Cell compartmentalisation in planctomycetes: novel types of structural organisation for the bacterial cell

The organisation of cells of the planctomycete species Pirellula marina, Isosphaera pallida, Gemmata obscuriglobus, Planctomyces maris and "Candidatus Brocadia anammoxidans" was investigated based on ultrastructure derived from thin-sections of cryosubstituted cells, freeze-fracture replicas, and in the case of Gemmata obscuriglobus and Pirellula marina, computer-aided 3-D reconstructions from serial sections of cryosubstituted cells. All planctomycete cells display a peripheral ribosome-free region, termed here the paryphoplasm, surrounding the perimeter of the cell, and an interior region including any nucleoid regions as well as ribosome-like particles, bounded by a single intracytoplasmic membrane (ICM), and termed the pirellulosome in Pirellula species. Immunogold labelling and RNase-gold cytochemistry indicates that in planctomycetes all the cell DNA is contained wholly within the interior region bounded by the ICM, and the paryphoplasm contains no DNA but at least some of the cell's RNA. The ICM in Isosphaera pallida and Planctomyces maris is invaginated such that the paryphoplasm forms a major portion of the cell interior in sections, but in other planctomycetes it remains as a peripheral zone. In the anaerobic ammonium-oxidising ("anammox" process) chemoautotroph "Candidatus Brocadia anammoxidans" the interior region bounded by ICM contains a further internal single-membrane-bounded region, the anammoxosome. In Gemmata obscuriglobus, the interior ICM-bounded region contains the nuclear body, a double-membrane-bounded region containing the cell's nucleoid and all genomic DNA in addition to some RNA. Shared features of cell compartmentalisation in different planctomycetes are consistent with the monophyletic nature of the planctomycetes as a distinct division of the Bacteria. The shared organisational plan for the planctomycete cell constitutes a new type not known in cells of other bacteria.

Histone contributions to the structure of DNA in the nucleosome

We describe the application of the hydroxyl radical footprinting technique to examine the contribution of the core histone tails and of histones H3 and H4 to the structure of DNA in the nucleosome. We first establish that, as was previously determined for a nucleosome containing a unique sequence of DNA, mixed-sequence nucleosomes contain two distinct regions of DNA structure. The central three turns of DNA in the nucleosome have a helical periodicity of approximately 10.7 base pairs per turn, while flanking regions have a periodicity of approximately 10.0 base pairs per turn. Removal of the histone tails does not change the hydroxyl radical cleavage pattern in either mixed- or unique-sequence nucleosome samples. A tetramer of histones H3 and H4, (H3/H4)2, organizes the central 120 base pairs of DNA identically to that found in the nucleosome. Moreover, "tailless" octamers and the (H3/H4)2 tetramer recognize the same nucleosome positioning signals as the intact octamer.

The terminal balls characteristic of eukaryotic rRNA transcription units in chromatin spreads are rRNA processing complexes

When spread chromatin is visualized by electron microscopy, active rRNA genes have a characteristic Christmas tree appearance: From a DNA "trunk" extend closely packed "branches" of nascent transcripts whose ends are decorated with terminal "balls." These terminal balls have been known for more than two decades, are shown in most biology textbooks, and are reported in hundreds of papers, yet their nature has remained elusive. Here, we show that a rRNA-processing signal in the 5'-external transcribed spacer (ETS) of the Xenopus laevis ribosomal primary transcript forms a large, processing-related complex with factors of the Xenopus oocyte, analogous to 5' ETS processing complexes found in other vertebrate cell types. Using mutant rRNA genes, we find that the same rRNA residues are required for this biochemically defined complex formation and for terminal ball formation, analyzed electron microscopically after injection of these cloned genes into Xenopus oocytes. This, plus other presented evidence, implies that rRNA terminal balls in Xenopus, and by inference, also in the multitude of other species where they have been observed, are the ultrastructural visualization of an evolutionarily conserved 5' ETS processing complex that forms on the nascent rRNA.

