Distribution and evolution of chitinase genes in Streptomyces species: involvement of gene-duplication and domain-deletion

Streptomyces coelicolor A3(2) possesses nine genes for family 18 chitinases and two for family 19, showing high multiplicity. By hybridization analyses, distribution of those chitinase genes was investigated in six other Streptomyces species covering the whole phylogenetic range based on 16S rDNA sequences. All strains showed high-multiplicity of chitinase genes, like S. coelicolor A3(2). The phylogeny and gene organization of the family 18 chitinase genes cloned from Streptomyces species so far were then analyzed to investigate the gene evolution. It was concluded that Streptomyces already possessed a variety of chitinase genes prior to branching into many species, and that the ancestral genes of chiA and chiB have been generated by gene-duplication. In the course of the analyses, evidence that the chi30 and chi40 genes of S. thermoviolaceus were derived from their corresponding original chitinase genes by losing gene parts for substrate-binding domains and fibronectin type III-like domains was obtained. It was thus shown that gene-duplication and domain-deletion were implicated in generating the high diversity and multiplicity of chitinase genes in Streptomyces species. This revised version was published online in June 2006 with corrections to the Cover Date.     

Chromosomal distribution of rDNA in Pan paniscus,Gorilla gorilla beringei,and Symphalangus syndactylus: Comparison to related primates

Hybridization in situ was used to identify rDNA in chromosomes of the pygmy chimpanzee, mountain gorilla, and siamang gibbon. In contrast to other Pongids, and man, the gorilla has only two pairs of rDNA-containing chromosomes. The single pair in the siamang bears no resemblance to the nucleolar chromosome of the closely related lar gibbon. Pan paniscus and P. troglodytes have the same rDNA distribution, and similar karyotypes except in the structure of chromosome 23p. Grain counts over unbanded preparations show that the human, orangutan, and both chimpanzees have about the same total rDNA multiplicity.     

Associations Among Rhizobial Chromosomal Background, nod Genes, and Host Plants Based on the Analysis of Symbiosis of Indigenous Rhizobia and Wild Legumes Native to Xinjiang

The associations among rhizobia chromosomal background, nodulation genes, legume plants, and geographical regions are very attractive but still unclear. To address this question, we analyzed the interactions among rhizobia rDNA genotypes, nodC genotypes, legume genera, as well as geographical regions in the present study. Complex relationships were observed among them, which may be the genuine nature of their associations. The statistical analyses indicate that legume plant is the key factor shaping both rhizobia genetic and symbiotic diversity. In the most cases of our results, the nodC lineages are clearly associated with rhizobial genomic species, demonstrating that nodulation genes have co-evolved with chromosomal background, though the lateral transfer of nodulation genes occurred in some cases in a minority. Our results also support the hypothesis that the endemic rhizobial populations to a certain geographical area prefer to have a wide spectrum of hosts, which might be an important event for the success of both legumes and rhizobia in an isolated region.     

Length heterogeneity of amplified circular rDNA molecules in oocytes of the house cricket Acheta domesticus (Orthoptera: Gryllidae)

Amplification of the genes coding for rRNA occurs in the oocytes of a wide variety of organisms. The amplification process appears to be mediated through a rolling-circle mechanism. The approximate molecular weight of the smallest rDNA circles is equivalent to the estimated combined molecular weight of DNA which codes for a single ribosomal RNA precursor molecule and an associated non-transcribed spacer DNA sequence. RNA-DNA hybridization studies carried out on oocytes of the house cricket, Acheta domesticus, suggest that DNA coding for rRNA accounts for only a small fraction of the rDNA satellite, all of which is amplified in the oocyte. In order to test the possibility that the remainder of the amplified rDNA represents spacer and to determine whether a rolling-circle mechanism might also be involved in amplification in A. domesticus oocytes, rDNA was isolated from ovaries of A. domesticus and spread for electron microscopy. A large proportion of the rDNA isolated from ovaries is circular, while main-band DNA and rDNA prepared from other tissues demonstrates few if any circles. The mean size of the smallest rDNA circles is approximately 8 times longer than the length estimated for DNA which codes for 18 S and 28 S rRNA. Denaturation mapping shows the rDNA circles to contain two major readily denaturing regions located about equidistant from one another on the circle. Each readily denaturing region accounts for 4–6% of the total DNA in the circle. The fact that only 12% of the average molecule is required to code for A. domesticus 18 S and 28 S rRNA is consistent with the hybridization data. Considerable size heterogeneity exists in the length of the smallest class of rDNA molecules. In the rDNA of other species such heterogeneity has been shown to reside in the non-transcribed spacer.     

