Transcribed and non-transcribed regions of Tetrahymena ribosomal gene chromatin have different accessibilities to micrococcal nuclease

Chromatin states at ribosomal DNA loci

Eukaryotic transcription of ribosomal RNAs (rRNAs) by RNA polymerase I can account for more than half of the total cellular transcripts depending on organism and growth condition. To support this level of expression, eukaryotic rRNA genes are present in multiple copies. Interestingly, these genes co-exist in different chromatin states that may differ significantly in their nucleosome content and generally correlate well with transcriptional activity. Here we review how these chromatin states have been discovered and characterized focusing particularly on their structural protein components. The establishment and maintenance of rRNA gene chromatin states and their impact on rRNA synthesis are discussed. This article is part of a Special Issue entitled: Transcription by Odd Pols.

Characterization of the Euplotes crassus macronuclear rDNA and its potential as a DNA transformation vehicle

We have cloned the macronuclear linear DNA molecule carrying the ribosomal RNA genes from the ciliated protozoan Euplotes crassus. DNA sequence analysis was carried out to locate coding regions and to determine whether sequences that have been mutated to confer antibiotic resistance are conserved in the E. crassus genes. The beginning and end of the primary transcript were mapped. In order to determine whether conserved sequences that might serve as replication origins were present, the 5' and 3' non-coding sequences from E. crassus were compared to the corresponding sequences from the macronuclear linear rDNA molecules from the following euplotid species: Euplotes vannus, Euplotes minuta, Euplotes raikovii and Euplotes rariseta. A DNA transformation construct was made by generating a putative anisomycin resistant mutation along with a mutation generating a restriction site polymorphism. Microinjection of the construct into the developing macronucleus of mated cells resulted in exconjugant cell lines with increased resistance to anisomycin. The injected rDNA with the restriction site polymorphism is detectable in the anisomycin resistant cells and appears to represent a minor fraction of the rDNA.

Regulatory sequences for the amplification and replication of the ribosomal DNA minichromosome in Tetrahymena thermophila

We have analyzed the cis-acting sequences that regulate rRNA gene (rDNA) replication in Tetrahymena thermophila. The macronucleus of this ciliated protozoan contains 9,000 copies of a 21-kbp minichromosome in the form of a palindrome comprising two copies of the rDNA. These are derived from a single chromosomally integrated copy during conjugation through selective amplification and are maintained by replicating once per cell cycle during vegetative growth. We have developed a transformation vector and carried out a deletion analysis to determine the minimal sequences required for replication, amplification, and/or stable maintenance of the rDNA molecule. Using constructs containing progressively longer deletions, we show that only a small portion (approximately 900 bp) of the rDNA is needed for extrachromosomal replication and stable maintenance of this molecule. This core region is very near but does not include the rRNA transcription initiation site or its putative promoter, indicating that replication is not dependent on normal rRNA transcription. It includes two nearly identical nuclease-sensitive domains (D1 and D2), one of which (D1) corresponds to the physical origin of replication determined previously. Deletion of both domains abolishes replication, whereas deletion of either domain allows the molecules to replicate, indicating that only one domain is required. In addition to this core region, we have found several DNA segments, including a tandem array of a 21-nucleotide repeat (type II repeats) and sequences within the rRNA coding region, that play distinctive and important roles in maintaining the rDNA at a high copy number.

Chromosomal proteins of Physarum polycephalum with preferential affinity for the sequence, poly d(A-T).poly d(A-T)

We have identified two novel chromosomal proteins from Physarum polycephalum using a protein blotting DNA-binding assay. A fraction of these proteins was readily released from nuclei by solutions of moderate ionic strength (0.15 N-0.35 M NaCl) or mild nuclease treatment and appear associated with chromatin that is nucleosome-free. A significant proportion of these proteins, however, was not released from nuclei by solutions of high ionic strength (1.6 M NaCl) or treatment with excess nuclease. These results suggest that these chromosomal proteins are distributed between transcriptionally-competent and inert domains of chromatin. Both proteins preferentially and tenaciously bound duplex DNA, especially to the alternating B-DNA conformation displayed by the synthetic sequence, poly d(A-T).poly d(A-T).

