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.     

Structure,molecular evolution,and phylogenetic utility of the 5(') region of the external transcribed spacer of 18S-26S rDNA in Lessingia (Compositae,Astereae)

The 18S-26S nuclear rDNA external transcribed spacer (ETS) has recently gained attention as a region that is valuable in phylogenetic analyses of angiosperms primarily because it can supplement nucleotide variation from the widely used and generally shorter internal transcribed spacers (ITS-1 and ITS-2) and thereby improve phylogenetic resolution and clade support in rDNA trees. Subrepeated ETS sequences (often occurring in the 5(') region) can, however, create a challenge for systematists interested in using ETS sequence data for phylogeny reconstruction. We sequenced the 5(')ETS for members of Lessingia (Compositae, Astereae) and close relatives (26 taxa total) to characterize the subrepeat variation across a group of closely related plant lineages and to gain improved understanding of the structure, molecular evolution, and phylogenetic utility of the region. The 5(')ETS region of Lessingia and relatives varied in length from approximately 245 to 1009 bp due to the presence of a variable number of subrepeats (one to eight). We assessed homology of the subrepeats using phylogenetic analysis and concluded that only two of the subrepeats and a portion of a third ( approximately 282 bp in total) were orthologous across Lessingia and could be aligned with confidence and included in further analyses. When the partial 5(')ETS data were combined with 3(')ETS and ITS data in phylogenetic analyses, no additional resolution of relationships among taxa was obtained beyond that found from analysis of 3(')ETS + ITS sequences. Inferred patterns of concerted evolution indicate that homogenization is occurring at a faster rate in the 3(')ETS and ITS regions than in the 5(')ETS region. Additionally, homogenization appears to be acting within but not among subrepeats of the same rDNA array. We conclude that challenges in assessing subrepeat orthology across taxa greatly limit the utility of the 5(')ETS region for phylogenetic analyses among species of Lessingia.     

Internal transcribed spacer region evolution in Larix and Pseudotsuga (Pinaceae)

The nuclear ribosomal DNA (nrDNA) internal transcribed spacer (ITS) region has been characterized in the sister genera Larix and Pseudotsuga (Pinaceae). Complete sequences were obtained for seven species of Larix from North America and Eurasia and five species of Pseudotsuga from western North America and eastern Asia. ITS region lengths ranged from 1759 to 1770 bp in Larix and from 1564 to 1571 bp in Pseudotsuga. In both genera, ITS1 is three times as long as the 5.8S plus ITS2 and contains subrepeats as observed in other genera of Pinaceae. Secondary structure models predicted that the subrepeats fold into terminal stem and loop domains. ITS polymorphism detected within individuals of Larix and Pseudotsuga suggests a slow rate of concerted evolution among nrDNA loci. Except for the placement of L. sibirica, phylogenetic analyses of the ITS region agreed with previously reported restriction site analyses of Larix and Pseudotsuga. The data were not consistent with phylogenetic hypotheses for Larix based primarily upon ovulate cone characters, failing to support a derivation of the North American L. laricina from a short-bracted Eurasian lineage. The phylogenetic hypothesis did not conflict with a stepping stone model of evolution for Pseudotsuga, but a basal lineage could not be inferred for either genus.     

Cytogenetic and molecular characterization of the Abies alba genome and its relationship with other members of the Pinaceae

Genome size, karyotype structure, heterochromatin distribution, position and number of ribosomal genes, as well as the ITS2 sequence of the internal transcribed spacer (ITS) were analysed in silver fir (Abies alba Mill.). The analysis also included characterization of the Arabidopsis-type of telomeric repeats in silver fir and in related species. The results were compared with results from other species of the Pinaceae, to evaluate phylogeny and chromosomal and molecular evolution in the Pinaceae. Integrated chromosomal data provided insights into chromosome and karyotype evolution in the Pinaceae. The evolutionary trend for GC-rich heterochromatic blocks seems to involve loss of blocks that are not associated with rDNA. Similarly, numerous large blocks of interstitial plant telomeric repeats that are typical for all analysed species of the genus Pinus were not observed in the evolutionarily younger genera, such as Abies, Picea and Larix. On the contrary, the majority of telomeric sequences in these three genera appeared confined to the chromosome ends. We confirmed the current position of Abies and Tsuga in subfamily Abietoideae and the position of Pinus in the subfamily Pinoideae based on ITS2 sequences. Pseudotsuga is placed together with Larix into the subfamily Laricoideae. We conclude that the current position of the genus Picea in the subfamily Abietoideae should be reconsidered and, possibly, the genus Picea should be reclassified as a separate subfamily, Piceoideae, as recently proposed.     

