Regulation of DNA replication on subchromosomal units of mammalian cells

The regulation of DNA replication at a subchromosomal level in mammalian cells has been investigated. DNA fiber autoradiographs were prepared from mouse L-929 cells pulse labeled with (3H)thymidine. Initiation events and subsequent chain growth occurring over short stretches (up to three replication units in length) of chromosomal DNA were analyzed. The results show that adjacent units usually initiate replication synchronously and that this synchrony is related to the proximity of initiation sites. In addition, adjacent units are of similar size and the rates of replication fork progression within units and on adjacent units are similar. The rate of fork progression increases with increasing replication unit size. Finally, no evidence for fixed termination sites for the units has been found. These observations suggest that despite large variations in size of replication units, timing of initiation events, and rates of fork progression found in chromosomal DNA as a whole, these processes are closely regulated within subchromosomal clusters of active replication units.     

Variations in the number of ribosomal DNA units in morphological mutants and normal strains of Candida albicans and in normal strains of Saccharomyces cerevisiae.

Naturally occurring strains of Candida albicans are opportunistic pathogens that lack a sexual cycle and that are usually diploids with eight pairs of chromosomes. C. albicans spontaneously gives rise to a high frequency of colonial morphology mutants with altered electrophoretic karyotypes, involving one or more of their chromosomes. However, the most frequent changes involve chromosome VIII, which contains the genes coding for ribosomal DNA (rDNA) units. We have used restriction fragment lengths to analyze the number and physical array of the rDNA units on chromosome VIII in four normal clinical strains and seven morphological mutants derived spontaneously from one of the clinical isolates. HindIII does not cleave the rDNA repeats and liberates the tandem rDNA cluster from each homolog of chromosome VIII as a single fragment, whereas the cleavage at a single site by NotI reveals the size of the single rDNA unit. All clinical strains and morphological mutants differed greatly in the number of rDNA units per cluster and per cell. The four clinical isolates differed additionally among themselves by the size of the single rDNA unit. For a total of 25 chromosome VIII homologs in a total of 11 strains considered, the variability of chromosome VIII was exclusively due to the length of rDNA clusters (or the number of rDNA units) in approximately 92% of the cases, whereas the others involved other rearrangements of chromosome VIII. Only slight variations in the number of rDNA units were observed among 10 random C. albicans subclones and 10 random Saccharomyces cerevisiae subclones grown for a prolonged time at 22 degrees C. However, when grown faster at optimal temperatures of 37 and 30 degrees C, respectively, both fungi accumulated higher numbers of rDNA units, suggesting that this condition is selected for in rapidly growing cells. The morphological mutants, in comparison with the C. albicans subclones, contained a markedly wider distribution of the number of rDNA units, suggesting that a distinct process may be involved in altering the number of rDNA units in these mutants.     

Temporal order of replication of mouse ribosomal RNA genes during the cell cycle

The timing of replication of mouse ribosomal RNA (rRNA) genes was determined in cultured cells by using 5-bromodeoxyuridine labeling of DNA coupled with synchronization. Two subclasses of rRNA genes were characterized that differ in their temporal order of replication during S-phase. Approximately half of the rDNA repeat units replicated primarily during the first half of S-phase and the other 50% preferentially in the second half. This difference in replication timing was consistently observed for the approximately 400 rDNA repeat units of NIH3T3 fibroblasts, but not for plasmid DNA containing fragments of rRNA genes that had been stably transfected into the genome of these cells. The rDNA fragments inserted into these transfection vectors contained the recently mapped origin of bidirectional replication with or without amplification-promoting sequences, or none of the above. Since the plasmid DNA that was integrated into the host cell genome replicated randomly during S-phase we conclude that the integrated plasmid DNA is either replicated from a chromosomal origin in the neighborhood of its integration site or that inserts are replicated from their own origins and the timing of replication is determined by flanking sequences. Received: 7 July 1997; in revised form: 1 October 1997; Accepted: 1 October 1997     

Extrachromosomal circular nuclear rDNA in Euglena gracilis.

