Detection of new genes participating in the trans-regulation of locus yellow of MDG-4 in Drosophila melanogaster

The aim of the present work was to obtain mutations in the genes involved in regulation of the yellow locus and mdg4. For this purpose, we searched for mutations changing phenotypic expression of the y(2) mutation induced by mdg4 insertion into the regulatory region of the yellow locus. Mutations have been obtained in the earlier described system of prolonged genome instability, sometimes combined with P-M hybrid dysgenesis. The mutation mod(mdg4) in a novel gene, modifier of mdg4, was detected which either enhanced or suppressed a phenotypic expression of several mutations induced by mdg4 insertion. We suggest that mod(mdg4) controls the expression of mdg4. In addition, the mutations in five loci located on the X chromosome have been found which enhanced the mutation phenotype of several y alleles induced by insertions of different mobile elements in the regulatory region of the latter. Possibly, the protein products of these genes designated as enhancers of yellow-1, 2, 3, 4 and 5 are directly or indirectly involved in control of the yellow locus expression.     

Identification of Mutations in Three Genes That Interact with Zeste in the Control of White Gene Expression in Drosophila Melanogaster

Three previously described genes, enhancer of yellow, 1, 2 and 3, are shown to cooperate with the zeste gene in the control of white gene expression. The mutations e(y)1(u1), e(y)3(u1), and to a lesser extent e(y)2(u1), enhance the effect of the zeste null allele z(v77h). Different combinations of e(y)1(u1), e(y)2(u1) and e(y)3(u1) mutations with several other z alleles also enhance the white mutant phenotype, but only to levels characteristic of white alleles containing a deletion of the upstream eye enhancer. Loss of zeste protein binding sites from the white locus does not eliminate the effect of e(y)1(u1) and e(y)3(u1) mutations, suggesting that the products of these genes interact with some other nucleotide sequences. Combinations of either e(y)1(u1) or e(y)2(u1) mutations with e(y)3(u1) are lethal. The products of these three genes may represent, together with zeste, a group of proteins involved in the organization of long-distance interactions between DNA sequences.     

Polymorphism of yellow locus in Drosophila melanogaster from natural populations

We studied molecular characteristics of yellow (y; 1-0.0) locus, which determines the body coloration of phenotypically wild-type and mutant alleles isolated from geographically distant populations of Drosophila melanogaster in different years. According to Southern data, restrictions map of yellow locus of all studied strains differ from each other as well as from that of Oregon stock. FISH analysis shows that in the neighborhood of yellow locus in X chromosome neither P nor hobo elements are found in y1-775 stock, while only hobo is found there in y1-859 and y1-866 stocks, only P element in y+sn849 stock, and both elements in y1-719 stock. Thus, all studied mutant variants of yellow are of independent origin. Yellow locus residing at the very end of X chromosome (region 1A5-8 of cytologic map) carries significantly more transposon than retrotransposon-induced mutations, as compared to white locus (regions 3C2). It is possible that transposons are more active than retrotransposons at the chromosomal ends of D. melanogaster.     

应用果蝇yellow基因的分子模式分析基因转应作用(英文)

基因转应作用（ｔｒａｎｓｖｅｃｔｉｏｎ）是基因表达的一种方式,这种方式是由等位基因配对及其相互作用所介导的。基因转应作用的现象已在果蝇的多种基因中发现。这种作用可产生正负两种效应。而且,在其它物种中,也逐渐发现了类似的现象。例如,在植物中的基因沉默现象（ｇｅｎｅｓｉｌｅｎｃｉｎｇ）以及在小鼠中的基因转激活作用（ｔｒａｎｓａｃｔｉｖａｔｉｏｎ）等。因此,阐明基因转应作用的机理,将有助于了解基因表达调节及增强子调控活动的分子基础。本文应用果蝇ｙｅｌｏｗ基因为模式来探讨基因转应作用的分子机制。前期研究表明,ｙｅｌｏｗ基因转应作用发生于ｇｙｐｓｙ诱导的ｙ２突变种和ｙｅｌｏｗ亚等位基因（ｙｈ）之间。为了证实是否ｇｙｐｓｙ是基因转应作用所必需的ＤＮＡ元件,我们鉴定了一种新的ｙｅｌｏｗ突变种,称为ｙ２３７４。ｙ２３７４突变是一种基因表达的组织特异性改变,这一改变使ｙ２３７４果蝇在翅和身体部位表皮着色呈突变型。通过遗传分析表明,ｙ２３７４也可与ｙｈ（如ｙ１＃８）产生基因转应作用。ｙ１＃８是一种无效的ｙｅｌｏｗ等位基因,它包含一个启动子和部分编码区序列的缺失。然而,当ｙ２３７４与ｙ１＃８杂交后,其杂交后代的表现型可由ｙ２３７     

