Ribosomal DNA Intergenic Spacer of the Swimming Crab, Charybdis japonica

We have determined the full sequence of the ribosomal DNA intergenic spacer (IGS) of the swimming crab, Charybdis japonica, by long PCR for the first time in crustacean decapods. The IGS is 5376 bp long and contains two nonrepetitive regions separated by one long repetitive region, which is composed mainly of four subrepeats (subrepeats I, II, III, and IV). Subrepeat I contains nine copies of a 60-bp repeat unit, in which two similar repeat types (60 bp-a and 60 bp-b) occur alternatively. Subrepeat II consists of nine successive repeat units with a consensus sequence length of 142 bp. Subrepeat III consists of seven copies of another 60-bp repeat unit (60 bp-c) whose sequence is complementary to that of subrepeat I. Immediately downstream of subrepeat III is subrepeat IV, consisting of three copies of a 391-bp repeat unit. Based on comparative analysis among the subrepeats and repeat units, a possible evolutionary process responsible for the formation of the repetitive region is inferred, which involves the duplication of a 60-bp subrepeat unit (60 bp-c) as a prototype. Received: 13 April 1999 / Accepted: 2 August 1999     

Structural evolution of nrDNA ITS in Pinaceae and its phylogenetic implications

Nuclear ribosomal DNA (nrDNA) has been considered as an important tool for inferring phylogenetic relationships at many taxonomic levels. In comparison with its fast concerted evolution in angiosperms, nrDNA is symbolized by slow concerted evolution and substantial ITS region length variation in gymnosperms, particularly in Pinaceae. Here we studied structure characteristics, including subrepeat composition, size, GC content and secondary structure, of nrDNA ITS regions of all Pinaceae genera. The results showed that the ITS regions of all taxa studied contained subrepeat units, ranging from 2 to 9 in number, and these units could be divided into two types, longer subrepeat (LSR) without the motif (5'-GGCCACCCTAGTC) and shorter subrepeat (SSR) with the motif. Phylogenetic analyses indicate that the homology of some SSRs still can be recognized, providing important informations for the evolutionary history of nrDNA ITS and phylogeny of Pinaceae. In particular, the adjacent tandem SSRs are not more closely related to one another than they are to remote SSRs in some genera, which may imply that multiple structure variations such as recombination have occurred in the ITS1 region of these groups. This study also found that GC content in the ITS1 region is relevant to its sequence length and subrepeat number, and could provide some phylogenetic information, especially supporting the close relationships among Picea, Pinus, and Cathaya. Moreover, several characteristics of the secondary structure of Pinaceae ITS1 were found as follows: (1) the structure is dominated by several extended hairpins; (2) the configuration complexity is positively correlated with subrepeat number; (3) paired subrepeats often partially overlap at the conserved motif (5'-GGCCACCCTAGTC), and form a long stem, while other subrepeats fold onto itself, leaving part of the conserved motif exposed in hairpin loops.     

Extraordinary ribosomal spacer length heterogeneity in a neotyphodium endophyte hybrid: implications for concerted evolution.

An extraordinary level of length heterogeneity was found in the ribosomal DNA (rDNA) of an asexual hybrid Neotyphodium grass endophyte, isolate Lp1. This hybrid Neotyphodium endophyte is an interspecific hybrid between two grass endophytes, Neotyphodium lolii, and a sexual form, Epichlöe typhina, and the length heterogeneity was not found in either of these progenitor species. The length heterogeneity in the hybrid is localized to the intergenic spacer (IGS) and is the result of copy-number variation of a tandemly repeated subrepeat class within the IGS, the 111-/119-bp subrepeats. Copy number variation of this subrepeat class appears to be a consequence of mitotic unequal crossing over that occurs between these subrepeats. This implies that unequal crossing over plays a role in the concerted evolution of the whole rDNA. Changes in the pattern of IGS length variants occurred in just two rounds of single-spore purification. Analysis of the IGS length heterogeneity revealed features that are unexpected in a simple model of unequal crossing over. Potential refinements of the molecular details of unequal crossing over are presented, and we also discuss evidence for a combination of homogenization mechanisms that drive the concerted evolution of the Lp1 rDNA.     

