Application of the dual-tagging gene trap method combined with a novel automatic selection system to identify genes involved in germ cell development in Drosophila melanogaster.

The passage of highly specialized germ cells to future generations is essential for the maintenance of species. To date, conventional genetic screens identified relatively few genes that are involved in germ cell development. We aimed to identify germ line specific genes on the X chromosome of Drosophila melanogaster by the application of a new method: the dual-tagging gene-trap system (GT). A modified version of the gene-trap element was used in our experiments and the resulting insertional mutants were screened for grandchild-less phenotype with the help of the attached-X system and a sensitized genetic background developed in our laboratory. Among the 800 insertions mapped to the X chromosome 33 new mutations were identified that exhibited grandchild-less phenotype, 6 gave visible phenotype and 12 were conditional lethal. The cloning of a selected group of the 33 lines showing grandchild-less phenotype confirmed that we have identified new candidates for genes involved in germ cell development. One of them named pebbled (peb) is discussed in details in this paper. Finally, we also describe a novel automatic selection system developed in our laboratory which enables the extension of the GT mutagenesis to the autosomes.

Efficient recruitment of transfected DNA to a homologous chromosomal target in mammalian cells.

A Chinese hamster ovary cell line hemizygous for a defective adenine phosphoribosyltransferase (aprt) gene was transfected with a plasmid, pAG100, capable of correcting the endogenous aprt mutation by targeted homologous recombination. In some experiments, pAG100 was transfected in combination with one of two 'competitor' plasmids. Competitor pCOMP-A was identical to pAG100 except that the aprt sequence on pCOMP-A had the same mutation as the endogenous aprt gene. Competitor pCOMP-B was identical to pAG100 except for a 763 bp deletion in the aprt sequence encompassing the site of mutation in the endogenous gene. Neither pCOMP-A nor pCOMP-B was capable of correcting the defect in the endogenous aprt gene via gene targeting. We asked whether cotransfection of a 4-fold excess of either competitor DNA molecule with pAG100 would reduce the efficiency of targeted correction of the endogenous aprt gene. We report that while plasmid pCOMP-B did not influence the efficiency of gene targeting by pAG100, plasmid pCOMP-A reduced the number of gene targeting events about 5-fold. These observations indicate that the initial homologous interaction between transfected DNA and a genomic target sequence occurs rapidly and that targeting efficiency is limited by a step subsequent to homologous pairing.

Mutations in the novel membrane protein spinster interfere with programmed cell death and cause neural degeneration in Drosophila melanogaster.

Mutations in the spin gene are characterized by an extraordinarily strong rejection behavior of female flies in response to male courtship. They are also accompanied by decreases in the viability, adult life span, and oviposition rate of the flies. In spin mutants, some oocytes and adult neural cells undergo degeneration, which is preceded by reductions in programmed cell death of nurse cells in ovaries and of neurons in the pupal nervous system, respectively. The central nervous system (CNS) of spin mutant flies accumulates autofluorescent lipopigments with characteristics similar to those of lipofuscin. The spin locus generates at least five different transcripts, with only two of these being able to rescue the spin behavioral phenotype; each encodes a protein with multiple membrane-spanning domains that are expressed in both the surface glial cells in the CNS and the follicle cells in the ovaries. Orthologs of the spin gene have also been identified in a number of species from nematodes to humans. Analysis of the spin mutant will give us new insights into neurodegenerative diseases and aging.

Dual-tagging gene trap of novel genes in Drosophila melanogaster.

A gene-trap system is established for Drosophila. Unlike the conventional enhancer-trap system, the gene-trap system allows the recovery only of fly lines whose genes are inactivated by a P-element insertion, i.e., mutants. In the gene-trap system, the reporter gene expression reflects precisely the spatial and temporal expression pattern of the trapped gene. Flies in which gene trap occurred are identified by a two-step screening process using two independent markers, mini-w and Gal4, each indicating the integration of the vector downstream of the promoter of a gene (dual tagging). mini-w has its own promoter but lacks a polyadenylation signal. Therefore, mini-w mRNA is transcribed from its own promoter regardless of the vector integration site in the genome. However, the eyes of flies are not orange or red unless the vector is incorporated into a gene enabling mini-w to be spliced to a downstream exon of the host gene and polyadenylated at the 3' end. The promoter-less Gal4 reporter is expressed as a fusion mRNA only when it is integrated downstream of the promoter of a host gene. The exons of trapped genes can be readily cloned by vectorette RT-PCR, followed by RACE and PCR using cDNA libraries. Thus, the dual-tagging gene-trap system provides a means for (i) efficient mutagenesis, (ii) unequivocal identification of genes responsible for mutant phenotypes, (iii) precise detection of expression patterns of trapped genes, and (iv) rapid cloning of trapped genes.

