Developmental analysis of the facets, a group of intronic mutations at the Notch locus of Drosophila melanogaster that affect postembryonic development

The activity of the Notch locus of Drosophila melanogaster during embryogenesis is necessary for the correct segregation of neural from epidermal lineages. The action of Notch is not confined to embryogenesis but is also essential for normal development during the postembryonic stages. Its action is pleiotropic, as revealed by the existence of several classes of mutations which affect various imaginal structures. Here, we examine a group of six recessive mutations, the facets (fa, fa3, fag, fag-2, fafx and fasw), which affect eye and optic lobe morphology and have been previously shown to be associated with the insertion of transposable elements into an intronic region of Notch. Using both somatic recombination and gynandromorph analysis, we find that their behavior in a mosaic analysis is not identical. While in the majority of alleles abnormal Notch function in the retina is sufficient to induce optic lobe abnormalities, in the case of fag-2, a considerable number of individuals having mosaic retinas exhibit normal optic lobe structure. All the facet alleles appear to behave in a cell-autonomous manner. A developmental analysis of the eye and optic lobe defects associated with the facet mutations support the contention that Notch may be involved not only in the formation of certain structures but also in their maintenance.     

Transposition without transposase: a spontaneous mutation in bacteria.

Transposition mutations are typically associated with the activities of transposable elements such as transposons and insertion sequences, whose mobility is dependent upon transposase enzymes that catalyze exchanges between element ends and target sites. We describe a single transposition event in which a block of donor sequence is inserted at a target site without the involvement of any known transposase or the ends of any known transposable element. We propose that this is a new type of spontaneous mutation which may be difficult to detect in standard mutant hunts but may be of evolutionary importance.     

Fs(1)yb Is Required for Ovary Follicle Cell Differentiation in Drosophila Melanogaster and Has Genetic Interactions with the Notch Group of Neurogenic Genes

Phenotypic and genetic analyses demonstrate that fs(1)Yb activity is required in the soma for the development of a subset of ovarian follicle cells and to support later stages of egg maturation. Mutations in fs(1)Yb cause a range of ovarian phenotypes, from the improper segregation of egg chambers to abnormal dorsal appendage formation. The mutant phenotypes associated with fs(1)Yb are very similar to the ovarian aberrations produced by temperature-sensitive alleles of Notch and Delta. Possible functional or regulatory interactions between fs(1)Yb and Notch are suggested by genetic studies. A duplication of the Notch locus partially suppresses the female-sterility caused by fs(1)Yb mutations, while reducing Notch dosage makes the fs(1)Yb mutant phenotype more severe. In addition, fs(1)Yb alleles also interact with genes that are known to act with or regulate Notch activity, including Delta, daughterless, and mastermind. However, differences between the mutant ovarian phenotype of fs(1)Yb and that of Notch or Delta indicate that the genes do not have completely overlapping functions in the ovary. We propose that fs(1)Yb acts as an ovary-specific factor that determines follicle cell fate.     

Tam3 produces a suppressible allele of the DAG locus of Antirrhinum majus similar to Mu-suppressible alleles of maize

Tam3 from Antirrhinum majus belongs to the Ac/Ds family of transposable elements. An allele of the DAG locus of Antirrhinum ( dag ::Tam3), which is required for chloroplast development and leaf palisade differentiation, has been generated by Tam3 insertion into the untranslated leader sequence of the gene. This allele gives rise to a cold-sensitive phenotype, where mutant tissue containing wild-type revertant somatic sectors is observed in the leaves of plants grown at 15°C, while leaves of plants grown at 25°C appear near wild-type. The temperature sensitivity of dag ::Tam3 results from expression of the DAG locus responding to the activity of the transposable element, the transposition of which is very sensitive to growing temperature. Genetic suppression of Tam3 transposition, using the STABILISER locus, also results in suppression of the dag mutant phenotype. dag ::Tam3 represents a Tam3-suppressible allele similar to those described for Mu transposons in maize. Suppression of the dag mutant phenotype in response to element inactivation appears to result from use of an alternative promoter at the 3' end of the Tam3 element. The production of suppressible alleles by an Ac-like element is discussed in relation to the mutagenic potential of plant transposons in producing complex genetic diversity.     

