Non-random loss of uninterrupted ribosomal DNA repeating units upon induction of a bobbed mutation

To investigate the physical organization of ribosomal RNA genes of two bobbed (bb) loci carried by the Dp(1;f)122 free duplication, a wild type and a deleted one derived from it, genomic DNAs from XXNO-/Dp122bb+ and XXNO-/Dp122bb adult females were analyzed by restriction enzyme digestions. We found that in the bb mutant there was a loss of uninterrupted genes, while genes interrupted by type I and type II insertions remained apparently unchanged. This is an indication that at least in this wild type bb+ locus, carried by the 122 free duplication, the different repeating units are not distributed randomly. In fact, after digestion of the rDNA carried by the bb+ duplication with the enzyme BamHI that cuts only in type I insertions, we have obtained long uncleaved fragments of DNA containing uninterrupted genes.     

Differential replication of ribosomal gene repeats in polytene nuclei of Drosophila.

The genes coding for the 18S and 28S rRNAs in D. melanogaster were examined using Southern transfers of DNA from diploid or polytene tissue. A ribosomal gene repeat 12 kb in length is present in DNA from diploid tissue of males and is the major repeat on the Y chromosome. This repeat is present in low amounts on the X chromosome, which contains major repeats of 17 and 11.5 kb. In polytene nuclei of males, the 12 kb band is disproportionately replicated, and only a very low amount of the 11.5 kb repeat and no 17 kb repeat are detected. Polytene nuclei of females contain reduced amounts of the 17 kb repeat relative to the 11.5 kb repeat. This disproportionate replication of specific ribosomal gene repeats suggests that polytenization of the rDNA may involve an extrachromosomal mechanism. Evidence that genes from only one nucleolus organizer are replicated during polytenization in X/Y and X/X flies is discussed. A method for analyzing DNA from tissue of individual larvae was developed to test for population heterogeneity in ribosomal gene structure. Heterogeneity was observed in the ribosomal genes of three Ore R lines, four other D. melanogaster strains and between males and females of the same strain.     

Chromosomal rearrangements which affect the chromosomal integration of the ribosomal genes in Drosophila melanogaster.

Sucrose gradient analysis of DNA from detergent-pronase lysates of whole adult flies has been used to examine a variety of genotypes for the presence of ribosomal genes not integrated into the DNA of the chromosome. Such genes were found in females in which one X chromosome carries an inversion, having one of its breakpoints between the nucleolus organizer and the centromere. These inversions move the nucleolus organizer to the distal end of the X chromosome. Other inversions which do not move the nucleolus organizer, as well as a series of bobbed deficiencies, did not induce unintegrated genes. The same inversions which induce unintegrated genes in adults also produce them in the diploid brain and imaginal discs of larvae. On the other hand, in the polytene salivary glands, unintegrated genes were found in every genotype examined.     

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.     

Reversal of a Neurospora Translocation by Crossing over Involving Displaced Rdna, and Methylation of the Rdna Segments That Result from Recombination

In translocation OY321 of Neurospora crassa, the nucleolus organizer is divided into two segments, a proximal portion located interstitially in one interchange chromosome, and a distal portion now located terminally on another chromosome, linkage group I. In crosses of Translocation X Translocation, exceptional progeny are recovered nonselectively in which the chromosome sequence has apparently reverted to Normal. Genetic, cytological, and molecular evidence indicates that reversion is the result of meiotic crossing over between homologous displaced rDNA repeats. Marker linkages are wild type in these exceptional progeny. They differ from wild type, however, in retaining an interstitial block of rRNA genes which can be demonstrated cytologically by the presence of a second, small interstitial nucleolus and genetically by linkage of an rDNA restriction site polymorphism to the mating-type locus in linkage group I. The interstitial rDNA is more highly methylated than the terminal rDNA. The mechanism by which methylation enzymes distinguish between interstitial rDNA and terminal rDNA is unknown. Some hypotheses are considered.     

Nonselective amplification of ribosomal DNA repeat units in compensating genotypes of Drosophila melanogaster

Compensation is a mechanism by which the X-chromosome nucleolus organizer region of Drosophila melanogaster can increase its ribosomal DNA content up to twofold. It occurs in somatic cells under specific genetic conditions and is mediated by a defined genetic site, the compensatory response locus. The In and various type I ribosomal DNA repeat units were separated by restriction endonuclease digestion. Comparison of the percentages of these repeat unit types between compensating and noncompensating genotypes showed the same distribution. Therefore no selective amplification of these repeat unit types occurs during ribosomal DNA compensation. These results demonstrate that two processes of rDNA amplification in somatic cells, compensation and independent rDNA polytenization, are exclusive events.This research was supported by NIH Grant GM 28008.     

