Different nucleosome structures on transcribing and nontranscribing ribosomal gene sequences

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.

Assembly into chromatin and subtype-specific transcriptional effects of exogenous linker histones directly introduced into a living Physarum cell

The apparent diversity of linker histone subtypes may be related to their specific roles in defining functional states of chromatin in vivo. We have developed a novel method to study constitutive peptides throughout the cell cycle and have demonstrated that an exogenous linker histone could be introduced into a living cell of the slime mold Physarum polycephalum. Here, we have used this method to assess the functional differences between three somatic linker histone subtypes in vivo, and to demonstrate the general applicability of this method. Exogenous linker histone proteins H1 degrees, H5 and H1 were directly absorbed into living cell segments of the naturally synchronous Physarum macroplasmodia at precise cell cycle stages. Fluorescence microscopy, native nucleoprotein gels and immunoblotting of nuclei and chromatin with subtype-specific antibodies revealed that exogenous linker histones were efficiently transported into nuclei and were integrated into chromatin. The immunoreactivity of a preparation of anti-H1 degrees antibodies that are blocked from binding to specific H1 degrees epitopes in native chromatin indicates that the exogenous linker histones were similarly associated into Physarum chromatin. Interestingly, linker histones were found to be less stably associated with Physarum chromatin during S-phase than during G(2)-phase. Furthermore, we show that exogenous linker histones incorporated in early G(2)-phase inhibited transcription and that the level of inhibition correlates with the apparent role of the linker histone subtype in regulating transcription in cells where it normally occurs.

Dynamics of the interactions of histones H2A,H2B and H3,H4 with torsionally stressed DNA

The interactions of histones H2A,H2B and H3,H4 with closed circular DNA maintained in either a positively or negatively coiled state have been studied. The interactions were assayed by measuring the rate at which negative stress was stored in the DNA by the histones and by the salt concentration sufficient to cause dissociation on sucrose gradients. Additional experiments were performed in which DNAs of substantially different molecular weights and opposite topological states were mixed with the histones in order to study histone mobility under varied conditions. This mobility was characterized by separating the complexes on sucrose gradients and by analyzing the DNA's topological state after topoisomerase I treatment. Histones H3,H4 were found to differ substantially from histones H2A,H2B with regard to the DNA topology with which they prefer to interact. The results are consistent with a model in which transcription-induced positive stress in advance of the RNA polymerase unfolds the nucleosome to facilitate the release of H2A,H2B. The data are also consistent with a model in which histones H3,H4 remain associated with the DNA during polymerase passage and serve as a nucleation site for the reassociation of H2A,H2B. The rapid production of transcription-induced negative stress in the wake of a polymerase would have substantial importance in facilitating the reassociation of histones H2A,H2B.

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).

Binding of histones to Xenopus laevis ribosomal genes with different levels of expression

The association of ribosomal RNA genes with histones as a function of their expression has been studied in Xenopus laevis erythrocytes, where the genes are silent, and tadpoles at stage 40, where these genes are actively transcribed. Isolated nuclei were either treated with formaldehyde or irradiated with an ultraviolet laser to cross-link proteins to DNA. The covalently linked protein-DNA complexes were purified by centrifugation through CsCl and immunoprecipitated with antibodies against H1, H2A and H4. DNA from the precipitated complexes was analysed for the presence of ribosomal DNA sequences by hybridization to specific probes. The actively transcribed ribosomal genes from X. laevis embryos are associated with H1, H2A and H4 as are the non-transcribed genes in the erythrocytes.

