Use of a Yeast Site-Specific Recombinase to Produce Female Germline Chimeras in Drosophila

We describe an efficient method for generating female germline mosaics by inducing site-specific homologous mitotic recombination with a yeast recombinase (FLP) which is driven by a heat shock promoter. These germline mosaics are produced in flies heterozygous for the agametic, germline-dependent, dominant female sterile (DFS) mutation ovoD1, where only flies possessing germline clones are able to lay eggs. This method, the "FLP-DFS" technique, is very efficient because more than 90% of females with germline clones can be recovered. We show that this heat-inducible, site-specific mitotic recombination system does not affect viability and that the germline clones recovered are physiologically the same as those created by X-ray induced mitotic recombination. We describe the parameters of FLP-recombinase induced germline mitotic recombination and the use of the "FLP-DFS" technique to analyze the maternal effect of X-linked zygotic lethal mutations.     

Use of a yeast site-specific recombinase to generate embryonic mosaics in Drosophila

An efficient method for generating embryonic mosaics using a yeast site-specific recombinase (FLP), under the control of a heat shock promoter, is described. FLP-recombinase can promote mitotic exchange between homologous chromosomes that contain FRT (FLP Recombination Target) sequences. To demonstrate the efficiency of FLP-recombinase to generate embryonic mosaics, clones of the recessive and cell autonomous mutation armadillo (arm), detected by their ability to differentiate ectopic denticles in the naked cuticle of each abdominal segment, have been induced. We have analyzed the parameters of FLP-recombinase induced embryonic mitotic recombination and have demonstrated that clones can be efficiently induced during the postblastoderm mitotic divisions. We discuss applications of this technique for the analyses of the roles of various mutations during embryonic patterning. © 1992 Wiley-Liss, Inc.     

FLP-mediated site-specific recombination in microinjected murine zygotes

The FLP recombinase of yeast catalyses site-specific recombination between repeated FLP recombinase target (FRT) elements in yeast and in heterologous system (Escherichia coli, Drosophila, mosquito and cultured mammalian cells). In this report, it is shown that transient FLP recombinase expression can recombine and activate an extrachromosomal silent reporter gene following coinjection into fertilized one-cell mouse eggs. Furthermore, it is demonstrated that introduction of a FLP-recombinase expression vector into transgenic one-cell fertilized mouse eggs induces a recombination event at a chromosomal FRT target locus. The resulting event occured at the one-cell stage and deleted a chromosomal tandem array of a FRT containinglacZ expression cassette down to one or two copies. These results demonstrate that the FLP recombinase can be utilized to manipulate the genome of transgenic animals and suggest that FLP recombinase-mediated plasmid-to-chromosome targeting is feasible in microinjected eggs.     

Developmental Analysis of the Achaete-Scute System of DROSOPHILA MELANOGASTER

The interpretation of the wild-type function of a gene depends on our knowledge of the phenotype caused by its absence. We have first defined the genetic extent of the achaete-scute system by studying the phenotype of different terminal and intercalary deficiencies including these genes. When these deficiencies were lethal, we have defined the phenoeffective phase of lethality and studied their phenotype in genetic mosaics (gynandromorphs and mitotic recombination clones). The achaete-scute system affects two functions, one necessary for the differentiation of the embryonic (central?) nervous system and the other necessary for the differentiation of peripheral nervous elements of the chaetes and sensillae of the adult cuticle. The possibility that these functions correspond to differential expression of a single mechanism is discussed.     

Quantitative analysis of antennal mosaic generation in Drosophila melanogaster by the MARCM system

Mosaics have been used in Drosophila to study development and to generate mutant structures when a mutant allele is homozygous lethal. New approaches of directed somatic recombination based on FRT/FLP methods, have increased mosaicism rates but likewise multiple clones in the same individual appeared more frequently. Production of single clones could be essential for developmental studies; however, for cell-autonomous gene function studies only the presence of homozygous cells for the target recessive allele is relevant. Herein, we report the number and extension of antennal mosaics generated by the MARCM system at different ages. This information is directed to obtain the appropriated mosaic type for the intended application. By applying heat shock at 10 different developmental stages from 0-12 h to 6-7 days after egg laying, more than 50% of mosaics were obtained from 5,028 adults. Single recombinant clones appeared mainly at early stages while massive recombinant areas were observed with late treatments.     

