Chromatin structure of the histone genes of D. melanogaster

We have examined the chromatin structure of the histone gene repeat of D. melanogaster using an indirect end-labeling technique. Our results show that each DNA segment of the repeat is packaged into a precisely defined and characteristic structure, as follows: the nontranscribed spacers display a "normal" chromatin arrangement, with each nucleosome precisely positioned on the underlying DNA sequence; the 5' ends of all five histone genes are in an exposed configuration, highly sensitive to both micrococcal nuclease and DNAase I; and the genes have an "altered" chromatin structure, as indicated by the weak and irregularly spaced nuclease cuts. This well-defined chromatin arrangement is established early in development and is stably maintained throughout the remainder of the D. melanogaster life cycle.     

The chromatin structure of specific genes: I. Evidence for higher order domains of defined DNA sequence.

When the chromatin of Drosophila is examined by digestion with DNAase I or micrococcal nuclease, no general structural organization above the level of the nucleosome is revealed by the cleavage pattern. In contrast, the DNAase I cleavage pattern of specific regions of the Drosophila chromosome shows discrete bands with sizes ranging from a few kilobase pairs (kb) to more than 20 kb. Visualization of such higher order bands was achieved by the use of the Southern blotting technique. The DNAase I-cleaved fragments were transferred onto a nitrocellulose sheet after size fractionation by gel electrophoresis. Hybridization was then carried out with radioactively labeled cloned fragments of DNA from D. melanogaster. For the five different chromosomal regions examined, each gives a unique pattern of higher order bands on the autoradiogram; the patterns are different for different regions. Restriction enzyme cleavage of the fragments generated indicates that the preferential DNAase I cleavage sites in chromatin are position-specific. The chromosomal regions bounded by preferential DNAase I cleavage sites are referred to as supranucleosomal or higher order domains for purposes of discussion and analysis. The micrococcal nuclease cleavage pattern of chromatin at specific loci was also examined. In the one case studied in detail, this nuclease also cleaves at position-specific sites.     

Regulation of expression and chromosomal subunit conformation of avian retrovirus genomes.

We have investigated the copy number, chromosomal subunit conformation and regulation of expression of integrated avian retrovirus genomes. Our results indicate that there are approximately two copies of the endogenous viral genomes (RAV-O) per haploid cell genome in uninfected chick embryo fibroblasts (CEF) and red blood cells (RBC). The copy number and subunit conformation (as measured by DNAasel sensitivity) of the RAV-O genomes are independent of the level of expression of these viral DNA sequences. In cells isolated from embryos of the V+, gs-chf- and gs+chf+ phenotypes, approximately one of the two viral genomes is in a DNAase l-sensitive conformation. Upon infection with an exogenous Rous sarcoma virus (PR-RSV-C), one new viral genome is integrated per haploid CEF genome. The newly integrated RSV genome is completely sensitive to DNAase l, and the subunit conformation of the endogenous viral genomes is not altered by the integration of additional exogenous proviruses. Both the endogenous and newly integrated exogenous viral genomes are present in "nu-body" structures, and the selective sensitivity of these proviral DNA sequences to DNAase l is maintained in isolated nucleosomes. Our experiments revealing the DNAase l sensitivity of one of the two RAV-O genomes in gs-chf-CEF led us to reexamine the level of viral specific RNA in CEF of various GS genotypes. We find that GS/GS CEF contain approximately 100 copies of viral RNA per cell, gs/gs CEF contain no detectable viral RNA, and the heterozygote GS/gs CEF contain approximately 50 copies of viral specific RNA per cell. These results suggest that the GS gene controls production of RAV-O RNA sequences in CEF in a "cis" fashion. In RBCs, however, the expression of the RAV-O genome is independent of the GS gene, with both GS/GS and gs/gs RBCs containing roughly equivalent amounts of viral specific RNA. Our results suggest that the chromosomal structure of the endogenous viral genes is independent of the GS gene, and that the GS gene is cis-acting and tissue-specific.     

