A comparison of the structural organization of amplified ribosomal DNA from Xenopus mulleri and Xenopus laevis.

Secondary structure maps of long single strands of amplified ribosomal DNA from two closely related species of frogs, Xenopus laevis and X. mulleri, have been compared. The secondary structure pattern of the gene region is identical in both ribosomal DNAs while the patterns in the non-transcribed spacers² differ. In X. mulleri, the spacer shows an extended region without any secondary structure adjacent to the 28 S ribosomal RNA sequence. In contrast, the same region in the X. laevis spacer has extensive secondary structure. A comparison of secondary structure maps and denaturation maps of these two ribosomal DNAs (Brown et al., 1972) reveals that the portion without secondary structure in the X. mulleri spacer corresponds to an early melting A + T-rich region. As in X. laevis ribosomal DNA, Escherichia coli restriction endonuclease (EcoRI) makes two cuts in each repeating unit of amplified ribosomal DNA from X. mulleri. The position of the cleavage sites is identical in the two species as judged from secondary structure mapping of the two classes of EcoRI fragments generated. The small fragments of X. mulleri ribosomal DNA are homogeneous in size with a duplex molecular weight of 3.0 × 10⁶, and contain about 85% of the 28 S ribosomal RNA gene and about 17% of the 18 S ribosomal RNA gene. The large fragments are heterogeneous in size with molecular weights ranging from 4.2 to 4.9 × 10⁶, and contain the remaining portions of the gene regions and the nontranscribed spacer. Heteroduplexes made between large fragments of different lengths show only deletion loops. The position of these loops indicates that the length heterogeneity resides in the non-transcribed spacer region. Electrophoretic analysis of EcoRI digests of chromosomal ribosomal DNA from X. mulleri demonstrates that this DNA is heterogeneous in length as well.     

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.     

Fragments of rDNA within the Chinese hamster genome

We report the isolation and partial characterization of distinctEcoRI fragments of the Chinese hamster genome which contain regions complementary to a 1-kb portion of the mature 18 S ribosomal RNA molecule. This previously undescribed 18 S rDNA-like region, which we have termed a fragment of ribosomal DNA (frDNA), has been shown by sequence analysis to correspond to a region extending 1 kb upstream from the 3 terminus of the mature 18 S rRNA. Within the five frDNA-containing clones described here, no other region of the ribosomal RNA cistron was detected, making it unlikely that these are polymorphic forms of the ribosomal DNA repeat. The 18 S rDNA-complementary region appears to be flanked by an imperfect direct repeat, which could have been the result of the retroinsertion of a fragment of ribosomal RNA. Directly adjacent to the 18 S rDNA-like region we have identified nonribosomal sequences which appear common to all of the frDNA-containing clones we examined. At least eight different-sizedEcoRI fragments contain frDNAs and the abundance of the frDNAs appears to be of the order of 30 per genome. The occurrence of multiple copies of this ribosomal-nonribosomal chimera suggests that, once formed, the chimera was duplicated within the genome.This work was supported by funds provided by the Graduate School of the University of Wisconsin—Milwaukee, the Cancer Center of the Medical College of Wisconsin, and the Shaw Scholars program of the James D. Shaw and Dorothy Shaw Fund, Milwaukee Foundation.     

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.     

Restriction site patterns in the ribosomal DNA of Camelidae

The restriction map of rDNA from South American camelids and the Bactrian camel was analyzed by digestion of high-molecular-weight DNA with endonucleases EcoRI, BamHI and the two combined followed by Southern blot hybridization with probes for the 18S and 28S rDNA sequences. We scored a total of 17 restriction sites, six of which were mapped conserved in all the species. The other eleven corresponded to spacer regions and revealed variations between these taxa. The study showed that the two groups differ in the length of the internal transcribed spacer. Also they showed the existence of two regions of fast evolution on the opposite termini of the external spacer. A restriction site present at low frequency in the non-transcribed spacer of guanaco and llama was the only difference encountered within the South American group.     