Mutant analysis by rescue gene excision: New tools for mosaic studies in Drosophila

A host of classical and molecular genetic tools make Drosophila a tremendous model for the dissection of gene activity. In particular, the FLP‐FRT technique for mitotic recombination has greatly enhanced gene loss‐of‐function analysis. This technique efficiently induces formation of homozygous mutant clones in tissues of heterozygous organisms. However, the dependence of the FLP‐FRT method on cell division, and other constraints, also impose limits on its effectiveness. We describe here the generation and testing of tools for Mutant Analysis by Rescue Gene Excision (MARGE), an approach whereby mutant cells are formed by loss of a rescue transgene in a homozygous mutant organism. Rescue‐transgene loss can be induced in any tissue or cell‐type and at any time during development or in the adult using available heat‐shock‐induced or tissue‐specific flippases, or combinations of UAS‐FLP with Gal4 and Gal80^ts reagents. The simultaneous loss of a constitutive fluorescence marker (GFP or RFP) identifies the mutant cells. We demonstrate the efficacy of the MARGE technique by flip‐out (clonal and disc‐wide) of a Ubi‐GFP‐carrying construct in imaginal discs, and by inducing a known yki mutant phenotype in the Drosophila ovary.     

Genetic screening of meiotic mutations in mosaic clones of the Drosophila melanogaster female germline]

A method of screening for meiotic mutations based on genetic analysis of chromosome disjunction in germline mosaic clones of females homozygous for potential mutations is proposed. The clones are obtained at high frequency due to the use of the transgenic FLP/FRT system of mitotic recombination. This system permits obtaining homozygous clones in the first generation after mutagenesis, whereas the cultures are set up after selection for potential meiotic mutations. This significantly enhances, the efficiency of screening by the elimination of the limiting stage. Using this method, the following mutations were revealed in the 3L arm of Drosophila: ff6 leading to disturbed centriole disjunction, which results in appearance of multi-tail spermatids and three-pole spindles during male meiosis; ff3 leading to the formation of chromosome bridges in anaphase and telophase, chromosome nondisjunction, and premature chromatin condensation after metaphase; embryonic lethal ff29, with disturbed coordination between nuclear and centrosome cycles during syncytial cleavage; and a series of other mutations causing a wide spectrum of disturbances in male meiosis. Comparison of the proposed method with procedures of screening for yeast cell-cycle mutations showed that we succeeded in attaining the efficiency of screening in the Drosophila model close to that in the yeast model.     

Mosaic Analysis Gives an Estimate of the Extent of Genomic Involvement in the Development of the Visual System in Drosophila Melanogaster

To investigate the role of vital loci in the development of the visual system of Drosophila, we induced mitotic recombination in individuals heterozygous for recessive organismal lethals and selected for analysis the resulting mosaics with homozygous mutant eye clones. Heads bearing clones were serially sectioned, silver-stained and examined for aberrations in the ommatidia and the neural structures to which they project. In our screen of 68 lines bearing diepoxybutane-induced X-linked lethals, 26 yielded few or no homozygous mutant clones (putative cell-lethals). Of the rest, 20 lines produced individuals with morphologically abnormal eye clones showing various degrees of aberrations in the ommatidial architecture. In 14 of these 20, the laminar cartridges innervated by the mutant clones were also disorganized. Clones with normal structure were found in 18 of the lines, and three lines were resistant to the induction of mitotic recombination. In a single line, comparatively normal clones in the eye projected to a lamina with subtle but consistent abnormalities. To the extent that we have a representative sample, these results suggest that about two-thirds of all vital genes may be essential for the normal assembly and neural connectivity of the eye. This points to a high degree of pleiotropy in the manner in which information in the genome of the fly is used in development.     

A genetic method for generating Drosophila eyes composed exclusively of mitotic clones of a single genotype.