Chromatin structure as probed by nucleases and proteases: Evidence for the central role of hitones H3 and H4

We have examined the role played by each histone in forming the structure of the ν-body. When DNAase I, DNAase II, trypsin, and chymotrypsin attack chromatin, characteristic discrete DNA and protein digest fragments are produced. Using this restriction of accessibility as diagnostic for chromatin structure, we have examined complexes of DNA with virtually all possible combinations of histones. The results strongly support our previous conclusion (Camerini-Otero, Sollner-Webb, and Felsenfeld, 1976) that the arginine-rich histones are unique in their ability to create, with DNA, a structure with many features of native chromatin. Acting together, slightly lysine-rich histones then modify this complex into one very similar to native chromatin. An analysis of the rate constants of staphylococcal nuclease digestion also confirms that the complex of H3, H4, and DNA is crucial to the structure of the ν-body.     

Chromatin structure at the replication origins and transcription-initiation regions of the ribosomal RNA genes of Tetrahymena

The chromatin structure of regulatory regions of the extrachromosomal rRNA genes of Tetrahymena thermophila was probed by nuclease treatment of isolated nuclei. The chromatin near the origins of replication contains hypersensitive sites for micrococcal nuclease, DNAase I, and DNAase II. These sites persist in starved cells, consistent with the origins' being maintained in an altered chromatin structure independent of DNA replication. The region between the two origins of replication is organized into a phased array of seven nucleosomes, the fourth of which is centered at the axis of symmetry of the palindromic rDNA. The entire transcribed region and 150 bp upstream from the initiation site are generally accessible to nucleases; any histone proteins associated with these regions are clearly not in a highly organized nucleosomal array as seen in the central region. Comparison of the chromatin structures of the central spacer of T. thermophila and T. pyriformis rDNA reveals that deletion or insertion of DNA has occurred in increments of 200 bp. This is taken to imply that there are constraints on the evolution of spacer DNA sequences at the level of the nucleosome.     

An altered DNA conformation detected by S1 nuclease occurs at specific regions in active chick globin chromatin

The single-stranded activity of S1-nuclease cleaves globin chromatin in red cell nuclei in specific regions. The cleavages are observed only in tissues in which the globin genes are active, and they "switch" to reflect the switching pattern of globin-gene expression in embryonic and adult red cells. The positions of the S1 cleavages in the beta- and alpha-globin chromatin correspond to the general region of known DNAase I-hypersensitive sites, but can be distinguished in detail. When DNA segments containing these regions are subcloned into pBR322 and the supercoiled molecules are treated with S1, similar sites are cleaved in the purified supercoiled (but not linear) recombinant plasmid DNA. However, the dominant S1 cutting sites are shifted in the plasmid vis-a-vis the chromatin. We believe that some aspect of DNA sequence is translated into an altered DNA structure in chromatin and that it is this altered structure that is recognized by s1 nuclease and possibly by certain chromosomal proteins. Several physical properties reflected in the S1 digestion of supercoiled plasmids suggest a mechanism for generating differences in daughter cells during development.     

Nucleosome structure in Aspergillus nidulans

The structure of chromatin from Aspergillus nidulans was studied using micrococcal nuclease and DNAase I. Limited digestion with micrococcal nuclease revealed a nucleosomal repeat of 154 base pairs for Aspergillus and 198 base pairs for rat liver. With more extensive digestion, both types of chromatin gave a similar quasi-limit product with a prominent fragment at 140 base pairs. The similarity of the two limit digests suggests that the structure of the 140 base pair nucleosome core is conserved. This implies that the difference in nucleosome repeat lengths between Aspergillus and rat liver is caused by a difference in the length of the DNA between two nucleosome cores. Digestion of Aspergillus chromatin with DNAase I produced a pattern of single-stranded fragments at intervals of 10 bases which was similar to that produced from rat liver chromatin.     

Mapping of DNAase I sensitive regions on mitotic chromosomes

We have shown that in fixed mitotic chromosomes from female G. gerbillus cells the inactive X chromosome is distinctly less sensitive to DNAase I than the active X chromosome, as demonstrated by in situ nick translation. These results indicated that the specific chromatin conformation that renders potentially active genes sensitive to DNAase I is maintained in fixed mitotic chromosomes. We increased the sensitivity and accuracy of in situ nick translation using biotinylated dUTP and a specific detection and staining procedure instead of radioactive label and autoradiography and now show that in both human and CHO chromosomes, the DNAase I sensitive and insensitive chromosomal regions form a specific dark and light banding pattern. The DNAase I sensitive dark D-bands usually correspond to the light G-bands, but not all light G-bands are DNAase I sensitive. Identifiable regions of inactive constitutive heterochromatin are in a DNAase I insensitive conformation. Our methodology provides a new and important tool for studying the structural and functional organization of chromosomes.     

