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

Studies on the isolated transcriptionally active and inactive chromatin fractions from rat liver nuclei

Using mild sonication, nucleoplasmic, nucleolar, and subnucleolar P-3 and S-3 chromatin fractions are isolated from rat liver nuclei. These fractions differ widely (over 80-fold) from each other in transcriptional activity as measured by the chromatin bound engaged RNA polymerases. Chemical analyses indicate that the active chromatin, e.g. P-3 and nucleolar fractions, are rich in RNA and protein as compared to the inactive chromatin, e.g. nucleoplasmic, and S-3 fractions. However, the DNA base content are all the same, showing 40% GC and 60% AT, including P-3 which is enriched in rDNA. Polyacrylamide gel electrophoresis of the 0.25 N HCl extracted proteins shows that all five histones are present in active chromatin. Additionally, the gel reveals two protein bands, one ahead of histone H2B and another ahead of histone H4, that are diminished or missing from the inactive chromatin. On the other hand, there is a fast moving protein band ahead of H4 in the inactive chromatin that is almost absent in the active chromatin. Transcriptional tests using E. coli RNA polymerase and several synthetic DNA templates of known base content and sequence indicate that the 0.25 N HCl soluble protein extracts from active chromatin contain activator proteins which are capable of countering the histone suppressors present in the extracts in a DNA base and sequence specific manner. The data show that although the histone suppressors are able to strongly inhibit the template function of poly[d(A-T)], the protein activators are able to overcome the suppressor activity and stimulate RNA synthesis several-fold when poly(dA).poly(dT) or poly(dT) is used.

[Structural arrangement of chromatin (author's transl)]

Recent observations and hypotheses on the structure of chromatin are reviewed. Elementary "subunit" for higher structural orders is the nucleosome, consisting of a histone octamer and doublehelical DNA wrapped around it. During the last years details of the nucleosomal structure could be deduced down to a resolution of 2 nm. In the chromatin fiber, built up by (mono-)nucleosomes, the superhelical DNA has a tertiary structure, from which structures of still higher order (quaternary structure of DNA) can be formed. The correlation of these structures to the terms euchromatin and heterochromatin are discussed. Finally, some functional aspects, especially transcription and replication, are discussed in view of the new knowledge of chromatin structure.

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.

Quantitation of transcribing native simian virus 40 minichromosomes extracted from CV1 cells late in infection

Simian virus 40 transcriptional complexes could be extracted from CV1 cells late in infection and separated from the bulk of inactive viral chromatin. Sucrose gradient sedimentation, cesium sulfate equilibrium density gradient centrifugation, and electron microscopy indicated that the viral transcriptional complexes corresponded to at least 0.5 to 1% of the viral minichromosomes extracted, about 5,000 copies per cell.

Distribution of high mobility group and other acid-soluble proteins in fractionated chromatin

Chromatin was fractionated by digestion with deoxyribonuclease II and precipitation with MgCl2. The Mg2+-soluble fraction, known to be enriched in transcribed DNA sequences, was enriched also in high mobility group proteins 1 and 2 and contained almost all other acid-soluble nonhistone proteins.

Enrichment of specific genes from genomic DNA or from clone library DNA, using R-looping

We have developed a procedure for enriching DNA for specific sequences that is based on R-looping (Thomas et al., 1976). R-loops are formed with the DNA using mRNAs containing the sequence of interest and then isolated on poly(U)-sepharose via the poly(A) tail of the mRNA. Model experiments showed that plasmid DNA containing a cDNA copy of an immunoglobulin kappa chain mRNA could be selectively retrieved using this procedure. Approx. 5-10% of the kappa sequences in mouse embryo DNA could be recovered by R-looping, while non-specific binding of mouse DNA to the poly(U)-sepharose column was 0.03-0.04%. This represents a 100-200-fold enrichment of mouse genomic kappa sequences. We have also used the procedure to rapidly screen a mouse clone library for immunoglobulin heavy chain genes. DNA from the clone library was enriched 100-200-fold using immunoglobulin heavy chain mRNAs, and the enriched DNA repackaged in vitro to recover the phage.

Subnuclear fractionation by mild micrococcal-nuclease treatment of nuclei of different transcriptional activities causes a partition of expressed and non-expressed genes

