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.     

Genetic Modulation of RNA Metabolism in Drosophila. II. Coordinate Rate Change in 4s, 5s, and Poly-a Associated RNA Synthesis

It has been demonstrated that a particular rDNA-deficient Y chromosome (Y(bbSuVar-5)) increases the rate of ribosomal RNA synthesis in adult testes (Shermoen and Kiefer 1975) and in whole flies (Clark, Strausbaugh and Kiefer 1977). As an initial attempt to explore the molecular basis of this phenomenon, experiments were designed to determine if the rate increase was specific for rRNA as opposed to the other species of RNA. The genotypes used in these studies were car bb/Y(bb-), car bb/Y( bbSuVar-5), and Sam(+) iso. car bb/Y(bbSuVar-5 ) and car bb/Y(bb-) are deficient to the same extent in rDNA and Sam(+) iso is a wild-type stock. Following isotope incorporation, total RNA was extracted by a phenol:chloroform method and separated by polyacrylamide gel electrophoresis. The various RNA species were quantified by UV absorption and their radioactivity determined by gel fractionation and liquid scintillation counting. The resulting data permitted the calculation of a specific activity (i.e., dpm/microg RNA) which was defined as synthetic rate. Polyadenylated RNA was isolated using a poly-U sepharose column and similar rate calculations were made. The data from these studies indicate that the rate of synthesis of all species of RNA examined (28S + 18S, 5S, 4S transfer RNA and polyadenylated RNA) is increased by the presence of the Y(bbSuVar-5) chromosome. Genetic and molecular mechanisms are discussed.     

Magnification of the Ribosomal Genes in Female DROSOPHILA MELANOGASTER

The genetically induced increase in the number of 18S + 28S ribosomal genes known as magnification has been reported to occur in male Drosophila but has not previously been observed in females. We now report that bobbed magnified (bbm) is recovered in progeny of female Drosophila carrying three different X bobbed (Xbb) chromosomes and the helper XYbb chromosome, which is a derivative of the Ybb- chromosome. Using different combinations of bb or bb+ X and Y chromosomes, we show that magnification in females requires both a deficiency in ribosomal genes and the presence of a Y chromosome: X/X females that are rDNA-deficient but do not carry a Y chromosome do not produce bbm; similarly, X/X/Y females that carry a Y chromosome but are not rDNA-deficient do not produce bbm. Bobbed magnified is only recovered from rDNA-deficient X/XY, X/X/Y or XX/Y females. We have also found that females carrying a ring Xbb chromosome together with the XYbb- chromosome do not produce bbm, indicating that ring X chromosomes are inhibited to magnify in females as in males. We postulate that the requirement for a Y chromosome is due to sequences on the Y chromosome that regulate or encode factor(s) required for magnification, or alternatively, affect pairing of the ribosomal genes.--These studies demonstrate that magnification is not limited to males but also occurs in females. Magnification in females is induced by rDNA-deficient conditions and the presence of a Y chromosome, and probably occurs by a mechanism similar to that in males.     

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.     

Regulation of Ribosomal RNA and 5s RNA Synthesis in DROSOPHILA MELANOGASTER: I. Bobbed Mutants

Analysis of the rates and amounts of rRNA and 5s RNA synthesized in Drosophila melanogaster bobbed mutants was done by using acrylamide-gel electrophoresis. The results show that the amounts of rRNA synthesized are constant, although the rates of rRNA synthesis in bb's are reduced to 30% of the wild-type level. The rates of synthesis of 5s RNA were constant. The rate of synthesis of the two kinds of molecules that enter in equimolar amounts into the mature ribosome is non-coordinated.-The rates of rRNA synthesis were shown to be proportional to the length of the scutellar bristles, supporting the notion that in trichogen cells there is no developmental delay, but the size of the bristle depends directly on the rate of rRNA synthesis.     

Ribosomal DNA content and bobbed phenotype in Drosophila hydei.

The number of ribosomal RNA genes in different Drosophila hydei stocks has been determined by filter saturation hybridisation experiments. It has been shown that there is no marked correlation between the average rRNA gene number per cell in the whole animal and the bobbed phenotype when Y chromosomal nucleolar organisers are present.     

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.     

The Synthesis of 5s RNA and Its Relationship to 18s and 28s Ribosomal RNA in the Bobbed Mutants of DROSOPHILA MELANOGASTER

Ribosomes contain one molecule each of 5S, 18S and 28S RNA. In Drosophila melanogaster although the genes for 18S+28S are physically separated from the 5S RNA genes, the multiplicity of various ribosomal RNA genes is roughly the same. Thus a coordinate synthesis of these three molecules might seem feasible. This problem has been approached by determining the molar ratios of various RNA's in ovaries and in adult flies. In ovaries there is a slight excess of 5S RNA molecules over other rRNA's, but in adult flies no such differences exist. Bobbed mutants also have the same molar ratios as wild-type flies. Results on 5S RNA synthesis in both in vitro and in vivo studies show that it is reduced in coordination with 18S+28S rRNA in the bobbed mutants of Drosophila melanogaster. Various possibilities are discussed in considering the implications of these results.     