Transcription in the yeast rRNA gene locus: distribution of the active gene copies and chromatin structure of their flanking regulatory sequences

In growing yeast cells, about half of the 150 tandemly repeated rRNA genes are transcriptionally active and devoid of nucleosomes. By using the intercalating drug psoralen as a tool to mark accessible sites along chromatin DNA in vivo, we found that the active rRNA gene copies are rather randomly distributed along the ribosomal rRNA gene locus. Moreover, results from the analysis of a single, tagged transcription unit in the tandem array are not consistent with the presence of a specific subset of active genes that is stably maintained throughout cell divisions. In the rRNA intergenic spacers of yeast cells, an enhancer is located at the 3' end of each transcription unit, 2 kb upstream of the next promoter. Analysis of the chromatin structure along the tandem array revealed a structural link between transcription units and adjacent, 3' flanking enhancer sequences: each transcriptionally active gene is flanked by a nonnucleosomal enhancer, whereas inactive, nucleosome-packed gene copies are followed by enhancers regularly packaged in nucleosomes. From the fact that nucleosome-free enhancers were also detected in an RNA polymerase I mutant strain, we interpret these open chromatin structures as being the result of specific protein-DNA interactions that can occur before the onset of transcription. In contrast, in this mutant strain, all of the rRNA coding sequences are packaged in nucleosomal arrays. This finding indicates that the establishment of the open chromatin conformation on the activated gene copies requires elongating RNA polymerase I molecules advancing through the template.

Depletion of functional ribosomal RNA operons in Escherichia coli causes increased expression of the remaining intact copies

The synthesis of ribosomal RNA is a complex and highly regulated process. To study this process, we have used deletion-insertions to disrupt sequentially from one to four of the seven rRNA (rrn) operons on the Escherichia coli genome. Inactivation of four rrn operons caused a 2.3-fold increase in the expression of a chloramphenicol acetyl transferase reporter gene fused to the tandem promoters of rrnA and a similar increase in the expression of the trp tRNA gene at the end of rrnC. This reflected enhanced expression of the remaining operons to compensate for having only three intact copies. The elevated expression was caused by an increase in both transcription initiation and RNA polymerase elongation rates specifically on rrn operons and occurred in the absence of changes in the intracellular concentration of ppGpp, suggesting that ppGpp is not involved in the regulation of this phenomenon. We discuss these results in relation to the ribosome feedback inhibition model described by Nomura and coworkers.

Replication of transcriptionally active chromatin

In eukaryotic cells, active genes and their regulatory sequences are organized into open chromatin conformations in which nucleosomes can be modified, disrupted or totally absent. It has been proposed that these characteristic chromatin structures and their associated factors might be directly inherited by the newly synthesized daughter strands during chromosome duplication. Here we show that in the yeast Saccharomyces cerevisiae, replication machinery entering upstream of a transcriptionally active ribosomal RNA gene generates two newly replicated coding regions regularly packaged into nucleosomes, indicating that the active chromatin structure cannot be directly inherited at the replication fork. Whereas the establishment of an exposed chromatin conformation at some newly replicated rRNA gene promoters can occur shortly after the passage of the replication fork, regeneration of the active chromatin structure along the coding region is always a post-replicative process involving disruption of preformed nucleosomes.

Functional analysis of internal transcribed spacer 2 of Saccharomyces cerevisiae ribosomal DNA

