Interactions among modifiers of retrotransposon-induced alleles of the white locus of Drosophila melanogaster

Mutations in five loci that modify the phenotype of whiteapricot (wa), caused by the retrotransposon, copia, were examined in two-way combinations to determine whether their effects were additive or epistatic. All two-way combinations of mutations in these five loci, mottler of white (mw), suppressor of forked (su(f], suppressor of white apricot (su(wa], Enhancer of whiteapricot, (E(wa] and Darkener of apricot (Doa), are additive in their effects on wa, implying that each second-site modifier locus affects a different process. Three other copia-induced mutations, HwUa, whd81b25 and ctns were also examined for responsiveness to mutations in these modifier loci. None clearly responded. Mutations associated with B104 insertions, including Gl, vgni, ctn and wric were also examined for responsiveness to mw mutations, which have specificity for this element as well. Both vgni and wric respond to mutations in mw. The former interaction demonstrates that mw is capable of interacting with B104 elements in loci other than white. The significance of the results with respect to the nature of second-site modifier loci is discussed.     

Weakener of White (Wow), a Gene That Modifies the Expression of the White Eye Color Locus and That Suppresses Position Effect Variegation in Drosophila Melanogaster

A locus is described in Drosophila melanogaster that modifies the expression of the white eye color gene. This trans-acting modifier reduces the expression of the white gene in the eye, but elevates the expression in other adult tissues. Because of the eye phenotype in which the expression of white is lessened but not eliminated, the newly described locus is called the Weakener of white (Wow). Northern analysis reveals that Wow can exert an inverse or direct modifying effect depending upon the developmental stage. Two related genes, brown and scarlet, that are coordinately expressed with white, are also affected by Wow. In addition, Wow modulates the steady state RNA level of the retrotransposon, copia. When tested with a white promoter-Alcohol dehydrogenase reporter, Wow confers the modifying effect to the reporter, suggesting a requirement of the white regulatory sequences for mediating the response. In addition to being a dosage sensitive regulator of white, brown, scarlet and copia, Wow acts as a suppressor of position effect variegation. There are many dosage sensitive suppressors of position effect variegation and many dosage-sensitive modifiers of gene expression. The Wow mutations provide evidence for an overlap between the two types of modifiers.     

Genotype-environment interactions and the maintenance of polygenic variation

The Enhancer of wa [E(wa)] mutation was shown to interact strongly with 4 of 41 tested alleles of the white (w) eye color locus. All four of the affected w alleles result from the insertion of a transposable element. E(wa) was further localized cytogenetically. The locus lies between the breakpoints of T(Y;2)L11 and T(Y;2)H137 (section 60) in 2R. The original mutation was shown to be antimorphic on the basis of its action in the presence of additional normal copies and the ability to revert the original allele to one that mimics the effect of a deficiency for the locus. The RNA transcribed from wa was analyzed from flies segregating for E(wa) and normal. The low level of normal functional messenger RNA present in white-apricot is reduced further in Enhancer homozygotes. Total copia RNA was also examined on Northern analyses from the segregating population but no quantitative change in the major copia RNA was produced by E(wa) homozygotes compared to normal.     

P Element-Mediated in Vivo Deletion Analysis of White-Apricot: Deletions between Direct Repeats Are Strongly Favored

We have isolated and characterized deletions arising within a P transposon, P[hsw(a)], in the presence of P transposase. P[hsw(a)] carries white-apricot (w(a)) sequences, including a complete copia element, under the control of an hsp70 promoter, and resembles the original w(a) allele in eye color phenotype. In the presence of P transposase, P[hsw(a)] shows a high overall rate (approximately 3%) of germline mutations that result in increased eye pigmentation. Of 234 derivatives of P[hsw(a)] with greatly increased eye pigmentation, at least 205 carried deletions within copia. Of these, 201 were precise deletions between the directly repeated 276-nucleotide copia long terminal repeats (LTRs), and four were unique deletions. High rates of transposase-induced precise deletion were observed within another P transposon carrying unrelated 599 nucleotide repeats (yeast 2μ FLP; recombinase target sites) separated by 5.7 kb. Our observation that P element-mediated deletion formation occurs preferentially between direct repeats suggests general methods for controlling deletion formation.     

A dosage-sensitive modifier of retrotransposon-induced alleles of the Drosophila white locus.