The presence of extrachromosomal nuclear ribosomal DNA (rDNA) in the unicellular alga Euglena gracilis has been established. This rDNA is circular. Each circle is 3.8 micron long and contains one rDNA unit. Oligomers are rare. Extrachromosomal rDNA is present in large amounts during the exponential phase of growth and appears less abundant during the stationary phase. It was found in all wild-type and mutant strains of Euglena examined. Our estimations suggest that rDNA in Euglena is mainly extrachromosomal. Research of extrachromosomal rDNA in spinach and Petunia was negative.     

Extrachromosomal DNA in yeast-Saccharomyces

The recombinant plasmids containing autonomously replicating sequence (ARS) of yeast rDNA repeat are characterized by a high instability in transformed yeast cells. The instability of chimaric plasmids in yeast may result from improper replication and/or irregular mitotic segregation. To study the replication properties alone we have constructed series of hybrid plasmids containing centromeric DNA (CEN3), a selective marker (leu2) and ARS of rDNA. Each of these plasmids with the functional centromere should exhibit chromosomal i. e. regular type of mitotic segregation. The study of mitotic segregation of constructed plasmids has shown that the ARS rDNA from yeast is distinguished from other ARSs described in literature: ARS1, ARS2, ARS o-micron DNA. 1. The activation of replication of ARS rDNA is accidental, i. e. probability of ARS rDNA in the cell cycle is much less than one. 2. Some nuclear mutations as well as rho- mutation result in the increase of replicative activity of ARS rDNA. In some yeast strains the activity of ARS rDNA can reach the activity of ARS1, i. e. was close to one. The features of ARS rDNA may account for the phenomenon of amplification of rDNA genes.     

The four ribosomal DNA units of the malaria parasite Plasmodium berghei. Identification, restriction map, and copy number analysis

The four ribosomal RNA genes (rDNA units) of the rodent malaria parasite, Plasmodium berghei, were identified and mapped by restriction enzyme analysis and Southern blot hybridization of genomic DNA. Although the four genes share common characteristics, they appear to be internally different from each other in expanse and sequence. One HindIII site near the 3' end of the coding region for the large rRNA is the only restriction site which we have detected that is conserved in all of the genes. The distance between the conserved HindIII site and the coding region for the small rRNA is at least 1-2 kilobases longer in two of the rDNA units than in a third unit. None of the four rDNA units were linked by restriction mapping where about 150 kilobases of the genome were accounted for. The copy number of two of the rDNA units was determined to be approximately 1 per haploid genome by quantitative analysis of cloned (plasmid) DNA versus genomic DNA digests on Southern blots. The other two genes also appear to be present in 1 copy. Restriction analysis confirms both the low copy number and that these genes are not in an easily recognizable tandem array. The low number of rDNA units requires that new copies of the genome produced during intraerythrocytic growth be active in RNA synthesis soon after their replication.     

Characterization of the nuclear ribosomal DNA of Euglena gracilis

A phage lambda recombinant library containing Euglena gracilis genomic DNA was screened for nuclear rDNA sequences. A recombinant phage was isolated that contained an 11.5-kb nuclear rDNA sequence. The 11.5-kb insert was mapped with restriction endonucleases and was shown to represent a complete rDNA repeat unit that carried the genes for the 19S, 25S, 5.8 S and 5 S cytoplasmic rRNAs. The 2000 rDNA repeat units per haploid genome are organized in the form of identical tandem repeats.     

Comparison between the organization of nuclear ribosomal DNA unit of Euglena gracilis Z and var. Bacillaris

Summary We have characterized the nuclear rDNA unit of Euglena gracilis var. bacillaris and compared it to that of the Z strain. We have localized restriction sites for Eco R1, Sal 1, Sma 1, Hind III, Bam H1 and Bgl II on this unit as well as the coding region for 20 S and 25 S rRNAs. For both strains, results suggest an homogeneity of the 11.6 kbp rDNA units. Comparison between strains shows differences characterized by two additional Sal 1 sites in bacillaris and the likely methylation of one Sma 1 site in Z. Both differences are localized in a non-coding region of the rDNA unit. Analyses of 18 Euglena strains from various origins confirm these differences and allow easy recognition of bacillaris and Z type strains.Abbreviations kb kilo base - kpb kilo base pair - plasmids pRH 59 and pRH 57 contain a Hind III-HInd III nuclear DNA fragment from W₃BUL of 5.9 and 5.7 kbp respectively, pRB 48 and pRB 35 contain a Bam H1-Bam H1 nuclear DNA fragment from wild-type Z of 4.8 and 3.5 kbp respectively - SDS sodium dodecyl sulfate - UV ultra-violet     