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.     

Genetic Analysis of the 5s RNA Genes in DROSOPHILA MELANOGASTER

The 5S RNA genes of Drosophila melanogaster in either an isogenic wild-type or a multiply inverted (SM1) chromosome 2 increase their multiplicity when opposite a deficiency for the 5S gene site. This is analogous to the compensation phenomenon previously described for the 18S and 28S ribosomal RNA genes of the X chromosome nucleolus organizer region. Molecular hybridization of 5S RNA to DNA containing various doses of the 56F1-9 region of chromosome 2 demonstrates that most, if not all, of the 5S genes reside in or near this region. Also, a deficiency missing approximately one-half of the wild-type number of 5S genes was isolated and genetically localized. This mutant has a phenotype like that of bobbed, a mutant known to be partially deficient in 18S and 28S ribosomal RNA genes. Finally, we report the existence of a chromosomal rearrangement which splits the second chromosome into two segments, each containing 5S DNA.     

Fine structure of the 21S ribosomal RNA region on yeast mitochondrial DNA. III. Physical location of mitochondrial genetic markers and the molecular nature of omega.

1. We have determined the physical location of mitochondrial genetic markers in the 21S region of yeast mtDNA by genetic analysis of petite mutants whose mtDNA has been physically mapped on the wild-type mtDNA. 2. The order of loci, determined in this study, is in agreement with the order deduced from recombination analysis and coretention analysis except for the position of omega+: we conclude that omega+ is located between C321 (RIB-1) and E514 (RIB-3). 3. The marker E514 (RIB-3) has been localized on a DNA segment of 3800 bp, and the markers E354, E553 and cs23 (RIB-2) on a DNA segment of 1100 base pairs; both these segments overlap the 21S rRNA cistron. The marker C321 (RIB-1) has been localized within a segment of 240 bp which also overlaps the 21S rRNA cistron, and we infer on the basis of indirect evidence that this marker lies within this cistron. 4. In all our rho+ as well as rho- strains there is a one-to-one correlation between the omega+ phenotype, the ability to transmit the omega+ allele and the presence of a mtDNA segment of about 1000 bp long, located between sequences specifying RIB-3 and sequences corresponding to the loci RIB-1 and RIB-2. This segment may be inserted at this same position into omega- mtDNA by recombination. 5. The role which the different allelic forms of omega may play in the polarity of recombination is discussed.     

Genetic and molecular organization of the 5S locus and mutants in D. melanogaster.

The topography of an entire redundant locus was analyzed by both genetic and molecular means. Three mutants (min0, min1, min2) allelic to the 5S rRNA genetic locus on chromosome 2 of D. melanogaster were isolated. Flies exhibit a mutant phenotype when hemizygous for a min allele, but flies having two doses are wild-type. Saturation hybridization experiments show that the alleles are gross defieciencies each deleting an equal amount of 5S DNA. Each of the three mutant min alleles produces a distinct temperature-sensitive viability phene, and thus they are suggested to be pseudoalleles within the same redundant locus. Using the segmental aneuploid method (Lindsley et al., 1972), the 5S gene cluster was subdivided into proximal and distal halves. Both saturation hybridization experiments and genetic tests show that each half contains about eighty 5S genes. The complementation of the min alleles with the proximal and distal halves of the cluster indicates that both halves function independently. We present evidence which supports the model that all of the 160 5S genes are arranged as a single continuous cluster of tandem repeats with no large interdispersive DNA segments not complementary to 5S rRNA.     

A lesson from flex: consider the Y chromosome when assessing Drosophila sex-specific lethals

Bhattacharya et al. (Bhattacharya, A., Sudha, S., Chandra, H. S. and Steward, R. (1999) Development 126, 5485-5493) reported that loss-of-function mutations in the flex (female-specific lethal on X) gene caused female-specific lethality because flex(+) acts as a positive regulator of the master switch gene Sex lethal (Sxl). Sxl is essential for female development. Key to their conclusion was the ability of flex mutations to suppress the male lethality caused by Sxl(M) mutations, which inappropriately activate Sxl female-specific expression. Here we report our contrary findings that flex mutations fail to suppress even the weakest Sxl(M )alleles, arguing against the proposed regulatory relationship between flex and Sxl. Instead we show that the lethal flex phenotype depends on the absence of a Y chromosome, not on the presence of two X chromosomes. flex lethality is caused by a defect in the functioning of the X-linked rDNA locus called bobbed, since this defect is complemented by the corresponding wild-type rDNA complex on the Y.     

Effect of temperature on the expression of bobbed mutations in Drosophila melanogaster

The expression of two bobbed mutations on the X chromosome was studied at two temperatures 25 degrees C and 18 degrees C (larval developmental time, viability, phenotype of adult...). Results showed that the wm4bb mutation is thermosensitive. Some hypothesis are expressed to explain this phenomenon.     

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.