The apricot allele of the white locus results from the insertion of the retrotransposon copia. Mutations in a newly discovered locus, the Darkener-of-apricot (Doa), suppress wa and some of its revertants. Of 44 other white alleles tested, only wsp55 is affected by Doa, although, in contrast, it is enhanced by Doa mutations. The Doa locus modulates wa and wsp55 expression as a function of its own dosage. Mutations in Doa are dominant suppressors or enhancers and are recessive lethals. Rare Doa mutant homozygotes escaping lethality demonstrate extreme phenotypic suppression of wa and enhancement of wsp55. RNA from wa is substantially wild-type in structure in escapers, although reduced in quantity.     

Elimination of Introns at the Drosophila Suppressor-of-Forked Locus by P-Element-Mediated Gene Conversion Shows That an RNA Lacking a Stop Codon Is Dispensable

The suppressor of forked [su(f)] locus affects the phenotype of mutations caused by transposable element insertions at unlinked loci. It encodes a putative 84-kD protein with homology to two proteins involved in mRNA 3' end processing; the product of the yeast RNA14 gene and the 77-kD subunit of human cleavage stimulation factor. Three su(f) mRNAs are produced by alternative polyadenylation. The 2.6- and 2.9-kb mRNAs encode the same 84-kD protein while a 1.3-kb RNA, which terminates within the fourth intron, is unusual in having no stop codon. Using P-element-mediated gene replacement we have copied sequences from a transformation construct into the su(f) gene creating a su(f) allele at the normal genomic location that lacks the first five introns. This allele is viable and appears wild type for su(f) function, demonstrating that the 1.3-kb RNA and the sequences contained within the deleted introns are dispensable for su(f) function. Compared with studies on gene replacement at the white locus, chromosomal breaks at su(f) appear to be less efficiently repaired from ectopic sites, perhaps because of the location of su(f) at the euchromatin/heterochromatin boundary on the X chromosome.     

Dominant Effects of Suppressor of Hairy-Wing Mutations on Gypsy-Induced Alleles of Forked and Cut in Drosophila Melanogaster

Mutations induced by the gypsy retrotransposon in the forked (f) and cut (ct) loci render their expression under the control of the suppressor of Hairy-wing [su(Hw)] gene. This action is usually recessive, but su(Hw) acts as a dominant on the alleles fk, ctk and ctMRpN30. Molecular analysis of the gypsy element present in fk indicates that this allele is caused by the insertion of a modified gypsy in which the region normally containing twelve copies of the octamer-like repeat that interacts with the su(Hw) product is altered. Analysis of the gypsy element responsible for the ctk and ctMRpN30 mutations also reveals a correlation between the dominant action of su(Hw) and disruption of the octamer region. We propose that these disruptions alter the affinity and interaction of su(Hw) protein with gypsy DNA, thereby sensitizing the mutant phenotype to fluctuations in su(Hw) product.     

A copy of the copia transposable element is very tightly linked to the Wa allele at the white locus of D. melanogaster

Results are described demonstrating that several X chromosomes of Drosophila melanogaster carrying the Wa (white-apricot) mutant allele also carry homology to the copia transposable element in distal 3C of the polytene chromosome map as assessed by situ hybridization. The locus of the Wa mutation, white, resides in distal 3C. We further show, using fine scale genetic mapping techniques, that the copia homology in distal 3C in Wa-bearing chromosomes is very tightly linked to the Wa mutation. Both the Wa mutation and the copia homology associated with it map to the central portion of the white locus.     

A Tripartite Interaction among Alleles of Notch, Delta, and Enhancer of Split during Imaginal Development of Drosophila Melanogaster

A dramatic example of a phenotypic interaction that involves neurogenic loci during Drosophila imaginal development is the synergistic impact of split (spl), a recessive allele of the Notch locus, and E(spl)D, a dominant gain-of-function allele of the Enhancer of split locus, on morphogenesis of the compound eye. Screens for mutations that relieve the enhancing effect of E(spl)D on spl have yielded three classes of mutations: intragenic revertants of the E(spl)D allele, extragenic suppressors that are allelic to the neurogenic gene Delta (Dl) and unlinked extragenic modifiers. Analysis of the suppression of the spl-E(spl)D interaction by various Dl alleles indicates that this modification is sensitive to the dosage of the Dl locus. This tripartite interaction illustrates the combinatorial action of N, Dl and E(spl) during imaginal development.     

