The use of netropsin with CsCl gradients for the analysis of DNA and its application to restriction nuclease fragments of ribosomal DNA from Physarum polycephalum

Netropsin binds to DNA in caesium chloride density gradients and reduces the density of the DNA. The DNA is saturated at a netropsin/DNA weight ratio of about 6 and the change in density, deltarho, at saturation is given by deltarho = -109 (dA + dT content)1.87 mg/ml for the six DNAs tested covering dA + dT contents from 0.28 to 0.69. At lower netropsin/DNA ratios the observed density shifts are consistent with a two-site model for netropsin binding to DNA. Netropsin approximately doubles the resolution of Physarum polycephalum nucleolar satellite DNA from main-band DNA. The fragments of P. polycephalum nucleolar satellite DNA obtained with the restriction endonuclease HindIII do not separate on CsCl gradients, even in the presence of netropsin, which shows that the transcribed and non-transcribed sequences in this DNA have similar nucleotide compositions.     

Direct repeats surrounding the ribosomal RNA genes of Physarum polycephalum

Sequence homology was found between the external transcribed spacer and the terminal non-transcribed spacer of Physarum polycephalum rDNA. The homologous sequences were located 2kb upstream from the 19s rRNA gene and 0.3kb downstream from 26S rRNA gene, respectively, and were arranged in a direct repeat manner. Sequence analyses showed that the direct repeats consisted of two parts: one was sequences of about 130bp which showed over 90% sequence homology with each other. The other consisted mainly of many tandem repeats of a 50 to 52bp unit. The direct repeat-rRNA genes-direct repeat unit was found to be flanked by short direct repetitious sequences. Based on these findings, the significance of the direct repeat is discussed in terms of evolution of rDNA.     

Nucleotide sequence of intergenic and external transcribed spacers of rDNA of diploid wheat Triticum urartu Thum. ex Candil

The primary structure of intergenic non-transcribed and external transcribed spacers of rDNA of diploid wheat Triticum urartu, cloned in pTu3 plasmid 2402 b.p. long was determined. The intergenic non-transcribed rDNA spacer of Tr. urartu was shown to consist of 8 subrepeats with an average of 133 b.p. long, heterogeneous in length and nucleotide sequence. A number of repeated sequences was revealed within each subrepeat. While comparing nucleotide sequences of rDNA subrepeats of Tr. urartu and Tr. aestivum a high homology was found (up to 82%). A high similarity between these plant species was also found in the promoter region and in the external transcribed rDNA spacer. Suppression of the nucleolar organizer of 1A chromosome in the presence of 1B and 6B chromosomes of Tr. aestivum is supposed to be connected with the existence of a great number of subrepeats in the intergenic non-transcribed rDNA spacer of B genome donors in polyploid wheat species of turgidum-aestivum row.     

Locating transcribed and non-transcribed rDNA spacer sequences within the nucleolus by in situ hybridization and immunoelectron microscopy.

Immunoelectron microscopy and in situ hybridization have been used to investigate the precise location of transcribed and non-transcribed rDNA spacer sequences. Whereas a 5'-external transcribed spacer sequence is predominantly visualized in the fibrillar centers of nucleoli, a non-transcribed spacer sequence is preferentially detected in the interstices, in close contact with the fibrillar centers and which interrupt the surrounding dense fibrillar component. Occasionally these two spacers are also observed in clumps of dense nucleolus-associated chromatin. These observations provide insights into the organization of ribosomal repeats within the nucleolus.     

Structural organization of mouse rDNA: Comparison of transcribed and non-transcribed regions

Summary The DNA of the recombinant phage gtWES Mr974 (Grummt et al., 1979) which contains the 18S region and adjacent spacer sequences of the ribosomal genes from mouse has been digested with the restriction endonuclease Sall. Fragments corresponding to the non-transcribed spacer (A and D) and the external transcribed spacer (B) have been prepared and their nucleotide composition and sequence organization has been determined. The data indicate that the part of the non-transcribed spacer contained in Mr974 consists of at least two structural domains of distinct sequence characteristics. Fragment A contains 49% G+C and exhibits a high sequence complexity. Fragment D, the spacer fragment flanking the coding region, is very rich in G+C and is obviously composed of an internally repetitive sequence which is cut by several restriction enzymes into a similar set of repetitive fragments. Most of the fragments have sizes that are multiples of 60 and 80 or 140 base pairs, respectively, suggesting an alternating 60/80bp arrangement. This regular sequence in fragment D accounts both for the observed instability and length heterogeneity of the rDNA insert in several clones and probably for the heterogeneity in the structure of the ribosomal repeats in the genomic DNA.     