Using the previously described "tagged ribosome" (pORCS) system for in vivo mutational analysis of yeast rDNA, we show that small deletions in the 5'-terminal portion of ITS2 completely block maturation of 26 S rRNA at the level of the 29 SB precursor (5.8 S rRNA-ITS2-26 S rRNA). Various deletions in the 3'-terminal part, although severely reducing the efficiency of processing, still allow some mature 26 S rRNA to be formed. On the other hand, none of the ITS2 deletions affect the production of mature 17 S rRNA. Since all of the deletions severely disturb the recently proposed secondary structure of ITS2, these findings suggest an important role for higher order structure of ITS2 in processing. Analysis of the effect of complete or partial replacement of S. cerevisiae ITS2 with its counterpart sequences from Saccharomyces rosei or Hansenula wingei, points to helix V of the secondary structure model as an important element for correct and efficient processing. Direct mutational analysis shows that disruption of base-pairing in the middle of helix V does not detectably affect 26 S rRNA formation. In contrast, introduction of clustered point mutations at the apical end of helix V that both disrupt base-pairing and change the sequence of the loop, severely reduces processing. Since a mutant containing only point mutations in the sequence of the loop produces normal amounts of mature 26 S rRNA, we conclude that the precise (secondary and/or primary) structure at the lower end of helix V, but excluding the loop, is of crucial importance for efficient removal of ITS2.

Organization of 5S rDNA in species of the fish Leporinus: two different genomic locations are characterized by distinct nontranscribed spacers

To address understanding the organization of the 5S rRNA multigene family in the fish genome, the nucleotide sequence and organization array of 5S rDNA were investigated in the genus Leporinus, a representative freshwater fish group of South American fauna. PCR, subgenomic library screening, genomic blotting, fluorescence in situ hybridization, and DNA sequencing were employed in this study. Two arrays of 5S rDNA were identified for all species investigated, one consisting of monomeric repeat units of around 200 bp and another one with monomers of 900 bp. These 5S rDNA arrays were characterized by distinct NTS sequences (designated NTS-I and NTS-II for the 200- and 900-bp monomers, respectively); however, their coding sequences were nearly identical. The 5S rRNA genes were clustered in two chromosome loci, a major one corresponding to the NTS-I sites and a minor one corresponding to the NTS-II sites. The NTS-I sequence was variable among Leporinus spp., whereas the NTS-II was conserved among them and even in the related genus Schizodon. The distinct 5S rDNA arrays might characterize two 5S rRNA gene subfamilies that have been evolving independently in the genome.

Yeast nuclear envelope subdomains with distinct abilities to resist membrane expansion

Little is known about what dictates the round shape of the yeast Saccharomyces cerevisiae nucleus. In spo7Delta mutants, the nucleus is misshapen, exhibiting a single protrusion. The Spo7 protein is part of a phosphatase complex that represses phospholipid biosynthesis. Here, we report that the nuclear protrusion of spo7Delta mutants colocalizes with the nucleolus, whereas the nuclear compartment containing the bulk of the DNA is unaffected. Using strains in which the nucleolus is not intimately associated with the nuclear envelope, we show that the single nuclear protrusion of spo7Delta mutants is not a result of nucleolar expansion, but rather a property of the nuclear membrane. We found that in spo7Delta mutants the peripheral endoplasmic reticulum (ER) membrane was also expanded. Because the nuclear membrane and the ER are contiguous, this finding indicates that in spo7Delta mutants all ER membranes, with the exception of the membrane surrounding the bulk of the DNA, undergo expansion. Our results suggest that the nuclear envelope has distinct domains that differ in their ability to resist membrane expansion in response to increased phospholipid biosynthesis. We further propose that in budding yeast there is a mechanism, or structure, that restricts nuclear membrane expansion around the bulk of the DNA.

When rDNA transcription is arrested during mitosis, UBF is still associated with non-condensed rDNA

