The ribosomal RNA cistrons

Nucleolar DNA: the host and the guests

Nucleoli are formed on the basis of ribosomal genes coding for RNAs of ribosomal particles, but also include a great variety of other DNA regions. In this article, we discuss the characteristics of ribosomal DNA: the structure of the rDNA locus, complex organization and functions of the intergenic spacer, multiplicity of gene copies in one cell, selective silencing of genes and whole gene clusters, relation to components of nucleolar ultrastructure, specific problems associated with replication. We also review current data on the role of non-ribosomal DNA in the organization and function of nucleoli. Finally, we discuss probable causes preventing efficient visualization of DNA in nucleoli.

No evidence that sex and transposable elements drive genome size variation in evening primroses

Genome size varies dramatically across species, but despite an abundance of attention there is little agreement on the relative contributions of selective and neutral processes in governing this variation. The rate of sex can potentially play an important role in genome size evolution because of its effect on the efficacy of selection and transmission of transposable elements (TEs). Here, we used a phylogenetic comparative approach and whole genome sequencing to investigate the contribution of sex and TE content to genome size variation in the evening primrose (Oenothera) genus. We determined genome size using flow cytometry for 30 species that vary in genetic system and find that variation in sexual/asexual reproduction cannot explain the almost twofold variation in genome size. Moreover, using whole genome sequences of three species of varying genome sizes and reproductive system, we found that genome size was not associated with TE abundance; instead the larger genomes had a higher abundance of simple sequence repeats. Although it has long been clear that sexual reproduction may affect various aspects of genome evolution in general and TE evolution in particular, it does not appear to have played a major role in genome size evolution in the evening primroses.

Optimal eukaryotic 18S and universal 16S/18S ribosomal RNA primers and their application in a study of symbiosis

Eukaryotic 18S ribosomal RNA (rRNA) gene primers that feature a wide coverage are critical in detecting the composition of eukaryotic microscopic organisms in ecosystems. Here, we predicted 18S rRNA primers based on consecutive conserved sites and evaluated their coverage efficiency and scope of application to different eukaryotic groups. After evaluation, eight of them were considered as qualified 18S primers based on coverage rate. Next, we examined common conserved regions in prokaryotic 16S and eukaryotic 18S rRNA sequences to design 16S/18S universal primers. Three 16S/18S candidate primers, U515, U1390 and U1492, were then considered to be suitable for simultaneous amplification of the rRNA sequences in three domains. Eukaryotic 18S and prokaryotic 16S rRNA genes in a sponge were amplified simultaneously using universal primers U515 and U1390, and the subsequent sorting of pyrosequenced reads revealed some distinctive communities in different parts of the sample. The real difference in biodiversity between prokaryotic and eukaryotic symbionts could be discerned as the dissimilarity between OTUs was increased from 0.005 to 0.1. A network of the communities in external and internal parts of the sponge illustrated the co-variation of some unique microbes in certain parts of the sponge, suggesting that the universal primers are useful in simultaneous detection of prokaryotic and eukaryotic microbial communities.

Intra-genomic variation in the ribosomal repeats of nematodes

Ribosomal loci represent a major tool for investigating environmental diversity and community structure via high-throughput marker gene studies of eukaryotes (e.g. 18S rRNA). Since the estimation of species' abundance is a major goal of environmental studies (by counting numbers of sequences), understanding the patterns of rRNA copy number across species will be critical for informing such high-throughput approaches. Such knowledge is critical, given that ribosomal RNA genes exist within multi-copy repeated arrays in a genome. Here we measured the repeat copy number for six nematode species by mapping the sequences from whole genome shotgun libraries against reference sequences for their rRNA repeat. This revealed a 6-fold variation in repeat copy number amongst taxa investigated, with levels of intragenomic variation ranging from 56 to 323 copies of the rRNA array. By applying the same approach to four C. elegans mutation accumulation lines propagated by repeated bottlenecking for an average of ~400 generations, we find on average a 2-fold increase in repeat copy number (rate of increase in rRNA estimated at 0.0285-0.3414 copies per generation), suggesting that rRNA repeat copy number is subject to selection. Within each Caenorhabditis species, the majority of intragenomic variation found across the rRNA repeat was observed within gene regions (18S, 28S, 5.8S), suggesting that such intragenomic variation is not a product of selection for rRNA coding function. We find that the dramatic variation in repeat copy number among these six nematode genomes would limit the use of rRNA in estimates of organismal abundance. In addition, the unique pattern of variation within a single genome was uncorrelated with patterns of divergence between species, reflecting a strong signature of natural selection for rRNA function. A better understanding of the factors that control or affect copy number in these arrays, as well as their rates and patterns of evolution, will be critical for informing estimates of global biodiversity.

