Intraindividual and Interspecies Variation in the 5S rDNA of Coregonid Fish

This study was designed to characterize further the nontranscribed intergenic spacers (NTSs) of the 5S rRNA genes of fish and evaluate this marker as a tool for comparative studies. Two members of the closely related North American Great Lakes cisco species complex (Coregonus artedi and C. zenithicus) were chosen for comparison. Fluorescence in situ hybridization found the ciscoes to have a single multicopy 5S locus located in a C band-positive region of the largest submetacentric chromosome. The entire NTS was amplified from the two species by polymerase chain reaction with oligonucleotide primers anchored in the conserved 5S coding region. Complete sequences were determined for 25 clones from four individuals representing two discrete NTS length variants. Sequence analysis found the length variants to result from presence of a 130-bp direct repeat. No two sequences from a single fish were identical. Examination of sequence from the coding region revealed two types of 5S genes in addition to pseudogenes. This suggests the presence of both somatic and germline (oocyte) forms of the 5S gene in the genome of Coregonus. The amount of variation present among NTS sequences indicates that accumulation of variation (mutation) is greater in this multicopy gene than is gene conversion (homogenization). The high level of sequence variation makes the 5S NTS an inappropriate DNA sequence for comparisons of closely related taxa. Received: 22 August 1997 / Accepted: 31 October 1997     

Organization of 5S rDNA in species of the fish Leporinus: two different genomic locations are characterized by distinct nontranscribed spacers.

To address understanding the organization of the 5S rRNA multigene family in the fish genome, the nucleotide sequence and organization array of 5S rDNA were investigated in the genus Leporinus, a representative freshwater fish group of South American fauna. PCR, subgenomic library screening, genomic blotting, fluorescence in situ hybridization, and DNA sequencing were employed in this study. Two arrays of 5S rDNA were identified for all species investigated, one consisting of monomeric repeat units of around 200 bp and another one with monomers of 900 bp. These 5S rDNA arrays were characterized by distinct NTS sequences (designated NTS-I and NTS-II for the 200- and 900-bp monomers, respectively); however, their coding sequences were nearly identical. The 5S rRNA genes were clustered in two chromosome loci, a major one corresponding to the NTS-I sites and a minor one corresponding to the NTS-II sites. The NTS-I sequence was variable among Leporinus spp., whereas the NTS-II was conserved among them and even in the related genus Schizodon. The distinct 5S rDNA arrays might characterize two 5S rRNA gene subfamilies that have been evolving independently in the genome.     

Identification of DNA cis elements essential for expansion of ribosomal DNA repeats in Saccharomyces cerevisiae

Saccharomyces cerevisiae carries approximately 150 ribosomal DNA (rDNA) copies in tandem repeats. Each repeat consists of the 35S rRNA gene, the NTS1 spacer, the 5S rRNA gene, and the NTS2 spacer. The FOB1 gene was previously shown to be required for replication fork block (RFB) activity at the RFB site in NTS1, for recombination hot spot (HOT1) activity, and for rDNA repeat expansion and contraction. We have constructed a strain in which the majority of rDNA repeats are deleted, leaving two copies of rDNA covering the 5S-NTS2-35S region and a single intact NTS1, and whose growth is supported by a helper plasmid carrying, in addition to the 5S rRNA gene, the 35S rRNA coding region fused to the GAL7 promoter. This strain carries a fob1 mutation, and an extensive expansion of chromosomal rDNA repeats was demonstrated by introducing the missing FOB1 gene by transformation. Mutational analysis using this system showed that not only the RFB site but also the adjacent approximately 400-bp region in NTS1 (together called the EXP region) are required for the FOB1-dependent repeat expansion. This approximately 400-bp DNA element is not required for the RFB activity or the HOT1 activity and therefore defines a function unique to rDNA repeat expansion (and presumably contraction) separate from HOT1 and RFB activities.     