Dna2 helicase/nuclease causes replicative fork stalling and double-strand breaks in the ribosomal DNA of Saccharomyces cerevisiae

We have proposed that faulty processing of arrested replication forks leads to increases in recombination and chromosome instability in Saccharomyces cerevisiae and contributes to the shortened lifespan of dna2 mutants. Now we use the ribosomal DNA locus, which is a good model for all stages of DNA replication, to test this hypothesis. We show directly that DNA replication pausing at the ribosomal DNA replication fork barrier (RFB) is accompanied by the occurrence of double-strand breaks near the RFB. Both pausing and breakage are elevated in the early aging, hypomorphic dna2-2 helicase mutant. Deletion of FOB1, encoding the fork barrier protein, suppresses the elevated pausing and DSB formation, and represses initiation at rDNA ARSs. The dna2-2 mutation is synthetically lethal with deltarrm3, encoding another DNA helicase involved in rDNA replication. It does not appear to be the case that the rDNA is the only determinant of genome stability during the yeast lifespan however since strains carrying deletion of all chromosomal rDNA but with all rDNA supplied on a plasmid, have decreased rather than increased lifespan. We conclude that the replication-associated defects that we can measure in the rDNA are symbolic of similar events occurring either stochastically throughout the genome or at other regions where replication forks move slowly or stall, such as telomeres, centromeres, or replication slow zones.     

Evolution of 5S rDNA units and their chromosomal localization in Allium cepa and Allium schoenoprasum revealed by microdissection and FISH

Allium cepa and Allium schoenoprasum each possess 5S rDNA units of two different sizes. The evolution of the two repeat units and their chromosomal localization were investigated. A. cepa has 5S rDNA loci in the proximal and distal regions of the short arm of chromosome 7. When the proximal and distal segments of the short arm of chromosome 7 were microdissected separately, and used as templates for PCR, the short and long 5S rDNA fragments were amplified predominantly from the proximal and distal segments, respectively. The nucleotide sequence of the long 5S rDNA unit resulted from partial duplication of a non-transcribed spacer (NTS) and the insertion of a unique sequence. FISH using a probe consisting of the unique sequence demonstrated that the long unit was distally localized. In A. cepa, the long 5S rDNA unit is only present distally and the short unit is predominantly located proximally on the short arm of chromosome 7. In A. schoenoprasum, the NTSs of the two different-sized 5S rDNAs had quite different sequences. The two 5S rDNA loci were localized very close together in the interstitial region of chromosome 6. FISH, using long and short 5S rDNA unit probes with a competitor of a 120-bp sequence of the 5S rRNA gene, indicated that the long 5S rDNA unit was localized proximally and the short unit distally. Although the NTSs of the 5S rDNA of A. cepa and A. schoenoprasum had quite different nucleotide sequences, the long 5S rDNA units of A. cepa and A. schoenoprasum share a common 75-bp sequence. This sequence might act in the formation of the long 5S rDNA unit in Allium species.     

Host DNA replication forks are not preferred targets for bacteriophage Mu transposition.

Bacteriophage Mu DNA integration in Escherichia coli strains infected after alignment of chromosomal replication was analyzed by a sandwich hybridization assay. The results indicated that Mu integrated into chromosomal segments at various distances from oriC with similar kinetics. In an extension of these studies, various Hfr strains were infected after alignment of chromosomal replication, and Mu transposition was shut down early after infection. The positions of integrated Mu copies were inferred from the transfer kinetics of Mu to an F- strain. Our analysis indicated that the location of Mu DNA in the host chromosome was not dependent on the positions of host replication forks at the time of infection. However, the procedure for aligning chromosomal replication affected DNA transfer by various Hfr strains differently, and this effect could account for prior results suggesting preferential integration of Mu at host replication forks.     