Pure genes, pure genius

The 2012 Albert Lasker Special Achievement Award in Medical Science will be shared by Donald Brown and Tom Maniatis for their scientific work leading to the purification and study of single genes by physical and molecular biological methodologies. Brown and Maniatis are also recognized for their extraordinary commitment and generosity in promoting the careers of young scientists. The impact of these accomplishments has transformed biological and medical science over the past four decades.

Genomic asymmetry in allopolyploid plants: wheat as a model

The evolvement of duplicated gene loci in allopolyploid plants has become the subject of intensive studies. Most duplicated genes remain active in neoallopolyploids contributing either to a favourable effect of an extra gene dosage or to the build-up of positive inter-genomic interactions when genes or regulation factors on homoeologous chromosomes are divergent. However, in a small number of loci (about 10%), genes of only one genome are active, while the homoeoalleles on the other genome(s) are either eliminated or partially or completely suppressed by genetic or epigenetic means. For several traits, the retention of controlling genes is not random, favouring one genome over the other(s). Such genomic asymmetry is manifested in allopolyploid wheat by the control of various morphological and agronomical traits, in the production of rRNA and storage proteins, and in interaction with pathogens. It is suggested that the process of cytological diploidization leading to exclusive intra-genomic meiotic pairing and, consequently, to complete avoidance of inter-genomic recombination, has two contrasting effects. Firstly, it provides a means for the fixation of positive heterotic inter-genomic interactions and also maintains genomic asymmetry resulting from loss or silencing of genes. The possible mechanisms and evolutionary advantages of genomic asymmetry are discussed.

Suitability of quantitative real-time PCR to estimate the biomass of fungal root endophytes

A nested single-copy locus-based quantitative PCR (qPCR) assay and a multicopy locus-based qPCR assay were developed to estimate endophytic biomass of fungal root symbionts belonging to the Phialocephala fortinii sensu lato-Acephala applanata species complex (PAC). Both assays were suitable for estimation of endophytic biomass, but the nested assay was more sensitive and specific for PAC. For mycelia grown in liquid cultures, the correlation between dry weight and DNA amount was strong and statistically significant for all three examined strains, allowing accurate prediction of fungal biomass by qPCR. For mycelia colonizing cellophane or Norway spruce roots, correlation between biomass estimated by qPCR and microscopy was strain dependent and was affected by the abundance of microsclerotia. Fungal biomass estimated by qPCR and microscopy correlated well for one strain with poor microsclerotia formation but not for two strains with high microsclerotia formation. The accuracy of qPCR measurement is constrained by the variability of cell volumes, while the accuracy of microscopy can be hampered by overlapping fungal structures and lack of specificity for PAC. Nevertheless, qPCR is preferable because it is highly specific for PAC and less time-consuming than quantification by microscopy. There is currently no better method than qPCR-based quantification using calibration curves obtained from pure mycelia to predict PAC biomass in substrates. In this study, the DNA amount of A. applanata extracted from 15 mm of Norway spruce fine root segments (mean diameter, 610 microm) varied between 0.3 and 45.5 ng, which corresponds to a PAC biomass of 5.1 +/- 4.5 microg (estimate +/- 95% prediction interval) and 418 +/- 264 microg.

