Intragenic recombination at the white locus of Drosophila hydei.

A fine-structure analysis of the white locus in Drosophila hydei was carried out by means of allele recombination. Four mutants, derived from wild type, mapped at three subloci. These are possibly homologous to the main subloci 2, 3, and 4 of D. melanogaster. Three secondary mutants, derived from the primary wiv allele, were located in the proximal part of the gene. One of them appeared as a homoallele of the original wiv, whereas the remaining two are better explained either as double mutants or as mutants which facilitate irregular exchange. Intragenic recombination at the white locus seems to be more frequent in D. hydei than in D. melanogaster. The comparatively high incidence is probably a general characteristic, common to intragenic and intergenic recombination in D. hydei.     

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.     

DNA sequence of the white locus of Drosophila melanogaster

The DNA sequence of the white locus of Drosophila melanogaster is presented. This 14,100 base-pair sequence includes the region of the locus required for wild-type levels of expression and control of expression. We also report the sequence of a complementary DNA clone which established the position of the 3' end of the white RNA on this genomic sequence. The probable exon-intron structure of the gene has been predicted from the DNA sequence of the regions known to be represented in the RNA. The amino acid sequence of the protein which would be produced by translation of this RNA suggests that the white locus gene product may be a membrane protein. The DNA sequence rearrangements associated with seven insertion mutants (white-dominant-zeste-like (wDZL), white-spotted (wsp), white-honey (wh), white-zeste-mottled (wzm), white-apricot (wa), white-buff (wbf) and white-hd81b11 (whd81b11)), one deletion mutant (white-spotted 4 (wsp4)) and one internal duplication mutant (white-ivory (wi)) have been determined and positioned on the wild-type sequence. The positions of these insertions and those of previously characterized insertions associated with six other mutations suggest that some insertions within an intron may still allow the production of correctly spliced RNA, but affect the amount, and correspondingly the expression of the w locus.     

Differential riboflavin deposition in white and variegated white mutants of Drosophila hydei

Riboflavin deposition in organs of Drosophila hydei was studied by means of a growth test using a riboflavin-deficient strain of the fungus Aspergillus nidulans. In wild-type animals, riboflavin is deposited in Malpighian tubules (MT) and testes but not in adult eyes. Certain white (w) mutants do not contain riboflavin, whereas intermediately colored w mutants contain minor amounts of the substance. Riboflavin-containing MT cells contain special globules that can be fixed and stained with the redox dye phenazine-methosulphate. The number and size of these granules is related to growth effect and point to a role of the w locus in the intracellular deposition of riboflavin in special organs. In white-mottled (wm) position-effect variegation mutants, a significant correlation was found between the extent of variegation (percentage of yellow cells) and riboflavin content (growth effect) of the MT. However, the individual variation of cell phenotype was extremely large and exaggerated types were observed indicating "overdominance" of the rearranged w+ gene. This contradicts an unsubstantiated dogma of position-effect variegation that assumes that the affected gene simply switches between the on and off state, as is discussed.     

Regulation of white locus expression: the structure of mutant alleles at the white locus of Drosophila melanogaster

We have analyzed the structures of 19 mutant alleles at the white locus of Drosophila melanogaster. Thirteen of the mutant alleles in our selected sample arose spontaneously, and of these, seven are associated with insertions of non-white-region DNA sequence elements. Several lines of evidence strongly suggest that these insertions are responsible for their associated mutant alleles, and further suggest that most or all of these insertions are transposons. Moreover, the white locus DNA sequences can be divided into two nonoverlapping domains on the basis of the properties of the two domains as mutational targets. One of these domains behaves, in this regard, in the manner expected of functional coding sequences, whereas the other does not. We propose a model for the nature and function of the presumptive noncoding white locus genetic elements. The two domains of the white locus defined by our studies are approximately coextensive with the functionally distinct subintervals of the locus defined by previous genetic analysis. Lastly, our results strongly suggest that the dominant, mutable wDZL allele results from the insertion of a transposon outside of, but near, the white locus. This putative transposon apparently carries genetic elements that act at a distance to repress expression of the white locus.     

Expression of cis-regulatory mutations of the white locus in metafemales of Drosophila melanogaster.

At the white eye colour locus, there are a number of alleles that have altered expression between males and females. To test these regulatory mutations of the white eye colour locus for their phenotypic expression in metafemales (3X; 2A) compared to diploid females and males, eleven alleles or transduced copies of white were analysed. Two alleles that exhibit dosage compensation between males and females (apricot, blood) also exhibit dosage compensation in metafemales. White-ivory and white-eosin, which fail to dosage compensate in males compared to females, but that are distinct physical lesions, also show a dosage effect in metafemales. Two alleles with greater expression in males than females (spotted, spotted-55) exhibit even lower expression in metafemales. Lastly, five transduced copies of white carrying three different lengths of the white promoter, but that all exhibit higher expression in males, show reduced expression in metafemales, exhibiting an inverse correlation between the level of expression and the dosage of the X chromosome. Because these alleles of white respond to dosage compensation in metafemales as a continuum of the male and female responses, it is concluded that the same basic mechanism of dosage compensation is involved and that the dosage of the X chromosome conditions the sexually dimorphic expression.     

An analysis of xanthine dehydrogenase negative mutants of the rosy locus in Drosophila melanogaster.