香菇菌株分子鉴别技术的分辨率比较

本研究运用酯酶同工酶、RAPD、IGS1和IGS24种方法鉴别2个野生香菇菌株和19个栽培香菇菌株,并比较这4种鉴别方法的分辨率,结果表明:16条酯酶同工酶带中有15条具有多态性,将21个供试菌株分成11个类型,分辨率为0.92;10个随机扩增引物共扩增出86个DNA片段,其中95.3%具有多态性,将21个供试菌株分成16个类型,分辨率为0.97;IGS1将21个供试菌株分成7个类型,分辨率为0.81;IGS2将21个供试菌株分成7个类型,分辨率为0.73。这4种鉴别方法中RAPD的分辨率最高,与这4种鉴别方法的综合分析结果相同,因此RAPD可以作为香菇菌株鉴别的可靠依据。     

Ribosomal DNA Evolution at the Population Level: Nucleotide Variation in Intergenic Spacer Arrays of Daphnia Pulex

Nucleotide variation was surveyed in 21 subrepeat arrays from the ribosomal DNA intergenic spacer of three Daphnia pulex populations. Eighteen of these arrays contained four subrepeats. Contrary to expectations, each of the four positions within the array had a different consensus sequence. However, gene conversion, involving sequences less than the length of a subrepeat, had occurred between subrepeats in different positions. Three arrays had more than four subrepeats and were undoubtedly generated by unequal crossing over between standard-length arrays. The data strongly suggested that most unequal exchanges between arrays are intrachromosomal and that they occur much less frequently than unequal exchanges at the level of the entire rDNA repeat. Strong associations among variants at different positions allowed the recognition of five groups of arrays, two of which were found in more than one population. Five of the seven individuals surveyed had arrays from more than one group. Analysis of the distribution of nucleotide variation suggested that the populations were quite divergent, a result that is concordant with previous surveys of allozyme and mitochondrial DNA variation. It was suggested that some of the subrepeat array types are quite old, at least predating the recolonization of pond habitats in the midwestern United States after the last glaciation.     

Patterns of variation in the intergenic spacers of ribosomal DNA in Drosophila melanogaster support a model for genetic exchanges during X-Y pairing

Detailed analysis of variation in intergenic spacer (IGS) and internal transcribed spacer (ITS) regions of rDNA drawn from natural populations of Drosophila melanogaster has revealed contrasting patterns of homogenization although both spacers are located in the same rDNA unit. On the basis of the role of IGS regions in X-Y chromosome pairing, we proposed a mechanism of single-strand exchanges at the IGS regions, which can explain the different evolutionary trajectories followed by the IGS and the ITS regions. Here, we provide data from the chromosomal distribution of selected IGS length variants, as well as the detailed internal structure of a large number of IGS regions obtained from specific X and Y chromosomes. The variability found in the different internal subrepeat regions of IGS regions isolated from X and Y chromosomes supports the proposed mechanism of genetic exchanges and suggests that only the "240" subrepeats are involved. The presence of a putative site for topoisomerase I at the 5' end of the 18S rRNA gene would allow for the exchange between X and Y chromosomes of some 240 subrepeats, the promoter, and the ETS region, leaving the rest of the rDNA unit to evolve along separate chromosomal lineages. The phenomenon of localized units (modules) of homogenization has implications for multigene family evolution in general.     

Cloning and analysis of a 6.8-kb rDNA intergenic spacer region of the European ash (Fraxinus excelsior L.)

The 6.8-kb rDNA intergenic spacer region of F. excelsior was isolated from a CsCl/actinomycin-D gradient and cloned into pUC18 for further characterization. We observed the presence of subrepeats delimited by HaeIII enzyme sites. These subrepeats were sub-cloned and 11 clones were sequenced. These corresponded to subrepeated elements of either 32 bp or 41 bp that shared a 23-bp common sequence in the 5 end. Within each family of subrepeats, the percentage of common nucleotides was 84.4% for the 5 32-bp subrepeats and 67.4% for the 640-bp subrepeats. Non-repeated HaeIII fragments of 450 bp and 650 bp were also sub-cloned. To compare homology at the IGS region between the rDNA spacers of F. excelsior and the three related species (F. oxyphylla, F. americana, F. ornus), we conducted Southern hybridization analyses using each member of the 32-bp and 40-bp subrepeat families and the unique 450-bp and 650-bp fragments as probes. These analyses indicated that (1) the American ash is more genetically distant from the other three species that the latter are from each other and (2) F. oxyphylla and F. excelsior are more closely related to each other than to F. ornus.     