Chloroplast ribosomal RNA genes in Euglena gracilis exist as three clustered tandem repeats

Chloroplast ribosomal DNA from Euglena gracilis was partially purified, digested with restriction endonucleases BamHI or EcoRI and cloned into bacterial plasmids. Plasmids containing the ribosomal DNA were identified by their ability to hybridize to chloroplast ribosomal RNA and were physically mapped using restriction endonucleases BamHI, EcoRI, HindIII and HpaI. The nucleotide sequences coding for the 16S and the 23S chloroplast ribosomal RNAs were located on these plasmids by hybridizing the individual RNAs to denatured restriction endonuclease DNA fragments immobilized on nitrocellulose filters. Restriction endonuclease fragments from chloroplast DNA were analyzed in a similar fashion. These data permitted the localization on a BamHI map of the chloroplast DNA three tandemly arranged chloroplast ribosomal RNA genes. Each ribosomal RNA gene consisted of a 4.6 kilobase pair region coding for the 16S and 23S ribosomal RNAs and a 0.8 kilobase pair spacer region. The chloroplast ribosomal DNA represented 12% of the chloroplast DNA and is G + C rich.     

Ribosomal DNA in Drosophila melanogaster. I. Isolation and characterization of cloned fragments.

Fragments of rDNA3 from Drosophila melanogaster produced by the restriction endonuclease EcoRI were cloned in the form of recombinant plasmids in Escheriehia coli. Maps were prepared showing the location of the coding regions and of several restriction endonuclease sites. Most rDNA repeats have a single EcoRI site in the 18 S gene region. Thus, 19 of 24 recombinant clones contained a full repeat of rDNA. Ten repeats with continuous 28 S genes and repeats containing insertions in the 28 S gene of 0.5, 1 and 5 kb were isolated. The 0.5 and 1 kb insertion sequences are homologous to segments of the 5 kb insertions; because of this homology they are grouped together and identified as type 1 insertions. Four recombinant clones contain an rDNA fragment that corresponds to only a portion of a repeating unit. In these fragments the 28 S gene is interrupted by a sequence which had been cleaved by EcoRI. The interrupting sequences in these clones are not homologous to any portion of type 1 insertions and are therefore classified as type 2. In one of the above clones the 28 S gene is interrupted at an unusual position; such a structure is rare or absent in genomic rDNA from the fly. Another unusual rDNA fragment was isolated as a recombinant molecule. In this fragment the entire 18 S gene and portions of the spacer regions surrounding it are missing from one repeat. A molecule with the same structure has been found in uncloned genomic rDNA by electron microscopic examination of RNA/DNA hybrids.     

Unique arrangement of coding sequences for 5 S, 5.8 S, 18 S and 25 S ribosomal RNA in Saccharomyces cerevisiae as determined by R-loop and hybridization analysis.

The arrangement of the coding sequences for the 5 S, 5.8 S, 18 S and 25 S ribosomal RNA from Saccharomyces cerevisiae was analyzed in λ-yeast hybrids containing repeating units of the ribosomal DNA. After mapping of restriction sites, the positions of the coding sequences were determined by hybridization of purified rRNAs to restriction fragments, by R-loop analysis in the electron microscope, and by electrophoresis of S₁ nuclease-treated rRNA/rDNA hybrids in alkaline agarose gels. The R-loop method was improved with respect to the length calibration of RNA/DNA duplexes and to the spreading conditions resulting in fully extended 18 S and 25 S rRNA R-loops. The qualitative results are: (1) the 5 S rRNA genes, unlike those in higher eukaryotes, alternate with the genes of the precursor for the 5.8 S, 18 S and 25 S rRNA; (2) the coding sequence for 5.8 S rRNA maps, as in higher eukaryotes, between the 18 S and 25 S rRNA coding sequences. The quantitative results are: (1) the tandemly repeating rDNA units have a constant length of 9060 ± 100 nucleotide pairs with one SstI, two HindIII and, dependent on the strain, six or seven EcoRI sites; (2) the 18 S and 25 S rRNA coding regions consist of 1710 ± 80 and 3360 ± 80 nucleotide pairs, respectively; (3) an 18 S rRNA coding region is separated by a 780 ± 70 nucleotide pairs transcribed spacer from a 25 S rRNA coding region. This is then followed by a 3210 ± 100 nucleotide pairs mainly non-transcribed spacer which contains a 5 S rRNA gene.     

Restriction enzyme mapping of ribosomal DNA ofSchistosoma spindale andS. leiperi (Digenea) and its application to interspecific differentiation

Restriction maps were determined for the ribosomal RNA gene complex ofSchistosoma spindale andS. leiperi. The restriction map of theS. spindale rRNA gene complex was found to differ from those of other schistosomes previously described by the presence of an additionalEcoRI site in the non transcribed spacer region. In common withS. mattheei andS. margrebowiei, bothS. leiperi andS. spindale appear to have insertions in the transcribed spacer region, relative toS. mansoni.EcoRI digests of genomic DNA, probed with pSM 889, enabled differentiation ofS. spindale andS. leiperi from four other species of schistosome.     