5S rDNA variation and its phylogenetic inference in the genus <Emphasis Type="Italic">Leporinus</Emphasis> (Characiformes: Anostomidae)

5S rDNA sequences have proven to be valuable as genetic markers to distinguish closely related species and also in the understanding of the dynamic of repetitive sequences in the genomes. In the aim to contribute to the knowledge of the evolutionary history of Leporinus (Anostomidae) and also to contribute to the understanding of the 5S rDNA sequences organization in the fish genome, analyses of 5S rDNA sequences were conducted in seven species of this genus. The 5S rRNA gene sequence was highly conserved among Leporinus species, whereas NTS exhibit high levels of variations related to insertions, deletions, microrepeats, and base substitutions. The phylogenetic analysis of the 5S rDNA sequences clustered the species into two clades that are in agreement with cytogenetic and morphological data.     

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.     

Molecular characterization and physical mapping of two classes of 5S rDNA in the genomes of Gymnotus sylvius and G. inaequilabiatus (Gymnotiformes, Gymnotidae)

The nucleotide sequences of the 5S rRNA multigene family and their distribution across the karyotypes in 2 species of Gymnotiformes, genus Gymnotus (G. sylvius and G. inaequilabiatus) were investigated by means of fluorescence in situ hybridization (FISH). The results showed the existence of 2 distinct classes of 5S rDNA sequences in both species: class I and class II. A high conservative pattern of the codifying region of the 5S rRNA gene was identified, contrasting with significant alterations detected in the nontranscribed spacer (NTS). The presence of TATA-like sequences along the NTS of both species was an expected occurrence, since such sequences have been associated with the regulation of the gene expression. FISH using 5S rDNA class I and class II probes revealed that both gene classes were collocated in the same chromosome pair in the genome of G. sylvius, while in that of G. inaequilabiatus, class II appeared more disperse than class I.     

Independent chromosomal localization of two different size 5S rDNA of Allium victorialis var. platyphyllum by sequential fluorescence in situ hybridization in accordance with sequence polymorphism

5S rRNA gene repeat units in a species are usually organized as either one relatively close size with numbers of intraspecific variations in NTS region or two different sizes with completely different sequence in NTS. Allium victorialis var. platyphyllum revealed two different size products of approximately 0.39 kb and 0.51 kb with highly conserved coding region of 120 bp. However, an extra sequences of approximately 120 bp between at 324 and 443 bp in long NTS region revealed, besides the remaining sequences of two NTS regions of short and long size were highly conserved giving the identity of 94.9%. To identify whether two different size 5S rDNA are occupied by a mixed state as random repeat or an independent group by each size in a particular locus, two rounds of FISH was sequentially performed using two probes of independent different size 5S rDNA and additional probe of only extra sequences of 120 bp in long NTS. Due to the highly conserved coding regions of both 5S rDNA, two different size 5S rDNA were detected in 3 loci in short arm of chromosome 6, however, extra sequences of long NTS was shown only in one locus within detected 5S rDNA from all examined chromosomes and interphase cells. This independent localization of two different size 5S rDNA suggests that 5S rDNA may be organized as a tandem repeat with random positions in a molecular level, but of cytogenetic view in chromosomes and interphase cells, they are organized as an independent group in a significant loci consisting of own size by the patterns of nucleotide variations.     

Molecular organization of 5S rDNA in fishes of the genus Brycon.

There are few reports on the genomic organization of 5S rDNA in fish species. To characterize the 5S rDNA nucleotide sequence and chromosomal localization in the Neotropical fishes of the genus Brycon, 5S rDNA copies from seven species were generated by PCR. The nucleotide sequences of the coding region (5S rRNA gene) and the nontranscribed spacer (NTS) were determined, revealing that the 5S rRNA genes were highly conserved, while the NTSs were widely variable among the species analyzed. Moreover, two classes of NTS were detected in each species, characterized by base substitutions and insertions-deletions. Using fluorescence in situ hybridization (FISH), two 5S rDNA chromosome loci that could be related to the two 5S rDNA NTS classes were observed in at least one of the species studied. 5S rDNA sequencing and chromosomal localization permitted the characterization of Brycon spp. and suggest a higher similarity among some of them. The data obtained indicate that the 5S rDNA can be an useful genetic marker for species identification and evolutionary studies.     