Site-specific initiation of DNA replication within the non-transcribed spacer of Physarum rDNA.

Physarum polycephalum rRNA genes are found on extrachromosomal 60 kb linear palindromic DNA molecules. Previous work using electron microscope visualization suggested that these molecules are duplicated from one of four potential replication origins located in the 24 kb central non-transcribed spacer [Vogt and Braun (1977) Eur. J. Biochem., 80, 557-566]. Considering the controversy on the nature of the replication origins in eukaryotic cells, where both site-specific or delocalized initiations have been described, we study here Physarum rDNA replication by two dimensional agarose gel electrophoresis and compare the results to those obtained by electron microscopy. Without the need of cell treatment or enrichment in replication intermediates, we detect hybridization signals corresponding to replicating rDNA fragments throughout the cell cycle, confirming that the synthesis of rDNA molecules is not under the control of S-phase. The patterns of replication intermediates along rDNA minichromosomes are consistent with the existence of four site-specific replication origins, whose localization in the central non-transcribed spacer is in agreement with the electron microscope mapping. It is also shown that, on a few molecules, at least two origins are active simultaneously.     

Isolation and organization of calf ribosomal DNA.

Ribosomal DNA (rDNA) from calf was isolated by three density gradient centrifugations. The first centrifugation in Cs2S04/BAMD was used to obtain partially resolved dG+dC-rich fractions from total DNA. The second and third centrifugations, in Cs2S04/Ag+, led to the isolation of an rDNA fraction characterized by a symmetrical band in CsCl, p = 1.724 g/cm3. This new procedure appears to be generally suitable for the isolation of rDNA and other dG+dC-rich repeated genes. The organization of isolated calf rDNA has been studied by restriction enzyme digestion and by hybridization with cloned rDNA from Xenopus laevis. The repeat unit of calf rDNA has a molecular weight of 21x10(6) and is split by EcoR1 into two fragments, 16x10(6) and 5.0x10(6), and by BamHI into seven fragments. EcoRI and BamHI sites have been mapped. Most of the 18S and 28S RNA genes and the transcribed spacer are contained in the small EcoRI fragment, while the non-transcribed spacer is localized in the large EcoRI fragment. This spacer showed length heterogeneity within a single individual; such heterogeneity is limited to two regions of the spacer.     

Protein tightly bound near the termini of the Physarum extrachromosomal rDNA palindrome

The genes coding for ribosomal RNa in plasmodia of Physarum polycephalum are arranged palindromically on extrachromosomal rDNA molecules of 61 kb (kilobasepairs). Incubation of mildly extracted rDNA with the 125I Bolton-Hunter reagent results in incorporation of label not removed by SDS, CsCl, or various organic solvents. Labeled protein is preferentially associated with terminal rDNA restriction fragments, as detected after gel electrophoresis of the DNA. Antibody reaction with dinitrophenylated protein-rDNA complexes allows visualization of protein located from 1 to 2 kb from the termini, in a region containing multiple inverted repeat sequences and single-strand gaps. DNase I treatment of either rDNA or rDNA termini releases primarily two labeled protein bands of 5,000 and 13,000 daltons as well as less prominent bands of higher molecular weight. We discuss mechanisms for involvement of terminal protein in replication of 3' ends and chromosomal integration of the rDNA.     

Isolation and characterization of Chinese hamster ribosomal DNA clones

We have examined the ribosomal RNA (rRNA) genes of the Chinese hamster ovary (CHO) cell line. A partial EcoRI library of genomic CHO DNA was prepared using lambda Charon-4A. We isolated two recombinants containing the region transcribed as 45S pre-rRNA and 13 kb of external spacer flanking 5' and 3' to the transcribed region. These sequences show restriction site homology with the vast majority of the genomic sequences complementary to rRNA. In addition to this form of rDNA, Southern blot analysis of EcoRI-cut CHO genomic DNA reveals numerous minor fragments ranging from 2 to 19 kb which are complementary to 18S rRNA. We isolated one clone which contains the 18S rRNA gene and sequences 5' which appear to contain length heterogeneity within the non-transcribed spacer region. We have nine additional cloned EcoRI fragments in which the homology with 18S rRNA is limited to a 0.9-kb EcoRI-HindIII fragment. This EcoRI-HindIII fragment is present in each of the cloned EcoRI fragments, and is flanked on both sides by apparently nonribosomal sequences which bear little restriction site homology with each other or the major cloned rDNA repeat.     

Sequence analysis of 28S ribosomal DNA from the amphibian Xenopus laevis.

