Sequence analysis of the maize mitochondrial 26 S rRNA gene and flanking regions

A single copy of the large ribosomal 26 S rRNA gene is found in the maize mitochondrial genome. The sequence of this gene and the flanking regions has been determined using the M13 dideoxy sequencing method. The maize mt 26 S rDNA shares a high degree of homology with the Escherichia coli 23 S rDNA, and the approximate 5′ and 3′ ends of the maize 26 S rDNA have been located by comparison with the E. coli sequence. The maize mt 26 S rDNA has also been compared with the sequences of the maize chloroplast 23 S rDNA, the human mitochondrial 16 S rDNA, part of the yeast mitochondrial 21 S rDNA, and the yeast cytoplasmic 25 S rDNA. In all cases, there are numerous regions of 70% or higher homology.     

Distribution of 45S and 5S rDNA sites in 23 species of Eleocharis (Cyperaceae)

Studies of rDNA location in holocentric chromosomes of the Cyperaceae are scarce, but a few reports have indicated the occurrence of multiple 45S rDNA sites at terminal positions, and in the decondensed state of these regions in prometaphase/metaphase. To extend our knowledge of the number 45S and 5S rDNA sites and distribution in holocentric chromosomes of the Cyperaceae, 23 Brazilian species of Eleocharis were studied. FISH showed 45S rDNA signals always located in terminal regions, which varied from two (E. bonariensis with 2n = 20) to ten (E. flavescens with 2n = 10 and E. laeviglumis with 2n = 60). 5S rDNA showed less variation, with 16 species exhibiting two sites and 7 species four sites, preferentially at terminal positions, except for four species (E. subarticulata, E. flavescens, E. sellowiana and E. geniculata) that showed interstitial sites. The results are discussed in order to understand the predominance of terminal rDNA sites, the mechanisms involved in the interstitial positioning of 5S rDNA sites in some species, and the events of amplification and dispersion of 45S rDNA terminal sites.     

Chromosomal localization of 45S and 5S rDNA in 14 species and the implications for genome evolution of genus Epimedium

Studying the genome structure of Epimedium has been hindered by the large genomes and uniform karyotypes. Consequently our understanding of the genome organization and evolutionary changes of Epimedium is extremely limited. In the present study, the 45S and 5S rDNA loci of 14 Epimedium species were physically mapped by double-probe FISH for the first time. Results showed the following: (1) Chromosomes I and II of all 14 species examined, except for E. shuichengense, hosted one pair of 45S rDNA sites, respectively. Most of the 45S rDNA sites gave clear signals and were positioned in the distal regions of the short arms. (2) All species studied of section Diphyllon were found to have one pair of 5S rDNA sites localized in the interstitial regions of the long arm of chromosome IV, and the two species of section Epimedium, E. alpinum and E. pubigerum, had two pairs of 5S rDNA sites localized in the interstitial regions of the long arm of chromosomes IV and V, respectively. (3) In section Diphyllon, all species of small flower taxa, except E. shuichengense, had three pairs of 45S rDNA sites, clearly more than species of big flower taxa, except E. davidii, with two pairs of 45S rDNA sites. Based on the 45S and 5S rDNA distribution patterns and other chromosomal morphological characteristics, six pairs of chromosomes can be unambiguously identified in all 14 Epimedium species. The stable differentiation in 45S and 5S rDNA FISH patterns between the two sections suggests that chromosomal rearrangements and transpositional events played a role in the splitting of the two sections, and section Diphyllon may be more primitive than section Epimedium. In the same way, big flower taxa may be more primitive than small flower taxa in section Diphyllon.     