Chromosomal localization and copy number of 18S + 28S ribosomal RNA genes in evolutionarily diverse mosquitoes (Diptera, Culicidae)

In situ hybridization using 3H-labeled 18S and 28S ribosomal DNA (rDNA) probes from Aedes albopictus was performed on the mitotic chromosomes of 20 species of mosquitoes belonging to 8 genera of subfamilies Culicinae and Anophelinae. In all but one species examined, the rDNA family was localized to a single chromosome per haploid genome. Aedes triseriatus was the only exception, with the rDNA cistrons present on chromosome 1 and on chromosome 3. The ribosomal RNA genes were located on chromosome 1 in Ae. albopictus, Ae. aegypti, Ae. flavopictus, Ae. seatoi, A. polynesiensis, Ae. alcasidi, Ae. annandalei, Ae. mascarensis, Ae. hendersoni, Ae. atropalpus, Ae. epactius, Culex pipiens quinquefasciatus, Wyeomyia smithii, and Sabethes cyaneus; chromosome 2 in Ae. mediovittatus and Haemagogus equinus; chromosome 3 in Armigeres subalbatus and Tripteroides bambusa; and the heteromorphic X and Y chromosomes in Anopheles quadrimaculatus. The variation in the location of ribosomal RNA genes on the different chromosomes and at different positions on the chromosome arm among the mosquito species examined is suggestive of considerable chromosome repatterning through translocations and inversions in the karyotypic evolution of mosquitoes. Dot-blot hybridization was used to estimate copy number of rRNA genes; the copy number per haploid genome ranged from 39 +/- 3.27 in Sa. cyaneus to 1023 +/- 68.14 in Ae. flavopictus.

The correlation between rDNA copy number and genome size in eukaryotes

Both rDNA gene multiplicity and genome size vary widely among eukaryotes. For some time, there has been debate regarding any possible relationship between these two parameters. The present study uses data on genome size and rDNA copy number for 162 species of plants and animals to test the association between genome size and rDNA copy number, and provides the first convincing evidence of a strong positive relationship between the two within and among these two groups of organisms. No simple explanations exist for this relationship, but it is nevertheless of clear relevance from both practical and theoretical perspectives.

The dawn of gene isolation

Ever since it became clear through the work of Watson and Crick that the gene is a stretch of double stranded helical DNA and is understandable in chemical terms, biochemists have striven to get their hands on isolated genes. The isolation of the ribosomal genes of Xenopus laevis in 1966 provided a first instance where a purified DNA of known function could be investigated, long before the advent of gene cloning technologies. The second instance was the purification of the Lac operon from Escherichia coli. Later, but still before the gene cloning days the 5S RNA genes of X. laevis and the histone genes of the sea urchin Psammechinus miliaris were isolated by physico-chemical methods, but their isolation marked the end of an era. By 1975, gene cloning technology was well established and the isolation of genes quickly became an everyday occurrence.

A ribosomal orphon sequence from Xenopus laevis flanked by novel low copy number repetitive elements

We have used a differential cloning approach to isolate ribosomal/non-ribosomal frontier sequences from Xenopus laevis. A ribosomal intergenic spacer sequence (IGS) was cloned and shown not to be physically linked with the ribosomal locus. This ribosomal orphon contained the IGS sequences found immediately downstream of the 28S gene and included an array of enhancer repetitions and a non-functional spacer promoter. The orphon sequence was flanked by a member of the novel 'Frt' low copy repetitive element family. Three individual Frt repeats were sequenced and all members of this family were shown to lie clustered at two chromosomal sites, one of which contained the ribosomal orphon. One of the Frt elements contained an insertion of 297 bp that showed extensive homology to sequences within at least three other Xenopus genes. Each homology region was flanked by members of the T2 family of short interspersed repetitive elements, (SINEs), and by its target insertion sequence, suggesting multiple translocation events. The data are discussed in terms of the evolution of the ribosomal gene locus.