Genetic mapping of 18s ribosomal RNA-related loci to mouse Chromosomes 5, 6, 9, 12, 17, 18, 19, and X

The organization of ribosomal RNA genes (rDNA) in the genome of the mouse varies significantly from one strain to another, but has been shown to follow the pattern of clusters of tandem repeats located at chromosome ends, often associated with cytological nucleolus organizer regions. The number of copies of the repeat unit at each locus also varies. A probe for the 18S ribosomal RNA sequence on Southern blots reveals both high copy number bands and fainter bands indicative of low repeat number. We have mapped a number of newly identified low-copy-number rDNA loci in C57BL/6J, in addition to placing some of the NOR-associated rDNA repeats on the Jackson interspecific backcross (BSS) map. We suggest that additional low-copy-number loci may remain to be mapped, and that the evolution of rDNA loci in the genome may include the proliferation of single copies by retroinsertion or other mechanisms. Received: 23 February 1996 / Accepted: 29 July 1996     

X and Y chromosomal ribosomal DNA of Drosophila: comparison of spacers and insertions.

In Drosophila melanogaster, the genes coding for 18S and 28S ribosomal RNA (rDNA) are clustered at one locus each on the X and the Y chromosomes. We have compared the structure of rDNA at the two loci. The 18S and 28S rRNAs coded by the X and Y chromosomes are very similar and probably identical (Maden and Tartof, 1974). In D. melanogaster, many rDNA repeating units are interrupted in the 28S RNA sequence by a DNA region called the insertion. There are at least two sequence types of insertions. Type 1 insertions include the most abundant 5 kilobase (kb) class and homologous small (0.5 and 1 kb) insertions. Most insertions between 1.5 and 4 kb have no homology to the 5 kb class and are identified as type 2 insertions. In X rDNA, about 49% of all rDNA repeats have type 1 insertions, and another 16% have type 2 insertions. On the Y chromosome, only 16% of all rDNA repeats are interrupted, and most if not all insertions are of type 2.rDNA fragments derived from the X and Y chromosomes have been cloned in E. coli. The homology between the nontranscribed spacers in X and Y rDNA was studied with cloned fragments. Stable heteroduplexes were found which showed that these regions on the two chromosomes are very similar.The evolution of rDNA in D. melanogaster might involve genetic exchange between the X and Y chromosomal clusters with restrictions on the movement of type 1 insertions to the Y chromosome.     

Molecular Characterization of Ribosomal Genes on the Ybb- Chromosome of DROSOPHILA MELANOGASTER

The question of whether the Ybb- chromosome contains ribosomal genes has been examined by using Southern blot analysis and comparing rDNA hybridization patterns for X/X and X/Ybb- DNA. The results demonstrate that the Ybb- chromosome contains sequences that hybridize to an rDNA probe under stringent conditions. Differential hybridization of some of these sequences with DNAs corresponding to different regions of a complete ribosomal gene repeat provides evidence that some of the genes on the Ybb- chromosome are type 2 repeats. Because data obtained by other workers suggest that type 2 repeats are transcribed only to low levels, these repeats may be classed as "nonfunctional". A further finding is that the ribosomal genes on the Ybb- chromosome do not undergo multiple rounds of DNA replication during polytenization of X/Ybb- cells.     

Amplification of rDNA and type I sequences in Drosophila males deficient in rDNA

rDNA magnification is a heritable change in rDNA content that occurs in D. melanogaster males when chromosomes deficient in rDNA are placed together for several generations. We have examined the restriction endonuclease cleavage pattern of the rDNA from an X chromosome undergoing magnification, and find no evidence for the selective amplification of either uninterrupted rDNA units or those containing insertion sequences. In addition, we observe an amplification of rDNA in the first generation of extremely bobbed male progeny to a level exceeding that of wild-type flies, but that reduces to the wild-type level in subsequent generations. The type I rDNA insertion elements also occur as tandem arrays, independently of rDNA. Southern hybridizations indicate that the majority of these sequences are located in the heterochromatin surrounding the nucleolus organizer on the X chromosome, and we find that they, too, amplify transiently in the first generation of magnifying males.     