Extremely mild treatment with micrococcal nuclease of isolated nuclei yields subnuclear fractions in which the majority of RNA polymerase II transcriptional complexes formed in vivo are segregated [Tata & Baker (1978) J. Mol. Biol. 118, 249-272]. We now describe different approaches followed to established whether or not the nuclei are thus resolved into transcribed and non-transcribed DNA. First, we have compared the sensitivity to deoxyribonuclease I, which is known to digest preferably expressed genes as present in nuclei or chromatin, of three micrococcal-nuclease-derived fractions from nuclei of different transcriptional activities. In transcriptionally active nuclei (rat liver, hen liver and oviduct, and Xenopus liver), the DNA in a polynucleosomal fraction comprising 6-15% of DNA and the majority of template-engaged RNA polymerase II (fraction P2) was 10-50 times as sensitive to deoxyribonuclease I as the DNA in the other two fractions (fractions P1 and S, comprising 78-88% of total nuclear DNA as large polynucleosomal aggregates and 2-6% of DNA mostly as mononucleosomes, respectively). In transcriptionally inactive nuclei obtained from hen erythrocytes, micrococcal nuclease did not separate DNA into fractions exhibiting such differential sensitivities. Second, we have monitored the partition of an expressed gene. Hybridization of complementary DNA to Xenopus albumin mRNA revealed a 5-10-fold enrichment of the albumin (but not the globin) gene in the P2 fraction of nuclei from Xenopus liver in which this gene is fully expressed. Third, a large part of the nascent rapidly labelled RNA synthesized in vivo in rat liver nuclei was recovered in the micrococcal-nuclease-derived fraction that is more susceptible to digestion with deoxyribonuclease I. It is concluded that mild micrococcal-nuclease treatment of nuclei causes their separation into transcribed and non-transcribed DNA as determined by a number of very different criteria.

Fractionation of native and reconstituted chromatin by digesting with deoxyribonuclease ii

Native and reconstituted chromatin from Ehrlich ascites tumor cells were fractionated into template-active and inactive fractions by the DNAase II/Mg2+-solubility method of Gottesfeld et al. (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). The Mg2+-soluble (template-active) fractions were compared in respect to sedimentation behavior in sucrose gradients and the relative content of specific transcribed (ribosomal) and non-transcribed (satellite) DNA sequences. It was found that the Mg2+-soluble fraction of the native chromatin was enriched in ribosomal DNA while almost completely devoid of satellite DNA; the nucleoprotein monomer of this fraction sedimented in sucrose gradient at 14 S. Similar-results were obtained if chromatin was fractionated in the presence of 3 M urea. With reconstituted chromatin, however, neither the sedimentation profile, nor the relative content of ribosomal and satellite DNA sequences were recovered, thus indicating that reconstitution did not yield nucleoprotein structurally similar to native chromatin.

In vivo binding of N-2-acetylaminofluorene and its N-hydroxy derivative to the DNA of fractionated rat liver chromatin

The in vivo binding of radioactive N-2-acetylaminofluorene (AAF) and N-hydroxy-2-acetylaminofluorene (N-OH-AAF) to the DNA of rat liver chromatin was examined. The chromatin was fractionated into putative transcriptionally active and inactive fractions by hydrodynamic shearing and subsequent glycerol gradient centrifugation, DNAase II digestion followed by MgCl2 aggregation of transcriptionally inactive chromatin, or mild digestion with micrococcal nuclease. Carcinogens were administered for various times prior to sacrifice. Irrespective of the duration of exposure, no preferential binding of either carcinogen to DNA was detected in any of the fractions prepared by hydrodynamic shearing of DNAase II digestion. When micrococcal nuclease was utilized, a 2-fold increase in carcinogen bound to the DNA of that chromatin fraction containing the smallest molecular weight fragments was detected. These small molecular weight fragments produced by micrococcal nuclease have been postulated to be derived from in vivo transcriptional units. Additionally, when DNAase II was used to probe chromatin from rat livers which had been exposed to a carcinogenic regimen of AAF, no preferential binding of radioactive N-OH-AAF to the DNA of any chromatin fraction was detected.

Simple isolation of DNA hydrophobically complexed with presumed gene regulatory proteins (M3)

Chromatin from chicken reticulocytes and mouse Ehrlich ascites tumor cells has been extracted with 2 M NaCl, leaving a portion of the DNA still complexed with a fraction of nonhistones (designated M3, since it can be dissociated from DNA in solutions of 3 M NaCl containing 5 M urea). The DNA complexed with M3, separated from the bulk DNA by centrifugation, was found to contain sequences poorly represented in bulk DNA. Specifically we found that DNA--M3 complexes isolated from chicken reticulocyte chromatin were enriched in globin gene sequences by 20-fold relative to unfractionated DNA and by over 1000-fold relative to DNA rendered free of protein following the extraction of chromatin with 2 M NaCl. We have therefore isolated DNA fractions complexed with M3 which are enriched in specific sequences as may be determined by M3.

Partial purification of transcriptionally active nucleosomes from trout testis cells

Mononucleosomes (MN1) enriched in structural non-histone proteins and transcribed DNA sequences were obtained by limited digestion of trout testis nuclei with micrococcal nuclease followed by selective solubilization in 0.1 M NaCl. These monosomes consist of the four inner histones plus stoichiometric amounts of the non-histone protein H6, of the HMG group, complexed with 140 base pairs of DNA. Hybridization experiments indicate that MN1 DNA is enriched in sequences complementary to cytoplasmic polyadenylated RNA.