Localization of 45S and 5S rDNA sites and karyotype of Chrysanthemum and its related genera by fluorescent in situ hybridization

The phylogenetic relationships among Chrysanthemum and its related genera (Anthemideae, Asteraceae) is poorly understood. In the present study, these relationships were investigated using 45S and 5S ribosomal DNA (rDNA)-targeted fluorescent in situ hybridization. The results showed that there were two 45S rDNA signals present in Crossostephium chinense, four 45S rDNA signals in Cercidiphyllum japonicum, Artemisia sieversiana, Artemisia annua and Artemisia absinthium, six 45S rDNA signals in Chrysanthemum boreale and Pyrethrum parthenium, eight 45S rDNA signals in Chrysanthemum nankingense, Chrysanthemum dichrum, Chrysanthemum lavandulifolium and Tanacetum vulgare, and ten 45S rDNA signals in Ajania przewalskii. For the 5S rDNA locus, two 5S rDNA signals were present in C. nankingense, C. dichrum, C. lavandulifolium, C. boreale, C. japonicum, C. chinense and P. parthenium, four in A. sieversiana, A. annua, A. absinthium and A. przewalskii, and six 5S in T. vulgare. In addition, karyotypes of the 12 species were investigated. From this study, we inferred that Chrysanthemum was closely related to Ajania, and that Chrysanthemum species originating from China and Japan may have evolved differently. These findings add a new level to the understanding of the phylogenetic relationships of Chrysanthemum and related genera.     

Chromosomal Locations of 5S and 45S rDNA in Gossypium Genus and Its Phylogenetic Implications Revealed by FISH

We investigated the locations of 5S and 45S rDNA in Gossypium diploid A, B, D, E, F, G genomes and tetraploid genome (AD) using multi-probe fluorescent in situ hybridization (FISH) for evolution analysis in Gossypium genus. The rDNA numbers and sizes, and synteny relationships between 5S and 45S were revealed using 5S and 45S as double-probe for all species, and the rDNA-bearing chromosomes were identified for A, D and AD genomes with one more probe that is single-chromosome-specific BAC clone from G. hirsutum (A₁D₁). Two to four 45S and one 5S loci were found in diploid-species except two 5S loci in G . incanum (E₄), the same as that in tetraploid species. The 45S on the 7th and 9th chromosomes and the 5S on the 9th chromosomes seemed to be conserved in A, D and AD genomes. In the species of B, E, F and G genomes, the rDNA numbers, sizes, and synteny relationships were first reported in this paper. The rDNA pattern agrees with previously reported phylogenetic history with some disagreements. Combined with the whole-genome sequencing data from G . raimondii (D₅) and the conserved cotton karyotype, it is suggested that the expansion, decrease and transposition of rDNA other than chromosome rearrangements might occur during the Gossypium evolution.     

Fine organization of genomic regions tagged to the 5S rDNA locus of the bread wheat 5B chromosome

Background

The multigene family encoding the 5S rRNA, one of the most important structurally-functional part of the large ribosomal subunit, is an obligate component of all eukaryotic genomes. 5S rDNA has long been a favored target for cytological and phylogenetic studies due to the inherent peculiarities of its structural organization, such as the tandem arrays of repetitive units and their high interspecific divergence. The complex polyploid nature of the genome of bread wheat, Triticum aestivum, and the technically difficult task of sequencing clusters of tandem repeats mean that the detailed organization of extended genomic regions containing 5S rRNA genes remains unclear. This is despite the recent progress made in wheat genomic sequencing. Using pyrosequencing of BAC clones, in this work we studied the organization of two distinct 5S rDNA-tagged regions of the 5BS chromosome of bread wheat.

Results

Three BAC-clones containing 5S rDNA were identified in the 5BS chromosome-specific BAC-library of Triticum aestivum. Using the results of pyrosequencing and assembling, we obtained six 5S rDNA- containing contigs with a total length of 140,417 bp, and two sets (pools) of individual 5S rDNA sequences belonging to separate, but closely located genomic regions on the 5BS chromosome. Both regions are characterized by the presence of approximately 70–80 copies of 5S rDNA, however, they are completely different in their structural organization. The first region contained highly diverged short-type 5S rDNA units that were disrupted by multiple insertions of transposable elements. The second region contained the more conserved long-type 5S rDNA, organized as a single tandem array. FISH using probes specific to both 5S rDNA unit types showed differences in the distribution and intensity of signals on the chromosomes of polyploid wheat species and their diploid progenitors.