Trap a gene and find out its function: toward functional genomics in Drosophila.

Many declared aims of the genome projects have been achieved. The total genomic sequences of several relatively noncomplex/complex organisms (such as E. coli, yeast, Caenorhabditis, Drosophila) are being determined, and the nucleotide sequencing of the entire human genome will be complete in the near future. However, this achievement is not the end of the road but rather the first step toward the functional understanding of the genome of humans and other organisms. The determined linear nucleotide sequences remain only lists of A, C, G and T, unless they are given functional significance. The coding sequences of genes can be identified in a relatively reliable manner by computational methods, but the exact function of their protein products can rarely be determined without obtaining much additional information, e.g., by biochemical or cell biological methods. Thus, following sequencing, the next step must be to assign functions to the identified genes. The final goal of genome research today may look futuristic, but the knowledge of the function of every single gene and the interactions between them will finally allow us to understand the development and functioning of an organism as a whole. Gene-trapping methodology is a powerful strategy for cloning and identifying functional genes, as it marks a gene with a tag and simultaneously generates a corresponding genetic variation for that particular locus. Therefore, gene trapping is an extremely useful tool for functional genomics, establishing a correlation between the physical and genetic maps of the genome. The relative simplicity of its genome and the availability of huge bodies of genetic and molecular information make Drosophila melanogaster one of the most important model organisms. Its genome will serve as a "reference" for the in-depth analysis of the organization of more complex eukaryotic genomes. Multifaceted approaches to Drosophila functional genomics and the dual-tagging gene trap system newly developed for functional analysis of Drosophila genes are discussed in this review.

Formation of the male-specific muscle in female Drosophila by ectopic fruitless expression.

The Drosophila fruitless (fru) gene product Fru has been postulated to be a neural sex-determination factor that directs the development of at least two male-specific characteristics, namely courtship behaviour and formation of the muscle of Lawrence (MOL). The fru gene encodes a putative transcription factor with a BTB domain and two zinc-finger motifs, and with consensus Tra-binding sequences. The binding of Tra to these sequences results in sex-specific alternative splicing of the fru mRNA, leading to production of the 'male-type' or 'female-type' Fru protein. We show here that the Fru protein is not detected in the female central nervous system (CNS), despite the similar level of expression of fru mRNA in both male and female CNS. As ectopic expression of both the 'male-type' (with the sequence for the amino-terminal extension) and 'female-type' (without the sequence for the amino-terminal extension) fru cDNA can induce formation of the MOL in females, the presence or absence of the Fru protein, and not its sex-specific structure, seems to be responsible for the sexually dimorphic actions of the fru gene.

Fruitless is in the regulatory pathway by which ectopic mini-white and transformer induce bisexual courtship in Drosophila.

Bisexual courtship in male Drosophila melanogaster may be induced in some circumstances. These include ectopic expression of the transformer (tra) gene, ectopic expression of the mini-white (mw) gene, and the homozygous presence of mutant alleles of the fruitless (fru) gene. Experiments were performed to determine if ectopic mw and fru, as well as ectopic tra and fru, acted in the same pathway to control courtship. Male flies homozygous for the frusat allele court females little if at all and males at a low level. When homozygous, the frusat allele suppresses the bisexual courtship induced by both ectopic mw and ectopic tra, indicating that the fru wild-type function is necessary for expression of the ectopic mw and ectopic tra effect. This demonstrates that fru shares a pathway controlling courtship behavior with these ectopically expressed genes.

Multiple pathways for repair of DNA double-strand breaks in mammalian chromosomes.

To study repair of DNA double-strand breaks (DSBs) in mammalian chromosomes, we designed DNA substrates containing a thymidine kinase (TK) gene disrupted by the 18-bp recognition site for yeast endonuclease I-SceI. Some substrates also contained a second defective TK gene sequence to serve as a genetic donor in recombinational repair. A genomic DSB was induced by introducing endonuclease I-SceI into cells containing a stably integrated DNA substrate. DSB repair was monitored by selection for TK-positive segregants. We observed that intrachromosomal DSB repair is accomplished with nearly equal efficiencies in either the presence or absence of a homologous donor sequence. DSB repair is achieved by nonhomologous end-joining or homologous recombination, but rarely by nonconservative single-strand annealing. Repair of a chromosomal DSB by homologous recombination occurs mainly by gene conversion and appears to require a donor sequence greater than a few hundred base pairs in length. Nonhomologous end-joining events typically involve loss of very few nucleotides, and some events are associated with gene amplification at the repaired locus. Additional studies revealed that precise religation of DNA ends with no other concomitant sequence alteration is a viable mode for repair of DSBs in a mammalian genome.