Closure of rRNA related gaps in the Chromobacterium violaceum genome with the PCR-assisted contig extension (PACE) protocol

In the finishing phase of the Chromobacterium violaceum genome project, the shotgun sequences were assembled into 57 contigs that were then organized into 19 scaffolds, using the information from shotgun and cosmid clones. Among the 38 ends resulting from the 19 scaffolds, 10 ended with sequences corresponding to rRNA genes (seven ended with the 5S rRNA gene and three ended with the 16S rRNA gene). The 28 non-ribosomal ends were extended using the PCR-assisted contig extension (PACE) methodology, which immediately closed 15 real gaps. We then applied PACE to the 16S rRNA gene containing ends, resulting in eight different sequences that were correctly assembled within the C. violaceum genome by combinatory PCR strategy, with primers derived from the non-repetitive genomic region flanking the 16S and 5S rRNA gene. An oriented combinatory PCR was used to correctly position the two versions (copy A and copy B, which differ by the presence or absence of a 100-bp insert); it revealed six copies corresponding to copy A, and two to copy B. We estimate that the use of PACE, followed by combinatory PCR, accelerated the finishing phase of the C. violaceum genome project by at least 40%.     

Sequence Variation and Comparison of the 5S rRNA Sequences in <Emphasis Type="Italic">Allium</Emphasis> Species and their Chromosomal Distribution in Four <Emphasis Type="Italic">Allium</Emphasis> Species

The gene structure and sequence diversity of 5S rRNA genes were analyzed in 13 Allium species. While the lengths and sequences of the coding gene segments were conserved, the spacers were highly variable and could be characterized as either short (213–404 bp) or long (384–486 bp) spacers. The short spacers were further classified into five subtypes (SS-I to SS-V) and the long spacers into four subtypes (LS-I to LS-IV). The short spacers were more conserved than were the long spacers. There was a sequence duplication of 85 bp in SS-III that distinguished it from SS-II. The coding sequences of the 5S rRNA genes started with CGG and ended with either CCC or TCC. Both long and short spacers started with TTTT at their 5′-ends. However, the long spacers ended with a 3′-TGA sequence, whereas the short spacers terminated with various sequences, such as TTA, ATA, or TGA. GC content ranged from 27 to 41% in whole repeats, and the GC content in the long spacers was lower than in the short spacers. The nucleotide diversity in the coding regions was lower than in the spacers, and the nucleotide diversity in the coding regions did not correlate with that of the spacers. FISH analysis confirmed that each Allium species has either short spacers or long spacers. Although chromosomal locations of the 5S rRNA genes in Allium wakegi confirmed the allodiploid nature of A. cepa and A. fistulosum, spacer sequences revealed the absence of SS-II in A. cepa and in A. wakegi. The current study demonstrated that the 5S rRNA genes diverged in early stages in Allium species differentiation except of the allodiploid A. wakegi.     

Characterization of the Pea Chloroplast DNA OriA Region

One of the two origins of replication in pea chloroplast DNA (oriA) maps in the rRNA spacer region downstream of the 16S rRNA gene, and further characterization of this origin is presented here. End-labeling of nascent DNA strands from in vivo replicating ctDNA was used to generate probes for Southern hybridization. Hybridization data identified the same region that was previously mapped to contain D-loops by electron microscopy. Subclones of the ori A region were tested for their ability to support in vitro DNA replication using a partially purified pea ctDNA replication system. Two-dimensional agarose gel electrophoresis identified replication intermediates for clones from the region just downstream of the 16S rRNA gene, with a 450-bp SacI-EcoRI clone showing the strongest activity. The experiments presented in this paper identify the 940 base pair region in the rRNA spacer between the 3′ end of the 16S rRNA gene and the Eco RI site as containing oriA. Previous studies by electron microscopy localized the D-loop in the spacer region just to the right of the Bam HI site, but the experiments presented here show that sequences to the left of the BamHI site are required for replication initiation from ori A. DNA sequence analysis of this region of pea ctDNA shows the presence of characteristic elements of DNA replication origins, including several direct and inverted repeat sequences, an A + T rich region, and dna A-like binding sites, most of which are unique to the pea ctDNA ori A region when compared with published rRNA spacer sequences from other chloroplast genomes.     

Nucleotide sequence of two repeating units of the 5S rRNA gene from the house cricket Acheta domesticus

The 5S rRNA genes of the house cricket, Acheta domesticus, are contained within two basic repeating units measuring 3.0 and 2.1 kb, that have been cloned. Nucleotide sequence analysis was done on a 528-bp and a 541-bp EcoRI-HinfI DNA fragment from each cloned repeating unit which contains the 5S rRNA coding region. The nucleotide sequences of the 5S rRNA coding region from the two repeating units are identical.     

