. With the use of high resolution non-isotopic fluorescence in situ hybridization the minor satellite is further localized to the outer surface of the centromere in a discrete region at or immediately adjacent to the kinetochore. Our cytological data suggests that the minor satellite might play a role in the organization of the kinetochore region rather than, as previously suggested, sites for general anchoring of the genome to the nuclear matrix.     

Composition and synthesis of DNA in synchronously growing cells of Chlorella pyrenoidosa

Summary The composition and synthesis of DNA in synchronous cultures of Chlorella pyrenoidosa strain 211/8b has been investigated. Analytical CsCl density gradient centrifugation gave a homogenous major DNA component with a (G+C) content of 51% and a minor component containing 28% (G+C). The (G+C) contents derived from melting profiles were 2–3% lower. A second minor component with approximately 41% (G+C) content was inferred from banding patterns of labelled DNA in preparative CsCl density gradients. ¹⁴C-uracil was readily incorporated into the pyrimidine moieties of the major (nuclear) DNA between the 10th and 18th hour after beginning of the light period, but not at any other time. ¹⁴C-uracil incorporation into the minor (satellite) component was low but continuous throughout the whole cell cycle. The incorporation is correlated with an increase in the proportion of satellite DNA from 6% up to 20% during the time when no nuclear DNA replication takes place. The results suggest that different regulatory mechanisms exist for the nuclear and for satellite DNA synthesis.     

The interphase distribution of satellite DNA-containing heterochromatin in mouse nuclei

The distribution of sites capable of binding mouse satellite-complementary RNA in the cytological hybridization reaction has been examined in mouse liver and testis interphase nuclei. The approach taken has been to combine hybridization with semi-thin sectioning and autoradiography in order to obtain a clear picture of the relationship of satellite DNA-containing structures to the rest of the interphase nucleus. In liver nuclei, hybridization occurs primarily with blocks of heterochromatin associated with the nuclear envelope. The most prominent of these, in terms both of size and intensity of hybridization, is the nucleolar stalk and the rest of the nucleolus-associated heterochromatin. The nucleolar body itself is not labeled, nor is much of the peripheral condensed chromatin ; in fact, a polarized distribution of satellite DNA is evident. In Sertoli and spematid nuclei, satellite DNA is found in a small number of large heterochromatin blocks with which the nucleolus is associated; some of this material bears a relationship to the nuclear envelope in these cells also.     

Deoxyribonucleic acid of the crab Cancer pagurus : III. Intracellular localization of poly d(A---T) of Cancer pagurus by hybridization in situ

The satellite DNA poly [d(A---T) · d(T---A)] of the crab Cancer pagurus has been localized in situ by DNA-DNA hybridization in the nuclei of various spermatogenetic, midgut gland, intestinal and tegument cells. The specificity of hybridization was checked by various tests before, during and after hybridization. The nuclear sites revealed by this method were compared with those shown by quinacrine mustard or Giemsa staining. The A---T-rich satellite DNA appears to be highly dispersed and does not seem to have any preferential localization inside the crab interphasic nucleus. This situation was compared with that presented by mouse nuclei using similar methods.     

Modifications in major satellite methylation in the nucleus of a two-cell mouse embryo with respect to developmental conditions

A study was conducted of the degree of DNA methylation in the nucleus, in particular, of the major satellite in two-cell mouse embryos developing in the maternal organism, in standard culture medium M16, used for cultivating mouse embryos; and M2 media used for manipulating embryos in air. Two-cell embryo nuclei at 44–46 h after injections of chorionic hormone were investigated. The results are evidence for the dependence of the major satellite’s methylation level on the developmental conditions of embryos. The methylation level of the nuclear DNA was shown to increase with a deterioration of environmental conditions. It was reported that in the case of cultivation in M2 media unsuitable for long cultivation, the DNAís methylation level, the major satellite in particular, was higher compared to other embryo groups. Accordingly, not only a significant number of genes but also sequences of satellite DNA are involved in epigenetic regulation.     

Deoxyribonucleic acid of the crab Cancer pagurus. 3. Intracellular localization of poly d(A-T) of Cancer pagurus by hybridization in situ

The satellite DNA poly [d(AT) · d(TA)] of the crab Cancer pagurus has been localized in situ by DNA-DNA hybridization in the nuclei of various spermatogenetic, midgut gland, intestinal and tegument cells. The specificity of hybridization was checked by various tests before, during and after hybridization. The nuclear sites revealed by this method were compared with those shown by quinacrine mustard or Giemsa staining. The AT-rich satellite DNA appears to be highly dispersed and does not seem to have any preferential localization inside the crab interphasic nucleus. This situation was compared with that presented by mouse nuclei using similar methods.