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.     

26S and 18S rRNA synthesis in bobbed mutants of Drosophila melanogaster

For the most part, bobbed mutations of Drosophila melanogaster consist of deletions of 26S and 18S rDNA located on the X and Y chromosomes. Studies on the synthesis of rRNA of third instar larvae and one day old adult females of three severe bobbed genotypes, indicate that no decrease can be detected, compared ot wild type strains. One of the bobbed mutants studied was a rather unusual type: these flies possess a quantity of rDNA that should confer upon them a near wild type phenotype whereas they actually show an extreme bobbed phenotype. The two other bobbed mutants are of a classical type: their severe bobbed phenotype corresponds to large deletions of rDNA. Two hypotheses can be proposed to explain the extreme bobbed phenotype of the flies, in spite of the fact that rRNA synthesis occurs normally. A regulatory phenomenon may interfere at the stages studied, but in earlier stages a net decrease in rRNA synthesis may have occurred producing an irreversible effect in the tissues affected by bobbed mutations (abdominal cuticle, bristles). The second hypothesis is that the rRNA produced may not be functional, perhaps because it is specific of earlier stages.     

Cloning and study of inserted sequences of gene 28S in Drosophila melanogaster ribosomal RNA

Cloning of fragments of ribosomal genes containing insertions in the 28S RNA gene has been reported earlier. Subcloning of DNA fragments corresponding to insertion sequences and their hybridization with DNA, RNA and polytene chromosomes from different flies is described. Type 1 insertions (containing BamI sites) are highly heterogeneous in length and sequence even in homozygotes. Type 2 insertions (with EcoRI sites) are rather homogeneous. Two types of insertions are represented in the D. melanogaster genome by 50 and 30 copies, respectively. Restriction fragments with insertions significantly differ in DNA from embryos and larvae. D. simulans and D. virilis also contain the sequences of both types of insertions, though in fewer number of copies. Type 1 insertions seem to be poorly transcribed, and type 2 insertions are not transcribed at all. Among 2000 recombinant clones screened a number of DI plasmids hybridizing to isolated insertions were obtained. Six of them were mapped with restriction endonucleases and hybridized with insertion fragments. rRNA and polytene chromosomes. All of these DI plasmids hybridize with the nucleoli, one with the chromocenter and one with the 79F 3L site. In LI9, not coding for rRNA, the sequences, corresponding to two types on insertions are located only a few kilobases apart. D17a does not encode for rRNA, but hybridizes in situ only with the nucleoli.     

Partial reversion at the bobbed locus of Drosophila melanogaster

In Drosophila melanogaster the tandemly arranged repetitive sequences coding for 18S and 28S rRNA are heterogenous at the level of the spacers between units and insertions that interrupt many 28S rRNA genes. This heterogeneity contrasts with the homogeneity of the regions transcribed into 18S and 28S rRNA. Homogenization and evolution of repetitive genes are usually explained by conversion, amplification events or unequal crossovers. In this paper we studied the change in rDNA patterns associated with partial reversion of bobbed mutations. In most cases, no increase in rDNA gene number, but a new repartition of gene types were found.     

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.     

Genetic Modulation of RNA Metabolism in Drosophila. IV. Measurement of Rates of RNA Synthesis by Density Labeling

Accumulation of RNA was measured in adult males of two genotypes: car bb/Ybb- and car bb/YbbSuVar-5. The two genotypes have similar amounts of rDNA, which is reduced in comparison to wild type (CLARK, STRAUSBAUGH and KIEFER 1977). Although genotypically bobbed, car bb/YbbSuVar-5 flies have a wild-type phenotype; car bb/Ybb- flies are both phenotypically and genotypically bobbed (CLARK, STRAUSBAUGH and KIEFER 1977). The wild-type phenotype observed in the car bb/YbbSuVar-5 flies is thought to be the result of an increased rate of rRNA synthesis due to the presence of the YbbSuVar-5 chromosome (SHERMOEN and KIFFER 1975; CLARK, STRAUSBAUGH and KIEFER 1977; CLARK and KIEFER 1977). To further define this phenomenon, the absolute accumulation of RNA was measured in the two genotypes, using density labeling methods. The accumulation of RNA is 1.4 to 1.8 times higher in car bb/YbbSuVar-5 flies than in car bb/Ybb- flies, demonstrating that there is genetic regulation of synthesis in this genotype. The use of density-labeled nucleosides has clearly shown that there is no difference in precusor pool sizes or use between the two genotypes studied.     