Conclusion

A detailed structural organization of two closely located 5S rDNA-tagged genomic regions on the 5BS chromosome of bread wheat has been established. These two regions differ in the organization of both 5S rDNA and the neighboring sequences comprised of transposable elements, implying different modes of evolution for these regions.

     

Bryophyte 5S rDNA was inserted into 45S rDNA repeat units after the divergence from higher land plants

The 5S ribosomal RNA genes (5S rDNA) are located independently from the 45S rDNA repeats containing 18S, 5.8S and 26S ribosomal RNA genes in higher eukaryotes. Southern blot and fluorescence in situ hybridization analyses demonstrated that the 5S rDNAs are encoded in the 45S rDNA repeat unit of a liverwort, Marchantia polymorpha, in contrast to higher plants. Sequencing analyses revealed that a single-repeat unit of the M. polymorpha nuclear rDNA, which is 16103 bp in length, contained a 5S rDNA downstream of 18S, 5.8S and 26S rDNA. To our knowledge, this is the first report on co-localization of the 5S and 45S rDNAs in the rDNA repeat of land plants. Furthermore, we detected a 5S rDNA in the rDNA repeat of a moss, Funaria hygrometrica, by a homology search in a database. These findings suggest that there has been structural re-organization of the rDNAs after divergence of the bryophytes from the other plant species in the course of evolution.     

Phylogeny of Cucurbitaceae species in Korea based on 5S rDNA non-transcribed spacer

The 5S rDNA coding region and its spacer have been successfully utilized in phylogenetic studies of plants. However, it has not been utilized in the phylogenetic analysis of Cucurbitaceae. Here, we obtained the 5S rDNA sequences of 12 Cucurbitaceae species by direct PCR or cloning. The 5S rDNA sequences ranged from 275 to 359 bp, and the coding regions of all species were 120 bp long, except for that of Cucurbita, which was 119 bp. Some genus-specific SNPs were observed in the coding regions of Cucurbita, Lagenaria, Melothria, and Tricosanthes. The GC content of the coding regions was generally higher than that of the NTS regions, and the difference in GC content between the coding and NTS regions varied among species, with Gynostemma pentaphyllum having the greatest difference of 20.3. The phylogenetic trees generated using maximum parsimony and maximum likelihood were congruent and well supported by the recently published classification of Cucurbitaceae. These results demonstrated the utility of the 5S rDNA sequence in inferring phylogenetic relationships among 12 Cucurbitaceae species, and its utility could be extended by using a greater number of species in future studies.     

Chromosomal location and reorganization of the 45S and 5S rDNA in theBrachyscome lineariloba complex (Asteraceae)

The chromosomal locations of the 45S (18S-5.8S-26S) and 5S ribosomal DNA in theBrachyscome lineariloba complex and two related species have been determined by the use of multicolor fluorescencein situ hybridization (McFISH). TheBrachyscome lineariloba complex includes five cytodemes with 2n=4, 8, 10, 12 and 16. Each of the 5S and 45S rDNA loci occurs at two sites on chromosomes in cytodemes with 2n=4. While in cytodemes with 2n=8, 10, 12 and 16, the number of 5S rDNA sites increases from four to eight paralleled to the genomic addition of diploid (4 chromosomes) or haploid (2 chromosomes) dosage. Of the 5S rDNA sites, only one pair is major, except for the cytodeme with 2n=10. The remaining 5S rDNA sites are minor and seem to have reduced the unit number of the 5S rDNA during the successive genomic additions. The 45S rDNA site is detected only at two nucleolar organizing regions in all cytodemes regardless of successive genomic addition. The loss or diminution of 45S rDNA sequences seem to have proceeded more rapidly than 5S rDNA sequences in theB. lineariloba complex.     