We have determined the complete nucleotide sequence of Xenopus laevis 28S rDNA (4110 bp). In order to locate evolutionarily conserved regions within rDNA, we compared the Xenopus 28S sequence to homologous rDNA sequences from yeast, Physarum, and E. coli. Numerous regions of sequence homology are dispersed throughout the entire length of rDNA from all four organisms. These conserved regions have a higher A + T base composition than the remainder of the rDNA. The Xenopus 28S rDNA has nine major areas of sequence inserted when compared to E. coli 23S rDNA. The total base composition of these inserts in Xenopus is 83% G + C, and is generally responsible for the high (66%) G + C content of Xenopus 28S rDNA as a whole. Although the length of the inserted sequences varies, the inserts are found in the same relative positions in yeast 26S, Physarum 26S, and Xenopus 28S rDNAs. In one insert there are 25 bases completely conserved between the various eukaryotes, suggesting that this area is important for eukaryotic ribosomes. The other inserts differ in sequence between species and may or may not play a functional role.     

Sequence analysis of the transcribed and 5'' non-transcribed regions of the ribosomal RNA gene in Dictyostelium discoideum

The nucleotide sequence of Dictyostelium discoideum rDNA extending over almost the entire transcribed region and a part of the 5' non-transcribed spacer region has been determined. Computer analysis revealed that there were several conserved sequences in the 17S, 5.8S and 26S coding regions when compared with the sequences at analogous positions in some eukaryotic rRNA genes. The data also showed that the D. discoideum rDNA contains several extra sequences, which have not been found in other eukaryotes' rDNAs , near the 3' terminus of the 17S coding region and the 5' terminus of the 26S coding region.     

Characterization of a cloned ribosomal fragment from mouse which contains the 18S coding region and adjacent spacer sequences.

The large EcoRI fragment of mouse ribosomal genes containing parts of the non-transcribed spacer, the external transcribed spacer located at the 5' end of the precursor molecule and about two thirds of the 18S sequence has been cloned in bacteriophage lambda gtWES. A physical map of the DNA was constructed by cleavage with several restriction endonucleases and hybridization of the restriction fragments of the recombinant DNA with labelled 18S and 45S rRNA. The orientation of the inserted fragment as well as the length of the 18S sequence was determined by electron microscopy of R-loop containing molecules. The absence of hybridization of the cloned fragment to other fragments in the genome shows that the non-transcribed spacer does not have a significant length of sequences in common with other sequences in the genome.     

Restriction analysis of spacers in ribosomal DNA of Drosophila melanogaster.

The sequence arrangement of ribosomal DNA (rDNA) spacers in Drosophila melanogaster was analyzed with restriction endonucleases. Spacers, derived from cloned rDNA repeats and from uncloned purified rDNA, are internally repetitive, as demonstrated by the regular 250 base pairs interval between sites recognized by the enzyme Alu I. Length heterogeneity of spacers is due at least in part to varying numbers of repeated sequence elements. All spacers and analyzed, whether derived from X or from Y chromosomal rDNA, have a very similar sequence organization. The distance separating the repeated nontranscribed spacer sequences from the 5' end of the transcribed region is conserved in all ten cloned fragments examined, and is probably less than 150 base pairs, as measured by electron microscopy.     

Structural analysis of ribosomal DNA homologues in nucleolus-less mutant of Xenopus laevis

Sequences homologous to the ribosomal DNA (rDNA) in a Xenopus anucleolate (nucleolus-less) mutant were analyzed by Southern blot analysis. The mutant was found to possess a variety of sequences homologous to non-transcribed spacer (NTS) and/or coding region of rDNA. 65 rDNA-homologous clones were isolated from a genomic DNA library of the mutant. All the clones showed only partial homology to the normal rDNA unit and their restriction maps differed from that of the normal rDNA unit. Based on the hybridization patterns, the rDNA-homologous clones were divided into four groups (I-IV). Structure of group IV, which most strongly hybridized to normal rDNA probe, was analyzed by nucleotide sequencing. The group IV sequence was found to contain a part of the rDNA, including Bam island, enhancer element, promoter region, external transcribed spacer, and a portion of 18S rRNA gene. The blotting analysis suggested that the group IV sequence is specific for a particular strain of Xenopus.     

Isolation and sequence organization of human ribosomal DNA.

