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     

The suppressor of Hairy-wing binding region is required for gypsy mutagenesis

Summary We undertook a deletional analysis of the gypsy retrotransposon in order to determine which sequences of the element are required for its mutagenic effect. We show that a phenotype indistinguishable from that ofy ² flies can be generated by transformingy ^– flies with a construct containing theyellow gene and a gypsy element located at the same insertion site inyellow as found iny ² flies. When flies are transformed with similar constructs in which increasing amounts of the 5 transcribed untranslated region of gypsy have been removed, either a partialy ² revertant or a completely revertant phenotype is obtained. These results yield direct proof that the region of gypsy to which thesu(Hw) protein binds is required for the generation of mutant phenotypes by this retrotransposon.     

An unstable mutant gene of the am locus of Neurospora results from a small duplication

We have cloned the unstable am mutant gene, am126, as well as the am gene from an am126 revertant. The mutation is a result of a 33-bp duplication that repeats a sequence starting 13 bp upstream of the 3' splice junction between intron 1 and exon 2 and extends 20 bp into exon 2. In addition, there is a G----A transition 2 bp upstream of the first copy of the duplicated sequence. In the revertant gene the wild-type sequence is precisely recovered, involving both the loss of the duplication and a reversion (A----G) of the associated transition. Our data suggest that only the more 5' of the two 3' splice junctions present in the duplicated version of the gene is used. This favors a 5'----3' scanning mechanism for exon splicing.     

Cloning of the y1 Locus of Maize,a Gene Involved in the Biosynthesis of Carotenoids

The y1 gene is one of the genes responsible for the production of [beta]-carotene in the endosperm and leaves of maize. We have cloned a Robertson's Mutator-tagged allele of the y1 gene (y1-mum) by using a Mu3 element as a hybridization probe. We substantiate that the cloned sequence is a portion of the y1 gene by molecular analyses of a revertant of a putative Mutator-induced y1 allele and the incidence of insertions within the cloned y1 sequence from several independently derived Mutator-induced y1 mutant stocks. The y1-mum sequence was used to isolate the standard Y1 allele, which conditions the presence of [beta]-carotene in the endosperm of the maize kernel.     

The gypsy insulator can function as a promoter-specific silencer in the Drosophila embryo.

The Drosophila gypsy retrotransposon disrupts gene activity by blocking the interactions of distal enhancers with target promoters. This enhancer-blocking activity is mediated by a 340 bp insulator DNA within gypsy. The insulator contains a cluster of binding sites for a zinc finger protein, suppressor of Hairy wing [su(Hw)]. Recent studies have shown that a second protein, mod(mdg4), is also important for normal insulator function. Mutations in mod(mdg4) exert paradoxical effects on different gypsy-induced phenotypes. For example, it enhances yellow2 but suppresses cut6. Here, we employ a stripe expression assay in transgenic embryos to investigate the role of mod(mdg4) in gypsy insulator activity. The insulator was inserted between defined enhancers and placed among divergently transcribed reporter genes (white and lacZ) containing distinct core promoter sequences. These assays indicate that mod(mdg4) is essential for the enhancer-blocking activity of the insulator DNA. Moreover, reductions in mod(mdg4)+ activity cause the insulator to function as a promoter-specific silencer that selectively represses white, but not lacZ. The repression of white does not affect the expression of the closely linked lacZ gene, suggesting that the insulator does not propagate changes in chromatin structure. These results provide an explanation for why mod(mdg4) exerts differential effects on different gypsy-induced mutations.     

The Tc2 transposon of Caenorhabditis elegans has the structure of a self-regulated element.

We have analyzed the sequence of the Tc2 transposon of the nematode Caenorhabditis elegans. The Tc2 element is 2,074 bp in length and has perfect inverted terminal repeats of 24 bp. The structure of this element suggests that it may have the capacity to code for a transposase protein and/or for regulatory functions. Three large reading frames on one strand exhibit nonrandom codon usage and may represent exons. The first open coding region is preceded by a potential CAAT box, TATA box, and consensus heat shock sequence. In addition to its inverted terminal repeats, Tc2 has an unusual structural feature: subterminal degenerate direct repeats that are arranged in an irregular overlapping pattern. We have also examined the insertion sites of two Tc2 elements previously identified as the cause of restriction fragment length polymorphisms. Both insertions generated a target site duplication of 2 bp. One element had inserted inside the inverted terminal repeat of another transposon, splitting it into two unequal parts.     

Pairing between gypsy insulators facilitates the enhancer action in trans throughout the Drosophila genome

The Suppressor of the Hairy wing [Su(Hw)] binding region within the gypsy retrotransposon is the best known chromatin insulator in Drosophila melanogaster. According to previous data, two copies of the gypsy insulator inserted between an enhancer and a promoter neutralize each other's actions, which is indicative of an interaction between the protein complexes bound to the insulators. We have investigated the role of pairing between the gypsy insulators located on homologous chromosomes in trans interaction between yellow enhancers and a promoter. It has been shown that trans activation of the yellow promoter strongly depends on the site of the transposon insertion, which is evidence for a role of surrounding chromatin in homologous pairing. The presence of the gypsy insulators in both homologous chromosomes even at a distance of 9 kb downstream from the promoter dramatically improves the trans activation of yellow. Moreover, the gypsy insulators have proved to stabilize trans activation between distantly located enhancers and a promoter. These data suggest that gypsy insulator pairing is involved in communication between loci in the Drosophila genome.     

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.     

Depression of the xylanase-encoding cgxA gene of Chaetomium gracile in Aspergillus nidulans

Regulation of the Chaetomium gracile xylanase A gene (cgxA) was investigated using Aspergillus nidulans as an intermediate host. Deletion of a 185 bp DNA fragment from its promoter region led to higher levels of the cgxA gene expression, indicating that the 185 bp DNA fragment contains an element involved in repression of the gene. A nuclear extract was assayed for proteins which bind to the 185 bp DNA fragment. A protein designated AnRP bound sequence specifically to the DNA fragment. The minimum sequence required for AnRP binding, 5'TTGACAAAT-3', was determined by means of gel mobility shift assays with various double-stranded oligonucleotides. Furthermore, this sequence repressed the expression of the cgxA gene when inserted at the 5' end of the cgxA gene on pXAH, which was deleted for the repressive element from the promoter region.     

Comparative analysis of the catechol 2,3-dioxygenase gene locus in thermoacidophilic archaeon Sulfolobus solfataricus strain 98/2

A catechol 2,3-dioxygenase (C23O) gene was found from Sulfolobus solfataricus strain 98/2. Heterologous thermophilic C23O expressed in Escherichia coli showed the highest activity against catechol and 4-chlorocatechol, and at neutral pH. The C23O gene located with a putative multicomponent monooxygenase (MM) gene cluster that exactly matched with the homologous region of S. solfataricus strain P2. Primary sequence comparison identified an insertion sequence (IS) element inserted into a putative MM protein A N-terminal fragment gene in strain 98/2. Both ends of the transposase gene in the IS element, ISC1234, were flanked by 19 bp inverted repeat and 4 bp direct repeat sequences which are typical features of mobile elements. Our analysis and the two geographically distant origins of strains 98/2 and P2 (USA and Italy, respectively) suggest that the two strains have evolved from a common ancestor.