Association of the yellow leaf (y10) mutant to soybean chromosome 3

At least 19 single recessive gene yellow leaf mutants and one duplicate recessive gene mutant have been described in soybean. This study was conducted to associate a yellow leaf mutant, y10, with a specific soybean chromosome by using primary trisomics (2n = 41). Seven soybean primary trisomics were hybridized as female parent with genetic stock strain, T161, carrying y10. F(1) disomic and primary trisomic plants were identified cytologically. One disomic (control) and all primary trisomic plants were allowed to self-pollinate and F(2) populations were classified for green versus yellow leaf mutant. The F(2) population of Triplo 3 segregated in a 17:1 ratio, while a disomic (3:1) ratio was observed with Triplo 8-, 17-, 18-, and 20-derived F(2) populations, suggesting that the y10 locus is on chromosome 3. The y10 locus was examined with four simple sequence repeat (SSR) markers (Satt584, Sat_033, Satt387, and Satt022) from molecular linkage group (MLG) N and y10 was found linked with Satt022. Therefore we confirmed the association of MLG N with chromosome 3. The possible association of y10 with Triplo 16 and Triplo 19 are discussed.     

Effect of the yellow locus on sensitivity of drosophila sex cells to chemical mutagens

The effect of the yellow (y) locus on germ cell sensitivity to the alkylating agent ethyl methanesulfonate (EMS) has been studied in Drosophila. Since DNA repair is one of the most important factors that control cell sensitivity to mutagens, the approaches used in our experiments aimed at evaluating the relationship between germ-cell mutability and activity of DNA repair. Germ-cell mutability and repair activity were assessed using several parameters, the most important of which was the frequency of the recessive sex-linked lethal mutations (RSLLM). In one series of experiments, the adult males of various genotypes (Berlin wild; y; y ct v; y mei-9a) were treated by mutagenic agents and then crossed to Basc females. Comparative analysis of germ-cell mutability as dependent on genotype and the stage of spermatogenesis showed that the yellow mutation significantly enhanced the premeiotic cell sensitivity to EMS, presumably, due to the effect on DNA repair. In the second series of experiments, the effect of the maternal DNA repair was studied and, accordingly, mutagen-treated Basc males were crossed to females of various genotypes including y and y mei-9a ones. The crosses involving y females yielded F1 progeny with high spontaneous lethality, whereas in F2, the frequency of spontaneous mutations was twice higher. The germ cell response to EMS depended also on female genotype: the effect of yellow resulted in increased embryonic and postembryonic lethality, whereas the RSLLM frequency decreased insignificantly. The latter result may be explained by elimination of some mutations due to 50% mortality of the progeny. The results obtained using the above two approaches suggest that the yellow locus has a pleiotropic effect on the DNA repair systems in both males and females of Drosophila.     

Interactions between su(Hw)-binding regions in neighboring y2 and scD1 alleles hinder trans-activation of the y2 promoter by yellow enhancers located on a homologous chromosome

The phenomenon of transvection has been well characterized for the yellow locus in Drosophila. Enhancers of a promoterless yellow locus in one homologous chromosome can activate the yellow promoter in the other when its own enhancers are blocked by the su(Hw) insulator introduced by the gypsy retrotransposon. Insertion of another gypsy into the neighboring scute locus hinders transvection presumably owing to disruption of chromosomal synapsis between the yellow alleles. We determined the sequences of gypsy required for inhibition of transvection. Two partial revertants of the scD1 mutation were obtained in which transvection between the yellow alleles was restored. Both sc revertants were generated by deletion of nine of the twelve su(Hw)-binding sites of gypsy inserted into the scute locus. This result suggests that the su(Hw) region is required for an interaction between two gypsy elements that disrupts trans activation of the yellow promoter by enhancers located on the homologous chromosome.     

Effect of mutations in the genes su(Hw) and mod(mdg4) on transvection between alleles of the Yellow locus in Drosophila melanogaster]

A typical example of transvection is a complementation between alleles in the yellow locus: y2 (mdg4 insertion inactivating certain y-enhancers) and y1 (deletion of the y-promoter but not of the enhancer). Transvection was explained by trans-activation of promoter in y2-allele by enhancer of y1-allele. Here we found that the mutation mod(mdg4)1u1 in the modifier of mdg4 locus (a regulatory gene controlling, together with suppressor of Hairy wing) expression of (mdg4) completely suppress the complementation. Removal of an acidic domain from su(Hw) protein product in su(Hw)j mutation partially suppress the complementation. We also have found that mod(mdg4)1u1 mutation trans-inactivates the yellow allele with a wild type phenotype (y+2MC) in heterozygote with the y2 allele, i.e. the negative transvection takes place. In this case, deletion removing an acidic domain even in one copy of su(Hw) suppresses the effect of mod(mdg4)1u1 mutation.