Cotranscription and processing of 23S, 4.5S and 5S rRNA in chloroplasts from Zea mays

The termini of rRNA processing intermediates and of mature rRNA species encoded by the 3' terminal region of 23S rDNA, by 4.5S rDNA, by the 5' terminal region of 5S rDNA and by the 23S/4.5S/5S intergenic regions from Zea mays chloroplast DNA were determined by using total RNA isolated from maize chloroplasts and 32P-labelled rDNA restriction fragments of these regions for nuclease S1 and primer extension mapping. Several processing sites detectable by both 3' and 5' terminally labelled probes could be identified and correlated to the secondary structure for the 23S/4.5S intergenic region. The complete 4.5S/5S intergenic region can be reverse transcribed and a common processing site for maturation of 4.5S and 5S rRNA close to the 3' end of 4.5S rRNA was detected. It is therefore concluded that 23S, 4.5S and 5S rRNA are cotranscribed.     

Cloning and sequence analysis of the 18 S ribosomal RNA gene of tomato and a secondary structure model for the 18 S rRNA of angiosperms

Summary The gene of a cytoplasmic 18 S ribosomal RNA (18 S rDNA) of the dicotyledonous plant tomato (ycopersicon esculentum) cv. Rentita has been cloned, and its complete primary structure has been determined. The tomato 18 S rDNA is 1805 by long with a G+C content of 49.6%. Its sequence exhibits 94%–96% positional identity when it is colinearly aligned with the previously reported sequences of the 17–18 S rDNAs of the dicot soybean and the monocots maize and rice. A model of the secondary structure of the 18 S rRNA of angiosperms is presented and its genera-specific structural features are compared with a current eukaryotic 18 S rRNA consensus model.     

Unusual sequences,homologous to 5S RNA,in ribosomal DNA repeats of the nematodeMeloidogyne arenaria

Summary There are sequences homologous to 5S ribosomal RNA in the ribosomal DNA (rDNA) repeats of the plant-parasitic nematodeMeloidogyne arenaria. This is surprising, because in all other higher eukaryotes studied to date, the genes for 5S RNA are unlinked to and distinct from a tandem rDNA repeat containing the genes for 18S, 5.8S, and 28S ribosomal RNA. Previously, only prokaryotes and certain lower eukaryotes (protozoa and fungi) had been found to have both the larger rRNAs and 5S rRNA represented within a single DNA repeat. This has raised questions on the organization of these repeats in the earliest cell (progenote), and on subsequent evolutionary relationships between pro- and eukaryotes.Evidence is presented for rearrangements and deletions withinMeloidogyne rDNA. The unusual life cycles (different levels of ploidy, reproduction by meiotic and mitotic parthenogenesis) of members of this genus might allow rapid fixation of any variants with introduced 5S RNA sequences. The 5S RNA sequences inMeloidogyne rDNA may not be expressed, but their presence raises important questions as to the evolutionary origins and stability of repeat gene families.     

Molecular Organization of 5S rDNAs in Rajidae (Chondrichthyes): Structural Features and Evolution of Piscine 5S rRNA Genes and Nontranscribed Intergenic Spacers

The genomic and gene organisation of 5S rDNA clusters have been extensively characterized in bony fish and eukaryotes, providing general issues for understanding the molecular evolution of this multigene DNA family. By contrast, the 5S rDNA features have been rarely investigated in cartilaginous fish (only three species). Here, we provide evidence for a dual 5S rDNA gene system in the Rajidae by sequence analysis of the coding region (5S) and adjacent nontranscribed spacer (NTS) in five Mediterranean species of rays (Rajidae), and in a large number of piscine taxa including lampreys and bony fish. As documented in several bony fish, two functional 5S rDNA types were found here also in the rajid genome: a short one (I) and a long one (II), distinguished by distinct 5S and NTS sequences. That the ancestral piscine genome had these two 5S rDNA loci might be argued from the occurrence of homologous dual gene systems that exist in several fish taxa and from 5S phylogenetic relationships. An extensive analysis of NTS-II sequences of Rajidae and Dasyatidae revealed the occurrence of large simple sequence repeat (SSR) regions that are formed by microsatellite arrays. The localization and organization of SSR within the NTS-II are conserved in Rajiformes since the Upper Cretaceous. The direct correlation between the SSRs extension and the NTS length indicated that they might play a role in the maintenance of the larger 5S rDNA clusters in rays. The phylogenetic analysis indicated that NTS-II is a valuable systematic tool limited to distantly related taxa of Rajiformes. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Rafael Zardoya]     

Sequence polymorphism and chromosomal localization of 5S rDNA of three cultivated varieties of sweetpotato (Ipomoea batatas (L.) Lam.)