Chloroplast DNA variation in pearl millet and related species

The evolution of specific regions of the chloroplast genome was studied in five grass species in the genus Pennisetum, including pearl millet, and one species from a related genus (Cenchrus). Three different regions of the chloroplast DNA were investigated. The first region included a 12-kilobase pair (kbp) EcoRI fragment containing the 23S, 16S and 5S ribosomal RNA genes, which is part of a larger duplicated region of reverse orientation. The second region was contained in a 21-kbp Sa/I fragment, which spans the short single-copy sequence separating the two reverse repeat structures and which overlaps the duplicated copies of the 12-kbp Eco RI fragment. The third region was a 6-kbp EcoRI fragment located in the large single-copy region of the chloroplast genome. Together these regions account for slightly less than 25% of the chloroplast genome. Each of these DNA fragments was cloned and used as hybridization probes to determine the distribution of homologous DNA fragments generated by various restriction endonuclease digests.—A survey of 12 geographically diverse collections of pearl millet showed no indication of chloroplast DNA sequence polymorphism, despite moderate levels of nuclear-encoded enzyme polymorphism. Interspecific and intergeneric differences were found for restriction endonuclease sites in both the small and the large single-copy regions of the chloroplast genome. The reverse repeat structure showed identical restriction site distributions in all materials surveyed. These results suggest that the reverse repeat region is differentially conserved during the evolution of the chloroplast genome.     

Characterization of mouse ribosomal gene fragments purified by molecular cloning.

Four mouse ribosomal gene fragments cloned in lambda gtWES were studied by restriction enzyme mapping and Southern transfer experiments. These fragments were found to contain 18S DNA and transcribed as well as non-transcribed spacer DNA. Variation in the structure of these mouse DNA inserts was limited to one region of spacer DNA. This variation may reflect real structural differences found in mouse ribosomal genes or possibly deletion events which occurred during cloning. The transcribed regions of the inserts appear identical to one antoher and restriction enzyme fragments from this region correspond to fragments observed in digests of total mouse DNA. These clones will be useful in studying the structure of transcribed spacer DNA including the ribosomal gene promoter.     

Physical mapping of the pea chloroplast DNA and localization of the ribosomal RNA genes

The closed circular DNA of pea chloroplast has been digested with restriction endonucleases SalI, SmaI, BamHI, XbaI, XhoI, HindIII, and EcoRI. A physical restriction map of pea ctDNA has been constructed by mapping the SalI and SmaI sites. The pea ctDNA has been found to contain one set of ribosomal RNA genes by Southern hybridization of restriction endonuclease digest, R-loop studies, and DNA-DNA heteroduplex mapping. The 23 S and 16 S RNA genes are confined to a DNA region of 3.0 and 1.5 kbp, respectively. The two rRNA chains are separated by a spacer region of 2.2 kbp.     

Human ribosomal RNA gene spacer sequences are found interspersed elsewhere in the genome

A cloned EcoRI fragment containing human 18 S rRNA gene sequences was used to screen a gene library to obtain a set of 8 overlapping cloned DNA segments extending into the non-transcribed spacer region of the human ribosomal RNA gene cluster. 19.4 kb of the approx. 43-kb rDNA repeat was obtained in cloned form and mapped with restriction endonucleases. None of the clones obtained extended into 28 S rRNA sequences. A 7-kb region of non-transcribed spacer DNA shared in common between five independent clones was subjected to comparative restriction digests. It was estimated that sequences among the five different spacer isolated varied by not more than 1.0%, if all the observed differences are assumed due to point mutation. HaeII-restriction fragments from within this same 7-kb region contain sequences carried not only within the tandem repeats of the gene cluster but interspersed elsewhere in the genome. Some of these sequences correspond to the Alu family of highly repeated interspersed sequences.     

An electron microscope heteroduplex study of the ribosomal DNAs of Xenopus laevis and Xenopus mulleri