Variation in the nrDNA ITS of Pinus subsection Cembroides: implications for molecular systematic studies of pine species complexes.

The pinyon pines (Pinus subsection Cembroides), distributed in semiarid regions of the western United States and Mexico, include a mixture of relictual and more recently evolved taxa. To investigate relationships among the pinyons, we screened and partially sequenced 3000-bp clones of the nuclear ribosomal DNA internal transcribed spacer (ITS) region for 16 taxa from subsect. Cembroides and nine representatives from four other subsections of subgenus Strobus. Restriction digests of clones reveal within-individual heterogeneity, suggesting that concerted evolution is operating slowly on the ITS in pine species. Two ITS clones were identified as pseudogenes. Tandem subrepeats in the ITS1 form stem loops comparable to those in other genera of Pinaceae and may be promoting recombination between rDNA repeats, resulting in ITS1 chimeras. Within the pinyon clade, phylogenetic structure is present, but different clones from the same (or different) individuals of a species are polyphyletic, indicating that coalescence of ITS copies within individual genomes predates evolutionary divergence in the group. At the level of subsection and above, the ITS region corresponds well with morphological and cpDNA evidence. Except for P. nelsonii, the pinyons are monophyletic, with both subsect. Cembroides and P. nelsonii forming a clade with the foxtail and bristlecone pines (subsect. Balfourianae) of western North America.     

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.     

Evolution of the 5.8S nrDNA gene and internal transcribed spacers in Carapichea ipecacuanha (Rubiaceae) within a phylogeographic context

Nuclear ribosomal DNA (nrDNA) constitutes a multicopy gene family that is used widely to test evolutionary hypotheses across a broad range of organisms. It is presumed that, as a result of concerted evolution, tandem nrDNA repeats are homogeneous within species and different between species. We sampled 77 specimens of a disjunct species (Carapichea ipecacuanha) from throughout its three geographic ranges and obtained 266 nrDNA sequences, of which 26 were obtained by direct sequencing and 240 by cloning of PCR products. Complementary sequence analyses, which included analyses of secondary structure stability, the pattern of base substitutions, GC content, and the presence of conserved motifs, were used to characterize the internal transcribed spacer (ITS) region (ITS1-5.8S nrDNA-ITS2). Our results showed that concerted evolution of the ITS region was incomplete in C. ipecacuanha, particularly in the Atlantic range. In the highly polymorphic populations of the Atlantic range, intraindividual variation was observed and involved 56 functional paralogs and 15 pseudogenes from two highly divergent ribogroups. The Amazonian range (with 12 functional paralogs) and the Central-American range (with five functional paralogs) were genetically depauperate and exhibited no pseudogenes. In the two latter ranges, almost complete homogenization of the ITS sequences had occurred. We argue that it is important to consider past evolutionary history when making inferences about the efficiency with which concerted evolution homogenizes tandem nrDNA repeats a single sequence.     

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.     

长苞铁杉nrDNA内转录间隔区及5.8S的二级结构分析研究

核糖体RNA及相邻区域的二级结构研究,作为一个重要的工具,已在一些分类等级上被应用于系统发育的分析。以长苞铁杉为实验材料,通过克隆、测序,利用最小自由能原理预测nrDNA内转录间隔区及5.8S转录本的二级结构,分析它们的结构特点,探讨假基因化拷贝与功能拷贝结构上的差异。分析结果表明:(1)ITS1区的二级结构主要由几个延展的发夹结构组成,配对的亚重复单位在松科植物特有的保守序列处有部分重叠,未配对的亚重复单位通常能自身折叠,保守序列的部分碱基出现在发夹结构的环中;(2)假基因化拷贝二级结构的自由能比正常拷贝高;(3)与正常拷贝的二级结构相比,假基因化拷贝在进化速率很低的5.8S功能区发生较大的变异,且在5.8 S末端没有和26 S连接配对。     

Variation in the nrDNA ITS of Pinus Subsection Cembroides: Implications for Molecular Systematic Studies of Pine Species Complexes