Chromosome Localization of 5S and 45S Ribosomal DNA in the Genomes of Linum L. Species of the Section Linum (Syn. Protolinum and Adenolinum)

Fluorescence in situ hybridization (FISH) was for the first time used to study the chromosomal location of the 45S (18S–5.8S–26S) and 5S ribosomal genes in the genomes of five flax species of the section Linum (syn. Protolinum and Adenolinum). In L. usitatissimum L. (2n = 30), L. angustifolium Huds. (2n = 30), and L. bienne Mill. (2n = 30), a major hybridization site of 45S rDNA was observed in the pericentric region of a large metacentric chromosome. A polymorphic minor locus of 45S rDNA was found on one of the small chromosomes. Sites of 5S rDNA were colocalized with those of 45S rDNA, but direct correlation between signal intensities from the 45S and 5S rDNA sites was observed only in some cases. Other 5S rDNA sites mapped to two chromosomes in these flax species. In L. grandiflorum Desf. (2n = 16) and L. austriacum L. (2n = 18), large regions of 45S and 5S rDNA were similarly located on a pair of homologous satellite-bearing chromosomes. An additional large polymorphic site of 45S and 5S rDNA was found in the proximal region of one arm of a small chromosome in the L. usitatissimum, L. angustifolium, and L. bienne karyotypes. The other arm of this chromosome contained a large 5S rDNA cluster. A similar location of the ribosomal genes in the pericentric region of the pair of satellite-bearing metacentrics confirmed the close relationships of the species examined. The difference in chromosomal location of the ribosomal genes between flax species with 2n = 30 and those with 2n = 16 or 18 testified to their assignment to different sections. The use of ribosomal genes as chromosome markers was assumed to be of importance for comparative genomic studies in cultivated flax, a valuable crop species of Russia, and in its wild relatives.     

Cloning of ribosomal RNA genes from an Indian isolate ofGiardia lamblia and the use of intergenic nontranscribing spacer regions in the differentiation ofGiardia from other enteric pathogens

The ribosomal RNA genes from an Indian isolate ofGiardia lamblia have been cloned and characterized with respect to size, composition and copy number. Southern blotting and rDNA cloning ofGiardia lamblia revealed that genes coding for ribosomal RNA (rRNA) are exceptionally small and are encoded within a 5.6 kb genome fragment repeat. The rDNA repeat unit of this isolate was found to be highly G-C rich like other human isolates and the physical map showed severalSmaI sites. There are 132 copies of the rDNA repeat unit per cell in a head to tail arrangement. Two fragments corresponding to intergenic (0.2 kb and 0.3 kb) region and one (0.8 kb) containing both an intergenic region and a small part of the small subunit ribosomal RNA (SS rRNA) have been identified within the rDNA. These were used in heterogeneity studies ofGiardia isolated from two geographic locations as well as in the analysis of cross reactivity with other enteric organisms. In Southern blots, all the three fragments were found to be highly specific for the differential diagnosis ofGiardia spp. from the other enteric pathogens. These findings should help in developing a sensitive and more specific method for the diagnosis of giardiasis over currently available techniques.     

