Genetic analysis of nuclear ribosomal DNA of Lentinula edodes

Genetic analysis of nuclear ribosomal DNA (rDNA) of Lentinula edodes was carried out using rDNA restriction fragment length polymorphisms (RFLPs) as genetic markers. Two compatible monokaryotic strains that differed in the endonuclease digestion patterns of their rDNA were used. The dikaryotic strain established by crossing them produced mixed RFLP patterns. Single-spore isolates derived from the dikaryotic strain showed three types of rDNA RFLP patterns: either one of the two parental types or a mixed type. From the frequency of the mixed type, the recombination value of rDNA tandem repeats was calculated to be 31.4%. Linkage analysis between rDNA and two incompatibility factors (A and B) revealed that rDNA was not linked to either factor. The rDNA genotypes did not affect mycelial growth among the single-spore isolates.     

Metschnikowia Species Share a Pool of Diverse rRNA Genes Differing in Regions That Determine Hairpin-Loop Structures and Evolve by Reticulation

Modern taxonomy of yeasts is mainly based on phylogenetic analysis of conserved DNA and protein sequences. By far the most frequently used sequences are those of the repeats of the chromosomal rDNA array. It is generally accepted that the rDNA repeats of a genome have identical sequences due to the phenomenon of sequence homogenisation and can thus be used for identification and barcoding of species. Here we show that the rDNA arrays of the type strains of Metschnikowia andauensis and M. fructicola are not homogenised. Both have arrays consisting of diverse repeats that differ from each other in the D1/D2 domains by up to 18 and 25 substitutions. The variable sites are concentrated in two regions that correspond to back-folding stretches of hairpin loops in the predicted secondary structure of the RNA molecules. The substitutions do not alter significantly the overall hairpin-loop structure due to wobble base pairing at sites of C-T transitions and compensatory mutations in the complementary strand of the hairpin stem. The phylogenetic and network analyses of the cloned sequences revealed that the repeats had not evolved in a vertical tree-like way but reticulation might have shaped the rDNA arrays of both strains. The neighbour-net analysis of all cloned sequences of the type strains and the database sequences of different strains further showed that these species share a continuous pool of diverse repeats that appear to evolve by reticulate evolution.     

Repeats and subrepeats in the intergenic spacer of rDNA from the nematode Meloidogyne arenaria

Summary Ribosomal DNA (rDNA) repeats of the plant-parasitic nematode Meloidogyne arenaria are heterogeneous in size and appear to contain 5S rRNA gene sequences. Moreover, in a recA ⁺ bacterial host, plasmid clones of a 9 kb rDNA repeat show deletion events within a 2 kb intergenic spacer (IGS), between 28S and 5S DNA sequences. These deletions appear to result from a reduction in the number of tandem 129 by repeats in the IGS. The loss of such repeats might explain how rDNA length heterogeneity, observed in the Meloidogyne genome, could have arisen. Each 129 by repeat also contains three copies of an 8 by subrepeat, which has sequence similarity to an element found in the IGS repeats of some plant rDNAs.     

Polymorphic Chromosomal Specificity of Centromere Satellite Families in Arabidopsis halleri ssp. gemmifera

The chromosomal localizations of repetitive DNA clusters (ribosomal DNA and centromere satellites) were analyzed by fluorescent in situ hybridization in five strains of Arabidopsis halleri ssp. gemmifera. All five A. gemmifera strains have three chromosome pairs with 45S (5.8S-16S-26S) rDNA loci, and one pair with both 5S and 45S rDNA loci. These localizations are different from that of A. thaliana. Very unusually, there are three families of centromeric satellite DNAs (pAa, pAge1, and pAge2), and they showed polymorphism among the five strains studied. Overall, we found four different centromere satellite compositions. A plant from Fumuro was heterozygous for the chromosome specificities of centromere satellite families, possibly due to a reciprocal translocation involving centromere regions. Changes of centromeric satellite repeats appear to be rapid and frequent events in the history of A. gemmifera, and seem to occur by exchanging clusters as units.     

The large spacer of a nuclear ribosomal RNA gene from radish: organization and use as a probe in rapeseed breeding

Summary An Eco RI fragment spanning the spacer region separating two adjacent radish rDNA units was isolated and partially characterized. Although previous studies did not reveal obvious length heterogeneity in radish rDNA units, we observed the presence of several short repeats within this spacer, thus demonstrating that these repeats are not typical of species with variable length rDNA spacer. A short fragment containing two and one-half repeats was sequenced and used as a probe to demonstrate that this short sequence is highly specific for the genus Raphanus. We used these rDNA spacer sequences in preliminary assays for variability among 14 rapeseed cultivars and for introgression of radish rDNA in rapeseed to illustrate the usefulness of these probes.     