The pinyon pines (Pinus subsection Cembroides), distributed in semiarid regions of the western United States and Mexico, include a mixture of relictual and more recently evolved taxa. To investigate relationships among the pinyons, we screened and partially sequenced 3000-bp clones of the nuclear ribosomal DNA internal transcribed spacer (ITS) region for 16 taxa from subsect. Cembroides and nine representatives from four other subsections of subgenus Strobus. Restriction digests of clones reveal within-individual heterogeneity, suggesting that concerted evolution is operating slowly on the ITS in pine species. Two ITS clones were identified as pseudogenes. Tandem subrepeats in the ITS1 form stem loops comparable to those in other genera of Pinaceae and may be promoting recombination between rDNA repeats, resulting in ITS1 chimeras. Within the pinyon clade, phylogenetic structure is present, but different clones from the same (or different) individuals of a species are polyphyletic, indicating that coalescence of ITS copies within individual genomes predates evolutionary divergence in the group. At the level of subsection and above, the ITS region corresponds well with morphological and cpDNA evidence. Except for P. nelsonii, the pinyons are monophyletic, with both subsect. Cembroides and P. nelsonii forming a clade with the foxtail and bristlecone pines (subsect. Balfourianae) of western North America.     

The ITS1-5.8S-ITS2 sequence region in the Musaceae: structure, diversity and use in molecular phylogeny

Genes coding for 45S ribosomal RNA are organized in tandem arrays of up to several thousand copies and contain 18S, 5.8S and 26S rRNA units separated by internal transcribed spacers ITS1 and ITS2. While the rRNA units are evolutionary conserved, ITS show high level of interspecific divergence and have been used frequently in genetic diversity and phylogenetic studies. In this work we report on the structure and diversity of the ITS region in 87 representatives of the family Musaceae. We provide the first detailed information on ITS sequence diversity in the genus Musa and describe the presence of more than one type of ITS sequence within individual species. Both Sanger sequencing of amplified ITS regions and whole genome 454 sequencing lead to similar phylogenetic inferences. We show that it is necessary to identify putative pseudogenic ITS sequences, which may have negative effect on phylogenetic reconstruction at lower taxonomic levels. Phylogenetic reconstruction based on ITS sequence showed that the genus Musa is divided into two distinct clades--Callimusa and Australimusa and Eumusa and Rhodochlamys. Most of the intraspecific banana hybrids analyzed contain conserved parental ITS sequences, indicating incomplete concerted evolution of rDNA loci. Independent evolution of parental rDNA in hybrids enables determination of genomic constitution of hybrids using ITS. The observation of only one type of ITS sequence in some of the presumed interspecific hybrid clones warrants further study to confirm their hybrid origin and to unravel processes leading to evolution of their genomes.     

The evolution pattern of rDNA ITS in Avena and phylogenetic relationship of the Avena species (Poaceae: Aveneae)

Ribosomal ITS sequences are commonly used for phylogenetic reconstruction because they are included in rDNA repeats, and these repeats often undergo rapid concerted evolution within and between arrays. Therefore, the rDNA ITS copies appear to be virtually identical and can sometimes be treated as a single gene. In this paper we examined ITS polymorphism within and among 13 diploid (A and C genomes), seven tetraploid (AB, AC and CC genomes) and four hexaploid (ACD genome) to infer the extent and direction of concerted evolution, and to reveal the phylogenetic and genome relationship among species of Avena. A total of 170 clones of the ITS1-5.8S-ITS2 fragment were sequenced to carry out haplotype and phylogenetic analysis. In addition, 111 Avena ITS sequences retrieved from GenBank were combined with 170 clones to construct a phylogeny and a network. We demonstrate the major divergence between the A and C genomes whereas the distinction among the A and B/D genomes was generally not possible. High affinity among the A(d) genome species A. damascena and the ACD genome species A. fatua was found, whereas the rest of the ACD genome hexaploids and the AACC tetraploids were highly affiliated with the A(l) genome diploid A. longiglumis. One of the AACC species A. murphyi showed the closest relationship with most of the hexaploid species. Both C(v) and C(p) genome species have been proposed as paternal donors of the C-genome carrying polyploids. Incomplete concerted evolution is responsible for the observed differences among different clones of a single Avena individual. The elimination of C-genome rRNA sequences and the resulting evolutionary inference of hexaploid species are discussed.     