Mapping protein-DNA interactions in vivo with formaldehyde: evidence that histone H4 is retained on a highly transcribed gene

We have used formaldehyde-mediated protein-DNA crosslinking within intact cells to examine the in vivo chromatin structure of the D. melanogaster heat shock protein 70 (hsp70) genes. In agreement with previous in vitro studies, we find that the heat shock-mediated transcriptional induction of the hsp70 genes perturbs their chromatin structure, resulting in fewer protein-DNA contacts crosslinkable in vivo by formaldehyde. However, contrary to earlier in vitro evidence that histones may be absent from actively transcribed genes, we show directly, by immunoprecipitation of in vivo-crosslinked chromatin fragments, that at least histone H4 remains bound to hsp70 DNA in vivo, irrespective of its rate of transcription. The formaldehyde-based in vivo mapping techniques described in this work are generally applicable, and can be used both to probe protein-DNA interactions within specific genes and to determine the genomic location of specific chromosomal proteins.

Two-dimensional gel analysis of repetitive nuclear DNA sequences in the genome of Physarum polycephalum. Developmental regulation of the ribosomal gene number

The composition of repetitive sequences in restriction patterns of nuclear DNA of Physarum polycephalum was determined by high-resolution gel analysis. Three types of repeated DNA fragments in the size range of (0.2-2) X 10(3) base pairs could be identified as discrete spots on the gels and distinguished by their abundance and above-average base composition of either guanine and cytosine (G + C) or adenine and thymidine (A + T). On comparing the DNA composition from exponentially growing plasmodia with that of starved plasmodia, which have become competent to sporulate and have lost 80% of their nuclei, no change was detected among the (A + T)-rich repeat fractions, whereas several of the (G + C)-rich fractions revealed fewer copies in the DNA prepared from starved cells. As shown by hybridization under saturating conditions, the reduction of several (G + C)-rich repeated sequences in the restricted nuclear DNA in sporulation-competent cells can be explained by a 64% elimination of the extrachromosomal nucleolar ribosomal DNA sequences.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Lack of nucleosomal structure in a DNase-I-solubilized transcriptionally active chromatin fraction of Physarum polycephalum

Light treatment of nuclei of Physarum polycephalum microplasmodia with DNase I, at low MgCl2 concentration (less than or equal to 3% DNA acid solubility, 0.1 mM MgCl2) selectively solubilizes a defined fraction of chromatin, in the form of a macromolecular complex. This fraction (up to 15% of the total chromatin) contains a full complement of the core histones and a reduced amount of histone H1, and is enriched in the high-mobility-group type of proteins. It is preferentially associated with nascent RNA and RNA polymerase B actively engaged in transcription. Digestion of DNAase-I-solubilized chromatin by micrococcal nuclease releases a size-heterogeneous population of cleavage products, indicative of lack of a typical nucleosomal packaging. It is concluded that the procedure used allows the isolation of structurally and functionally distinct regions of Physarum chromatin.

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.

5-Methyldeoxycytidine in the Physarum minichromosome containing the ribosomal RNA genes

5-Methyldeoxycytidine (5MC) was analyzed by high pressure liquid chromatography (HPLC) and by restriction enzyme digestion in rDNA isolated from Physarum polycephalum. rDNA from Physarum M3C strain microplasmodia has a significant 5MC content (about half that of the whole genomic DNA). This rDNA contains many C5MCGG sites because it is clearly digested further by Msp I than by Hpa II. However, most 5MC is in other sites. In particular, alternating CG sequences appear to be highly methylated. HPLC of deoxyribonucleosides shows tha most of the transcribed regions contain little or no 5MC. Restriction digestion indicates that there is little or no 5MC in any of the transcribed regions including the transcription origin and adjacent sequences. Over 90% of the total 5MC is in or near the central nontranscribed spacer and most methylated restriction sites are in inverted repeats of this spacer. rDNA is very heterogeneous with respect to 5MC. The 5MC pattern doesn't appear to change with inactivation of the rRNA genes during reversible differentiation from microplasmodia (growing) to microsclerotia (dormant), showing that inactivation is due to changes in other chromatin variables. The 5MC pattern is different between Physarum strains. The possible involvement of this 5MC in rDNA chromatin structure and in cruciform and Z-DNA formation is discussed.

