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.     

Characterization of cloned rat ribosomal DNA fragments

Summary Two Charon 4A lambda bacteriophage clones were characterized which contain all and part of the 18S ribosomal DNA of the rat. One clone contained two Eco RI fragments which include the whole 18S ribosomal RNA region and part of 28S ribosomal RNA region. The other clone contained an Eco RI fragment which covers part of 18S ribosomal RNA region. There were differences between the two clones in the non-transcribed spacer regions suggesting that there is heterogeneity in the non-transcribed spacer regions of rat ribosomal genes. The restriction map of the cloned mouse ribosomal DNA. Eco RI, Hind III, Pst I, and Bam HI sites in 18S ribosomal RNA region were in the same places in mouse and rat DNA but the restriction sites in the 5-spacer regions were different.     

Genomic organization of ribosomal DNA and related sequences inTriturus

The ribosomal RNA genes ofTriturus vulgaris meridionalis are clustered at variable and often multiple chromosomal loci. The rDNA repeats exhibit only a limited and discrete length heterogeneity which is accounted for by the non-transcribed spacer (NTS). Interestingly, sequences homologous to the NTS are clustered outside the ribosomal loci. Clones containing such non ribosomal sequences have been isolated from a genomic library ofT. v. meridionalis and analyzed by restriction mapping. These sequences appear to consist mostly of repetitive Bam HI fragments ranging from 500 bp to 1000 bp. The Bam HI fragments are internally repetitious and highly homologous to each other.     

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.     

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.     

More ribosomal spacer sequences from Xenopus laevis.

The base sequence analysis of a Xenopus laevis ribosomal DNA repeat (7) has been extended to cover almost the entire non-transcribed and external transcribed spacer. A compilation of these sequences is presented. All the repetitive and non-repetitive sequence elements of the spacer are identified and their evolution discussed. Comparison of the X.laevis and S.cerevisiae (25,26) ribosomal DNAs shows about 80% sequence conservation in the 18S gene but no sequence conservation, from the available data, in the external transcribed spacer. The sequence coding for the 3' terminus of the X.laevis 40S ribosomal precursor RNA is presented and its structural features analyzed.     

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.     

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.     

Analysis of a large nontranscribed spacer in the ribosomal DNA of the house cricket,Acheta domesticus (Orthoptera:Gryllidae)

An analysis of a 29-kilobase nontranscribed spacer fragment in the ribosomal DNA (rDNA) of the house cricket, Acheta domesticus, revealed a highly repetitious structure. A total of eight EcoRI repeats of three different size classes measuring 259, 420, and 508 base pairs (bp) was mapped to a region 2 kilobases (kb) from the 18 S coding region. The repeats were oriented in a nonrandom manner and had sequences homologous to DNA located immediately adjacent to the repetitive array. DNA sequence analysis showed that the repetitive region was composed of smaller direct repeats 66, 67, and 383 bp in length. There was minor length heterogeneity of the chromosomal restriction fragments containing the entire array, indicating that a variable number of EcoRI repeats is a minor contributor to the total repeat-unit length heterogeneity. Immediately upstream from the EcoRI array there is a 17-kb region composed of 50 to 60 subrepeat elements recognized by a variety of restriction endonucleases. A subcloned SmaI repeat from the array was not homologous to any other part of the rDNA repeat unit or other chromosomal DNA. There was little length heterogeneity in restriction fragments containing the chromosomal 17-kb repetitions region. Immediately upstream from the 17-Kb region there is a 4.1-kb segment with sequences homologous to the EcoRI repeats.     

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.     

Structure of the central spacer region of extrachromosomal ribosomal DNA in Physarum polycephalum