The genes coding for 28 S and 18 S ribosomal RNA have been purified from leukemic leukocytes of one human individual by density gradient centrifugation. The purified ribosomal DNA was analyzed by restriction endonuclease digestion and electron microscopy. The location of cleavage sites for the restriction endonuclease EcoRI was established by R-loop mapping of restriction fragments by electron microscopy. The results are in agreement with gel analysis and gel transfer hybridization. One type of ribosomal DNA repeating unit contains four cleavage sites for EcoRI. Two of these cuts are located in the genes coding for 28 S and 18 S rRNA, while the other two are in the non-transcribed spacer. Thus, one of the restriction fragments generated contains non-transcribed spacer sequences only and is not detected by gel transfer hybridization if labeled rRNA is used as the hybridization probe. A second type of repeating unit lacks one of the EcoRI cleavage sites within the non-transcribed spacer. This indicates that sequence heterogeneity exists in human rDNA spacers. R-loop mapping of high molecular weight rDNA in the electron microscope reveals that the majority of repeats are rather uniform in length. The average size of 22 repeats was 43.65(±1.27) kb. Two repeats were found with lengths of 28.6 and 53.9 kb, respectively. This, and additional evidence from gels, indicates that some length heterogeneity does exist in the non-transcribed spacer. The structure of the human rDNA repeat is summarized in Figure 10.     

Extra-ribosomal spacer sequences in Triturus

We show that, in Triturus vulgaris meridionalis, sequences homologous to the rDNA "non-transcribed" spacer (NTS) are clustered at chromosomal loci where they are not associated with 18 S or 28 S rDNA genes: these sequences are referred to as the extra-ribosomal spacer sequences. Genomic clones containing such extra-ribosomal spacer sequences have been isolated. As shown by restriction mapping, these clones appear to consist mostly of repetitive BamHI fragments that are, in turn, internally repetitious and highly homologous to each other. The structure of the clones was confirmed by nucleotide sequence analysis, which also demonstrates the high degree of conservation between the BamHI elements and the homologous NTS sequences. An intriguing 12 base-pair homology between the extra-ribosomal spacer sequences and a Xenopus NTS enhancer sequence is reported. The possibility that a repetitive octanucleotide motif found within the BamHI elements could act as a recombination hotspot by virtue of its similarity with the Escherichia coli chi sequence is discussed.     

Unique sequence arrangement of ribosomal genes in the palindromic rDNA molecule of Physarum polycephalum.

R-loop and restriction mapping procedures reveal the organization of coding regions at each end of the giant rDNA palindrome of Physarum polycephalum. A 19S coding region of 2.10 +/- 0.21 kb is located at each end of a very long central spacer (35.64 +/- 2.08 kb). An internal spacer of 1.66 +/- 0.12 kb lies distal to the 19S gene. The 5.8S rRNA coding region is located in this spacer. The 26S gene lies distal to the internal spacer. The 26S gene is unusual among those of eukaryotes in that it consists of 3 coding regions (alpha, beta and gamma) interrupted by 2 intervening sequences. The 26S alpha (most central) coding segment of 2.41 +/- 0.33 kb is separated from the 26S beta segment by an intervening sequence of 0.68 +/- 0.13 kb. The 26S beta segment (0.70 +/- 0.11 kb) is separated from the most distal 26S gamma segment (0.59 +/- 0.14 kb) by an intervening sequence of 1.21 +/- 0.14 kb. The 2 intervening sequences are present in at least 88% of ribsomal genes from active plasmodia, indicating that genes containing these sequences are transcribed. The rDNA termini contain a heterogeneous region which varies in length by +/- 300 base pairs.     

Replication termini in the rDNA of synchronized pea root cells (Pisum sativum)

In synchronized root cells of Pisum sativum (cv. Alaska) the joining of nascent replicons is delayed until cells reach the S-G(2) boundary or early G(2) phase. To determine if the delayed ligation of nascent chains occurs at specific termination sites, we mapped the location of arrested forks in the ribosomal DNA (rDNA) repeats from cells in late S and G(2) phases. Two-dimensional (neutral-alkaline) agarose electrophoresis and Southern blot hybridization with specific rDNA sequences show that only cells located at the S-G(2) boundary and early G(2) phase produce alkali-released rDNA fragments of discrete size. The released fragments are from a particular restriction fragment, demonstrating that the replication forks stop non-randomly within the rDNA repeats. Indirect end-labeling with probes homologous to one or the other end of the fork-containing restriction fragment shows that there are two termination regions, T(1) and T(2), where forks stop. T(1) is located in the non-transcribed spacer and T(2) is at the junction between the non-transcribed spacer and the 18S gene. The two termini are separated by 1.3 kb. Replication forks stop at identical sites in both the 8.6- and 9.0-kb rDNA repeat size classes indicating that these sites are sequence determined.