Phylogenetic utility of the external transcribed spacer (ETS) of 18S-26S rDNA: congruence of ETS and ITS trees of Calycadenia (Compositae)

The 3' region of the external transcribed spacer (ETS) of 18S-26S nuclear ribosomal DNA was sequenced in 19 representatives of Calycadenia/Osmadenia and two outgroup species (Compositae) to assess its utility for phylogeny reconstruction compared to rDNA internal transcribed spacer (ITS) data. Universal primers based on plant, fungal, and animal sequences were designed to amplify the intergenic spacer (IGS) and an angiosperm primer was constructed to sequence the 3' end of the ETS in members of tribe Heliantheae. Based on these sequences, an internal ETS primer useful across Heliantheae sensu lato was designed to amplify and sequence directly the 3' ETS region in the study taxa, which were the subjects of an earlier phylogenetic investigation based on ITS sequences. Size variation in the amplified ETS region varied across taxa of Heliantheae sensu lato from approximately 350 to 700 bp, in part attributable to an approximately 200-bp tandem duplication in a common ancestor of Calycadenia/Osmadenia. Phylogenetic analysis of the 200-bp subrepeats and examination of apomorphic changes in the duplicated region demonstrate that the subrepeats in Calycadenia/Osmadenia have evolved divergently. Phylogenetic analyses of the entire amplified ETS region yielded a highly resolved strict consensus tree that is nearly identical in topology to the ITS tree, with strong bootstrap and decay support on most branches. Parsimony analyses of combined ETS and ITS data yielded a strict consensus tree that is better resolved and generally better supported than trees based on either data set analyzed separately. We calculated an approximately 1.3- to 2.4-fold higher rate of sequence evolution by nucleotide substitution in the ETS region studied than in ITS-1 + ITS-2. A similar disparity in the proportion of variable (1.3 ETS:1 ITS) and potentially informative (1.5 ETS:1 ITS) sites was observed for the ingroup. Levels of homoplasy are similar in the ETS and ITS data. We conclude that the ETS holds great promise for augmenting ITS data for phylogenetic studies of young lineages.     

Intraspecific Concerted Evolution of the rDNA ITS1 in Anopheles farauti Sensu Stricto (Diptera: Culicidae) Reveals Recent Patterns of Population Structure

We examined the intraindividual variation present in the first ribosomal internal transcribed spacer (ITS1) of Anopheles farauti to determine the level of divergence among populations for this important malarial vector. We isolated 187 clones from 70 individuals and found regional variation among four internal tandem repeats. The data were partitioned prior to analysis given the presence of a paralogous ITS2 sequence, called the 5'-subrepeat, inserted in the ITS1 of most clones. A high level of homogenization and population differentiation was observed for this repeat, which indicates a higher rate of turnover relative to the adjacent 'core' region. Bayesian analysis was performed using several substitutional models on both a combined and a partitioned data set. On the whole, the ITS1 phylogeny and geographic origin of the samples appear to be congruent. Some interesting exceptions indicate the spread of variant repeats between populations and the retention of ancestral polymorphism. Our data clearly demonstrate concerted evolution at the intraspecific level despite intraindividual variation and a complex internal repeat structure from a species that occupies a continuous coastal distribution. A high rate of genomic turnover in combination with a high level of sequence divergence appears to be a major factor leading to its concerted evolution within these populations.     

The complete external transcribed spacer of 18S-26S rDNA: amplification and phylogenetic utility at low taxonomic levels in asteraceae and closely allied families

For molecular phylogenetic reconstruction of some intrageneric groups of plants, a DNA region is needed that evolves more rapidly than the internal transcribed spacer (ITS) of the 18S-26S nuclear ribosomal DNA (nrDNA) repeat. If the region identified is nuclear, it would also be desirable for it to undergo rapid concerted evolution to eliminate problems with coalescence. The external transcribed spacer (ETS) of the nrDNA repeat has shown promise for intrageneric phylogenetic reconstruction, but only the 3' end of the region has been utilized for phylogenetic reconstruction and "universal" primers for PCR amplification have been elusive. We present a method for reliably amplifying and sequencing the entire ETS throughout Asteraceae and some closely allied families. We also show that the ETS is more variable and phylogenetically informative than the ITS in three disparate genera of Asteraceae-Argyranthemum (tribe Anthemideae), Asteriscus (tribe Inuleae), and Helianthus (tribe Heliantheae). The full ETS was amplified using a primer (ETS1f) within the intergenic spacer in combination with a primer (18S-2L) in the 5' end of the highly conserved 18S gene. ETS1f was designed to correspond to a highly conserved region found in Helianthus and Crepis, which are in separate subfamilies of Asteraceae. ETS1f/18S-2L primed in all of the tribes of Asteraceae as well as exemplar taxa from Campanulaceae, Goodeniaceae, and Calyceraceae. For both Argyranthemum and Asteriscus, we were able to directly sequence the ETS PCR products when a single band was produced. When multiple bands were produced, we gel-purified and occasionally cloned the band of interest before sequencing. Although PCR produced single bands for Helianthus species, it was necessary to clone Helianthus amplifications prior to sequencing due to multiple intragenomic ETS repeat types. Alignment of ETS sequences for Argyranthemum and Asteriscus was straightforward and unambiguous despite some subrepeat structure in the 5' end. For Helianthus, different numbers of large tandem subrepeats in different species required analysis of the orthology of the subrepeats prior to alignment. In all three genera, the ETS provided more informative variation for phylogenetic reconstruction and allowed better resolution of relationships than the ITS. Although cloned sequences from Helianthus differed, intragenomic clones consistently formed clades. This result indicated that concerted evolution was proceeding rapidly enough in ETS that species-specific phylogenetic signal was retained. It should be now be possible to use the entire ETS for phylogenetic reconstruction of recently diverged lineages in Asteraceae and at least three other families (approximately 26,000 species or about 8% of all angiosperms).     