Dynamics of 5S rDNA in the tilapia (Oreochromis niloticus) genome: repeat units,inverted sequences,pseudogenes and chromosome loci

In higher eukaryotes, the 5S ribosomal DNA (5S rDNA) is organized in tandem arrays with repeat units composed of a coding region and a non-transcribed spacer sequence (NTS). These tandem arrays can be found on either one or more chromosome pairs. 5S rDNA copies from the tilapia fish, Oreochromis niloticus, were cloned and the nucleotide sequences of the coding region and of the non-transcribed spacer were determined. Moreover, the genomic organization of the 5S rDNA tandem repeats was investigated by fluorescence IN SITU hybridization (FISH) and Southern blot hybridization. Two 5S rDNA classes, one consisting of 1.4-kb repeats and another one with 0.5-kb repeats were identified and designated 5S rDNA type I and type II, respectively. An inverted 5S rRNA gene and a 5S rRNA putative pseudogene were also identified inside the tandem repeats of 5S rDNA type I. FISH permitted the visualization of the 5S rRNA genes at three chromosome loci, one of them consisting of arrays of the 5S rDNA type I, and the two others corresponding to arrays of the 5S rDNA type II. The two classes of the 5S rDNA, the presence of pseudogenes, and the inverted genes observed in the O. niloticus genome might be a consequence of the intense dynamics of the evolution of these tandem repeat elements.     

Ribosomal Gene Magnification in Drosophila: A Chromosomal Change

The sex-linked mutant "bobbed" can undergo a rapid phenotypic reversion during a prescribed series of outcrosses. The experiments reported here distinguish between two general genetic models. The first is that the phenotypic change results from the changing genetic background brought about by the outcrosses. The second is that the phenotypic change results from an alteration of the X chromosome in the germ line. The data support the second model. It is shown that both the bobbed and reverted phenotypes segregate from the same female. In addition, the reverted phenotype maps in or near the proximal heterochromatin of the X chromosome, which is the standard map position of both bobbed and the nucleolus organizer.     

Increased number of nucleoli in the salivary gland cells of Drosophila melanogaster under conditions of rDNA dose compensation

A considerable increase in the number of nucleoli non-associted with the nucleolar organizer (NO) was shown in the salivary gland cells of Drosophila melanogaster mutants, heterozygous for a deficiency of NO. The frequency of formation of additional nucleoli increased with the raising of the chromosome polyteny level. By means of in situ hybridization we showed that in the mutant and the wildtype polytene cells the ribosomal DNA (rDNA) of these unlawful nucleoli included ribosomal gene repeats (18S+28S) with two types of insertions: ivs-I and ivs-II Such additional nucleoli can be attached to varying sites of the polytene chromosomes containing type I insertion sequences.     

Differential elimination of rDNA genes in bobbed mutants of Drosophila melanogaster.

In Drosophila melanogaster, the multiply repeated genes encoding 18S and 28S rRNA are located on the X and Y chromosomes. A large percentage of these repeats are interrupted in the 28S region by insertions of two types. We compared the restriction patterns from a subcloned wild-type Oregon R strain to those of spontaneous and ethyl methanesulfonate-induced bobbed mutants. Bobbed mutations were found to be deficiencies that modified the organization of the rDNA locus. Genes without insertions were deleted about twice as often as genes with type I insertions. Type II insertion genes were not decreased in number, except in the mutant having the most bobbed phenotype. Reversion to wild type was associated with an increase in gene copy number, affecting exclusively genes without insertions. One hypothesis which explains these results is the partial clustering of genes by type. The initial deletion could then be due either to an unequal crossover or to loss of material without exchange. Some of our findings indicated that deletion may be associated with an amplification phenomenon, the magnitude of which would be dependent on the amount of clustering of specific gene types at the locus.     

The Effect of mei-41 on Rdna Redundancy in DROSOPHILA MELANOGASTER

The recombination and repair defective mutant, mei-41, exhibits three rather striking effects on the genetic properties and chromosomal stability of rDNA in Drosophila. First, mei-41 inhibits rDNA magnification. However, mei-9, another recombination and repair defective mutation has no similar effect. This indicates that magnification requires some, but not all, of the gene products necessary for meiotic exchange. Second, under magnifying conditions, mei-41 induces interchanges between the X rDNA and either arm of the Ybb- chromosome. These interchanges occur at high frequency and are independent of rDNA orientation. Third, in mei-41 bb+/Ybb+ males, bobbed mutants in the X, but not the Y, also arise at high frequency. Evidence suggests that these events involve the rDNA type I insertion. The recombination and repair defective properties of mei-41 together with our results regarding its unusual and specific effects involving rDNA are explained in a simple model that has general implications for chromosome structure.