Characterisation of complete type II insertions in cloned segments of ribosomal DNA from Drosophila melanogaster

We have isolated cloned segments of ribosomal DNA that have EcoRI restrictable (type II) insertions in their 28 S genes. The type II insertions in these plasmids are homologous sequences and have three characteristic cleavage sites for EcoRI. One of these clones is unusual in that it has undergone a deletion of part of the 28 S gene at or near the site of the type II insertion. A second is unusual in that, in addition to the type II insertion in the rDNA, the transcribed spacer sequences are interrupted by an unidentified sequence. This sequence differs in its arrangement of restriction sites from the sequence that interrupts the transcribed spacer of cDm207 (Glover, 1977). The type II sequences in all these clones share homology with the unusually long ‘insertion’ that interrupts the 28 S gene of cDm207. We have re-examined the nature of the additional sequences linked to the type II sequences of cDm207 and find them to be related to type I rDNA insertion sequences.     

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.     

Nucleotide sequences at the boundaries between gene and insertion regions in the rDNA of Drosophila melanogaster

Ribosomal RNA genes interrupted by type 1 insertions of 1 kb and 0.5 kb have been sequenced through the insertion region and compared with an uninterrupted gene. The 0.5 kb insertion is flanked by a duplication of a 14 bp segment that is present once in the uninterrupted gene; the 1 kb insertion is flanked by a duplication of 11 of these 14 bp. Short insertions are identical in their entire length to downstream regions of long insertions. No internal repeats occur in the insertion. The presence of target site duplications suggests that type 1 insertions arose by the introduction of transposable elements into rDNA. Short sequence homologies between the upstream ends of the insertions and the 28S' boundaries of the rRNA coding region suggest that short type 1 insertions may have arisen by recombination from longer insertions.We have sequenced both boundaries of two molecules containing type 2 insertions and the upstream boundary of a third; the points of interruption at the upstream boundary (28S' site) differ from each other in steps of 2 bp. Between the boundary in the 0.5 kb type 1 insertion and the type 2 boundaries there are distances of 74, 76, and 78 bp. At the downstream boundary (28S' site) the two sequenced type 2 insertions are identical. The rRNA coding region of one molecule extends across the insertion without deletion or duplication, but a 2 bp deletion in the RNA coding region is present in the second molecule. Stretches of 13 or 22 adenine residues occur at the downstream (28S') end of the two type 2 insertions.     

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.     

Coding region deletions associated with the major form of rDNA interruption in Drosophila

The nucleotide sequences at and around the termini of 5 kb type 1 interruptions in three separate clones of D. melanogaster rDNA repeats have been determined, and have been compared with the sequence of the corresponding region of an insertion-free rDNA repeat. All three interrupted rDNA repeats contain a small deletion of 28S rRNA coding material at the left coding/insertion sequence junction. A second deletion was found in one of the three clones, ad other aberrations were suggested by the results of restriction enzyme digestions of unfractionated rDNA. The termini of 5 kb type 1 rDNA insertions in D. melanogaster were also compared with the corresponding regions of 28S rDNA interruptions in D. virilis: the insertion site is identical in the two species, but the termini of the two species' interruptions show no homology. I sequenced a 1.1 kb region of the 5 kb type 1 D. melanogaster rDNA interruption that covers the sequences of the 1 kb and 0.5 kb insertions. There is 98% homology between the rightmost 1 kb of the 5 kb interruption and the sequences of the shorter insertions. Data suggest that Drosophila rDNA interruptions arose as a transposable element, and that divergence had included length alterations generated by unequal crossing over.     

