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.     

The small chromatin fragments released by micrococcal nuclease from hepatoma tissue cultured cell nuclei are strongly enriched in coding DNA sequences and are related to an actively transcribed single-stranded DNA fraction

It was shown with the use of specific probes that mild micrococcal nuclease digestion releases from chromatin actively-transcribed genes as small nucleosome oligomers. In the present work we demonstrate that most if not all of the active genes are accessible to the nuclease. It was found that the short released fragments are greatly enriched in transcribed DNA sequences, the most enriched being the dimers of nucleosomes since 35% of their DNA could be hybridized to cytoplasmic RNA. The results of cDNA-DNA hybridizations indicate that the monomers and dimers of nucleosomes contain most of the DNA sequences which encode poly(A⁺) RNAs, however larger released fragments include some transcribed sequences, while the nuclease-resistant chromatin is considerably impoverished in coding sites. These evidences and the finding that about 25% of the DNA from the dimers of nucleosomes are exclusively located in this class of fragments, tend to prove that the active chromatin regions are attacked in a non-random way by micrococcal nuclease. We have previously isolated, without using exogenous nuclease, an actively transcribed genomic fraction amounting to 1.5–2% of the total nuclear DNA, formed of single-stranded DNA. In the present study we show that all or nearly all the single-stranded DNA sequences could be reassociated with the DNA fragments present in the released monomers and dimers of nucleosomes. Our observations confirmed our previous finding that the greatest part of single-stranded DNA selectively originates from the coding strand of genomic DNA.     

Release of a globin gene enriched chromatin fraction from chicken erythrocyte nuclei following DNase II digestion

Mild digestion of chicken erythrocyte nuclei with deoxyribonuclease II results in the release of a chromatin fraction which is 4- to 13-fold enriched for the globin coding sequences when compared to total chicken DNA. The remaining nuclear pellet is depleted in these sequences. A maximum of 25% of the globin genes have been recovered in the released fraction. The addition of 5 mM sodium butyrate to the digestion buffer is required to obtain reproducible globin gene enrichment. The released fraction contains equimolar amounts of the four core histones and a subset of the nonhistone chromosomal proteins. The globin genes are released as large chromatin fragments which exceed the 1.6 kilobase size of the transcribed portion of the gene.     

Sequence composition of the template-active fraction of rat liver chromatin.

Rat liver chromatin has been separated into nuclease-sensitive and -resistant fractions after mild digestion with DNAase II. The nuclease-sensitive material is further fractionated into Mg2+ -soluble and -insoluble chromatin fractions. The kinetics of production of these chromatin fractions have been investigated. After a brief enzyme treatment (5 min at 10 enzyme units/A260 unit of chromatin at pH 6.6), 11% of the input chromatin DNA is found in the Mg2+ -soluble fraction. This DNA has a weight-average single-strand length of about 400 nucleotides and, as determined by renaturation kinetics, comprises a subset of nonrepetitive DNA sequences and a subset of families of middle repetitive sequences. This demonstrates the nonrandom distribution of repetitive and single copy sequences in the Mg2+ -soluble fraction of chromatin. Previous studies have shown that the Mg2+ -soluble fraction is enriched in nonrepeated sequences which are transcribed in vivo (Gottesfeld, J.M., Garrard, W.T., Bagi, G., Wilson, R.F., and Bonner, J. (1974), Proc. Natl. Acad. Sci. U.S.A. 71, 2193-2197). We now report that the Mg2+ -soluble fraction of liver chromatin contains a low proportion of sequences in common with the Mg2+ -soluble fraction of brain chromatin. Thus, fractionation does not depend on some general property of chromatin but is specific with regard to the template activity of the tissue from which the chromatin was obtained.     

Fractionation of chromatin by differential solubility in dilute salt.

Chromatin prepared from the livers of rats was fractionated on the basis of solubility in dilute NaCl. Neither of the fractions obtained was enriched in newly synthesized DNA. The salt-soluble fraction had a higher protein content (usually up to 50%) relative to the DNA, and contained 72% or more of the rapidly synthesized RNA. This RNA was found to be complexed with the salt-soluble deoxyribonucleoprotein, not merely co-solubilized with it. Also, polylysine-binding studies showed that about 70% or more of the nucleic acid phosphates were accessible as compared to about 40% in the unfractionated chromatin. These properties suggested that the soluble fraction was enriched in activity transcribed chromatin. In contrast molecular hybridization studies showed that the complexity of the DNA and its homology with cDNA transcribed from rat-liver polysomal mRNA were the same as those of DNA from unfractionated chromatin, or from the salt-insoluble fraction. This suggests that the criteria commonly accepted as distinguishing between euchromatin and heterochromatin in vitro are not invariably valid.     