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.     

The 5S ribosomal RNA gene in Pythium species: two different genomic locations.

The 5S ribosomal RNA (rRNA) genes in eukaryotes may occur either interspersed with the other rRNA genes in the ribosomal DNA (rDNA) repeat, or in separate tandem arrays, or dispersed throughout the genome. In Pythium species and in several related Oomycetes, polymerase chain reaction (PCR) amplification of the nontranscribed spacer (NTS) region with one primer specific for the 5S gene revealed, with several exceptions, that the 5S rRNA gene was present in the rDNA repeat of those species with filamentous sporangia and was absent from the rDNA repeat of those with globose or unknown sporangia. When present, the gene was located approximately 1 kb downstream of the large-subunit rRNA gene and on the strand opposite that on which the other rRNA genes were located. This was confirmed in P. torulosum by sequencing of the gene and its flanking regions. The 5S rRNA genes of P. ultimum were found in tandem arrays outside the rDNA repeat. Evidence of dispersed 5S rRNA sequences was also observed. For many of the species of Pythium having the 5S gene in the NTS, the region between the large-subunit rRNA gene and the 5S gene was found to have length heterogeneity. Oomycetes related to Pythium were also found to have the 5S gene in the NTS, although sometimes in the opposite orientation. This may mean that the presence of the gene in the NTS is ancestral for the Oomycetes and that the absence of the gene in the NTS in those Pythiums with globose sporangia is due to loss of the gene from the rDNA repeat in an ancestor of this group of species. These results favor the view that 5S rRNA gene linkage to the rRNA cistron existed prior to the unlinked arrangement seen in most plants and animals.     

A sensitive and specific PCR-based discrimination of split red vetch and lentil seeds

A PCR-based marker technique was developed to discriminate between morphologically similar split seed of vetch (Vicia sativa) and lentil (Lens culinaris subsp.culinaris). Sequence tagged microsatellite site (STMS) markers were more discriminatory than markers produced from the nontranscribed spacer (NTS) region of the 5S ribosomal RNA gene. A sequence characterized amplified region (SCAR) marker, developed from the 5S rRNA NTS region, was sensitive when resolved on agarose. However, the fluorescent-labeled 5S rRNA SCAR marker was unable to discriminate between vetch and lentil, probably because of the low copy number of the marker, and was not visualized on agarose. An STMS primer-pair (PSMPSAD123), developed from field pea, was able to discriminate split red cotyledon vetch from split red cotyledon lentil because it produced specific markers at 563 bp for lentil and 353 and 474 bp for vetch. The vetch-specific STMS marker was conserved among all species of theVicia genus used in this study and was sensitive enough to discriminate both on agarose gels and on polyacrylamide gel-based fluorescent systems. The fluorescent-tagged STMS analysis revealed peaks for vetch and lentil at the expected sizes in admixtures of milled vetch and lentil seeds, and it was sensitive enough to detect one vetch seed in 1999 lentil seeds. The development of PCR-based tests for detecting the level of vetch seed contamination in lentil export seed may provide a method for quality assurance of export lentil seed.     

Distribution of 5S ribosomal RNA genes in somatic and germ cells of the house cricket,Acheta domesticus

In the house cricket,Acheta domesticus, the 110 genes per haploid genome encoding 18S and 28S rRNA are contained within rDNA repeats which are amplified during oogenesis. The 5S rRNA coding sequences of this cricket are found in two sizes of 5S DNA repeating units (measuring 2.1 and 3.0 kb). The 3.0 kb repeats account for more than 90% of the totalAcheta 5S DNA. We have determined the number of cricket 5S rRNA genes by RNA-DNA hybridization analysis: 310 5S DNA repeats/haploid genome clearly approximates the number of 18S and 28S rRNA genes. Because of the relatively low copy number of 5S rRNA genes the possibility of 5S DNA amplification in oocytes ofA. domesticus was also examined. Although amplification of rDNA is readily detectable, amplification of 5S DNA is not observed in oocytes ofA. domesticus. Unlike the genes coding for 18S and 28S rRNA which are localized at a single chromosomal site in the genome ofA. domesticus, the 5S rRNA genes occupy numerous sites distributed along the length of most chromosomes.