The effects of transcription on the nucleosome structure of four Dictyostelium genes

Micrococcal nuclease digestion of Dictyostelium discoideum nuclei from various developmental stages was used to investigate transcription-related changes in the chromatin structure of the coding region of four genes. Gene activity was determined by Northern blotting and nuclear run on experiments. During strong transcription of the developmentally regulated cysteine proteinase I gene, a smear superimposed on a nucleosomal ladder was observed, indicating perturbation of nucleosomal structure was occurring. However, two other developmentally regulated genes, discoidin I and pSC253, showed only slight nucleosome disruption during high levels of transcription. The chromatin structure of a fourth gene (pCZ22) was disrupted throughout development, even at those stages where transcription was greatly reduced. We suggest that although nucleosome structure can be transiently perturbed by the passage of the transcription complex in vivo, the degree of perturbation and the speed with which nucleosomes reassemble is also influenced by the DNA sequence.

In vivo photoreaction of a chiral cobalt complex: DNA cleavage by Co(DIP)3(3+) in mammalian cells

The chiral complex tris (diphenylphenanthroline) cobalt (III) (Co(DIP)3(3+) provides a photoreactive probe for chromatin structure in mammalian cells. The complex, which upon photoactivation cleaves DNA in a conformation-specific fashion in vitro, is shown also to cleave DNA in vivo upon irradiation with ultraviolet light (greater than 300 nm). delta- and lambda-Co (DIP)3(3+) isomers are taken up efficiently into cultured Chinese hamster ovary cells and concentrate within cell nuclei. In the absence of light the complexes are toxic to the cells (10% survival at approximately 300 nM), but after ultraviolet irradiation, the toxicity is markedly (greater than 10-fold) increased. The synergism between irradiation and Co(DIP)3(3+) administration may lie in photoreactions with DNA elicited by the cobalt complex. Alkaline sucrose gradient analysis of DNA from cells exposed to lambda-Co(DIP)3(3+) and irradiation show single-stranded DNA fragmentation under conditions where little cleavage is seen in cells either incubated with lambda-Co(DIP)3(3+) or irradiated with greater than 300 nm A ultraviolet light. Cellular DNA is cleaved with lower efficiency than naked DNA, likely due to decreased accessibility of sites in vivo. Hybridization of fragments obtained from the alkaline sucrose gradients to a probe specific for the amplified dihydrofolate reductase gene reveals a similar distribution of dhfr sequences and total DNA, indicating that the family of conformations recognized by lambda-Co(DIP)3(3+) are dispersed throughout the genome.

Methidiumpropyl-EDTA-iron(II) cleavage of ribosomal DNA chromatin from Dictyostelium discoideum

We have used methidiumpropyl-EDTA-iron(II) [MPE.Fe(II)] in parallel with micrococcal nuclease to investigate the chromatin structure of the extrachromosomal palindrome ribosomal RNA genes of Dictyostelium. Confirming our earlier results with micrococcal nuclease (1,2), MPE.Fe(II) digested the coding region of rapidly transcribing rRNA genes as a smear, indicating the absence or severe disruption of nucleosomes, whereas in slowly transcribing rRNA genes, a nucleosomal ladder was produced. In the central non-transcribed spacer region of the palindrome, MPE.Fe(II) digestion resulted in a normal nucleosomal repeat, whereas micrococcal nuclease gave a complex banding pattern. The difference is attributed to the lower sequence specificity of MPE.Fe(II) compared to micrococcal nuclease. In the terminal region of the palindrome, however, both substances gave a complex chromatin digestion pattern. In this region the DNA appears to be packaged in structures strongly positioned with respect to the underlying DNA sequence.