Determination of copy number of rRNA genes in Pneumocystis carinii f. sp. hominis

Differential PCR was performed to determine the copy number of rRNA genes in Pneumocystis carinii f. sp. hominis. Two different reference genes, thymidylate synthase (TS) and beta-tubulin (BTU) genes, were used. Primers for the internal transcribed spacer (ITS) region of nuclear rRNA genes and either the TS or BTU gene were mixed together to perform PCR on seven different bronchoalveolar lavage specimens from patients with P. carinii pneumonia. The radioactivity derived from the incorporated radioactive nucleotides of each PCR product band was then used to calculate the copy number of the ITS relative to that of the TS or BTU gene. The copy number ratio between the ITS and the TS gene was determined to be 0.8, and that between the ITS and the BTU gene was also 0.8. These results suggest that the ITS has the same copy number as the TS or BTU gene. Since the copy number of the TS or BTU gene is presumed to be 1, the results also suggest that P. carinii f. sp. hominis has only one copy of the ITS and thus one copy of the nuclear rRNA genes. Therefore, two types of ITS sequences derived from a specimen would indicate that the patient is infected by two types of P. carinii f. sp. hominis.

Characterization of a tandemly repeated DNA sequence family originally derived by retroposition of tRNA(Glu) in the newt

A previous report from this laboratory showed that in vitro transcription of total genomic DNA of the newt Cynopus pyrrhogaster resulted in a discrete sized 8 S RNA, which represented highly repetitive and transcribable sequences with a glutamic acid tRNA-like structure in the newt genome. We isolated four independent clones from a newt genomic library and determined the complete sequences of three 2000 to 2400 base-pair PstI fragments spanning the 8 S RNA gene. The glutamic acid tRNA-related segment in the 8 S RNA gene contains the CCA sequence expected as the 3' terminus of a tRNA molecule. Further, the 11 nucleotides located 13 nucleotides upstream from one of the two transcription initiation sites of the 8 S RNA were found to be repeated in the region upstream from the termination site, suggesting that the original unit, which is shorter than the 8 S RNA, was retrotransposed via cDNA intermediates from the PolIII transcript. In the upstream region of the 8 S RNA gene, a 360 nucleotide unit containing the glutamic acid tRNA-related segment was found to be duplicated (clones NE1 and NE10) or triplicated (clone NE3). Except for the difference in the number of the 360 nucleotide unit, the three sequences of the 2000 to 2400 base-pair PstI fragment were essentially the same with only a few mutations and minor deletions. Inverse polymerase chain reaction and sequence determination of the products, together with a Southern hybridization experiment, demonstrated that the family consists of a tandemly repeated unit of 3300, 3700 or 4100 base-pairs. Thus during evolution, this family in the newt was created by retroposition via cDNA intermediates, followed by duplication or triplication of the 360 nucleotide unit and multiplication of the 3300 to 4100 base-pair region at the DNA level.

rRNA genes from the lower chordate Herdmania momus: structural similarity with higher eukaryotes

Ascidians, primitive chordates that have retained features of the likely progenitors to all vertebrates, are a useful model to study the evolutionary relationship of chordates to other animals. We have selected the well characterized ribosomal RNA (rRNA) genes to investigate this relationship, and we describe here the cloning and characterization of an entire ribosomal DNA (rDNA) tandem repeat unit from a lower chordate, the ascidian Herdmania momus. rDNA copy number and considerable sequence differences were observed between two H. momus populations. Comparison of rDNA primary sequence and rRNA secondary structures from H. momus with those from other well characterized organisms, demonstrated that the ascidians are more closely related to other chordates than invertebrates. The rDNA tandem repeat makes up a larger percentage (7%) of the genome of this animal than in other higher eukaryotes. The total length of the spacer and transcribed region in H. momus rDNA is small compared to most higher eukaryotes, being less than 8 kb, and the intergenic spacer region consists of smaller internal repeats. Comparative analysis of rDNA sequences has allowed the construction of secondary structures for the 18S, 5.8S and 26S rRNAs.