The mechanisms that control inactivation of ribosomal gene (rDNA) transcription during mitosis is still an open question. To investigate this fundamental question, the precise timing of mitotic arrest was established. In PtK1 cells, rDNA transcription was still active in prophase, stopped in prometaphase until early anaphase, and activated in late anaphase. Because rDNA transcription can still occur in prophase and late anaphase chromosomes, the kinetics of rDNA condensation during mitosis was questioned. The conformation of the rDNA was analyzed by electron microscopy from the G2/M transition to late anaphase in the secondary constriction, the chromosome regions where the rDNAs are clustered. Whether at transcribing or non-transcribing stages, non-condensed rDNA was observed in addition to axial condensed rDNA. Thus, the persistence of this non-condensed rDNA during inactive transcription argues in favor of the fact that mitotic inactivation is not the consequence of rDNA condensation. Analysis of the three-dimensional distribution of the rDNA transcription factor, UBF, revealed that it was similar at each stage of mitosis in the secondary constriction. In addition, the colocalization of UBF with non-condensed rDNA was demonstrated. This is the first visual evidence of the association of UBF with non-condensed rDNA. As we previously reported that the rDNA transcription machinery remained assembled during mitosis, the colocalization of rDNA fibers with UBF argues in favor of the association of the transcription machinery with certain rDNA copies even in the absence of transcription. If this hypothesis is correct, it can be assumed that condensation of rDNA as well as dissociation of the transcription machinery from rDNA cannot explain the arrest of rDNA transcription during mitosis. It is proposed that modifications of the transcription machinery occurring in prometaphase could explain the arrest of transcription, while reverse modifications in late anaphase could explain activation.

Electron microscopic study of Saccharomyces cerevisiae rDNA chromatin replication

An electron microscopic study was made of the replication of rDNA chromatin of Saccharomyces cerevisiae. Two different methods were used to synchronize cells. cdc7-1 cells were raised to a restrictive temperature, whereas A364a cells were blocked with mating factor. Replication bubbles typically opened in the nontranscribed spacers of rDNA repeats in both cell types. The mean position of the center of these bubbles corresponds closely to a position where an autonomously replicating sequence previously has been mapped in an rDNA repeat. Clusters of replication bubbles containing up to four bubbles spaced one to three genes apart were seen opening in early S phase.

Circular DNA of Entamoeba histolytica encodes ribosomal RNA

The presence of repeated DNA sequences encoding RNA in Entamoeba histolytica has been reported. In the present study we demonstrate by agarose gel electrophoresis. DNase digestion and electron microscopic analysis that these genes are located on extrachromosomal circular DNA molecules with an approximate size of 26 kb. Detection of replication intermediates suggests the episomal nature of these molecules. Amplified, extrachromosomal rRNA genes appear to be a common feature among the lower eukaryotes, occurring more commonly as linear molecules and less commonly as circles. Entamoeba histolytica is 1 of the few organisms studied in which rRNA genes are located predominantly on extrachromosomal circles.

Heterogeneity of rDNA distribution and genome size in Silene spp

Genus Silene L. (Caryophyllaceae) contains about 700 species divided into 44 sections. According to recent taxonomic classification this genus also includes taxa previously classified in genera Lychnis and Melandrium. In this work, four Silene species belonging to different sections were studied: S. latifolia (syn. Melandrium album, Section Elisanthe), S. vulgaris (Inflatae), S. pendula (Erectorefractae), and S. chalcedonica (syn. Lychnis chalcedonica, Lychnidiformes). Flow cytometric analysis revealed a genome size of 2.25 and 2.35 pg/2C for S. vulgaris and S. pendula and of 5.73 and 6.59 pg/2C for S. latifolia and S. chalcedonica. All four species have the same chromosome number including the pair of sex chromosomes of the dioecious S. latifolia (2n = 2x = 24). Double target fluorescence in-situ hybridization revealed the chromosomal locations of 25S rDNA and 5S rDNA. A marked variation in number and localization of rDNA loci but no correlation between the numbers of rDNA clusters and genome size was found. FISH and genome size data indicate that nuclear genomes of Silene species are highly diversified as a result of numerous DNA amplifications and translocations.