Hb switching in chickens

We have taken advantage of the preferential digestion of active genes by DNAase I to investigate the chromosomal structure of embryonic and adult β-globin genes during erythropoiesis in chick embryos, and in particular to examine the question of hemoglobin switching during development. DNA in isolated red cell nuclei was mildly digested with DNAase I to about 10–15 kb, purified and restricted with a variety of restriction enzymes. The DNA was then separated on agarose gels, transferred to nitrocellulose filters and hybridized with an adult-specific β-globin cDNA clone or a genomic clone containing the genes coding for both an embryonic and an adult β-globin chain. Preferential sensitivity of the respective globin genes was monitored by the disappearance of specific restriction bands after DNAase I digestion of nuclei. In embryonic red cells, both adult and embryonic β-globin genes are very sensitive to DNAase I; however, in adult erythroid lines, the embryonic β-globin gene becomes relatively more resistant but the adult gene remains highly sensitive. Controls showed that all globin genes were resistant to DNAase I in brain nuclei and nuclei from lymphoid cells. Thus the switch from embryonic to adult globin expression is associated with an apparent change in the chromosome structure of the embryonic globin gene as reflected in the gene becoming less accessible to DNAase I in adult red cell nuclei. Our results also show that the chromosomal structure of both adult and embryonic genes is altered in embryonic red cell nuclei; thus the nonexpressed globin gene (that is, the adult gene in embryonic red cells) has already been “recognized” to some degree and marked by the erythroid compartment. The sensitivity of the adult globin gene in embryonic cells may represent a “pre-activation” state of the chromosome.     

Correlation between DNase I hypersensitive sites and putative regulatory sequences in human immunoglobulin genes of the kappa light chain type.

The human lymphoid cell lines Walker and Daudi constitute a particularly suitable system for studies on the chromatin structure of K light chain genes (see preceding paper). The rearranged and non-rearranged alleles of Walker cells were found to be about equally sensitive towards digestion with DNAase I. A DNAase I hypersensitive site was mapped 0.13 kb upstream of the leader segment of the rearranged VK genes; it comprises a region in which promoter-like regulatory elements were discovered recently. Additional hypersensitive sites are located further upstream. A hypersensitive site in the JK-CK intron coincides with a putative tissue specific enhancer element. A hypersensitive region down-stream of CK overlaps with the cleavage/polyadenylation recognition signal which is flanked by sequences related to the above mentioned putative regulatory sequences. The coincidence between DNAase I hypersensitive sites and those sequences may be functionally significant.     

Inhibition of HIV derived lentiviral production by TAR RNA binding domain of TAT protein

Background

Retroviruses have a diploid genome and recombine at high frequency. Recombinant proviruses can be generated when two genetically different RNA genomes are packaged into the same retroviral particle. It was shown in several studies that recombinant proviruses could be generated in each round of HIV-1 replication, whereas the recombination rates of SNV and Mo-MuLV are 5 to 10-fold lower. The reason for these differences is not clear. One possibility is that these retroviruses may differ in their ability to copackage genomic RNAs produced at different chromosomal loci.

Results

To investigate whether there is a difference in the efficiency of heterodimer formation when two proviruses have the same or different chromosomal locations, we introduced two different Mo-MuLV-based retroviral vectors into the packaging cell line using either the cotransfection or sequential transfection procedure. The comparative study has shown that the frequency of recombination increased about four-fold when the cotransfection procedure was used. This difference was not associated with possible recombination of retroviral vectors during or after cotransfection and the ratios of retroviral virion RNAs were the same for two variants of transfection.

Conclusions

The results of this study indicate that a mechanism exists to enable the preferential copackaging of Mo-MuLV genomic RNA molecules that are transcribed on the same DNA template. The properties of Mo-MuLV genomic RNAs transport, processing or dimerization might be responsible for this preference. The data presented in this report can be useful when designing methods to study different aspects of replication and recombination of a diploid retroviral genome.