Extrachromosomal circular DNAs and genomic sequence plasticity in eukaryotic cells

The ability of eukaryotic organisms of the same genotype to vary in developmental pattern or in phenotype according to varying environmental conditions is frequently associated with changes in extrachromosomal circular DNA (eccDNA) sequences. Although variable in size, sequence complexity, and copy number, the best characterized of these eccDNAs contain sequences homologous to chromosomal DNA which indicates that they might arise from genetic rearrangements, such as homologous recombination. The abundance of repetitive sequence families in eccDNAs is consistent with the notion that tandem repeats and dispersed repetitive elements participate in intrachromosomal recombination events. There is also evidence that a fraction of this DNA has characteristics similar to retrotransposons. It has been suggested that eccDNAs could reflect altered patterns of gene expression or an instability of chromosomal sequences during development and aging. This article reviews some of the findings and concepts regarding eccDNAs and sequence plasticity in eukaryotic genomes.

Fragments of rDNA within the Chinese hamster genome

We report the isolation and partial characterization of distinct EcoRI 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-sized EcoRI 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.

Rat ribosomal protein L35a multigene family: molecular structure and characterization of three L35a-related pseudogenes

The rat ribosomal protein L35a gene comprises a multigene family which contains 15-20 members as shown by the Southern blot analysis using L35a cDNA as a probe. We isolated 15 independent clones which contained distinct genes from a rat genomic library. Analysis of the restriction sites showed that all of them lacked the intervening sequences. Thermal stability of the hybrid molecules between these genes and the cDNA indicated that the similarity of the genes to the cDNA sequence varied. The nucleotide sequences of three genes gRL35a-A, gRL35a-B and gRL35a-G were determined. They shared some characteristics; namely: they lacked the intervening sequences, they contained (A)-rich tracts, and they were flanked by direct repeats. Two genes, gRL35a-A and gRL35a-B, contained a sequence completely identical to that of the cDNA. The nucleotide sequence of the 5' flanking region of gRL35a-B showed a significant homology with that of the same region of mouse ribosomal protein L32-related unmutated processed genes. Although this region of gRL35a-B contained the sequences homologous to the TATA box and the CCAAT box, gRL35a-B was not transcribed in an in vitro assay system. Thus, the L35a gene family comprises mostly processed pseudogenes. Further, Southern blot analysis in various animals indicated that the multigene construction of this ribosomal protein gene was a feature of mammalian genes. The origin and the evolutionary aspect of processed pseudogenes are discussed.

The ribosomal spacer in Xenopus laevis is transcribed as part of the primary ribosomal RNA

S1 mapping of Xenopus laevis ribosomal RNA transcripts, both in oocyte microinjection experiments and in vivo, shows that all but 212 bp of the so-called "non-transcribed" spacer (NTS) of the ribosomal DNA repeat is transcribed as part of the primary ribosomal transcript. The 40S pre-ribosomal RNA (pre-rRNA) is therefore a processing intermediate. The primary ribosomal transcript co-terminates with the previously described spacer transcripts [Moss], at a site 213 bp upstream of the 40S pre-rRNA initiation site. This mode of transcription suggests a simple mechanism for the recently proposed phenomenon of "readthrough-enhancement", [Moss et al, Moss], where readthrough transcription from an upstream gene may enhance transcription of a gene immediately downstream in the tandem ribosomal repeat.

Regular distribution of length heterogeneities within non-transcribed spacer regions of cloned and genomic rDNA of Saccharomyces cerevisiae

A length difference of about 50 bp in the EcoRI fragment B of the rDNA from two different strains of Saccharomyces cerevisiae has been mapped in detail by sequencing of cloned fragments. This 2.4 kb EcoRI fragment contains the start of the 35S rRNA gene at one end and the 5S rRNA gene in the middle flanked by non-transcribed spacers, NTS1 and NTS2. The difference appeared as short deletions or insertions in five regularly spaced regions within the 1 kb NTS1, 3' to the 5S rRNA gene. The same regions of heterogeneities were displayed when all available sequence data of the NTS1 were compared. Four of the variable regions are located 160-170 bp apart, indicating that they might represent linker sequences between phased nucleosomes. Two variant clones, differing in the length of one subfragment of NTS1, were isolated for each strain. In both cases these represented the major variants among chromosomal NTS1 as revealed by sequencing of genomic fragments.