Multiple nucleosome positioning with unique rotational setting for the Saccharomyces cerevisiae 5S rRNA gene in vitro and in vivo

A simple no-background assay was developed for high-resolution in vivo analysis of yeast chromatin. When applied to Saccharomyces cerevisiae 5S rRNA genes (5S rDNA), this analysis shows that nucleosomes completely cover this chromosomal region, occupying alternative positions characterized by a unique helical phase. This supports the notion that sequence-intrinsic rotational signals are the major determinant of nucleosome localization. Nucleosomal core particles reconstituted in vitro occupy the same positions and have the same helically phased distribution observed in vivo, as determined by mapping of exonuclease III-resistant borders, mapping by restriction cleavages, and by DNase I and hydroxyl-radical digestion patterns.

Electron microscopic localization of replication origins in Oenothera chloroplast DNA

The origins of chloroplast DNA (cpDNA) replication were mapped in two plastome types of Oenothera in order to determine whether variation in the origin of cpDNA replication could account for the different transmission abilities associated with these plastomes. Two pairs of displacement loop (D-loop) initiation sites were observed on closed circular cpDNA molecules by electron microscopy. Each pair of D-loops was mapped to the inverted repeats of the Oenothera cpDNA by the analysis of restriction fragments. The starting points of the two adjacent D-loops are approximately 4 kb apart, bracketing the 16S rRNA gene. Although there are small DNA length variations near one of the D-loop initiation sites, no apparent differences in the number and the location of replication origins were observed between plastomes with the highest (type I) and lowest (type IV) transmission efficiencies.

3-D organization of ribosomal transcription units after DRB inhibition of RNA polymerase II transcription

In each bead of the nucleolar necklace, using adenosine analog DRB-treated PtK1 cells, we investigated the three components of rDNA transcription, i.e. the gene, transcription factor UBF and transcripts. In situ hybridization revealed the unraveling and 3-D dispersion of most of the rDNA coding sequences within the nucleus. The signals were small, of similar intensity and tandemly organized in the necklace. This observation is compatible with the fact that they might correspond to single gene units. Active transcription was visualized in these units, demonstrating that they were active functional units. Transcript labeling was not similar for each unit, contrary to UBF labeling. UBF and rRNA transcripts were only partially colocalized, as demonstrated by 3-D image analysis and quantification. As visualized by electron microscopy, the necklace was composed of a small fibrillar center partially surrounded by a dense fibrillar component. The 3-D arrangement of this individual unit in the necklace, investigated both by confocal and electron microscopy in the same cells, showed that the individual beads were linked by a dense fibrillar component. The reversibility of this organization after removal of DRB indicated that the beads in the necklace are certainly the elementary functional domain of the nucleolus. In addition, these results lead us to suggest that the organization of a functional domain, presumably corresponding to a single gene, can be studied by in situ approaches.

Structure of the extrachromosomal ribosomal RNA chromatin of Physarum polycephalum

Isolated nucleoli from exponentially growing microplasmodia of Physarum polycephalum were digested with micrococcal nuclease or DNAase I, or were photoreacted with trimethyl psoralen. In the coding region for the precursor of the ribosomal RNA, micrococcal nuclease and DNAase I digestions show predominantly a smear, and treatment with psoralen leads to a fairly continuous crosslinking of the DNA. All three assays are compatible with the absence of a typical nucleosomal array in most of the gene copies. In contrast, in the central non-transcribed spacer, except in the immediate 5'-flanking region, micrococcal nuclease and DNAase I digestions yield fragments that are multiples of a basic repeat, compatible with a nucleosomal packing of this region. The crosslinking pattern with psoralen confirms this conclusion. In addition, there are three sites over 400 base-pairs long that are inaccessible for psoralen crosslinking. Two of these sites have been mapped to the putative origins of replication. In the terminal non-transcribed spacer, except in the immediate 3'-flanking region, digestions with micrococcal nuclease and DNAase I give a smeared repeat. The crosslinking pattern after treatment with psoralen suggests that this region is packed in nucleosomes, except for about 900 base-pairs constituting the telomere regions of the linear extrachromosomal palindromic rDNA. Micrococcal nuclease digestion of the immediate 5'-flanking region shows a complete absence of any nucleosomal repeat, but digestion with DNAase I leads to a faint ten base-pair repeat. In contrast, in the 3'-flanking regions both nuclease assays indicate a chromatin structure similar to the coding region. Both flanking regions are unusual with respect to psoralen crosslinking, in that crosslinking is reduced both in chromatin and deproteinized DNA. On the basis of the known sequence-dependent psoralen crosslinking and the established sequences in these regions, crosslinking should be expected to occur. However, it does not and we therefore propose the presence of an unusual DNA conformation in these regions.