The properties of hybrids formed between the P-group plasmid RP1 and various plasmids from Pseudomonas aeruginosa

Summary Ribosomal DNA content has been determined in several adult and larval tissues of Drosophila melanogaster. Underreplication of rRNA genes was observed in polytenic salivary glands of larvae. On the contrary, polytenic/polyploid ovaries showed no decrease in rDNA. It is concluded that polyteny is not necessarily associated with underreplication of rDNA. No other tissue examined displayed any change in rDNa redundancy. Third-instar-larvae showed a decrease in rDNA amount which might be partly accounted for by underreplication of rDNA in salivary glands. No such decrease was seen in pupae. Bobbed genotypes were essentially similar to wild type in all tissues except salivary glands. In this case, it was found that the extent of underreplication is less in bobbed as compared to wild genotypes.Ribosomal DNA activity was examined in various tissues of Drosophila melanogaster. The rates of rRNA synthesis vary greatly between various tissues. It is concluded that a control at the level of gene activity operates as differences in the amount of precursor rRNA synthesized can be observed both in flies of varying rDNA contents as well as in various tissues of the same genotype.     

Evolution of DNA in Heterochromatin: the Drosophila Melanogaster Sibling Species Subgroup as a Resource

The Drosophila melanogasterspecies subgroup is a closely-knit collection of eight sibling species whose relationships are well defined. These species are too close for most evolutionary studies of euchromatic genes but are ideal to investigate the major changes that occur to DNA in heterochromatin over short periods during evolution. For example, it is not known whether the locations of genes in heterochromatin are conserved over this time. The 18S and 28S ribosomal RNA genes can be considered as genuine heterochromatic genes. In D. melanogasterthe rRNA genes are located at two sites, one each on the X and Y chromosome. In the other seven sibling species, rRNA genes are also located on the sex chromosomes but the positions often vary significantly, particularly on the Y. Furthermore, rDNA has been lost from the Y chromosome of both D. simulansand D. sechellia, presumably after separation of the line leading to present-day D. mauritiana.We conclude that changes to chromosomal position and copy number of rDNA arrays occur over much shorter evolutionary timespans than previously thought. In these respects the rDNA behaves more like the tandemly repeated satellite DNAs than euchromatic genes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Physical mapping of the 5S ribosomal RNA genes in Arabidopsis thaliana by multi-color fluorescence in situ hybridization with cosmid clones

The 5S ribosomal RNA genes were mapped to mitotic chromosomes of Arabidopsis thaliana by fluorescence in situ hybridization (FISH). In the ecotype Landsberg erecta, hybridization signals appeared on three pairs of chromosomes, two of which were metacentric and the other acrocentric. Hybridization signals on one pair of metacentric chromosomes were much stronger than those on the acrocentric and the other pair of metacentric chromosomes, probably reflecting the number of copies of the genes on the chromosomes. Other ecotypes, Columbia and Wassilewskija, had similar chromosomal distribution of the genes, but the hybridization signals on one pair of metacentric chromosomes were very weak, and detectable only in chromosomes prepared from young flower buds. The chromosomes and arms carrying the 5S rDNA were identified by multi-color FISH with cosmid clones and a centromeric 180 bp repeat as co-probes. The metacentric chromosome 5 and its L arm carries the largest cluster of the genes, and the short arm of acrocentric chromosome 4 carries a small cluster in all three ecotypes. Chromosome 3 had another small cluster of 5S rRNA genes on its L arm. Chromosomes 1 and 2 had no 5S rDNA cluster, but they are morphologically distinguishable; chromosome 1 is metacentric and 2 acrocentric. Using the 5S rDNA as a probe, therefore, all chromosomes of A. thaliana could be identified by FISH. Chromosome 1 is large and metacentric; chromosome 2 is acrocentric carrying 18S-5.8S-25S rDNA clusters on its short arm; chromosome 3 is metacentric carrying a small cluster of 5S rDNA genes on its L arm; chromosome 4 is acrocentric carrying both 18S-5.8S-25S and 5S rDNAs on its short (L) arm; and chromosome 5 is metacentric carrying a large cluster of 5S rDNA on its L arm.     