Sequence comparison of distal and proximal ribosomal DNA arrays in rice (Oryza sativa L.) chromosome 9S and analysis of their flanking regions

Rice (Oryza sativa ssp. japonica cv. Nipponbare) harbors a ribosomal RNA gene (rDNA) cluster in the nucleolar-organizing region at the telomeric end of the short arm of chromosome 9. We isolated and sequenced two genomic clones carrying rice rDNA fragments from this region. The rice rDNA repeat units could be classified into three types based on length, which ranged from 7,928 to 8,934 bp. This variation was due to polymorphism in the number of 254-bp subrepeats in the intergenic spacer (IGS). Polymerase chain reaction (PCR) analysis suggested that the rDNA units in rice vary widely in length and that the copy number of the subrepeats in the IGS ranges from 1 to 12 in the rice genome. PCR and Southern blot analyses showed that most rDNA units have three intact and one truncated copies of the subrepeats in the IGS, and distal (telomere-side) rDNA units have more subrepeats than do proximal (centromere-side) ones. Both genomic clones we studied contained rDNA-flanking DNA sequences of either telomeric repeats (5′-TTTAGGG-3′) or a chromosome-specific region, suggesting that they were derived from the distal or proximal end, respectively, of the rDNA cluster. A similarity search indicated that retrotransposons appeared more frequently in a 500-kb portion of the proximal rDNA-flanking region than in other subtelomeric regions or sequenced regions of the genome. This study reveals the repetitive nature of the telomeric end of the short arm of chromosome 9, which consists of telomeric repeats, an rDNA array, and a retrotransposon-rich chromosomal region.Sequence accession numbers in DDBJ assigned for OSJNOa063K24 and OSJNBb0013K10 are AP009051 and AP008245, respectively.     

Preferential homogenization between adjacent and alternate subrepeats in wheat rDNA.

DNA from the "non-transcribed spacer" (NTS) of two wheat ribosomal RNA gene (rDNA) clones was sequenced. The regions flanking the internal subrepeat arrays are highly conserved between the two clones; the nucleotide sequence differ by less than one-half percent. In contrast, the consensus sequences of the subrepeats in the two arrays differ by three percent. Mutations unique to each array, yet found in more than one subrepeat of the array, are preferentially found in adjacent and alternate subrepeats. The similarity of the DNA sequences of the flanking regions is consistent with a model of homogenization among rDNA gene units by intergenic conversion. We propose that a different mechanism, preferential conversion between neighboring subrepeats, is largely responsible for the homogenization of subrepeats within an array.     

Sequence subfamilies of satellite repeats related to rDNA intergenic spacer are differentially amplified on<Emphasis Type="Italic"> Vicia sativa</Emphasis> chromosomes

We cloned and sequenced the Vicia sativa 25S-18S rDNA intergenic spacer (IGS) and the satellite repeat S12, thought to be related to the spacer sequence. The spacer was shown to contain three types of subrepeats (A, B, and C) with monomers of 173 bp (A), 10 bp (B), and 66 bp (C), separated by unique or partially duplicated sequences. Two spacer variants were detected in V. sativa that differed in length (2990 and 3168 bp) owing to an extra copy of the subrepeat A. The A subrepeats were also shown to be highly homologous to the satellite repeat S12, which is located in large clusters on chromosomes 4, 5, and 6, and is not associated with the rDNA loci. Sequencing of additional S12 clones retrieved from a shotgun genomic library allowed definition of three subfamilies of this repeat based on minor differences in their nucleotide sequences. Two of these subfamilies could be discriminated from the rest of the S12 sequences as well as from the IGS A subrepeats using specific oligonucleotide primers that labeled only a subset of the S12 loci when used in the primed in situ DNA labeling (PRINS) reaction on mitotic chromosomes. These experiments showed that, in spite of the high overall similarity of the IGS A subrepeats and the S12 satellite repeats, there are S12 subfamilies that are divergent from the common consensus and are present at only some of the chromosomes containing the S12 loci. Thus, the subfamilies may have evolved at these loci following the spreading of the A subrepeats from the IGS to genomic regions outside the rDNA clusters.Electronic Supplementary Material Supplementary material is available in the online version of this article at Accession numbers: GenBank AY234364–AY234374. The monomer sequences and additional information about the family of IGS-like repeat S12 will also appear in the PlantSat database (Macas et al. 2002, ) under Accession name Vicia_sativa_IGS-like     

Unraveling the sequence dynamics of the formation of genus-specific satellite DNAs in the family solanaceae