Insertion mutations at the maizeOpaque2 locus induced by transposable element familiesAc,En/Spm andBg

Eight independently isolated unstable alleles of theOpaque2 (O2) locus were analysed genetically and at the DNA level. The whole series of mutations was isolated from a maize strain carrying a wild-typeO2 allele and the transposable elementActivator (Ac) at thewx-m7 allele. Previous work with another unstable allele of the same series has shown that it was indeed caused by the insertion of anAc element. Unexpectedly, the remaining eight mutations were not caused by the designatedAc element, but by other insertions that are structurally similar or identical to one of two different autonomous transposable elements. Six mutations were caused by the insertion of a transposable element of theEnhancer/Suppressor-Mutator (En/Spm) family. Two mutations were the result of the insertion of a transposable element of theBergamo (Bg) family. Genetic tests carried out with plants carrying the unstable mutations demonstrated that all were caused by the insertion of an autonomous transposable element.     

Insertion mutations at the maizeOpaque2 locus induced by transposable element familiesAc, En/Spm andBg

Eight independently isolated unstable alleles of theOpaque2 (O2) locus were analysed genetically and at the DNA level. The whole series of mutations was isolated from a maize strain carrying a wild-typeO2 allele and the transposable elementActivator (Ac) at thewx-m7 allele. Previous work with another unstable allele of the same series has shown that it was indeed caused by the insertion of anAc element. Unexpectedly, the remaining eight mutations were not caused by the designatedAc element, but by other insertions that are structurally similar or identical to one of two different autonomous transposable elements. Six mutations were caused by the insertion of a transposable element of theEnhancer/Suppressor-Mutator (En/Spm) family. Two mutations were the result of the insertion of a transposable element of theBergamo (Bg) family. Genetic tests carried out with plants carrying the unstable mutations demonstrated that all were caused by the insertion of an autonomous transposable element.     

Novel events associated with phenotypic reversion of a P element mutant in Drosophila melanogaster.

Transposable P elements have been used extensively for Drosophila mutagenesis. While their mutagenic activity has long been recognized, the mechanisms by which P elements cause mutations are varied and not completely understood. We describe here an experiment to replace a P element at vestigial (vg) that caused a strong mutant phenotype (P[21-3]) with a P element (P[21]) known to produce a very weak phenotype when inserted at vg. In addition to testing the feasibility of P element replacements at vg, our investigation led to the production of 7 new vg alleles and 1 apparent second site suppressor. All the vg21-3 revertants that we recovered had a P element inserted into the first exon of vg at the same location and in the same orientation as the original element in vg21-3, providing a unique opportunity to study the mechanism of transposon mutagenesis. A majority of the revertants arose from a previously described event: internal deletion of P sequences, including the P promoter. In addition, 3 novel reversions of the vg21-3 wing phenotype were recovered. The wings of homozygous vg21r36 flies were normal. However, vg21r36 in combination with a deletion of the vg locus exhibited a strong mutant wing phenotype. This was surprising, because the P element insertion in vg21r36 was very similar to that found in the vg21 allele, which showed only slight nicking of the wings in combination with a deletion. In vg21r4, reversion was caused by a tandem insertion of P[21] and the original P[21-3] element present in vg21-3. Finally, the vg21r7 revertant had a P[21-3] insert at vg and 3 additional P elements elsewhere in the genome. We hypothesize that reversion in the 3 novel cases might be caused by P repressor produced by an element at vg or, in the case of vg21r7, elsewhere in the genome. This raises an interesting aspect of P element evolution. While P transposons produce mutations that might prove deleterious to their host, their success in invading the genome of D. melanogaster may be explained by their ability to silence those same mutations by a range of repressor-producing elements.     

Oculocutaneous albinism in the i6 mutant of the medaka fish is associated with a deletion in the tyrosinase gene.

Three mutant alleles (i1, i4, and i5) of the tyrosinase gene in the i locus of the medaka fish Oryzias latipes have hitherto been described, all being associated with transposable element insertion. We have recently identified another allele causing a complete albino phenotype in homozygous carriers and named it i6. Sequence comparison between the tyrosinase gene for the i6 allele (Tyr-i6) and the wild-type gene previously obtained (Tyr-i+) revealed three deletions of 8, 44, and 245 bp. The first two deletions reside in an intron and are differences in the number of tandem tetranucleotide repeats that are polymorphic even among wild-type genes, and, thus, not likely to be responsible for the i6 albino phenotype. The largest deletion spans over the last 180 bp of the second intron and the first 65 bp of the third exon. Because of this deletion, the Tyr-i6 gene lacks the branch point sequence and the acceptor site for the second intron, both being considered to be necessary for normal RNA splicing. Therefore, the 245-bp deletion is likely to be responsible for the albino phenotype. With a mutant gene of this type, unlike ones bearing transposable element insertions, the possibility of reversion mutations to the wild-type would be negligible. Therefore, fish having the i6/i6 genotype should serve as superior recipients for the tyrosinase gene in rescue experiments.