The Drosophila melanogaster 60A chromosomal division is extremely dense with functional genes: their sequences, genomic organization, and expression.

We cloned and sequenced genomic DNA contigs spanning over 45 kb, surrounding the insertion site of the P-element that is responsible for the developmental defects in the ken and barbie (ken) mutant of Drosophila. This region harbors 10 functional transcription units, in addition to the already well-characterized TGFbeta-60A gene. These include the genes, undefined 1 (UD1), UD2, and UD3, each coding for proteins of unknown function, the ken gene encoding a new Krüppel-like putative transcription factor, the fly homologues of the mammalian mitochondrial trifunctional enzyme (thiolase), and the TAR DNA-binding protein-43 (TBPH), the first nonvertebrate member of the transmembrane 4 superfamily (TM4SF) gene, a new homeodomain gene, and a gene coding for a putative nuclear binding protein (PNBP) that is homologous to maleless, and a Copia-like element. UD3 exists in an intron of the maleless homologue, yet is expressed independent of it. The UD1 and TM4SF genes orient in a tail-to-tail manner with their 3' untranslated region sequences overlapping over 44 nucleotides. Thus the partial overlap and intraintronic organization permitted dense packing of the functional genes within a short segment of the genome.

Suppression of intrachromosomal gene conversion in mammalian cells by small degrees of sequence divergence.

Pairs of closely linked defective herpes simplex virus (HSV) thymidine kinase (tk) gene sequences exhibiting various nucleotide heterologies were introduced into the genome of mouse Ltk- cells. Recombination events were recovered by selecting for the correction of a 16-bp insertion mutation in one of the tk sequences. We had previously shown that when two tk sequences shared a region of 232 bp of homology, interruption of the homology by two single nucleotide heterologies placed 19 bp apart reduced recombination nearly 20-fold. We now report that either one of the nucleotide heterologies alone reduces recombination only about 2.5-fold, indicating that the original pair of single nucleotide heterologies acted synergistically to inhibit recombination. We tested a variety of pairs of single nucleotide heterologies and determined that they reduced recombination from 7- to 175-fold. Substrates potentially leading to G-G or C-C mispairs in presumptive heteroduplex DNA (hDNA) intermediates displayed a particularly low rate of recombination. Additional experiments suggested that increased sequence divergence causes a shortening of gene conversion tracts. Collectively, our results suggest that suppression of recombination between diverged sequences is mediated via processing of a mispaired hDNA intermediate.

Repair of a specific double-strand break generated within a mammalian chromosome by yeast endonuclease I-SceI.

We established a mouse Ltk- cell line that contains within its genome a herpes simplex virus thymidine kinase gene (tk) that had been disrupted by the insertion of the recognition sequence for yeast endonuclease I-SceI. The artificially introduced 18 bp I-SceI recognition sequence was likely a unique sequence in the genome of the mouse cell line. To assess whether an induced double-strand break (DSB) in the genomic tk gene would be repaired preferentially by gene targeting or non-homologous recombination, we electroporated the mouse cell line with endonuclease I-SceI alone, one of two different gene targeting constructs alone, or with I-SceI in conjunction with each of the two targeting constructs. Each targeting construct was, in principle, capable of correcting the defective genomic tk sequence via homologous recombination. tk+ colonies were recovered following electroporation of cells with I-SceI in the presence or absence of a targeting construct. Through the detection of small deletions at the I-SceI recognition sequence in the mouse genome, we present evidence that a specific DSB can be introduced into the genome of a living mammalian cell by yeast endonuclease I-SceI. We further report that a DSB in the genome of a mouse Ltk- cell is repaired preferentially by non-homologous end-joining rather than by targeted homologous recombination with an exogenous donor sequence. The potential utility of this system is discussed.

Increased mutation rate in bacteria overexpressing a cloned foreign gene.

Escherichia coli cells growing slowly as a result of the overexpression of a cloned foreign gene were shown to exhibit an increased mutation rate in the foreign gene as well as in several non-selected markers. This phenomenon is discussed in terms of the model proposed by Hall (1990).

A family of expression vectors based on the rrnB P2 promoter of Escherichia coli.

We describe here the construction of a family of expression vectors, based on the P2 promoter of the Escherichia coli rrnB gene by removing regulatory sequences downstream of the Pribnow-box and replacing them with the lac operator. These vectors allow cloning of foreign genes in such a way that their products are synthesized either in the form of fusion proteins of different length, or without fusion partners, with or without the original translational initiation signals. One of the vectors contains a synthetic oligothreonine-coding sequence that helps to stabilize the product of the cloned gene. These vectors allow high-level regulated expression of foreign genes, even if their products are relatively short peptides.