The arrangement of the genes and spacers has been analyzed in ribosomal DNA of Xenopus laevis and Xenopus mulleri by heteroduplex mapping and visualization of ribosomal RNA-DNA hybrids. Heterologous reassoeiated molecules show a characteristic pattern in which two perfectly duplexed regions, whose lengths are those predicted by the known lengths of the 18 S and 28 S genes, are separated by a small substitution loop of about 0.23 × 10⁶ daltons and a large region of partial homology which averages 3.24 × 10⁶ daltons. These mismatched regions are entirely consistent with the known sequence divergence previously described (Brown et al., 1972) for the transcribed and non-transcribed spacer regions of the two rDNAs, respectively. Hybrids of X. laevis rDNA with 18 S and 28 S rRNA contain two duplex regions of the expected lengths for the 18 S and 28 S genes separated by 0.49 × 10⁶ daltons of single-strand DNA. This latter value is the length of the transcribed spacer region between the 18 S and 28 S RNAs that has been measured within the 40 S RNA precursor molecule by secondary structure mapping (Wellauer &; Dawid, personal communication). There is also a longer single-strand region separating one 18 S + 28 S gene set from the next; this is considered to be mainly non-transcribed spacer.We conclude that the 18 S and 28 S genes are separated by about 0.5 × 10⁶ daltons of DNA of which about half is homologous in the two Xenopus species. This region is part of the transcribed spacer. In addition, the longer non-transcribed spacer can be seen to have some homology between the two species; the location of this homology is fairly reproducible between molecules and has been carefully documented by contour length measurements.     

Organization of nuclear ribosomal DNA and species-specific polymorphism in closely related Fraxinus excelsior and F. oxyphylla

The ribosomal DNA repeat units of two closely related species of the genus Fraxinus, F. excelsior and F. oxyphylla, were characterized. The physical maps were constructed from DNA digested with BamHI, EcoRI, EcoRV and SacI, and hybridized with three heterologous probes. The presence or the absence of an EcoRV restriction site in the 18s RNA gene characterizes two ribosomal DNA unit types found in both species and which coexist in all individuals. A third unit type appeared unique to all individuals of F. oxyphylla. It carries an EcoRI site in the intergenic spacer. Each type of unit displayed length variations. The rDNA unit length of F. excelsior and F. oxyphylla was determined with EcoRV restriction. It varied between 11kb and 14.5kb in F. excelsior and between 11.8kb to 13.8kb in F. oxyphylla. Using SacI restriction, at least ten spacer length variants were observed in F. excelsior, for which a detailed analysis was conducted. Each individual carries 2–4 length variants which vary by a 0.3-kb step multiple. This length variation was assigned to the intergenic spacer. By using the entire rDNA unit of flax as probe in combination with EcoRI restriction, each species can be unambiguously discriminated. The species-specific banding pattern was used to compare trees from a zone of sympatry between the two species. In some cases, a conflicting classification was obtained from morphological analysis and the use of the species-specific rDNA polymorphism. Implications for the genetic management of both species are discussed.     

Unmethylated regions in the intergenic spacer of maize and teosinte ribosomal RNA genes

The restriction endonucleases Hpa II and Msp I were used to examine cytosine methylation in the ribosomal RNA genes (rDNA) of inbred lines of maize and species of teosinte. In all of the rDNAs examined, Msp I (not sensitive to mCpG) digestion yielded a distribution of lower molecular weight fragments indicative of multiple recognition sites. The majority of the rDNA arrays in an individual were inaccessible to Hpa II (sensitive to mCpG) cleavage, but a significant fraction (10–25%) was cleaved at least once by Hpa II into repeat unit length fragments (9.1 kbp). In some maize inbred lines, one or two additional fragment populations (less than 9.1 kbp in length) were also produced by Hpa II digestion. All of the unmethylated Hpa II sites mapped to the intergenic spacer (IGS), and the major unmethylated site was located approximately 800 bp 5 to the start of the 18S RNA coding sequence. An Eco RI polymorphism, present in the 26S gene of certain inbred lines and hybrids, was utilized to investigate the organization of unmethylated repeat units in the rDNA array. In double digest experiments with Hpa II/Eco RI, the fragments from repeat units with two Eco RI sites were sensitive to Hpa II digestion, whereas, the fragments from repeat units with a single Eco RI site were almost completely resistant to Hpa II digestion. Similar digestion patterns were also observed in Eco RII (sensitive to mCNG)/Eco RI digests. These results suggest that unmethylated and Eco RI polymorphic sites occur in the same repeat units.     

Characterisation of complete type II insertions in cloned segments of ribosomal DNA from Drosophila melanogaster

We have isolated cloned segments of ribosomal DNA that have EcoRI restrictable (type II) insertions in their 28 S genes. The type II insertions in these plasmids are homologous sequences and have three characteristic cleavage sites for EcoRI. One of these clones is unusual in that it has undergone a deletion of part of the 28 S gene at or near the site of the type II insertion. A second is unusual in that, in addition to the type II insertion in the rDNA, the transcribed spacer sequences are interrupted by an unidentified sequence. This sequence differs in its arrangement of restriction sites from the sequence that interrupts the transcribed spacer of cDm207 (Glover, 1977). The type II sequences in all these clones share homology with the unusually long ‘insertion’ that interrupts the 28 S gene of cDm207. We have re-examined the nature of the additional sequences linked to the type II sequences of cDm207 and find them to be related to type I rDNA insertion sequences.     