Tandemly repeated DNAs, referred to as satellite DNAs, often occur in a genome in a genus-specific manner. However, the mechanisms for generation and evolution for these sequences are largely unknown because of the uncertain origins of the satellite DNAs. We found highly divergent genus-specific satellite DNAs that showed sequence similarity with genus-specific intergenic spacers (IGSs) in the family Solanaceae, which includes the genera Nicotiana, Solanum and Capsicum. The conserved position of the IGS between 25S and 18S rDNA facilitates comparison of IGS sequences across genera, even in the presence of very low sequence similarity. Sequence comparison of IGS may elucidate the procedure of the genesis of complex monomer units of the satellite DNAs. Within the IGS of Capsicum species, base substitutions and copy number variation of subrepeat monomers were causes of monomer divergence in IGS sequences. At the level of inter-generic IGS sequences of the family Solanaceae, however, genus-specific motif selection, motif shuffling between subrepeats and differential amplification among motifs were involved in formation of genus-specific IGS. Therefore, the genus-specific satellite DNAs in Solanaceae plants can be generated from differentially organized repeat monomers of the IGS rather than by accumulation of mutations from pre-existent satellite DNAs.     

Identification of repetitive, genome-specific probes in crucifer oilseed species.

Direct amplification of minisatellite DNA by PCR (DAMD PCR) was used to amplify and subsequently clone several fragments of DNA from crucifer species. The PCR-derived fragments of DNA were generated using known minisatellite core sequences as PCR primers. Southern hybridization of these putative minisatellite DNA fragments revealed that many were genome-specific; they hybridized with high affinity only to the genomic DNA of the species from which they were cloned. The DNA fragments were believed to be dispersed in the genome, based on smear-like hybridization signals on EcoRI-, BamHI-, and HindIII-digested genomic DNA. Genome-specific probes were specifically isolated from Brassica rapa (A genome), Brassica nigra (B genome), and Sinapis alba in addition to several other crucifer species. The sequence of a B. rapa specific probe (pBr17.1.3A) contained a minisatellite region that could be divided into three tandem repeats; each repeat contained between two and five subrepeats and each subrepeat shared a highly conserved core region of 29 bp. This minisatellite sequence also hybridized with high affinity to the A genome species B. napus and B. juncea. This research showed that dispersed, genome-specific probes can be isolated using DAMD PCR and that these probes could be used to detect and quantify alien DNA present in progeny from intergeneric or interspecific crosses.     

Balbiani ring DNA: Sequence comparisons and evolutionary history of a family of hierarchically repetitive protein-coding genes

Summary All known types of Balbiani ring (BR) gene consist of multiple, tandemly arranged, ca. 180 to 300-bp repeat units that can be divided into a constant region and a subrepeat region. The latter region includes short tandem subrepeats (SRs). Comparison of all available BR sequences using computer methods has enabled us (a) to define more precisely the constant and subrepeat regions, (b) to infer the evolutionary relationships among the various types of BR repeats, (c) to derive a consensus approximation of an ancestral sequence from a small segment of which the highly diverse present-day SRs may have originated, and (d) to detect an underlying substructure in the constant region, evident in the consensus but not in the present-day sequences and possibly corresponding to an original 39-bp DNA segment from which the extant, giant BR sequences may have evolved. We discuss the processes of reduplication, diversification, and homogenization within the hierarchically repetitive BR sequences as examples of how a simple DNA element may evolve into a diverse family of large, protein-coding genes.     

Subrepeats within the BR1β repeat unit inChironomus pallidivittatus can be classified into different types depending on codon usage

Summary A new type of repeat unit was isolated from Balbiani ring 1 ofChironomus pallidivittatus and designated, BR1 repeat. It consists of a constant and a subrepeated part, like previously described units belonging to the core blocks of the BR genes. The subrepeated part contains 10-codon subrepeats with an arrangement similar to the subrepeats of the previously described BR2 gene. The present unit differs from earlier reported core units firstly in a much lower number of copies (about 15) per genome, which are tandemly arranged. Secondly, the number of subrepeats per BR1 repeat unit can show great variations. On the basis of the pattern of codon usage, three types of subrepeats can be distinguished. One type lies 5-proximal in the subrepeat array and consists of variable numbers of subrepeats almost identical at the nucleotide level. The last complete subrepeat represents another type, with consistent differences in codon usage as compared to subrepeats of the proximal type. Finally, there is an intermediate type represented by the subrepeat preceding the distal one. Here, codon characteristics from proximal and distal subrepeats are mixed in a patchy and irregular way. The evolution of the arrays can be understood either as being the result of subrepeat formation in two steps (occurring before and after amplification of whole repeat units) or as the result of a continuous process in which there is evidence for participation of gene conversion.