DNA sequence and secondary structures of the large subunit rRNA coding regions and its two class I introns of mitochondrial DNA from Podospora anserina

DNA sequence analysis has shown that the gene coding for the mitochondrial (mt) large subunit ribosomal RNA (rRNA) from Podospora anserina is interrupted by two class I introns. The coding region for the large subunit rRNA itself is 3715 bp and the two introns are 1544 (r1) and 2404 (r2) bp in length. Secondary structure models for the large subunit rRNA were constructed and compared with the equivalent structure from Escherichia coli 23S rRNA. The two structures were remarkably similar despite an 800-base difference in length. The additional bases in the P. anserina rRNA appear to be mostly in unstructured regions in the 3' part of the RNA. Secondary structure models for the two introns show striking similarities with each other as well as with the intron models from the equivalent introns in Saccharomyces cerevisiae, Neurospora crassa, and Aspergillus nidulans. The long open reading frames in each intron are different from each other, however, and the nucleotide sequence similarity diverges as it proceeds away from the core structure. Each intron is located within regions of the large subunit rRNA gene that are highly conserved in both sequence and structure. Computer analysis showed that the open reading frame for intron r1 contained a common maturase-like polypeptide. The open reading frames of intron r2 appeared to be chimeric, displaying high sequence similarity with the open reading frames in the r1 and ATPase 6 introns of N. crassa.

Circular ribosomal RNA genes are a general feature of schizopyrenid amoebae

We have recently shown that the ribosomal RNA genes of the amoebo-flagellate Naegleria gruberi Schardinger, 1899, strain NEG-M are carried exclusively on a 14 kilobasepair plasmid. To explore the distribution of this unique gene arrangement, we have examined another strain of N. gruberi and four other species from the order Schizopyrenida. All have this unusual gene arrangement although the size of the plasmid varies widely. Species groups based on morphological criteria do not agree with those resulting from comparison of plasmid restriction enzyme patterns.

Spatio-temporal dynamics at rDNA foci: Global switching between DNA replication and transcription

We have investigated the in situ organization of ribosomal gene (rDNA) transcription and replication in HeLa cells. Fluorescence in situ hybridization (FISH) revealed numerous rDNA foci in the nucleolus. Each rDNA focus corresponds to a higher order chromatin domain containing multiple ribosomal genes. Multi-channel labeling experiments indicated that, in the majority of cells, all the rDNA foci were active in transcription as demonstrated by co-localization with signals to transcription and fibrillarin, a protein involved in ribosomal RNA processing. In some cells, however, a small portion of the rDNA foci did not overlap with signals to transcription and fibrillarin. Labeling for DNA replication revealed that those rDNA foci inactive in transcription were restricted to the S-phase of the cell cycle and were replicated predominantly from mid to late S-phase. Electron microscopic analysis localized the nucleolar transcription, replication, and fibrillarin signals to the dense fibrillar components of the nucleolus and at the borders of the fibrillar centers. We propose that the rDNA foci are the functional units for coordinating replication and transcription of the rRNA genes in space and time. This involves a global switching mechanism, active from mid to late S-phase, for turning off transcription and turning on replication at individual rDNA foci. Once all the rRNA genes at individual foci are replicated, these higher order chromatin domains are reprogrammed for transcription.