Phenotypic reversion in fas mutants of Arabidopsis thaliana by reintroduction of FAS genes: variable recovery of telomeres with major spatial rearrangements and transcriptional reprogramming of 45S rDNA genes

Arabidopsis thaliana mutants dysfunctional in the evolutionarily conserved protein complex chromatin assembly factor‐1 (CAF‐1), which deposits the canonical histone H3 variant H3.1 during DNA synthesis‐dependent chromatin assembly, display complex phenotypic changes including meristem and growth alterations, sensitivity to DNA‐damaging agents, and reduced fertility. We reported previously that mutants in the FAS1 subunit of CAF‐1 progressively lose telomere and 45S rDNA repeats. Here we show that multiple aspects of the fas phenotype are recovered immediately on expression of a reintroduced FAS1 allele, and are clearly independent of the recovery of rDNA copy‐numbers and telomeres. In reverted lines, 45S rDNA genes are recovered to diverse levels with a strikingly different representation of their variants, and the typical association of nucleolar organizing region 4 with the nucleolus is perturbed. One of 45S rDNA variants (VAR1), which is silenced in wild‐type (WT) plants without mutation history (Col‐0 WT), dominates the expression pattern, whereas VAR2 is dominant in Col‐0 WT plants. We propose an explanation for the variability of telomere and 45S rDNA repeats associated with CAF‐1 function, suggesting that the differences in nuclear partitioning and expression of the rDNA variants in fas mutants and their revertants provide a useful experimental system to study genetic and epigenetic factors in gene dosage compensation.     

Close sequence identity between ribosomal DNA episomes of the non-pathogenicEntamoeba dispar and pathogenicEntamoeba histolytica

Entamoeba dispar andEntamoeba histolytica are now recognized as two distinct species-the former being nonpathogenic to humans. We had earlier studied the organization of ribosomal RNA genes inE. histolytica. Here we report the analysis of ribosomal RNA genes inE. dispar. The rRNA genes ofE. dispar, like their counterpart inE. histolytica are located on a circular rDNA molecule. From restriction map analysis, the size ofE. dispar rDNA circle was estimated to be 24·4 kb. The size was also confirmed by linearizing the circle withBsaHI, and by limited DNAseI digestion. The restriction map of theE. dispar rDNA circle showed close similarity to EhR1, the rDNA circle ofE. histolytica strain HM-1:IMSS which has two rDNA units per circle. The various families of short tandem repeats found in the upstream and downstream intergenic spacers (IGS) of EhR1 were also present inE. dispar. Partial sequencing of the cloned fragments ofE. dispar rDNA and comparison with EhR1 revealed only 2·6% to 3·8% sequence divergence in the IGS. The region Tr and the adjoiningPvuI repeats in the IGS of EhR1, which are missing in thoseE. histolytica strains that have one rDNA unit per circle, were present in theE. dispar rDNA circle. Such close similarity in the overall organization and sequence of the IGS of rDNAs of two different species is uncommon. In fact the spacer sequences were only slightly more divergent than the 18S rRNA gene sequence which differs by 1·6% in the two species. The most divergent sequence betweenE. histolytica andE. dispar was the internal transcribed spacer, ITS2. Therefore, it was concluded that probes derived from the ITS1 and ITS 2 sequences would be more reliable and reproducible than probes from the IGS regions used earlier for identifying these species.     

Single-step co-integration of multiple expressible heterologous genes into the ribosomal DNA of the methylotrophic yeast Hansenula polymorpha

We have investigated the methylotrophic yeast Hansenula polymorpha as a host for the co-integration and expression of multiple heterologous genes using an rDNA integration approach. The ribosomal DNA (rDNA) of H. polymorpha was found to consist of a single rDNA cluster of about 50-60 repeats of an 8-kb unit located on chromosome II. A 2.4-kb segment of H. polymorpha rDNA encompassing parts of the 25S, the complete 5S and the non-transcribed spacer region between 25S and 18S rDNA was isolated and inserted into conventional integrative H. polymorpha plasmids harboring the Saccharomyces- cerevisiae-derived URA3 gene for selection. These rDNA plasmids integrated homologously into the rDNA repeats of a H. polymorpha (odc1) host as several independent clusters. Anticipating that this mode of multiple-cluster integration could be used for the simultaneous integration of several distinct rDNA plasmids, the host strain was co-transformed with a mixture of up to three different plasmids, all bearing the same URA3 selection marker. Transformations indeed resulted in mitotically stable strains harboring one, two, or all three plasmids integrated into the rDNA. The overall copy number of the plasmids integrated did not exceed the number of rDNA repeats present in the untransformed host strain, irrespective of the number of different plasmids involved. Strains harboring different plasmids co-expressed the introduced genes, resulting in functional proteins. Thus, this approach provides a new and attractive tool for the rapid generation of recombinant strains that simultaneously co-produce several proteins in desired stoichiometric ratios.     

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.     

Telomere and 45S rDNA sequences are structurally linked on the chromosomes in <Emphasis Type="Italic">Chrysanthemum segetum</Emphasis> L.