Eighteen alleles of the rosy locus in Drosophila melanogaster were characterized to identify putative nonsense mutants. Seven alleles exhibited no evidence of intragenic complementation, no evidence of immunological complementation, no evidence of immunological cross-reactivity to antibodies elicited by wild type xanthine dehydrogenase (XDH), and of course were completely deficient in measurable XDH activity. It is possible that one or more of these highly negative ry alleles are nonsense mutants. The remaining eleven ry alleles code for XDH molecules that retain some antigenic similarities to the wild type enzyme as assessed by immunoelectrophoresis and six of these eleven were capable of intragenic complementation.     

Insertional DNA and spontaneous mutation at the white locus in Drosophila simulans

A large body of data on molecular analyses of several multiallelic loci in Drosophila melanogaster has demonstrated a high incidence of mobile DNA element insertions among spontaneous mutations. In the sibling species D. simulans, the dispersed, middle repetitive, nomadic sequences are reduced to about one-seventh that of its sibling species (Dowsett and Young 1982). Does this reduced amount of middle repetitive DNA (or mobile DNA sequences) mean that in D. simulans the occurrence of insertion mutants will be rare compared with that of D. melanogaster? To test this possibility, we collected seven different spontaneous white mutants of D. simulans and studied their molecular gene structures. Five out of seven mutants had insertion sequences which varied in length from 0.4 kb to 16 kb. One bore a deletion spanning the w region and another showed no gross structural alteration. Thus the proportion of insertional mutations at the white locus in D. simulans is equivalent to that observed in D. melanogaster. Among the five insertional mutants, one, wmky, showed genetic instability; the other four were stable. wmky was found to mutate at a frequency of 2.1 x 10(-5) in meiotic cells and may also be unstable in somatic cells.     

A series of mutable alleles of the white locus in Drosophila melanogaster

Summary The origin and phenotypes of a number of zeste mutant stocks with mutable white loci are described. Each newly arising form was lighter in eye color than the mutant it originated from. In each case the lighter pigmentation is believed to be due to an increase in genetic material in the proximal region of the white locus, the increase supposedly being the result of unequal crossing over. Some of the mutations which arose in the mutable stocks are reversions. They occurred in males as well as in homo- and heterozygous females. The reversions are believed to be due to a decrease in genetic material in the proximal region of the white locus. The decrease is assumed to be the result of intrachromosomal recombination. At least some of these events took place premeiotically. New mutants which originate frequently from mutable stocks are stable. In addition to the structure of the mutable white locus there is probably at least one still unknown factor which affects its mutability since the frequency of mutations arising in the mutable stocks decreases over the years.     

The nature of N-ethyl-N-nitrosourea-induced mutations at the white locus of Drosophila melanogaster

The molecular basis of 36 mutations induced by N-ethyl-N-nitrosourea (ENU) at the white locus of Drosophila melanogaster was analyzed. Blot-hybridization showed that only two of them are rearrangements. One is a 200-bp deletion and the second mutant is an insertion of about 10 kb. The latter might be of spontaneous origin. 34 mutants did not show a detectable alteration of the normal restriction enzyme profile. 21 mutants were also analyzed by Northern blot-hybridization. Normal or nearly normal levels of white mRNA were observed in 8 pigmented and 7 non-pigmented mutants. In 5 other non-pigmented mutants a strong reduction of the amount of mature white mRNA was seen. In one of the pigmented mutants, hybridization occurred with 2 RNAs. When taken together, these results strongly indicate that most of the ENU-induced mutations are caused by base-pair changes or rearrangements smaller than 50-100 bp.     

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.     

DNA sequence analysis of X-ray-induced deletions at the white locus of Drosophila melanogaster

We have determined the nucleotide sequence of 5 X-ray-induced white mutants containing small rearrangements. Comparison with wild-type sequences showed deletions in the coding region ranging in size between 6 bp and 29 bp. These small deletions are distributed non-randomly over the white locus. Two mutants contain the same 29-bp deletion, while the other 3 deletions are clustered. All 5 deletions have occurred between 2 and 3 bp repeats. One of the repeats is preserved in the novel junction formed by the deletion. Our results suggest that recombinational processes may be involved in the generation of X-ray-induced deletions.     

Molecular analysis of large transposable elements carrying the white locus of Drosophila melanogaster

A large transposable element (TE) comprising the white-apricot and roughest genes has been found to transpose to well over a hundred sites scattered over the Drosophila genome. We report the cloning of the essential parts of several TEs. TE98 and TE28 sequences were cloned by `walking' along the chromosome from the previously cloned heatshock genes. The ends of the TEs are characterized by dispersed repetitive elements belonging to the foldback (FB) family. FB elements are also associated with two independently isolated transposable elements originating from the white locus, Tp w^c-1 and Tp w^+IV. The strong correlation between FB elements and large composite transposons suggests that a pair of these elements can mobilize large intermediary DNA segments. One particular FB family member, FB-NOF, is associated with TE28, the white-crimson (w^c) mutant, the w^c-derived Tp w^c-1 and probably also with Tp w^+IV. A unique sequence located close to the white end of TE28 was used to clone the borders of TE77 and the surrounding sequences in the bithorax region, indicating that the TE can be used as a probe for gene isolation. Some evolutionary implications of the large composite transposons are discussed.