Reversible changes in nucleosome structure and histone H3 accessibility in transcriptionally active and inactive states of rDNA chromatin

The sulfhydryl reagent iodoacetamidofluorescein (IAF) was used to probe the structure of chromatin subunits in transcribed and nontranscribed regions of Physarum rDNA. IAF labels histone H3 -SH groups in the elongated monomeric subunits (A particles) from the transcribed region, but it does not label H3 in the 11S monomers from the nontranscribed central spacer. All H3 reactivity is lost from rDNA chromatin in the inactive spherule stage of Physarum. Restriction cleavage of rDNA chromatin generates fragments from the transcription unit with reactive H3 -SH groups, whereas fragments containing nontranscribed spacer sequences are unreactive. The extended rDNA chromatin contains all four core histones and other prominent proteins. Electron microscopy shows that most of the extended subunits consist of two roughly spherical bodies connected by a 50 bp nucleoprotein bridge.

Chromatin structure along the ribosomal DNA of Dictyostelium. Regional differences and changes accompanying cell differentiation

The ribosomal genes of Dictyostelium discoideum are extrachromosomal palindromic DNA molecules situated in the nucleolus. Each molecule comprises ribosomal RNA coding regions and non-transcribed spacer regions. We used both biochemical and electron microscopic approaches to investigate the structure of transcribing and non-transcribing chromatin. Nucleoli from exponentially growing cells were digested with micrococcal nuclease, and the resulting DNA fragments were separated by gel electrophoresis and transferred to DBM paper. They were hybridized with cloned EcoRI fragments derived from different parts of the ribosomal gene. Probes of the coding region showed a smear, while probes of the non-transcribed regions gave pronounced banding patterns more complex than typical nucleosome repeats, but not due solely to sequence-specific cutting by micrococcal nuclease. The DNA of the coding region was digested more quickly than that of the non-transcribed ones. When nucleoli were digested with restriction enzymes, sites within the coding region were accessible and sites in the non-transcribed region were protected. The structure of ribosomal chromatin in differentiating cells, in which the rate of ribosomal RNA synthesis is reduced, was examined using essentially the same methods. The coding region, probed by hybridization to micrococcal digests, then showed a typical DNA repeat pattern indicating that this region had become condensed into nucleosomes, and its accessibility to restriction enzymes was very much reduced. On electron micrographs of lysed nucleoli from exponentially growing cells, two types of chromatin were observed, one with a beaded nucleosomal appearance, the other with putative RNA polymerase molecules attached to fibres indistinguishable from free DNA adsorbed to the same grid. The combined results suggest that whereas regions that are not transcribed are packaged with proteins that protect them from nuclease digestion, actively transcribing ribosomal genes are associated with few macromolecular constituents apart from those required for transcription and its regulation.

Different nucleosome spacing in transcribed and non-transcribed regions of the ribosomal RNA gene in Tetrahymena thermophila

The chromatin structure of the palindromic macronuclear ribosomal RNA genes of Tetrahymena thermophila was probed with micrococcal nuclease. Independent of the state of transcriptional activity, the transcribed region had a shorter nucleosome repeat (184 +/- 3 base pairs) than the non-transcribed central spacer or bulk chromatin (both 200 base pairs). The transcribed region displayed an increased sensitivity to micrococcal nuclease in rapidly growing cells, which suggested an altered chromatin structure during transcription. At early stages of nuclease digestion, the central spacer appeared to be in a highly structured nucleosomal array. Based on the differences in nucleosome repeat distance and sensitivity to nuclease, we conclude that quite different chromatin structures are maintained in two adjacent regions of the Tetrahymena ribosomal RNA gene. The DNA of the non-transcribed terminal spacer was found to contain sequences which are highly susceptible to micrococcal nuclease, precluding any conclusions about nucleosome structure in this region.

