Adenovirus DNA is associated with the nuclear matrix of infected cells.

Viral DNA was found to be tightly associated with the nuclear matrix from HeLa cells lytically infected with human adenovirus type 5. The bound viral DNA, like cell DNA, was resistant to nonionic detergent and to extraction with high-salt (2 M NaCl) solution. However, whereas over 95% of the cell DNA was recovered in the matrix fraction, the amount of associated viral DNA varied during infection. Throughout the lytic cycle, the amount of matrix-associated adenovirus type 5 DNA increased until it reached a plateau level at 20 to 24 h after infection. At this stage, the matrix-bound DNA represented 87% of the total viral DNA; after this stage, additional newly synthesized viral DNA accumulated as non-matrix-associated DNA. DNase digestion studies revealed that all viral DNA sequences were equally represented in the matrix-bound DNA both early and late in infection; thus, unlike cell DNA, there seem to be no preferred attachment sites on the viral genome. An enrichment of viral DNA relative to cell DNA was found in the matrix-associated DNA after extensive DNase I digestion. This finding, together with an in situ hybridization study, suggests that the viral DNA is more intimately associated with the nuclear matrix than is cell DNA and probably does not exist in extended loops.     

Screening of isolated DNA for sequences released from anchorage sites in nuclear matrix

Isolated chromosomal DNA is associated with polypeptides that are not released from DNA by several methods designed to purify DNA, e.g. treatment with sodium dodecyl sulphate. DNA fragments associated with these very tight DNA/protein complexes show high affinity to nitrocellulose filters in the presence of salt concentrations of 500 mM or greater. Consequently, a fraction of AluI-fragmented native DNA comprising the complexes and 0.2 to 0.3 micron of vicinal DNA can be isolated by one filtration step. This fraction of DNA shows characteristics of residual DNA sequences retained in nuclei after extraction with nucleases and high salt (nuclear matrix). The DNA fragments retained on filters are highly enriched in replicative DNA; and their degree of hybridization with poly(A)+ RNA points to enrichment in actively transcribed sequences. The results support previous work indicating that the very tight DNA/polypeptide complexes co-isolating with DNA under conditions that release other peptide materials from DNA may be anchorage sites of DNA in the nuclear matrix. Moreover, the method described here allows isolation of replicating and actively transcribed DNA sequences directly from isolated total genomic DNA by skipping artefact-prone isolations of the nuclear matrix.     

Identification of a matrix-associated region 5'' of an immunoglobulin heavy chain variable region gene.

In the accompanying report (C. F. Webb, C. Das, S. Eaton, K. Calame, and P. Tucker, Mol. Cell. Biol. 11:5197-5205, 1991), we characterize B-cell-specific protein-DNA interactions at -500 and -200 bp upstream of the mu immunoglobulin heavy chain promoter whose abundances were increased by interleukin-5 plus antigen. Because of the high A + T/G + C ratio of these sequences and the consistent findings by others that enhancer- and promoterlike regions are often located near matrix-associated regions, we asked whether these sequences might also be involved in binding to the nuclear matrix. Indeed, DNA fragments containing the -500 binding site were bound by nuclear matrix proteins. Furthermore, UV cross-linking studies showed that the DNA binding site for interleukin-5-plus-antigen-inducible proteins could also bind to proteins solubilized from the nuclear matrix. Nuclear matrix-associated sequences have also been demonstrated on either side of the intronic immunoglobulin heavy chain enhancer. Our data suggest a topological model by which interactions among proteins bound to the promoter and distal enhancer sequences might occur.     

Chromatin fractionation according to the strength of its matrix bond

Extraction in low salt concentration followed by centrifugation allows rat liver nuclear chromatin to be divided into two fractions: the supernatant chromatin and matrix chromatin. The former fraction contains about 60-70% of initial DNA and about 15% of initial protein along with all five histones, and an insignificant amount of non-histone proteins. RNA synthesis in the matrix chromatin fraction is 2-3 times more intense than that in the original nuclei. The data on gradient centrifugation do not suggest the elongation of RNA molecules synthesized in the matrix fraction. The results obtained as compared with the literature data suggest that the matrix chromatin fraction is enriched with active genes.     

Enrichment of selected active human gene sequences in the placental deoxyribonucleic acid fraction associated with tightly bound nonhistone chromosomal proteins

A DNA fraction which is highly enriched in active gene sequences and tightly associated with a subset of nonhistone chromosomal proteins has been isolated from human placenta. After extraction with 2 M NaCl, placental chromatin was separated into two distinct components by centrifugation. Of the total DNA, approximately 96% (DNA-S) is protein free, while the remaining 4% (DNA-P) is tightly complexed with nonhistone chromosomal proteins. Reassociation studies revealed that the DNA-P fraction was enriched 22-fold in actively transcribed human placental lactogen gene sequences, while the DNA-S fraction was correspondingly depleted 22-fold in these sequences. Approximately 45% of the sequences present in DNA-P (equivalent to 1.8% of the genome) were not present in the DNA-S fraction. Reassociation of nick-translated DNA-P to DNA from a partial digest of DNase I treated nuclei indicated that 27% of the DNA-P sequences were DNAase I sensitive, suggesting they may represent actively transcribed gene sequences. Analysis of the overall sequence organization of DNA-P showed that relative to unfractionated DNA and DNA-S, DNA-P was enriched in single-copy sequences, slightly enriched in the class of middle repetitive sequences from C0t 0.01 to 100 M.s, devoid of the more highly repetitive sequences (C0t less than or equal to 0.01). The distribution of total active placental genes between DNA-P and DNA-S was measured by hybridization with a complementary DNA probe transcribed from total polysomal poly(A+) messenger RNA. We found that 57% of this cDNA probe reassociated to DNA-P and 58% to DNA-S, while 95% reassociated to DNA-P mixed with DNA-S at the observed ratio of 4 to 96, suggesting that the DNA-P fraction contained a different population of active gene sequences than DNA-S. From these results we estimate that approximately 85% of the transcribed sequences appear to be distinctly distributed and equally proportioned between DNA-P and DNA-S, while approximately 15% of the transcribed sequences are common to both fractions. We suggest that the strong affinity of the tightly bound nonhistone chromosomal proteins for the DNA-P fraction indicates a likely role for these proteins in the regulation of gene expression.     