151 Phylogenetic Analysis of The Subgenus Euglena with Particualr Reference to the Type Species Euglena Viridis (Euglenophyceae)

Euglena viridis was first described by Antony van Leeuwenhoek in 1674. This taxon later became the type for the genus Euglena erected by Ehrenberg in 1838. The primary characters that distinguish this taxon are the single stellate chloroplast and spherical mucocysts. A number of related Euglena species are similar in size, bear one or two stellate plastids and possess spherical or spindle-shaped mucocysts. We conducted morphological and molecular studies on taxa in the subgenus Euglena (all of which bear stellate chloroplasts) and compared this to genera in the subgenus Calliglena (non-stellate chloroplasts). Morphologically the strains in subgenus Euglena were very similar, except for chloroplast number and mucocyst shape. The E. stellata group has one chloroplast and a distinctive spindle-shaped mucocyst; the E. geniculata group has two chloroplasts and spherical mucocysts; the E. viridis group has one chloroplast and spherical mucocysts. Molecular analyses using SSU and LSU rDNA demonstrated that the subgenus Euglena is not monophyletic. The combined SSU/LSU trees provide strong support for a stellate clade (subgenus Euglena ), but one strain of E. viridis diverges at the base of the Euglena/Calliglena lineage. Multiple subclades are found within the main stellate clade. E. tristellata forms a separate divergence and four E. stellata strains form a single, well-supported subclade. Two E. viridis strains are among the E. geniculata group clade, while six others form two separate, but well-supported clades. This study demonstrates that the type species, E. viridis , is paraphyletic and will need to be redefined.     

Inheritance of extrachromosomal ribosomal DNA during the asexual life cycle of Dictyostelium discoideum: examination by use of DNA polymorphisms.

Wild-type isolates of Dictyostelium discoideum exhibited differences in the size of restriction fragments of the extrachromosomal 88-kilobase ribosomal DNA (rDNA) palindrome. Polymorphisms in rDNA also were found among strains derived solely from the NC4 wild-type isolate. These variations involved EcoRI fragments II, III, and V; they included loss of the EcoRI site separating fragments II and V and deletion and insertion of DNA. More than one rDNA form can coexist in the same diploid or haploid cell. However, one or another parental rDNA tended to predominate in diploids constructed, using the parasexual cycle, between haploid NC4-derived strains and haploid wild-type isolates. In some cases, most if not all of the rDNA of such diploids were of one form after ca. 50 generations of growth. Segregant haploids, derived from diploids that possessed predominantly a single rDNA allele, possessed the same allele as the diploid and did not recover the other form. This evidence implies that replication does not proceed from a single chromosomal or extrachromosomal copy of the rDNA during the asexual life cycle of D. discoideum.     

Determination of the size of rat ribosomal deoxyribonucleic acid repeating units by electron microscopy.

The empoyment of a novel method of affinity chromatography, which makes use of antibodies that specifically bind DNA/RNA hybrids, has made it possible to enrich for rat rDNA molecules which contain R loops formed with the 18S and 28S rRNAs. An approximately 150-fold enrichment of the ratrRNA coding sequences was obtained by this affinity chromatography procedure. This degree of enrichment made it possible to visualize these R loop containing molecules in the electron microscope and, thus, to obtain a map of the transcribed and spacer regions of rat rDNA. Eleven of the molecules that were observed contained either 3 or 4 R loops, or else 2 R loops separated by a long spacer. Thus, these molecules provided direct information in regard to the length of rat rDNA repeating units. The mean length of the repeating units was 37.2 kbp with a standard deviation of 1.3 kbp. Within the errors of the measurements, these could all represent repeating units of exactly the same length, although a certain degree of length heterogeneity, possibly up to 4 or 5 kbp, cannot be ruled out by the data. If significantly longer or shorter rDNA repeating units exist in the rat genome, they are probably much less common than the 37.2 kbp unit. These electron microscopic measurements provide the most definitive data yet available on the size of the repeating units of mammalian rRNA genes.     