Molecular systematics of Brassica and allied genera in subtribes Brassicinae, Raphaninae, Moricandiinae, and Cakilinae (Brassicaceae, tribe Brassiceae); the organization and evolution of ribosomal gene families

DNA restriction endonuclease fragment analysis was used to obtain new information on the genomic organization of ribosomal DNA (rDNA) of Brassica and allied genera. The total genomic DNA of 95 accessions of 52 species representing 16 genera was restricted with six enzymes, and the restriction fragments were probed with three ribosomal clones (pTA71, Ver 18‐6, and Ver 6‐5). Eleven repeat unit length classes were recognized. The repeat unit size classes of 8.9 kb and 9.5 kb were observed most commonly, being represented in 17 and 14 species, respectively. The restriction enzyme SacI produced three to six (generally three) bands with detectable hybridization to the probe pTA71. This probe–enzyme combination indicated a remarkable uniformity amongst Brassica and allied genera in the coding region of repeat units. By contrast, an extensive size variation in the restriction fragments could be localized in the intergenic spacer (IGS) region. Eleven IGS‐containing length variants were detected. Complex hybridization patterns, resulting from extensive repeat unit heterogeneity and taxon‐specific methylation of one or more cleavage sites, were obtained with the EcoRI + pTA71 combination. The relative homologies between the coding regions were evident from the presence of 1.5 kb in all the taxa, and 0.4‐, 1.3‐, and 1.7‐kb fragments in 33, 27, and 24 species, respectively. The SacI + pTA71 and EcoRI + pTA71 combinations were generally able to distinguish taxa both within and between genera. Three restriction endonuclease digests probed with three ribosomal clones yielded essentially identical fragmentation patterns across all the accessions within the cultivated species Brassica campestris, B. oleracea, and B. juncea. In B. napus, three and seven accessions exhibited restriction profiles similar to one and both diploid progenitor species, respectively. Overall, rDNA repeat unit length polymorphism showed good correlation with the cytodeme‐based classification of Brassica and allied genera. © 2008 The Linnean Society of London, Botanical Journal of the Linnean Society, 2008, 157 , 545–557.     

Fine structure physical mapping of 4S RNA genes on mitochondrial DNA of Saccharomyces cerevisiae.

Summary We have localized the genes for mitochondrial 4S RNA on the physical map of themtDNA of severalSaccharomyces cerevisiae strains by hybridization of iodinated 4S RNA to the restriction fragments obtained with endonucleasesHindII+III,EcoRI andHapII. The data indicate that 5–8 of the 4S RNA genes are dispersed over a large area of the genome whereas the rest (about 18 genes) is located within an area of about 9000 bp in length (about 12% of the genome) between the markers for chloramphenicol and paromomycin resistance (RIB 1 and PAR 1 loci). Within this region a cluster is present of 5 genes on a DNA fragment of 460 bp.Abbreviations Used mtDNA mitochondrial DNA - mtRNA mitochondrial RNA - rRNA ribosomal RNA - tRNA transfer RNA - C, E, P and O cytoplasmically-inherited resistance markers for chloramphenicol, erythromycin, paromomycin and oligomycin, respectively - SSC 150 mM sodium chloride, 15 mM sodium citrate (pH 7.0) - SDS sodium dodecylsulphate - EDTA (sodium)ethylenediaminetetraacetate; TEMED - N,N,N N-tetramethylethylenediamine; (k)bp, (kilo)base pairs - EthBr ethidium bromide     

Complete cloning of the chloroplast genome of safflower in λ EMBL3 and mapping of 23S and 16S rRNA genes

Summary A recombinant DNA library was constructed from partial BamHI or MboI digests of safflower (Carthamus tinctorius L.) chloroplast DNA, in the BamHI site of EMBL3. Seventeen recombinants, selected by chromosome walking, were found to contain overlapping fragments of the entire chloroplast genome. These clones were mapped using single and double digests of BamHI, EcoRI and HindIII. cDNAs synthesized from isolated 16S and 23S chloroplast rRNAs were used to map the ribosomal RNA genes relative to physical maps of the above restriction enzymes. The mapped positions of the rRNA genes for the safflower chloroplast DNA are in good agreement with previously published data for tobacco, spinach and several other higher plants.