A DNA segment from D. melanogaster which contains five tandemly repeating units homologous to the major rDNA insertion

We describe a cloned segment of D. melanogaster DNA (cDm219) that contains five tandemly arranged sequence units homologous to the type I insertion sequence found in the majority of 28S rRNA genes on the X chromosome. Heteroduplex studies show that two of the units have a deletion corresponding to a 1.1 kb piece of DNA close to the right-hand end of the type I insertion. Another unit has a 7.5 kb sequence (zeta) substituted for a 0.95 kb piece of DNA close to the left-hand part of the type I rDNA insertion. The two remaining units are interrupted by the Col E1 plasmid vector. There are also differences in the restriction endonuclease cleavage maps both between the units of cDm219 themselves and compared to the restriction endonuclease cleavage maps of cloned rDNA segments that contain type I insertions. Quantitation of the gel transfer hybridization of zeta element probes to restriction endonuclease digests of D. melanogaster DNA indicates there are 30--40 copies of zeta sequences distributed in seven major arrangements within the haploid genome. The hybridization of zeta and insertion sequence probes to a library of D. melanogaster DNA segments cloned in bacteriophage lambda indicates at least 4--6 copies of the zeta element could be linked to insertion sequences. The common site of in situ hybridization of zeta sequences is to the chromocentral heterochromatin of polytene chromosomes.     

The Molecular through Ecological Genetics of Abnormal Abdomen. II. Ribosomal DNA Polymorphism Is Associated with the Abnormal Abdomen Syndrome in DROSOPHILA MERCATORUM

Restriction endonuclease cleavage analyses of cloned and genomic DNA samples indicate that the structure of the DNA encoding the large cytoplasmic RNAs (rDNAs) is altered in Drosophila mercatorum lines which exhibit an abnormal abdomen (aa) phenotype. In a majority of the rDNA repeat units from aa flies, the 28S coding sequence is interrupted by a large [5-6 kilobase pairs (kbp)] insert. A subclone containing this inserted DNA (ins 3) hybridizes primarily to rDNA-containing sequences in in situ and genomic blot hybridization experiments. Additionally, genomic nitrocellulose blot hybridization analyses show that ins- containing rDNA repeat units are clustered in a spontaneously arising aa mutant. This rDNA alteration in D. mercatorum flies with the aa phenotype more closely resembles the bobbed (bb) defect of D. hydei than the bb defect of D. melanogaster, which involves alterations in rDNA copy number. By analogy with the other Drosophila systems, we propose that the altered D. mercatorum rDNA repeat units are defective in rRNA production at a critical stage. The lowered levels of rRNA ultimately would limit the concentration of ribosomes needed to produce large quantities of a protein (in these cases, juvenile hormone esterase) needed for normal development.     

X chromosome nucleolus organizer mutants which alter major type I repeat multiplicity in Drosophila melanogaster

The nucleolus organizer (NO) of the D. melanogaster X chromosome is composed of ribosomal repeat units which contain two types (I and II) of non-rDNA insertions (In+) and repeats with no insertions (In-). Evidence from other laboratories indicate random interspersion of all types of repeat units within the X NO. An EcoRI and BamHI examination of rDNA from two bobbed mutants, bb2rI and mal12 demonstrates segregation of the major type I repeat units. The 46 rDNA repeats of the bb2rI NO contain no detectable major type I repeats whereas the majority of the 68 rDNA mal12 repeats are major type I and tandemly linked. This observation suggests that gross deletions of rDNA can result in nucleolus organizer regions with predominantly one type of repeat unit. Additivity tests demonstrate that the 46 ribosomal repeats of the bb2rI chromosome revert the phenotype of other bobbed NOs, but the 68 mal12 ribosomal repeats show no or slight additivity. This is in agreement with the observation that In+ repeats do not significantly contribute to functional rRNA. A Southern blot analysis using BamHI which cuts only in type I insertions demonstrates that the majority of major type I In+ repeating units exist in tandem linkage group(s) within the X NO.     

The number and location of genes for 5S ribonucleic acid within the genome of Drosophila melanogaster

DNA was prepared from wild-type and two mutant stocks of Drosophila melanogaster that differed in their dosage of the nucleolar organizer region. The relative amounts of DNA from the nucleolar organizer region in these preparations of DNA were determined by hybridization with (3)H-labelled 28S rRNA. As expected, the amount of (3)H-labelled 28S rRNA that hybridized was directly related to the dosage of nucleolar organizer region. No positive correlation was observed between the amount of (3)H-labelled 5S RNA that hybridized and the dosage of nucleolar organizer region. Thus genes for 5S RNA are located primarily, if not exclusively, outside the nucleolar organizer region. The haploid genome of the wild-type D. melanogaster used in this work has 106 genes for 28S rRNA and 96-105 genes for 5S RNA.