Psoralen-crosslinking of DNA as a probe for the structure of active nucleolar chromatin

Trimethylpsoralen was used to crosslink the extrachromosomal ribosomal DNA in nucleoli or nuclei of growing Dictyostelium discoideum cells. The DNA was extracted and was examined by spreading under denaturing conditions for electron microscopy. Intact 95,000 base ribosomal DNA molecules were seen, showing regularly spaced, single-stranded bubbles of about 200 to 400 bases in size, interrupted twice by 11,000 base heavily crosslinked stretches, which correspond to the known positions of the coding regions. The bubbles on the nontranscribed regions indicate the presence of nucleosomes during crosslinking. The DNA was digested with restriction enzymes and analysed by gel electrophoresis in parallel with DNA not treated with psoralen. Fragments from the non-coding region had the same mobility as untreated DNA, while those from the coding region had a markedly lower mobility, though not as low as that of crosslinked pure DNA. This shifting of the bands, specific to the coding region, was also seen when whole cells were treated with psoralen. Treatment of nucleoli with 2 m-NaCl (which is known to dissociate histones) before addition of psoralen led to strong crosslinking all along the ribosomal DNA, resulting in a decreased electrophoretic mobility of bands from the non-coding region, but no further retardation of those from the coding region. In differentiating Dictyostelium cells, slugs, where ribosomal RNA synthesis is very much reduced, the extent of psoralen-crosslinking in the coding region was reduced, but not completely to the level of that of the non-transcribed spacer. In order to test whether psoralen itself alters chromatin structure, crosslinked and non-crosslinked nucleoli from growing cells were lysed with heparin and spread for electron microscopy. There was no difference in the appearance or the frequency of the transcription units seen. Digestion of crosslinked nuclei with micrococcal nuclease indicated an undisturbed structure for bulk chromatin, as well as for the chromatin in the non-transcribed spacer of the ribosomal DNA. Thus psoralen-crosslinking does not lead to extensive disruption or distortion of the structure of either inactive or active chromatin. We conclude, taking the results presented in the Appendix into account, that the extent of psoralen-crosslinking in chromatin DNA is diagnostic for the structure of undistorted chromatin.(ABSTRACT TRUNCATED AT 400 WORDS)

Transcriptionally active chromatin

Eukaryotic chromatin has a dynamic, complex hierarchical structure. Active gene transcription takes place on only a small proportion of it at a time. While many workers have tried to characterize active chromatin, we are still far from understanding all the biochemical, morphological and compositional features that distinguish it from inactive nuclear material. Active genes are apparently packaged in an altered nucleosome structure and are associated with domains of chromatin that are less condensed or more open than inactive domains. Active genes are more sensitive to nuclease digestions and probably contain specific nonhistone proteins which may establish and/or maintain the active state. Variant or modified histones as well as altered configurations or modifications of the DNA itself may likewise be involved. Practically nothing is known about the mechanisms that control these nuclear characteristics. However, controlled accessibility to regions of chromatin and specific sequences of DNA may be one of the primary regulatory mechanisms by which higher cells establish potentially active chromatin domains. Another control mechanism may be compartmentalization of active chromatin to certain regions within the nucleus, perhaps to the nuclear matrix. Topological constraints and DNA supercoiling may influence the active regions of chromatin and be involved in eukaryotic genomic functions. Further, the chromatin structure of various DNA regulatory sequences, such as promoters, terminators and enhancers, appears to partially regulate transcriptional activity.

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.

Nucleosome phasing in Tetrahymena macronuclei

Core-protected DNA can drive only 60% of the Tetrahymena thermophila macronuclear genome into duplexes in hybridization experiments. This core-protected DNA therefore contains only a subset of the genome complexity. We interpret this to mean that a large fraction, if not all, of the genome is phased with respect to nucleosome placement. Among the sequences present in total DNA and absent from core-protected DNA are most of the sequences containing N6-methyladenine (MeAde) residues, consistent with our previous demonstration that most of these residues lie in linker DNA. We show that these results are not due to artifacts resulting from the small size of the DNA driver, nor are they due to any sequence preferences exhibited by staphylococcal (staph) nuclease. This is the first evidence that nucleosome phasing may be a bulk genome characteristic.