Ribosomal RNA genes in soybean and common bean: chromosomal organization, expression, and evolution

Ribosomal RNA (5S and 45S) genes were investigated by FISH in two related legumes: soybean [Glycine max (L.) Merr.] and common bean (Phaseolis vulgaris L.). These species are both members of the same tribe (Phaseoleae), but common bean is diploid while soybean is a tetraploid which has undergone diploidization. In contrast to ploidy expectations, soybean had only one 5S and one 45S rDNA locus whereas common bean had more than two 5S rDNA loci and two 45S rDNA loci. Double hybridization experiments with differentially labelled probes indicated that the soybean 45S and 5S rDNA loci are located on different chromosomes and in their distal regions. Likewise, the common bean 45S and 5S rDNA loci were on unique chromosomes, though two of the 5S rDNA loci were on the same chromosome. FISH analysis of interphase nuclei revealed the spatial arrangement of rDNA loci and suggested expression patterns. In both species, we observed one or more 5S rDNA hybridization sites and two 45S rDNA hybridization sites associated with the nucleolar periphery. The 45S rDNA hybridization patterns frequently exhibited gene puffs as de-condensed chromatin strings within the nucleoli. The other condensed rDNA sites (both 5S and 45S) were spatially distant from the nucleolus in nucleoplasmic regions containing heterochromatin. The distribution of rDNA between the nucleoplasm and the nucleoli is consistent with differential gene expression between homologous alleles and among homoeologous loci.     

Detection of 5S and 25S rRNA genes in Sinapis alba, Raphanus sativus and Brassica napus by double fluorescence in situ hybridization

Different ribosomal RNA (5S and 25S) genes were investigated simultaneously by fluorescence in situ hybridization (FISH) in Sinapis alba, Raphanus sativus and Brassica napus. The chromosomes of S. alba carried four 5S and six 25S gene sites, and those of R. sativus four sites of each gene, respectively. These two species have one chromosome pair with both rDNA genes; the two are closely located on a short arm of S. alba, while in R. sativus one is distal on the short arm (5S) and the other more proximal on the long arm (25S). In B. napus we have confirmed 12sites of 25S rDNA. The detection of 5S rDNA genes revealed 14 signals on 12 chromosomes. Of these, six chromosomes had signals for both rDNA genes. The FISH with 5S rDNA probes detected two sites closely adjacent in four chromosomes of B napus. These results are discussed in relation to a probable homoeologous chromosome pair in B. oleracea. Received: 20 July 1999 / Accepted: 8 October 1999     

Characterization of Mitochondrial Small-Subunit Ribosomal RNAs from Holoparasitic Plants

Mitochondrial small-subunit (19S) rDNA sequences were obtained from 10 angiosperms to further characterize sequence divergence levels and structural variation in this molecule. These sequences were derived from seven holoparasitic (nonphotosynthetic) angiosperms as well as three photosynthetic plants. 19S rRNA is composed of a conservative core region (ca. 1450 nucleotides) as well as two variable regions (V1 and V7). In pairwise comparisons of photosynthetic angiosperms to Glycine, the core 19S rDNA sequences differed by less than 1.4%, thus supporting the observation that variation in mitochondrial rDNA is 3–4 times lower than seen in protein coding and rDNA genes of other subcellular organelles. Sequences representing four distinct lineages of nonasterid holoparasites showed significantly increased numbers of substitutions in their core 19S rDNA sequences (2.3–7.6%), thus paralleling previous findings that showed accelerated rates in nuclear (18S) and plastid (16S) rDNA from the same plants. Relative rate tests confirmed the accelerated nucleotide substitution rates in the holoparasites whereas rates in nonparasitic plants were not significantly increased. Among comparisons of both parasitic and nonparasitic plants, transversions outnumbered transitions, in many cases more than two to one. The core 19S rRNA is conserved in sequence and structure among all nonparasitic angiosperms whereas 19S rRNA from members of holoparasitic Balanophoraceae have unique extensions to the V5 and V6 variable domains. Substitution and insertion/deletion mutations characterized the V1 and V7 regions of the nonasterid holoparasites. The V7 sequence of one holoparasite (Scybalium) contained repeat motifs. The cause of substitution rate increases in the holoparasites does not appear to be a result of RNA editing, hence the underlying molecular mechanism remains to be fully documented. Received: 18 May 1997 / Accepted: 11 July 1997     