We have analyzed the sequence organization of the central spacer region of the extrachromosomal ribosomal DNA from two strains of the acellular slime mold Physarum polycephalum. It had been inferred previously from electron microscopy that this region, which comprises about one third of the 60 kb³ palindromic rDNA, contains a complex series of inverted repetitious sequences. By partial digestion of end-labeled fragments isolated from purified rDNA and from rDNA fragments cloned in Escherichia coli, we have constructed a detailed restriction map of this region. The 11 kb of spacer DNA of each half molecule of rDNA contains the following elements: (a) two separate regions, one of 1.1 kb and one of 2.1 kb, composed of many direct repeats of the same 30 base-pair unit; (b) a region of 4.4 kb composed of a complex series of inverted repeats of a 310 base-pair unit; (c) another region of 1.6 kb composed of inverted repeats of the same 310 base-pair unit located directly adjacent to the center of the rDNA; (d) two copies of a unique sequence of 0.85 kb, which probably contains a replication origin. Some of the CpG sequences in the spacer resist cleavage by certain restriction endonucleases and thus appear to be methylated. The lack of perfect symmetry about the central axis and the arrangement of inverted repeated sequences explain the complex pattern of branches and forks of the fold-back molecules previously observed by electron microscopy. Comparison of the rDNA restriction maps from the two strains of Physarum suggests that the repeat units in the spacer are undergoing concerted evolution. We propose a model to explain the evolutionary origin of the several palindromic axes in the Physarum rDNA spacer.     

Molecular analysis of the heterogeneity region of the human ribosomal spacer

The human ribosomal non-transcribed spacers are 30 X 10(3) base-pairs (or 30 kb) in length with a limited length heterogeneity localized in a specific region downstream from the 3' end of the transcribed region. Total DNA digested with EcoRI and BamHI and hybridized with a probe containing the 3' end of the 28 S ribosomal RNA coding region shows four major bands of 3.9 kb, 4.6 kb, 5.4 kb and 6.2 kb. The 5.4 kb band is the most abundant in every individual, followed by the 4.6 kb band. The longest and the shortest size classes are less well-represented and may even be absent. Every individual shows his own pattern of relative abundance of non-transcribed spacer length classes that can be followed through generations. We decided to investigate the molecular structure of the heterogeneity region, in order to cast light onto the mechanisms underlying the origin and maintenance of this length heterogeneity. Pertinent spacer regions of eight ribosomal clones from two human genomic libraries were subcloned and analyzed by restriction mapping and nucleotide sequencing. In the minimal length class, there is a sequence of 700 base-pairs that appears to be tandemly duplicated once, twice or three times in the other length classes. This repeated DNA module contains a region consisting of repetitions of simple pyrimidine groups like C-T, C-T-T-T or C-C-C-T. DNA module repeats may differ by the length of this pyrimidine-rich region. However, these length variations are not continuous, as revealed by Southern transfer analysis of several individuals and different cloned gene units: instead, the repeated modules fall into two discrete length classes of about 700 base-pairs and 800 base-pairs. An imperfect duplication of a short sequence of 86/89 base-pairs is present at the boundary between the heterogeneity region and the upstream flanking region, representing a very ancient duplication event.     

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.     

Nontranscribed spacers in Drosophila ribosomal DNA

Ribosomal DNA nontranscribed spacers in Drosophila virilis DNA have been examined in some detail by restriction site analysis of cloned segments of rDNA, nucleic acid hybridizations involving unfractionated rDNA, and base composition estimates. The overall G+C content of the spacer is 27–28%; this compares with 39% for rDNA as a whole, 40% for main band DNA, and 26% for the D. virilis satellites. Much of the spacer is comprised of 0.25 kb repeats revealed by digestion with Msp I, Fnu DII or Rsd I, which terminate very near the beginning of the template for the ribosomal RNA precursor. The spacers are heterogeneous in length among rDNA repeats, and this is largely accounted for by variation among rDNA units in the number of 0.25 kb elements per spacer. Despite its high A+T content and the repetitive nature of much of the spacer, and the proximity of rDNA and heterochromatin in Drosophila, pyrimidine tract analysis gave no indication of relatedness between the spacer and satellite DNA sequences. Species of Drosophila closely related to D. virilis have rDNA spacers that are homologous with those in D. virilis to the extent that hybridization of a cloned spacer segment of D. virilis rDNA to various DNA is comparable with hybridization to homologous DNA, and distributions of restriction enzyme cleavage sites are very similar (but not identical) among spacers of the various species. There is spacer length heterogeneity in the rDNA of all species, and each species has a unique major rDNA spacer length. Judging from Southern blot hybridization, D. hydei rDNA spacers have 20–30% sequence homology with D. virilis rDNA spacers, and a repetitive component is similarly sensitive to Msp I and Fnu DII digestion, D. melanogaster rDNA spacers have little or no homology with counterparts in D. virilis rDNA, despite a similar content of 0.25 kb repetitive elements. In contrast, sequences in rDNA that encode 18S and 28S ribosomal RNA have been highly conserved during the divergence of Drosophila species; this is inferred from interspecific hybridizations involving ribosomal RNA and a comparison of distributions of restriction enzyme cleavage sites in rDNA.Dedicated to Professor Wolfgang Beermann on the occasion of his sixtieth birthday     