Some reports have shown that nucleolar organizer regions are located at the telomeric region and have a structural connection with telomeres at the cellular level in many organisms. In this study, we found that all 45S ribosomal DNA (rDNA) signals were located at telomeric regions on the chromosomes in Chrysanthemum segetum L., and the 45S rDNA showed distinct signal patterns on different metaphase chromosome spreads. The bicolor fluorescence in situ hybridization experiment on the extended fibers revealed that telomere repeats were structurally connected with or interspersed into rDNA sequences. The close cytological structure relation between rDNA and telomere sequences led us to use PCR with combinations of the telomere primer and the rDNA primer to obtain some fragments, which were flanked by different rDNA and telomere primer sequences. One representative clone CHS2 contains closely connected rDNA and telomere sequences, suggesting that the telomere sequence invaded into the conserved rDNA sequence. In addition, the sequences of some PCR clones were flanked by the single telomeric primer sequence or the rDNA primer sequence. These results suggested that homologous recombination occurred between tandem repeat units of rDNA sequences or telomere repeats at the chromosome terminus.     

Species-specific evolution of telomeric and rDNA repeats in the tobacco composite genome

In order to investigate possible interactions between parental genomes in the composite genome of Nicotiana tabacum we have analyzed the organization of telomeric (TTTAGGG)_n and ribosomal gene (rDNA) repeats in the progenitor genomes Nicotiana sylvestris and Nicotiana tomentosiformis or Nicotiana otophora. Telomeric arrays in the Nicotiana species tested are heterogeneous in length ranging from 20 to 200 kb in N. sylvestris, from 20 to 50 kb in N. tomentosiformis, from 15 to 100kb in N. otophora, and from 40 to 160kb in N. tabacum. The patterns of rDNA repeats (18S, 5.8S, 25S RNA) appeared to be highly homogeneous and speciesspecific; no parental rDNA units corresponding to N. sylvestris, N. tomentosiformis or N. otophora were found in the genome of N. tabacum by Southern hybridization. The results provide evidence for a species-specific evolution of telomeric and ribosomal repeats in the tobacco composite genome.     

Cytological characterization of the tandem repetitive sequences and their methylation status in the Antirrhinum majus genome

Tandem repetitive sequences are DNA motifs common in the genomes of eukaryotic species and are often embedded in heterochromatic regions. In most eukaryotes, ribosomal genes, as well as centromeres and telomeres or subtelomeres, are associated with abundant tandem arrays of repetitive sequences and typically represent the final barriers to completion of whole-genome sequencing. The nature of these repeats makes it difficult to estimate their actual sizes. In this study, combining the two cytological techniques DNA fiber-FISH and pachytene chromosome FISH allowed us to characterize the tandem repeats distributed genome wide in Antirrhinum majus and identify four types of tandem repeats, 45S rDNA, 5S rDNA, CentA1, and CentA2, representing the major tandem repetitive components, which were estimated to have a total length of 18.50 Mb and account for 3.59% of the A. majus genome. FISH examination revealed that all the tandem repeats correspond to heterochromatic knobs along the pachytene chromosomes. Moreover, the methylation status of the tandem repeats was investigated in both somatic cells and pollen mother cells from anther tissues using an antibody against 5-methylcytosine combined with sequential FISH analyses. Our results showed that these repeats were hypomethylated in anther tissues, especially in the pollen mother cells at pachytene stage.     

MOLECULAR PHYLOGENY AND PHENOTYPIC VARIATION IN THE HETEROTROPHIC GREEN ALGAL GENUS PROTOTHECA (TREBOUXIOPHYCEAE,CHLOROPHYTA)1

Species of the heterotrophic green microalgal genus Prototheca and related taxa were phylogenetically analyzed based on the nuclear small subunit (SSU) and the 5′ end of the large subunit (LSU) rRNA gene (rDNA) sequences. We propose restricting the genus Prototheca to the four species: P. moriformis Krüger, P. stagnora (Cooke) Pore, P. ulmea Pore, and P. zopfii Krüger. The main diagnostic feature of these taxa is the absence of growth on trehalose.Of these, it was suggested that P. moriformis should be merged into P. zopfii; P. moriformis and three varieties of P. zopfii constituted a paraphyletic assemblage with estimated short evolutionary distances. The trehalose‐assimilating strains (Prototheca wickerhamii Tubaki et Soneda strains and Auxenochlorella protothecoides (Krüger) Kalina et Pun?ochá?ová SAG 211‐7a), together with an invertebrate pathogen Helicosporidium sp., diverged before the radiation of the four species of Prototheca in the SSU rDNA and composite (SSU rDNA plus LSU rDNA) analyses. Comparison between the results from physiological data in this work (fermentative pattern) and those described earlier (growth requirements) lead us to propose a hypothesis that the phenotypic variation, which did not represent diagnostic characters for species delimitation, may reflect the history of genetic diversification within the genus Prototheca as inferred from rDNA sequence characters.     

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