Variation at the Nor loci in triticale derived from tissue culture

Summary Plants derived from tissue cultures of six triticale genotypes were the subject of an analysis for changes in the rRNA genes located at the site of nucleolar organizer regions (the Nor loci) on chromosomes 1B, 6B and 1R. In addition whole plant phenotypes and the chromosomal constitutions of their progenies were examined for alterations. Following treatment of DNA with the restriction endonuclease Taq1, it was possible to assign electrophoretic bands representing rDNA spacer sequences to each of the chromosomes known to carry a major Nor locus. In general, the rRNA genes were found to be stable except in one family where a marked reduction in the number of rDNA units was observed. This reduction in 1R rDNA spacer sequences was heritable and correlated with reduced C-banding at the position of Nor-R1 on chromosome 1R. The change was clearly a consequence of tissue culture since six other plants regenerated from the same culture, and the original parent, did not carry the alteration.     

Physical mapping of 5S and 45S rDNA loci in pufferfishes (Tetraodontiformes)

Chromosomal features, location and variation of the major and minor rDNA genes cluster were studied in three pufferfish species: Sphoeroides greeleyi and Sphoeroides testudineus (Tetraodontidae) and Cyclichthys spinosus (Diodontidae). The location of the major rDNA was revealed with an 18S probe in two loci for all species. The minor rDNA loci (5S rDNA) was found in one chromosome pair in tetraodontid fishes and four sites located on two distinct chromosomal pairs in C. spinosus. A syntenical organization was not observed among the ribosomal genes. Signal homogeneity for GC/AT-DNA specific fluorochromes was observed in diodontid fish except in the NORs regions, which were CMA₃-positive. Giemsa karyotypes of tetraodontid species presents 2n = 46, having the same diploid value of other Sphoeroides species that have been investigated. On the other hand, the karyotype of C. spinosus, described for the first time, shows 2n = 50 chromosomes (4m + 18sm + 12st + 16a). The foreknowledge of the karyotypic structure of this group and also the physical mapping of certain genes could be very helpful for further DNA sequence analysis.     

Differential magnification of rDNA gene types in bobbed mutants of Drosophila melanogaster

Summary In Drosophila melanogaster a partial loss of ribosomal genes leads to the bobbed phenotype. Magnification is a heritable increase in rDNA that may occur in males carrying a deleted X chromosome with a strong bobbed phenotype. The restriction patterns of X chromosome total rDNA, insertions and spacers from magnified bobbed strains were compared with those of the original bobbed mutations. It was found that magnification modifies restriction patterns and differentially affects gene types, increasing specific genes lacking insertions (INS^-). Increases in copy number of genes with type I insertions are generally lower than the total number of INS^- genes, while type II insertion genes are not perceptibly increased. The recovery of homogeneous progeny from a single premagnified male indicates that the magnification event might take place and become stable very early in the germ line, arguing against magnification being due to extrachromosomal amplification. Additionally, some gene types increase 3.5-fold while others are eliminated, indicating that they could not result from a single unequal cross-over. These results are in good agreement with the existence of partial clustering of rDNA genes according to type, and suggest that magnification could result from local amplification of genes.     

Insertion of a genetic marker into the ribosomal DNA of yeast

Plasmid pBR322 carrying the yeast LEU2+ gene transforms leu⁻ yeast into LEU+ at a low frequency by integration at homologous chromosomal DNA. When one-half of the yeast rDNA repeat unit (BglII-A) is inserted into the plasmid, the frequency of yeast transformation increases 100- to 200-fold, in proportion to the increased amount of homologous repetitive rDNA available for integration. When the other half of the repeat unit (BglII-B) is inserted into the plasmid, the transformation frequency increases by a factor of 10⁴, and the transformants are very unstable. It is likely that this fragment of rDNA contains a yeast origin of replication. This plasmid is a useful vector for cloning fragments of yeast DNA in yeast. We have used the LEU2+ gene, inserted into the rDNA locus, as a genetic marker for mapping the rDNA, in a procedure analogous to the use of antibiotic resistance transposons in the mapping of bacterial genes. Yeast ribosomal DNA is on chromosome XII between asp5 and ura4 as determined by mitotic linkage. Genetic analysis of markers inserted at the rDNA locus should be a useful tool for studying the conservation of sequence homology and the conservation of copy number of repeated genes.