Regulatory elements downstream of the promoter of an rRNA gene of E. coli.

Previously we have shown that plasmid constructs carrying a reporter gene fused to the P2 promoter of the E. coli rrnB gene exhibited a strange two-phase kinetics of expression depending on the physiological conditions of the cell if a short DNA region downstream of the promoter was present between the promoter and the reporter gene (Lukacsovich et al. (1987) J. Bacteriol. 169, 272-277). Insertion of a synthetic oligonucleotide corresponding to the first half of this region into constructs where the reporter directly follows the promoter, leads to a complete block of expression in vivo, while in vitro--in a purified system--transcription is not inhibited. Band-shift experiments indicate that the putative regulatory region downstream of the promoter specifically binds protein(s) present in total bacterial extracts.

New approaches to increase the expression and stability of cloned foreign genes in Escherichia coli.

A family of expression plasmid vectors were constructed by fusing the strong P2 promoter of the rrnB gene of Escherichia coli (coding for ribosomal RNA) to the lac operator, thereby eliminating regulatory sequences from the rrnB gene and placing the expression under lac repressor control. This promoter proved to be stronger in vivo than the well-known consensus tac promoter, and its strength could be further increased by converting the sequence to consensus. The stability of the recombinant proteins could be increased by fusion to various lengths of the N-terminal end of beta-galactosidase, or by inserting a synthetic oligonucleotide, coding for heptathreonine. A new method was developed for the stabilization of recombinant plasmids without antibiotic selection, based on the presence of an essential gene on the plasmid and its absence from the chromosome. The application of this method is illustrated by the example of a plasmid expressing human proinsulin.

A new procedure for the targeted inactivation of essential bacterial genes.

A new method is described for the exchange of a plasmid encoded mutant gene with its chromosomal counterpart. The method is based on positive selection and is applicable for the exchange of essential genes. The main features of the method are: (1) cloning of an antibiotic resistance marker (without its promoter) downstream of the cloned target gene, thus forming an artificial operon; (2) inactivating the target gene (and consequently also the antibiotic resistance gene) by inserting a strong transcriptional termination signal into it; and (3) selection for double recombinants by means of the antibiotic resistance gene.

The structural basis of the high in vivo strength of the rRNA P2 promoter of Escherichia coli.

Ribosomal RNA promoters of Escherichia coli are probably the strongest promoters in vivo and they can be used on plasmid vectors to express protein-coding sequences at a high rate. In fact, the P2 promoter of the rrnB gene is stronger (in vivo) than the tac promoter, which has a perfect consensus sequence. Conversion of the rrnB P2 promoter sequence to consensus significantly increases in vivo promoter strength. The removal of four nucleotides downstream of the -10 region also increases the strength of this promoter. On the other hand, shifting of the A + T-rich region upstream of this promoter by an 11-bp insertion drastically decreases in vivo activity. It is concluded that the two functionally important hexanucleotide sequences, -35 and -10, are necessary but not sufficient factors for the optimalization of in vivo promoter strength.

New regulatory features of the promoters of an Escherichia coli rRNA gene.

Recombinant plasmids were constructed by fusing either promoter p1 or p2 or both promoters of the rrnB gene of Escherichia coli to a DNA fragment coding for the N-terminal alpha-peptide of beta-galactosidase. These plasmids contained various lengths of the 5'-leader region of rRNA as the 5'-terminal end of the alpha-peptide messenger. In some cases the entire 5'-terminal rRNA-coding sequence was removed, and alpha-peptide synthesis was governed by rac promoters formed by fusion of rrnBp2 and lac promoters. By measuring the level of alpha peptide, conclusions could be drawn about the activities of the promoters under various physiological conditions. It was found that the rate of transcription starting from promoter p1 or p2 might vary more than 10-fold during the growth cycle, showing a sharp maximum during outgrowth from the stationary phase into exponential growth or during nutritional shift-up. The target sequence of this regulation was localized to the leader region of the rrnB gene.

Expression vectors based on the rac fusion promoter.

The -35 region of the rrnB P2 promoter and the -10 region of the lacZpo promoter-operator were fused to form the strong and regulatable rac promoter. Vectors were constructed that allow the attachment of protein-coding sequences to the beta-galactosidase alpha-peptide (LacZ alpha) in any reading frame. By introducing a high-copy-number mutation, the synthesis of a LacZ alpha-chloramphenicol acetyltransferase fusion protein reached more than 60% of total cell protein in Escherichia coli.