Molecular organization of 5S rDNA in bitterlings (Cyprinidae)

Molecular organization and nucleotide sequences of the 5S rRNA gene and NTS were investigated in freshwater fish, bitterlings (Acheilognathinae), including 10 species/subspecies of four genera, Acheilognathus, Pseudoperilampus, Rhodeus, and Tanakia, to understand the evolutionary trait of 5S rDNA arrays. Southern hybridization analysis revealed a general trend with tandem repeats of 5S rDNA in all the examined bitterlings. Sequence analysis demonstrated a conserved 120 bp sequence of the 5S rRNA gene and a short NTS of 56–67 bp with two distinct portions, a conserved (5′-flanking portion; at positions −1 to −38) and a variable part (3′-flanking portion), in 6 of 10 species/subspecies examined. The conserved NTS region was most likely an external promoter so far observed in various vertebrates, whereas the variable NTS region could be divided into two types due to its nucleotide polymorphisms. Molecular phylogeny using the 5S rRNA gene and NTS sequences suggested the occurrence of 5S rDNA duplication before speciation and a concerted evolution for the gene and conserved NTS regions, but a birth-and-death process to maintain the variable NTS region. Thus, the 5S rDNA in the examined bitterlings might have evolved under a mixed process of evolution.     

Cryptic long internal repeat sequences in the ribosomal DNA ITS1 gene of the dinoflagellate Cochlodinium polykrikoides (dinophyceae): a 101 nucleotide six-repeat track with a palindrome-like structure

Extremely long PCR fragments were generated by PCR amplification of ITS and 5.8S rDNA from Cochlodinium polykrikoides against other dinoflagellates. These patterns were consistent among geographically different isolates of C. polykrikoies. DNA sequencing reactions revealed that the PCR products were 1,166 bp in length and consisted of 813 bp of ITS1, 160 bp of 5.8S rDNA and 193 bp of ITS2. Thus, the long length was caused mainly by the long ITS1 sequence. Cryptically, the ITS1 contained a tract of 101 bp that occurs six times in tandem. The six repeated elements had identical nucleotide sequences. ITS1, therefore, separated three distinct regions: the 5' end (122 bp), the six parallel repeats (606 bp), and the 3' region (85 bp). Interestingly, both the single and six-repeat sequences should be palindrome-like sequences. In inferred secondary structures, both repeat sequences formed a long helical structure. This is the first reported discovery of comparatively long internal repeats in the ITS1 of dinoflagellates.     

Characterization of subrepeat regions within rDNA intergenic spacers of the edible basidiomycete Lentinula edodes

For 16 commercial cultivars of Lentinula edodes, DNA fragments for the nuclear rDNA intergenic spacers IGS1 and IGS2 were amplified and analyzed. IGS1 contained a subrepeat region, named SR1, and IGS2 contained a pair of direct repeats and a subrepeat region, named SR2. Three and five types of subrepeats were found in SR1 and SR2, respectively. Heterogeneity in the lengths of IGS1 and IGS2 arose mainly from the number of different kinds of subrepeats within SR1 and SR2. The DNA fingerprints from the PCR products targeting SR1 and SR2 were specific for each of the 16 cultivars, and had enough variation for discrimination among the cultivars. This result suggests that the DNA fingerprints targeting SR1 and SR2 are useful for investigations of L. edodes cultivars.     

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.