Ribosomal RNA contents of maize genotypes with different ribosomal RNA gene numbers

Ribosomal RNA (rRNA) contents were determined in 16 maize genotypes whose individual rRNA gene numbers varied from 5000 to 23,000 per 2C nucleus. Analytical polyacrylamide gel electrophoresis of total RNA showed that no obvious relation existed between rRNA gene number and rRNA content. Only two of nine common inbred lines contained more rRNA than W-23, the inbred with the lowest rRNA gene number. Two of four lines with altered protein content (due to long-term experimental selection) had rRNA contents significantly reduced from those of W-23. A line with an apparent duplication of the nucleolus organizer region of chromosome 6 (called 2-NOR) was expected to possess an elevated quantity of rRNA because it possesses a larger nucleolus; however, we produced a 2-NOR isogenic version and found no difference in rRNA content. The rRNA genes in maize are distributed throughout the NOR-heterochromatin and the NOR-secondary constriction portions of the NOR. The absence of an obvious correlation between rRNA gene number and cellular rRNA content may reflect the presence of a large number of rRNA genes in an inactive state, at least during the stage of growth examined in these experiments.

Structural organization of the two main rDNA size classes of Ascaris lumbricoides

The two main rDNA size classes in the genome of Ascaris lumbricoides consist of 8.8 kb and 8.4 kb long repeating units present in a quantitative ratio of roughly 10:1. They both contain the genes coding for 18 , 5.8S and 26S ribosomal RNAs. The length heterogeneity is due to a 450 bp long spacer region localized in the longer repeating unit which begins 870 bp upstream of the 5'-end 18S gene. A few additional microheterogeneities in base sequence occur at the 5'-end of the 26S gene. The 18S, 5.8S and 26S coding regions have been mapped on both the 8.8 kb and 8.4 kb repeating units and the localization of the 5'- and 3'-ends of the 18S and 26S genes has been performed by S1 protection. No intervening sequences are present in either coding region of the two main rDNA size classes.

The widespread nature of phenotypic variability in hepatomas and cell lines, in the form of a geometric series

The phenomenon of geometric phenotypic variability is described and its widespread occurrence is established by a new analysis of data from a literature survey of quantitative variation in 39 different enzymes and other cell products in hepatomas and cell lines. The range of variation from hepatoma to hepatoma or from cell line to cell line was between 3- and 700-fold, depending on the particular cell product. By collating together and normalizing the data for the enzymes and other cell products surveyed, it was demonstrated in a statistically valid manner that the quantitative variation for most, if not all, of the enzymes and serum albumin was not random, but followed a geometric series, the consecutive terms of which differed by a factor of square root 2. In addition, examples are presented to show that quantitative inheritance in normal tissues also occurs along this geometric series.

Progress in visualization of eukaryotic gene transcription

Methods for visualization of the ultrastructure of transcriptionally active eukaryotic genes have been developed using chromatin from giant nuclei of amphibian oocytes (Miller and Beatty 1969). Rapidly isolated chromatin is subjected to low salt treatment in order to dissociate most chromatin associated proteins. As a result, gene-chromatin with associated RNA polymerase particles and RNA transcripts can be directly analysed in electron microscope chromatin spread preparations. More recently, progress has been made in utilising living amphibian oocyte nuclei as a transcription system for cloned eukaryotic genes. In this article, an account of such experiments is given, with emphasis on results and problems of chromatin and transcription organization of microinjected cloned genes. The described transcription assay system possesses important potential for investigation of gene mutations and in particular for the elucidation of molecular aspects of experimental oncology and molecular human genetics.

A transcriptional function for the repetitive ribosomal spacer in Xenopus laevis

The function of the Xenopus laevis ribosomal spacer has been studied in vivo and by microinjection of in vitro mutants into Xenopus oocytes. It is shown that the spacer directs specific RNA transcripts which most probably terminate upstream of the ribosomal genes and that it is able to modulate transcription of these genes. The data lead to a model in which the ribosomal spacer is a loading site for RNA polymerase I and spacer transcription is the driving force by which polymerase is delivered to the ribosomal gene promoter.