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

DNA renaturation kinetics was used to examine the relative accessibility of various regions of the Tetrahymena ribosomal RNA gene (rDNA) chromatin to micrococcal nuclease. In nuclei from cells active in rRNA transcription, the transcribed region of the rDNA chromatin was as much as 5-fold more accessible than the average of the total chromatin. As few as 20% inactive genes in the population could have accounted for all of the hybridization, so the transcribed region of the active units may be totally unprotected from nuclease degradation. The terminal non-transcribed spacer downstream from the transcription unit was also preferentially digested, but to a smaller degree. The central non-transcribed spacer was degraded to the same extent as total chromatin after a high degree of nuclease digestion. In nuclei from starved cells, which have 96% reduced rRNA transcription, the transcribed and terminal spacer regions of the rDNA were again more accessible than the total chromatin from the same nuclei, but the difference did not exceed 2-fold. We conclude that transcriptional activation is accompanied by major changes in the structure of the ribosomal gene chromatin, and that the extent and/or type of structural alteration differs in each functionally defined region of the rDNA.

Sequence and hairpin structure of an inverted repeat series at termini of the Physarum extrachromosomal rDNA molecule

The termini of the 61 kb palindromic rDNA molecules of Physarum polycephalum possess a series of multiple inverted repeats in which are located specific single-strand gaps and tightly attached protein. After treating rDNA with S1 nuclease, we have cloned several 5 kb Eco RI terminal restriction fragments. Sequencing of more than 800 nucleotides from the end of one such clone reveals the presence of six to ten tandemly repeated units averaging 140 +/- 4 bp in length and flanked by Hae III sites. Each 140 nucleotide repeat unit can form thermodynamically stable hairpin structures based on complex internal palindromic components. When the specific gap sequence CCCTA is present, it is located near the apex of a hairpin component. These secondary structures are formed in growing plasmodia, as seen in electron micrographs of native rDNA molecules, which also reveal apparent recombination forms involving rDNA ends and noncontiguous DNA segments. Recombination initiated at terminal single-strand hairpin loops can result in genetic exchange of ribosomal gene sequences and can lead to completion of 5' nucleotide sequences at ends of newly replicated rDNA molecules.

Nucleosomal particles open as the histone core becomes hyperacetylated

Lymphoblastoid cells grown in the presence of the deacetylase inhibitor butyrate were used to isolate nucleosomal particles in a hyperacetylated state. During a non-denaturing gel electrophoresis these particles revealed a heterogeneity which is only in part due to the presence of nonhistone proteins. Monomers that are free from histone H1 and high-mobility-group (HMG) proteins 14 and 17 yield a subfractionation according to the degree of core histone acetylation beyond a limiting value of 10 acetyl groups/particle. It is shown that hyperacetylation provides particles with low mobilities and a considerable conformational freedom in contrast to HMG protein 14 which locks them in a conformation that has a similar electrophoretic behaviour but is more defined.

Isolation, identification, and characterization of histones from plasmodia of the true slime mold Physarum polycephalum using extraction with guanidine hydrochloride

Histones from plasmodia of the true slime mold Physarum polycephalum have been prepared free of slime by an approach to histone isolation that uses extraction of nuclei with 40% guanidine hydrochloride and chromatography of the extract on Bio-Rex 70. This procedure followed by chromatography or electrophoresis has been used to obtain pure fractions of histones from Physarum microplasmodia. Physarum microplasmodia have five major histone fractions, and we show by amino acid analysis, apparent molecular weight on three gel systems containing sodium dodecyl sulfate, mobility on gels containing Triton X-100, and other characterizations that these fractions are analogous to mammalian histones H1, H2A, H2B, H3, and H4. Significant differences between Physarum and mammalian histones are noted, with histone H1 showing by far the greatest variation. Histones H1 and H4 from Physarum microplasmodia have similar, but not identical, products of partial chymotryptic digestion compared with those of calf thymus histones H1 and H4. Labeling experiments, in vivo, showed that histone H1 is the major phosphorylated histone and approximately 15 separate phosphopeptides are present in a tryptic digest of Physarum histone H1. The core histones from Physarum, histones H2A, H2B, H3, and H4, are rapidly acetylated; histone H4 shows five subfractions, analogous to the five subfractions of mammalian histone H4 (containing zero to four acetyllysine residues per molecule); histone H3 has a more complex pattern that we interpret as zero to four acetyllysine residues on each of two sequence variants of histone H3; histones H2A and H2B show less heterogeneity. Overall, the data show that Physarum microplasmodia have a set of histones that is closely analogous to mammalian histones.