The 5S rDNA of plant is organized into clusters of tandem repeat units which include a coding region of 5S rRNA gene and variable sequences of nontranscribed spacer (NTS). In this study, we investigated sequence polymorphism and chromosomal localization of 5S rDNA in three cultivated varieties of sweet potato (Ipomoea batatas Lam.). Two different PCR products of 5S rDNA were amplified from all three varieties, as approximately 0.25 kb and 0.34 kb with multiples. In sequence analysis, the 5S rDNA ofI. batatas were discriminated from four consensus sequences by in reasonable sizes and molecular informative factors. Four consensus sequences were divided into three short sequences, including 263, 253, and 243 – 283 bp by sequence variation between 160 and 186 bp in NTS region, and one long sequence with 340 bp. To identify molecular relationship among varieties, phylogenetic analysis was applied. A total of 35 sequenced clones in this study were classified into four groups in phylogenetic tree. Interestingly, two varieties included all four groups, but one variety only two groups. To localize the physical map of 5S rDNA, fluorescencein situ hybridization (FISH) was performed in metaphase chromosomes of each varieties. In 90 chromosomes ofI. batatas, 6 loci of 5S rDNA were detected in chromosomes for all varieties. Our results will help to further more understand the genomic relationship inI. batatas, to investigate molecular relationship among varieties.     

Concerted and birth-and-death evolution of 26S ribosomal DNA in Camellia L.

Background and AimsThe ribosomal DNA (rDNA) gene family, encoding ribosomal RNA (rRNA), has long been regarded as an archetypal example illustrating the model of concerted evolution. However, controversy is arising, as rDNA in many eukaryotic species has been proved to be polymorphic. Here, a metagenomic strategy was applied to detect the intragenomic polymorphism as well as the evolutionary patterns of 26S rDNA across the genus Camellia.MethodsDegenerate primer pairs were designed to amplify the 26S rDNA fragments from different Camellia species. The amplicons were then paired-end sequenced on the Illumina MiSeq platform.Key ResultsAn extremely high level of rDNA polymorphism existed universally in Camellia. However, functional rDNA was still the major component of the family, and was relatively conserved among different Camellia species. Sequence variations mainly came from rRNA pseudogenes and favoured regions that are rich in GC. Specifically, some rRNA pseudogenes have existed in the genome for a long time, and have even experienced several expansion events, which has greatly enriched the abundance of rDNA polymorphism.Conclusions Camellia represents a group in which rDNA is subjected to a mixture of concerted and birth-and-death evolution. Some rRNA pseudogenes may still have potential functions. Conversely, when released from selection constraint, they can evolve in the direction of decreasing GC content and structural stability through a methylation-induced process, and finally be eliminated from the genome.     

Physical mapping of the 5S ribosomal RNA genes on rice chromosome 11

One 5S ribosomal RNA gene (5S rDNA) locus was localized on chromosome 11 of japonica rice by in situ hybridization. The biotinylated DNA probe used was prepared by direct cloning and direct labeling methods, and the locus was localized to the proximal region of the short arm of chromosome 11 (llpl.l) by imaging methods. The distance between the signal site and the centromere is 4.0 arbitrary units, where the total length of the short arm is 43.3 units. The 5S rDNA locus physically identified and mapped in rice was designated as 5SRrn. The position of the 5S rDNA locus reported here differs from that in indica rice; possible reasons for this difference are discussed. DNA sequences of 5S rDNA are also reported.