Transcription and in vitro processing of yeast 5 S rRNA

A method is described for the isolation of a yeast chromatin fraction highly enriched in ribosomal DNA sequences. In the presence of exogenous yeast RNA polymerase III, this purified chromatin actively synthesizes a set of 5 S ribosomal RNAs all of which have 5'-sequences identical with mature 5 S RNA but which end with a variable number (up to 10) of additional residues at the 3'-terminus. These extra nucleotides are precisely removed by a processing nuclease found in the chromatin supernatant fraction.     

Non-histone proteins of soluble nucleoproteins released from mouse myeloma nuclei by mild micrococcal nuclease digestion

Mono- and dinucleosomes preferentially cleaved from mouse myeloma chromatin by very mild micrococcal nuclease digestion at 0 degree C are soluble and are released from nuclei under near-physiological conditions in which normal nucleosomes containing Hl are insoluble. These nucleosomes are highly enriched in RNA, high-mobility-group proteins and a unique subset of other non-histone proteins. They are nearly devoid of histone Hl and contain DNA significantly less methylated than whole myeloma DNA, indicating that they comprise a subset of genomic sequences. Previously we have shown that this fraction is enriched in transcribed DNA sequences. Non-histone proteins that co-sedimented with readily solubilized nucleosomes included many of the most basic, low-to-moderate molecular weight chromosomal proteins. Many of these proteins were also preferentially acetylated in vivo. The residual, pelleted chromatin was highly enriched in high molecular weight proteins (greater than 60 000), and very depleted in medium molecular weight proteins. Readily solubilized nucleoproteins sedimenting like mononucleosomes were partly resolved by electrophoresis, under non-denaturing conditions, into several subfractions differing significantly in non-histone protein contents. Methods described here should be useful for identifying and isolating non-histone proteins bound to nucleosomes and other chromatin regions that are structurally and functionally unique.     

Lipid peroxidation and the polymerase activities of liver chromatin fractions in rats during aging

Lipids, which enter the composition of actively transcribed and repressed chromatin fractions are found to undergo a peroxidation. This process decreased with aging and more pronounced in actively transcribed chromatin fraction. A decreased activity of DNA polymerase beta and increased activity of RNA polymerase I in this chromatin fraction with aging were observed. It is assumed that observed changes of genome function of old animals may be caused by decreased peroxidation of chromatin lipids.     

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.     

Enrichment for the globin coding region in a chromatin fraction from chick reticulocytes by endonuclease digestion.

A nuclease-sensitive fraction was obtained from chick reticulocyte chromatin by brief digestion with an endonuclease (DNAase II, deoxyribonucleate 3'-oligonucleotidohydrolase, EC 3.1.4.6). The nuclease-sensitive fraction typically contained less than 1% of the chromatin-DNA but about 50% or more of the nascent chromatin-bound RNA. Hybridization of chick globin complementary DNA to the DNA component of the nuclease-sensitive fraction of reticulocyte chromatin indicated a 3--5 fold enrichment for the globin coding region of the chromatin. The control experiment utilizing DNA from a nuclease-sensitive fraction of chick liver chromatin did not show a comparable enrichment for the globin coding region. This suggests that the endonuclease-effected enrichment for the globin coding region in the nuclease-sensitive fraction of reticulocyte chromatin is to some degree specific for structural genes transcribed in reticulocytes.     

Attempted separation of transcriptively active and inactive chromatin by hydroxylapatite thermal chromatography

Chromatin and purified DNA were fractionated by hydroxylapatite thermal chromatography. Fractions of varying thermal stability were tested for the proportions of transcribed sequences and repetitive sequences relative to the unfractionated genome. The first 80--85% of either total chromatin or purified DNA eluted from hydroxylapatite contained the same proportion of hybridizable sequences as total DNA. The remaining 15--20% of chromatin eluting at the highest temperatures was depleted of transcribed sequences. Analysis of the 20% highest melting fraction of purified DNA showed that, while the first two-thirds of this fraction contained the same proportion of transcribed sequences as unfractionated DNA, the last third, comprising about 6% of total DNA, was depleted of active sequences. Although no major differences were detected in nonrepetitive sequence complexity of chromatin fractions, there was a correlation between relative thermal stability and repetitive sequence content in fractions of both chromatin and DNA separated by thermal chromatography. Fragments eluting at higher temperatures contained a greater proportion of repetitive sequences, as indicated by a rapidly renaturing component. Most likely, the latest eluting fractions from both chromatin and purified DNA were enriched for a nontranscribed, highly reiterated, G+C rich satellite component of the chicken genome.