Accessibility of ribosomal genes to trimethyl psoralen in nuclei of Physarum polycephalum

We have probed the accessibility of the genes for rRNA in Physarum polycephalum by using the photoreactive DNA cross-linking agent 4,5',8-trimethyl psoralen. Nuclei isolated from actively growing Physarum were treated with trimethyl psoralen and irradiated with 360-nm light in order to form cross-links. The palindromic, extrachromosomal rDNA then was isolated, and the positions of cross-links were determined by electron microscopy of the DNA under totally denaturing conditions. The results indicate that the frequency of cross-linking, after correction for base sequence bias of the reaction, is up to sixfold higher in the transcribed regions than in the central or the terminal spacer regions. There is no detectable heterogeneity among the different rDNA molecules or between the halves of a single molecule. Cross-linked molecules invariably occur in a linear as opposed to a cruciform structure. The preferential cross-linking of the transcribed region is nearly eliminated in spherules, a dormant transcriptionally inactive form in the Physarum life cycle.

Ultrastructural organization of yeast chromatin

The ultrastructural organization of yeast chromatin was examined in Miller spread preparations of samples prepared from spheroplasts or isolated nuclei of Saccharomyces cerevisiae. Micrographs from preparations dispersed in 1 mM Tris (pH 7.2) illustrate that the basic chromatin fiber in yeast exists in two ultrastructurally distinct conformations. The majority (up to 95%) of the chromatin displays a beaded nucleosomal organization, although adjacent nucleosomes are separated by internucleosomal linkers of variable lengths. Ribonucleoprotein (RNP) fibrils are only occasionally associated with chromatin displaying the conformation. The remaining 5-10% of the chromatin appears to be devoid of discrete nucleosomes and has a smooth contour with a fiber diameter of 30-40 A. Transcriptional units, including putative ribosomal precursor RNA genes, defined by the presence of nascent RNP fibrils are restricted to chromatin displaying this smooth morphology. Chromatin released from nuclei in the presence of 5 mM Mg++ displays higher-order chromatin fibers, 200-300 A in diameter, these fibers appear to be arranged in a manner than reflects the two forms of the basic chromatin fiber.

Accessibility of ribosomal genes to trimethyl psoralen in nuclei of Physarum polycephalum

We have probed the accessibility of the genes for rRNA in Physarum polycephalum by using the photoreactive DNA cross-linking agent 4,5',8-trimethyl psoralen. Nuclei isolated from actively growing Physarum were treated with trimethyl psoralen and irradiated with 360-nm light in order to form cross-links. The palindromic, extrachromosomal rDNA then was isolated, and the positions of cross-links were determined by electron microscopy of the DNA under totally denaturing conditions. The results indicate that the frequency of cross-linking, after correction for base sequence bias of the reaction, is up to sixfold higher in the transcribed regions than in the central or the terminal spacer regions. There is no detectable heterogeneity among the different rDNA molecules or between the halves of a single molecule. Cross-linked molecules invariably occur in a linear as opposed to a cruciform structure. The preferential cross-linking of the transcribed region is nearly eliminated in spherules, a dormant transcriptionally inactive form in the Physarum life cycle.

Modifications of chromatin structure in control of gene expression

Repetitive sequences in intron and spacer DNA could be sites for binding of chromosomal proteins which maintain chromatin structure and control gene activity. Methylation of DNA guides the binding of acidic nonhistone proteins and maintains the differentiation state during DNA replication. Differentiation inducers modify repressor proteins permitting unfolding of chromatin. Histone H 1 must be removed for gene activity. Phosphorylation of nonhistone proteins probably induces allosteric modifications which permit unfolding of chromatin. Acetylation of nucleosomal histones is necessary to permit passage of RNA polymerase. Deacetylation quickly returns the gene to a normal histone repressed state. Chromosomal RNA attached to nonhistone proteins aids the binding of RNA polymerase to the DNA template. Carcinogens can disrupt normal gene control leading to circumvention of normal cell cycle controls.