Hypersensitivity of DNA in transcriptionally active chromatin to ionizing radiation

We have examined the size distribution of single-strand fragments of total 3H-labeled DNA and of DNA sequences complementary to specific probes in gamma-irradiated and unirradiated mouse L929 cells. Those DNA sequences which hybridize to rDNA or to poly(A+)RNA have lower number average molecular weights and sustain 5--6-times the number of single-strand breaks as do satellite DNA sequences or the bulk DNA. We therefore conclude that transcriptionally active DNA sequences are more susceptible to ionizing radiation-induced damage than are inactive sequences, and suggest that these differential susceptibilities are a likely consequence of differences in their chromatin organization.

Reiteration frequency of procollagen genes in the guinea pig genome. Collagen genes are not amplified during granuloma fibroblasts differentiation

Procollagen mRNA was purified from collagen synthesizing polysomes obtained from an experimental guinea pig granuloma, and iodinated in vitro. The procollagen 125I-labelled mRNA was hibridized with granuloma and liver guinea pig DNA in vast DNA excess conditions. A Cot 1/2 800-900 mol . s . 1-1 for both tissues was obtained from the hybridization curves. With these results, we could suggest the existence of 11-13 procollagen genes per haploid genome. By the analysis of the hybridization data it was possible to infer that there is no genomic amplification in tissues highly specialized in the synthesis of collagen such as granuloma.

Isolation and characterisation of ribosomal RNA from the human malaria parasite Plasmodium falciparum

Ribosomal RNA isolated from the malaria parasite Plasmodium falciparum consists of two species with molecular weight of 1.49 +/- 0.09 X 10(6) and 0.78 +/- 0.02 X 10(6) present in equimolar quantities. Their molecular weights are comparable with those of other protozoa but quite distinct from those of the human host. The overall base composition of the rRNA (40% G+C) is close to that of the rodent parasite Plasmodium berghei, unlike the latter, however, P. falciparum has no nick in the RNA from its large ribosomal subunit.

Mutations in rDNA. 1. Dependence of chromosome mutation induction on positions and activity of nucleolus organizer regions

Studies on chromatid aberration induction in NORs of standard and reconstructed karyotypes, as well as in the single translocation lines of barley, indicate a correlation between synthetic activity (transcription) of rDNA and frequency of chromosome mutations induced by HU. Experimental evidence in favour of this inference arises from analyzing karyotypes with NORs located at their original sites and karyotypes with NORs translocated from their original sites. The close correlation between the different rate of synthetic activity (transcription) in nucleolus formation and the comparable range of variation in aberration involvement of NORs observed in translocation lines are discussed.

Localization of SV40 genes within supercoiled loop domains

Recent studies indicate that eukaryotic DNA is organized into supercoiled loop domains. These loops appear to be anchored at their bases to an insoluble nuclear skeleton or matrix. Most of the DNA in the loops can be released from the matrix by nuclease digestion; the residual DNA remaining with the nuclear matrix represents sequences at the base of the loops, and possibly other sequences which are intimately associated with the nuclear matrix for other reasons. Using a quantitative application of the Southern blotting technique, we have found this residual DNA from SV40 infected 3T3 cells to be enriched in SV40 sequences, indicating that they reside near matrix-DNA attachment points. An enrichment of 3-7 fold relative to total cellular DNA, was found in each of three different lines of SV40 infected 3T3 cells. Control experiments with globin genes showed no such enrichment in this residual matrix DNA. This sequence specificity suggests that the spatial organization of DNA sequences within loops may be related to the functionality of these sequences within the cell.