Fractionation of the nuclear matrix. I. Partial separation into matrix protein fibrils and a residual ribonucleoprotein fraction

Isolated rat liver nuclear matrices have been partially separated by means of mild sonication into a matrix protein (matricin) fraction and a residual ribonucleoprotein (RNP) fraction. The initial matricin fraction is composed largely of protein (91.1%) but also contains significant amounts of DNA (8.4%). Reconstruction experiments indicate that this DNA is not the result of the artifactual binding of DNA to the matrix during the extraction procedures. Subsequent treatment with DNase I results in purified matricin composed of greater than 99.5% protein. SDS acrylamide gel electrophoresis of the matrix protein fibrils reveals only three bands: the primary matrix polypeptides of 62,000, 66,000, and 70,000 daltons. Electron microscopy demonstrates a diffuse reticulum with fibrils as thin as 30--50 A and the presence of 80--100-A globular structures. The residual RNP fraction is composed largely of protein (80.1%) and RNA (19.5%), with only traces of DNA (1.1%). Over 98% of the total matrix-associated RNA is recovered in this fraction. SDS acrylamide gel electrophoresis indicates an enrichment in both low and high molecular weight secondary matrix polypeptides, although the 60,000--70,000-dalton polypeptides are present in significant amounts as well. Ultrastructural analysis of the residual RNP fraction reveals distinct electron-dense-staining matrix particles (150--350 A) attached to a fibrous matricin network.     

LINE L1 retrotransposable element is targeted during the initial stages of apoptotic DNA fragmentation

Using a directional cloning strategy, DNA sequence information was obtained corresponding to the site of early radiation-induced apoptotic DNA fragmentation within the human lymphoblastoid cell line TK6. Data were obtained from 88 distinct clones comprising approximately 65 kbp of sequenced material. Analysis of all cloned material showed that sequences in the 10 bp immediately adjacent to the cleavage sites were enriched in short oligoT tracts. The proportion of repetitive DNA within the entire cloned material was found to be within the normal range. However the distribution of Alu and LINE repetitive DNA were biased to positions at or adjacent to the apoptotic cleavage site. In particular, a non-random distribution of five cleavage sites was found clustered within the second ORF of the LINE L1 that partially overlapped with two binding sites for the nuclear matrix-associated protein SATB1. Three other clones, containing alpha satellite elements, were also linked to a DNA matrix binding function. These data indicate that the site of chromatin loop formation at the nuclear matrix may be a specific target for early DNA fragmentation events during apoptosis.     

Isolation and characterization of stable nuclear matrix preparations and associated DNA from avian erythroblasts

A novel procedure for isolation of nuclear matrices from chicken erythroblast cells was elaborated. The influence of variations in the isolation procedure on structural integrity and morphology of nuclear matrices as well as on properties of the nuclear matrix-associated DNA fractions was investigated. The incubation of isolated nuclei in the presence of Cu2+ ions provided significant stabilization of the nuclear matrix. Copper treatment of nuclei did not affect the properties of the nuclear skeleton-associated DNA fraction. In both copper-stabilized as well as unstabilized nuclei, nuclear matrix-attached DNA was digested to the same extent with nucleolytic enzymes, and could be totally removed from nuclear matrices by 2 M NaCl-2 M urea treatment. The fine morphology of the nuclear matrix did not change after extraction of nuclear skeleton-associated DNA fragments. In the presence or absence of copper ions, matrix DNA was found to be qualitatively different compared with total DNA, in particular with respect to the representation of specific repetitive sequences of the chicken beta globin gene domain.     

Structure of transcriptionally-active chromatin subunits.

Rat liver chromatin is organized into regions of DNA which differ in degree of susceptibility to attack by the endonucleases DNase I and DNase II. The most nuclease-sensitive portion of chromatin DNA is enriched in transcribed sequences. This fraction may be separated from the bulk of chromatin by virtue of its solubility in solutions containing 2 mM MgCl2. Both transcribed and nontranscribed regions of chromatin are organized into repeating units of DNA and histone, which appear as 100 A beads in the electron microscope. The length of DNA in the repeat unit is the same for these two classes of chromatin (198 +/- 6 base pairs in rat liver); however, the subunits of active, Mg++-soluble chromatin differ from the nucleosomes of inactive regions of chromatin in several respects. Active subunits are enriched in nascent RNA and nonhistone protein and exhibit higher sedimentation values than the corresponding subunits of inactive chromatin.     

Sub-set characteristics of DNA sequences involved in tight DNA/polypeptide complexes and their homology to nuclear matrix DNA

Polypeptides co-isolating with DNA induce the binding of a fraction of native DNA fragments to nitrocellulose filters. Southern analysis reveals a high intensity of self-hybridization of the DNA sequences retained on nitrocellulose filters. Consistently, the DNA fraction passing the filters shows only weak hybridization when probed with DNA retained on filters. This indicates that the DNA/polypeptide complexes reside on a non-random sub-set of DNA sequences. Moreover, a high degree of homology was found between residual nuclear matrix DNA sequences and the DNA sequences retained on nitrocellulose filters. This indicates that the DNA sequences associated with tightly bound polypeptides originate from sites where the genome is salt-stably anchored in the nuclear matrix.