Different chromatin structures in Physarum polycephalum: a special form of transcriptionally active chromatin devoid of nucleosomal particles

Nonnucleolar chromatin from interphase nuclei of Physarum polycephalum plasmodia occurs in two different structural configurations as seen in electron microscopic spread preparations. While the majority of the chromatin is devoid of nascent ribonucleoprotein (RNP) fibrils and compacted into nucleosomal particles, a minor proportion (10-20%) is organized differently and reveals a smooth contour. It is this form of smooth chromatin which is rich in transcription units (mean length: 1.36 +/- 0.21 micrometer). Only occasionally are solitary nascent RNP fibrils observed which are associated with beaded strands of chromatin. In transcribed smooth chromatin nucleosomal particles are not only absent from the transcription units but also from their nontranscribed flanking regions, indicating that this special structural aspect is not merely a direct consequence of the transcriptional process. The existence of ca. 10-20% of Physarum chromatin in the smoothly contoured form is discussed in relation to reports of a preferential digestibility of a similar proportion of Physarum chromatin by DNAse I (Jalouzot et al., 1980) and to the altered configuration of "peak A" chromatin subunits after micrococcal nuclease digestion (Johnson et al., 1978 a, b).

Nuclease-sensitive regions on the extrachromosomal r-chromatin from Tetrahymena pyriformis

The extrachromosomal DNA coding for the ribosomal precursor in Tetrahymena contains a transcribed region with a size of 6 x 10(3) base pairs plus non-transcribed central and distal spacers. In the present study the chromatin structure of the transcribed region and the terminal spacer have been compared. Micrococcal nuclease and DNase I were used to investigate the nucleosomal and the higher order structures. The specific DNA fragments were visualized by gel electrophoresis, Southern blotting onto nitrocellulose sheets and hybridization with specific 32P-labelled RNA probes. Investigations of the cleavage patterns demonstrate the presence of a defined nucleosomal structure in the non-transcribed region, while there is no indication of a nucleosomal pattern in the transcribed region. Specific regions on the r-chromatin are hypersensitive to DNase I. The first cleavage occurs in the non-transcribed central spacer region, while the second cleavage takes place in a region near the 3' end. The hypersensitivity of the central part of r-chromatin is also found by autodigestion in isolated nucleoli.

A family of inverted repeat sequences and specific single-strand gaps at the termini of the Physarum rDNA palindrome

Ribosomal genes of Physarum polycephalum are located on multiple copies of an extrachromosomal, 61 kb rDNA palindrome. Each terminus of the palindrome consists of a nontranscribed spacer, averaging 5.4 kb in length, which includes a region of multiple inverted repeat sequences. Electron microscopy of denatured and reannealed termini reveals foldback segments that are multiples of a unit length of 50 bp, a length confirmed by sizing of restriction fragments from labeled termini. The total length of this inverted repeat region averages 600 bp per terminus, and the region is centered approximately 4 kb from the 3' end of the 26S gene. Restriction fragments containing the termini are heterogeneous, varying in length by +/- 400 bp. This heterogeneity is due to variability in both the number of 100 bp inverted repeats and the length of additional terminal spacer sequences. The inverted repeat region contains selectively located single-strand discontinuities as revealed by brief incubation with deoxynucleoside alpha-32P-triphosphates and E. coli DNA polymerase I (nick translation). Labelling at the discontinuities begins specifically with the sequence CCCTA. Discontinuities are nonligatable and are most likely gaps one nucleotide long. Each terminus contains 3 to 5 such gaps spaced approximately 200 bp apart. As measured by hybridization with selectively labeled foldback DNA, sequences homologous to the inverted repeats are widely distributed throughout chromosomal DNA.