Metazoan rDNA enhancer acts by making more genes transcriptionally active

Enhancers could, in principle, function by increasing the rate of reinitiation on individual adjacent active promoters or by increasing the probability that an adjacent promoter is activated for transcription. We have addressed this issue for the repetitive metazoan rDNA enhancer by microinjecting Xenopus oocytes with enhancer-less and enhancer-bearing genes and determining by EM the frequency that each gene type forms active transcription units and their transcript density. We use conditions where transcription requires the normal rDNA promoter and is stimulated 30-50-fold by the enhancer. (In contrast, at saturating template conditions as used in previous EM studies, an aberrant mode of transcription is activated that is not affected by the rDNA enhancer or by the generally recognized rDNA promoter). The active transcription units on enhancer-less genes are found to be as densely packed with nascent transcripts and polymerases as those on enhancer-bearing genes and on the endogenous rRNA genes. Significantly, the enhancer-bearing genes are approximately 30-50-fold more likely to form such active transcription units than enhancer-less genes, consistent with their amounts of transcript. Complementary studies confirm that the enhancer does not affect elongation rate, the stability of the transcription complex, or transcript half-life. These data demonstrate that the repetitive metazoan rDNA enhancer causes more genes to be actively transcribed and does not alter the reinitiation rate on individual active genes.

Electron microscopic localization of ribosomal DNA in rat liver nucleoli by nonisotopic in situ hybridization

We have used postembedding nonisotopic in situ hybridization, with biotinylated rat ribosomal DNA (rDNA) as a probe and streptavidin coupled to 10-nm colloidal gold particles as the detection system, to localize rDNA sequences in rat liver nucleoli at the electron microscopic level. For comparison purposes, immunoelectron microscopy was performed for the detection of DNA. Our results indicate that ribosomal DNA sequences are enriched in the dense fibrillar component of the rat liver nucleolus. These data are discussed in relation to the putative site(s) for transcription of ribosomal genes.

Selective visualization of gene structure with ultraviolet light

The ability of the ultraviolet (UV) "footprinting" technique to detect chromatin has been investigated in vitro. Two basic types of chromatin, a phased nucleosome and a phased nucleosome containing a phased H1 protein, have been reconstituted onto a cloned 5S ribosomal RNA gene from sea urchin. The histone-DNA interactions in each complex have been probed with exonuclease III, DNase I, dimethyl sulfate, and UV light. Whereas DNase I and exonuclease III readily detect interactions between histones and DNA, UV light and dimethyl sulfate do not. In contrast to histone-DNA interactions, we demonstrate that intimate sequence-specific contacts between the same sea urchin 5S DNA and the Xenopus laevis transcription factor IIIA (TFIIIA) are readily detected with UV light. Since the sensitivity of UV light for TFIIIA contacts is similar to its sensitivity for other regulatory protein-DNA contacts, these studies demonstrate the feasibility of using UV light to selectively visualize regulatory protein-DNA interactions in vivo with little or no interference from histone-DNA interactions.

DNA sequence, structure, and phylogenetic relationship of the small subunit rRNA coding region of mitochondrial DNA from Podospora anserina

DNA sequence analysis and the localization of the 5' and 3' termini by S1 mapping have shown that the mitochondrial (mt) small subunit rRNA coding region from Podospora anserina is 1980 bp in length. The analogous coding region for mt rRNA is 1962 bp in maize, 1686 bp in Saccharomyces cerevisiae, and 956 bp in mammals, whereas its counterpart in Escherichia coli is 1542 bp. The P. anserina mt 16S-like rRNA is 400 bases longer than that from E. coli, but can be folded into a similar secondary structure. The additional bases appear to be clustered at specific locations, including extensions at the 5' and 3' termini. Comparison with secondary structure diagrams of 16S-like RNAs from several organisms allowed us to specify highly conserved and variable regions of this gene. Phylogenetic tree construction indicated that this gene is grouped with other mitochondrial genes, but most closely, as expected, with the fungal mitochondrial genes.