Genetic interactions of modifier genes and modifiable alleles in Drosophila melanogaster

We have examined the effects of mutations in the six allele-specific modifier genes su(Hw), e(we), su(f), su(s), su(wa), and su(pr) on the expression of 18 modifiable alleles, situated at 11 loci. Ten of the modifiable alleles are associated with insertions of the gypsy retrotransposon and the others include alleles associated with insertions of copia and 412. We tested or retested 90 of the 108 possible combinations and examined the expression of modifiable alleles in flies mutant for pairs of modifier genes in various heterozygous and homozygous configurations. Our principal findings are: (1) a screen of 40,000 mutagenized X chromosomes yielded three new mutations in known modifier genes, but revealed no new modifier genes; (2) the modification effects of different mutations in a given modifier gene were qualitatively similar; (3) each of the six modifiers suppressed some modifiable alleles, enhanced others, and had no noticeable effect on still others; (4) the modifier genes could be placed in four classes, according to their effects on the gypsy-insertion alleles; and (5) the effects of mutations in different modifier genes combined additively. Implications of these results for models of modifier gene action are discussed.     

Changes in the chromosomal insertion pattern of the copia element during the process of making chromosomes homozygous in Drosophila melanogaster

In situ hybridization on polytene chromosomes of Drosophila melanogaster was used to compare the insertion patterns of copia and mdgl transposable elements on chromosome 2 in male gametes sampled by two different methods: (i) by crossing the males tested with females from a highly inbred line with known copia and mdgl insertion profiles; (ii) by crossing the same males with females from a marked strain, and analysing the resulting homozygous chromosomes. Crossing of the males with the inbred line led to homogeneous insertion profiles for both the copia and mdgl elements in larvae, thus giving an accurate estimation of the patterns in the two gamete classes of each male. Crossing with the marked strain led, however, to heterogeneity in insertion patterns of the copia transposable element, while no significant polymorphism was observed for mdgl. The use of balancer chromosomes is thus not an adequate way of inferring transposable element insertion patterns of Drosophila males, at least for the copia element. This technique could, however, be powerful for investigating the control of movements of this element.     

Changes in the chromosomal insertion pattern of the copia element during the process of making chromosomes homozygous in Drosophila melanogaster

In situ hybridization on polytene chromosomes of Drosophila melanogaster was used to compare the insertion patterns of copia and mdgl transposable elements on chromosome 2 in male gametes sampled by two different methods: (i) by crossing the males tested with females from a highly inbred line with known copia and mdgl insertion profiles; (ii) by crossing the same males with females from a marked strain, and analysing the resulting homozygous chromosomes. Crossing of the males with the inbred line led to homogeneous insertion profiles for both the copia and mdgl elements in larvae, thus giving an accurate estimation of the patterns in the two gamete classes of each male. Crossing with the marked strain led, however, to heterogeneity in insertion patterns of the copia transposable element, while no significant polymorphism was observed for mdgl. The use of balancer chromosomes is thus not an adequate way of inferring transposable element insertion patterns of Drosophila males, at least for the copia element. This technique could, however, be powerful for investigating the control of movements of this element.     

Genetic enhancement of RNA-processing defects by a dominant mutation in B52, the Drosophila gene for an SR protein splicing factor.

SR proteins are essential for pre-mRNA splicing in vitro, act early in the splicing pathway, and can influence alternative splice site choice. Here we describe the isolation of both dominant and loss-of-function alleles of B52, the gene for a Drosophila SR protein. The allele B52ED was identified as a dominant second-site enhancer of white-apricot (wa), a retrotransposon insertion in the second intron of the eye pigmentation gene white with a complex RNA-processing defect. B52ED also exaggerates the mutant phenotype of a distinct white allele carrying a 5' splice site mutation (wDR18), and alters the pattern of sex-specific splicing at doublesex under sensitized conditions, so that the male-specific splice is favored. In addition to being a dominant enhancer of these RNA-processing defects, B52ED is a recessive lethal allele that fails to complement other lethal alleles of B52. Comparison of B52ED with the B52+ allele from which it was derived revealed a single change in a conserved amino acid in the beta 4 strand of the first RNA-binding domain of B52, which suggests that altered RNA binding is responsible for the dominant phenotype. Reversion of the B52ED dominant allele with X rays led to the isolation of a B52 null allele. Together, these results indicate a critical role for the SR protein B52 in pre-mRNA splicing in vivo.