Evolution of R1 and R2 in the rDNA units of the genus Drosophila

R1 and R2 are non-long terminal repeat (non-LTR) retrotransposable elements that specifically insert in the 28S ribosomal RNA (rRNA) genes of insects. Using the Drosophila genus, which includes some of the best characterized insect taxa, we have conducted a number of studies on the evolution of these elements. We find that R1 and R2 are subject to the same recombinational forces that give rise to the concerted evolution of the rDNA units. The turnover of R1 and R2 elements can be readily documented in different strains of D. melanogaster using 5′ truncated elements as restriction-length polymorphisms. This turnover leads to uniform populations of elements with nucleotide sequence divergence of different copies averaging only 0.23% for the R2 and 0.47% for the R1 elements. Molecular phylogenetic analysis of elements from 16 different species of Drosophila suggests that these elements have been stable components of the rDNA locus for the 50–70 million year history of the Drosophila genus. Using changes at synonymous positions within the protein-encoding regions as estimates of the baseline substitution rate, it could be shown that R1 and R2 are evolving at rates similar to that of typical protein encoding genes provided corrections are made for the low codon bias of the elements. R1 and R2 are clearly well-adapted for their existence in the rDNA units of their host. This revised version was published online in August 2006 with corrections to the Cover Date.     

Fate of amplified nucleoli in Xenopus laevis embryos

We have followed the fate of two components of extrachromosomal nucleoli, amplified ribosomal DNA (rDNA) and 7.5 kb precursor rRNA, during early embryogenesis of Xenopus laevis. Other workers have shown that the amount of amplified rDNA accumulated during oogenesis remains unchanged through the 16-cell stage of embryogenesis. Here we show that as embryonic cleavage continues, the amount of amplified rDNA decreases until it is no longer detectable in the early gastrula embryo. In contrast, the amount of 7.5 kb precursor rRNA in eggs, early cleavage stage embryos, or blastula stage embryos is the same as in oocyte nuclei. Since no rRNA synthesis occurs during these early stages, we conclude that the precursor rRNA sequences synthesized in the oocyte are neither processed nor degraded during early development. The amplified rDNA is not replicated in the early embryo even though the chromosomal DNA of the embryo replicates every 30 min during the first 7.5 hr of embryogenesis. When amplified rDNA is purified and then injected into cleaving embryos, however, we find that it is replicated. This finding suggests that some factor(s) prevents the endogenous amplified rDNA from responding to the cellular replication signals. We show that methylation of cytosine in the rDNA is not related to the DNA's capacity for replication in this system since amplified (unmethylated) and chromosomal (methylated) rDNA are both replicated when injected into embryos. The methylation pattern of these rDNAs appears to be maintained after replication in the embryo.     

The arrangement of length heterogeneity in repeating units of amplified and chromosomal ribosomal DNA from Xenopus laevis

Non-transcribed spacer regions of Xenopus laevis ribosomal DNA have been found which vary in length between 1.8 × 10⁶ and 5.5 × 10⁶ daltons. Length variation of rDNA² repeats exists within a single nucleolar organizer. Amplified rDNA contains repeats of the same size classes but often in different abundance than the chromosomal rDNA of the same animal. If a certain repeat length is preferred during amplification in an individual, it is also preferred in siblings with the same chromosomal rDNA composition. Thus, preference for a size class in amplification is inherited. Some animals selectively amplify repeat lengths which are rarely found in their chromosomal rDNA; others amplify their most abundant size class.The intramolecular arrangement of length variability was analyzed by the electron microscopy of heteroduplex molecules. Long single strands from two separate preparations of amplified and chromosomal rDNA each were reannealed with an homogeneous cloned spacer-containing rDNA fragment (CD30), and the size of adjacent heteroduplex regions was determined. The arrangement of length heterogeneity is very different in the two types of rDNA. Most, if not all, tandem repeats along a single molecule of amplified rDNA are equal in length. This observation supports a rolling circle mechanism for amplification. In contrast, between 50% and 68% of adjacent repeats in a given molecule of chromosomal rDNA differ in length. For one of the chromosomal rDNA preparations analyzed, the frequency of non-identical nearest-neighbors is compatible with random scrambling of repeats of different lengths. This result bears on the mechanism by which tandem genes evolve. It rules out sudden correction mechanisms of tandem genes such as the “master-slave” or certain “expansion-contraction” models, which predict that tandem genes will be identical.