Molecular evidence for genetic exchanges among ribosomal genes on nonhomologous chromosomes in man and apes

We have found that human and ape ribosomal genes undergo concerted evolution involving genetic exchanges among nucleolus organizers on nonhomologous chromosomes. This conclusion is based upon restriction enzyme analysis of the ribosomal gene families in man and five ape species. Certain structural features were found to differ among (but not within) species even though the ribosomal genes have a multichromosomal distribution. Genetic exchanges among nucleolus organizer regions may be related to the well-known phenomenon of acrocentric chromosome associations observed in man and apes. Length variation in a region of the nontranscribed spacer was found in both chimpanzee species we examined. The nature of this length variation was found to be identical to that previously described in man. The origin of the length variation and its polymorphism within these three species might be explained by unequal alignment and unequal cross-over among the ribosomal genes. An especially surprising finding was a nucleotide sequence polymorphism present in each individual human and ape we examined. Some ribosomal genes of each individual have a HindII site in the 28S gene about 800 base pairs from the EcoRI site in this gene. The remaining 28S genes lack this HindII site. The presence of this polymorphism within individuals of every species we examined suggests that it has been maintained by natural selection.

Divergence of primate ribosomal RNA genes as assayed by restriction enzyme analysis

Primate ribosomal RNA (rRNA) genes have been compared by restriction endonuclease mapping. In all species examined, the restriction map of the reiterated ribosomal DNA is simple (within the limits of detection by hybridization with rRNA) and is consistent with a high degree of homogeneity among the repeats. Within a species, all members have similar rDNA restriction patterns. However, different species of primates have distinctly different rDNA restriction maps; even chimpanzee and man can be discerned by their rDNA restriction patterns. Possible mechanisms for maintenance of homogeneity of the rDNA repeats within a species, while allowing divergence among closely related species, are discussed.

Variable patterns of total DNA and rDNA methylation in animals

Restriction endonucleases were used to determine the degree of methylation at the sequences CCGG and GCGC in a wide range of animal DNAs. Both total DNA methylation and ribosomal DNA methylation were studied. Whole DNA methylation was indetectable in arthropods, fractional in other invertebrate phyla, and high in the vertebrates. Ribosomal DNA was predominantly unmethylated in all animals except fish and amphibia, where it was heavily methylated. We discuss the evolutionary and functional implications of these results, and suggest that the large differences between genome types are the result of evolutionary changes in the relative size of heavily methylated and unmethylated compartments.

Comparative studies of the primary structures of ribosomal RNAs of several eukaryotic cell lines by the fingerprinting method

Comparisons of the primary structures of 18S and 28S ribosomal RNAs of man, rat, mouse and chicken were made by two-dimensional fractionation including electrophoresis at pH 3.5 and homochromatography. All large T1 oligonucleotides were recovered from the different fingerprints and their radioactivity was measured. They were then hydrolysed with pancreatic RNase and the pancreatic products were digested with alkali to determine their base composition and detect modified residues. Finally, residues bearing a modification on the ribose were analysed by hydrolyses with snake venom and spleen phosphodiesterases. For the 18A RNAs 23, 27, 26, 24 oligonucleotides, whose lengths range from 22 to 10 residues, were analyzed respectively for man, rat, mouse and chicken. Among these, 14 are identical in the four species, two at least are common to man, rat, mouse but differ by the presence of A-Cps in chicken spot 4' instead of A-Up in spot 4 and A2-Gp in chicken spot 14 instead of A2-Gp in spot 13. For the 28S RNAs of man, rat, mouse and chicken, 20, 19, 21 and 22 oligonucleotides ranging in length from 27 to 12 residues were analyzed. 11 of them are common to the four species; 4 of them are found in man, rat, mouse and one of these (spot 1) has a corresponding spot in chicken from which it differs only by the existence of A3-Up instead of A2-Up. Another mammalian oligonucleotide (spot 6) differs from its homologous chicken spot (spot 6') bytwo point mutations. The same modified residues as found by Khan and Maden in man, chicken, and xenopus, have been found in rat and mouse. Moreover when these modified residues are common to several species they are found within an identical nucleotide sequence, as can be seen in the case of spots 1, 3, 9, 11 of 18S RNAs and 4, 7, 13 for 28S RNAs. The number of differences observed between the ribosomal RNAs of the four species were compared to the number of differences observed in the same species for several proteins, globins alpha and beta, insulin, cytochrome C and lysozyme.