Cloning and analysis of ribosomal DNA of Chironomus thummi piger and chironomus thummi thummi

The ribosomal DNAs from Ch. thummi piger and Ch. th. thummi were cloned and analysed by a variety of restriction endonucleases. Comparison of rDNA clones from the two subspecies revealed a considerable length difference: the length of the analysed rDNA cistrons is approximately 9.0 kb for Ch. th. piger and approximately 14.5 kb for Ch. th. thummi. The nearly 5 kb additional DNA in Ch. th. thummi is clearly located within the non-transcribed spacer region, and consists of AT-rich, reptitive DNA elements. These elements with a basic repeat length of approximately 120 bp, are arranged tandemly in stretches of up to about 50 identical copies, which are characterized by a cleavage site for ClaI restriction endonuclease. They are found only in the Ch. th. thummi rDNA clones and not in the Ch. th. piger clones. Southern hybridizations between cloned ribosomal DNA and centromeric highly repetitive DNA have shown that the ribosomal repetitive Cla-elements are closely related to a highly repetitive DNA sequence family, which is present in various chromosomal sites particularly the centromeres. Sequence analysis has revealed more than 90% homology between the ribosomal Cla-elements and the centromeric Cla-elements. — Since it is clear from cytological investigations that Ch. th. piger with the small rDNA repeating unit is the phylogenetically older subspecies, we postulate a transposition of Cla-elements into the nucleolar DNA during the evolution of Ch. th. thummi.     

Cloning and characterization of the ribosomal genes of the sea-urchin Paracentrotus lividus. Heterogeneity of the multigene family

A Paracentrotus lividus genomic library was constructed using sperm DNA prepared from a single animal. The DNA was fragmented by partial digestion with DNase II, sized on a preparative agarose gel and inserted in the Pst I site of pBR 322 by the dG X dC tailing method. Recombinant plasmids containing ribosomal DNA were isolated, a restriction map of the gene was determined and the 18S and 26S transcribed sequences were located by S1 protection mapping. The organization of the ribosomal genes in genomic DNA of individual animals and of a pool of animals was studied by blot-hybridization of the restriction fragments, using as probes nick-translated 32P-labelled cloned ribosomal DNA fragments or 18S and 26S sea-urchin ribosomal RNA. The repeat length of the ribosomal unit was about 10.5 X 10(3) bases. A comparison of the restriction patterns of DNA from different animals showed a marked sequence heterogeneity in the spacer region of these genes. Variations of about 200 base pairs were detectable in the length of the spacer of some individuals.     

Mapping of the ribosomal RNA genes on spinach chloroplast DNA.

Spinach chloroplast ribosomal RNAs have been hybridized to restriction endonuclease fragments of spinach chloroplast DNA. All three RNA species (23S, 16S and 5S) hybridized to a single large fragment when the DNA was digested with either Sall or Pstl. Hybridization of 23S RNA to fragments produced by Smal yielded two radioactive bands which corresponded to the bi-molar 2.5 X 10(6) and 1.15 X 10(6) Mr fragments. 16S RNA also hybridized to two, bi-molar Smal fragments (3.4 X 10(6) and 2.5 X 10(6) Mr) and 5S RNA hybridized to the 1.15 X 10(6) Mr bi-molar Smal fragment. The 23S RNA and 16S RNA cistrons were each also shown to contain a single EcoRI site. From the data it was possible to conclude that the ribosomal RNA genes are located on the inverted repeat region of the spinach chloroplast DNA restriction map [1,2], that the sequence of the cistrons is 16S - 23S - 5S and that the size of the spacer between the 16S and 23S RNA cistrons is approximately 0.90 X 10(6) Mr.