The genetic analysis of a gene at a late developmental stage can be impeded if the gene is required at an earlier developmental stage. The construction of mosaic animals, particularly in Drosophila, has been a means to overcome this obstacle. However, the phenotypic analysis of mitotic clones is often complicated because standard methods for generating mitotic clones render mosaic tissues that are a composite of both mutant and phenotypically normal cells. We describe here a genetic method (called EGUF/hid) that uses both the GAL4/UAS and FLP/FRT systems to overcome this limitation for the Drosophila eye by producing genetically mosaic flies that are otherwise heterozygous but in which the eye is composed exclusively of cells homozygous for one of the five major chromosome arms. These eyes are nearly wild type in size, morphology, and physiology. Applications of this genetic method include phenotypic analysis of existing mutations and F(1) genetic screens to identify as yet unknown genes involved in the biology of the fly eye. We illustrate the utility of the method by applying it to lethal mutations in the synaptic transmission genes synaptotagmin and syntaxin.     

Identification of the DNA-binding domain of the FLP recombinase

We have subjected the FLP protein of the 2-micron plasmid to partial proteolysis by proteinase K and have found that FLP can be digested into two major proteinase K-resistant peptides of 21 and 13 kDa, respectively. The 21-kDa peptide contains a site-specific DNA-binding domain that binds to the FLP recognition target (FRT) site with an affinity similar to that observed for the native FLP protein. This peptide can induce DNA bending upon binding to a DNA fragment containing the FRT site, but the angle of the bend (approximately 24 degrees) is smaller in magnitude than that induced by the native FLP protein (60 degrees). The additional DNA bending induced by the interaction between two native FLP molecules bound to the FRT site is not observed with the 21-kDa DNA-binding peptide. Amino-terminal sequencing has been used to map this peptide to an internal region of FLP that begins at residue Leu-148. It is likely that the DNA-binding peptide includes the catalytic site of the FLP protein.     

Genetic Screening for Meiotic Mutations of the Female Germline Mosaic Clones in Drosophila melanogaster

A method of screening for meiotic mutations based on genetic analysis of chromosome disjunction in germline mosaic clones of females homozygous for potential mutations is proposed. The clones are obtained at high frequency due to the use of the transgenic FLP/FRT system of mitotic recombination. This system permits obtaining homozygous clones in the first generation after mutagenesis, whereas the cultures are set up after selection for potential meiotic mutations. This significantly enhances, the efficiency of screening by the elimination of the limiting stage. Using this method, the following mutations were revealed in the 3L arm of Drosophila: ff6leading to disturbed centriole disjunction, which results in appearance of multi-tail spermatids and three-pole spindles during male meiosis; ff3leading to the formation of chromosome bridges in anaphase and telophase, chromosome nondisjunction, and premature chromatin condensation after metaphase; embryonic lethal ff29, with disturbed coordination between nuclear and centrosome cycles during syncytial cleavage; and a series of other mutations causing a wide spectrum of disturbances in male meiosis. Comparison of the proposed method with procedures of screening for yeast cell-cycle mutations showed that we succeeded in attaining the efficiency of screening in the Drosophilamodel close to that in the yeast model.     

Generation of Dhx9‐deficient clones in T‐cell development with a mitotic recombination technique

Mitotic recombination is an effective tool for generating mutant clones in somatic tissues. Because of difficulties associated with detecting and quantifying mutant clones in mice, this technique is limited to analysis of growth‐related phenotypes induced by loss function of tumor suppressor genes. Here, we used the polymorphic CD45.1/CD45.2 alleles on chromosome 1 as pan‐hematopoietic markers to track mosaic clones generated through mitotic recombination in developing T cells. We show that lineage‐specific mitotic recombination can be induced and reliably detected as CD45.1 or CD45.2 homozygous clones from the CD45.1/CD45.2 heterozygous background. We have applied this system in the analysis of a lethal mutation in the Dhx9 gene. Mosaic analysis revealed a stage‐specific role for Dhx9 during T‐cell maturation. Thus, the experimental system described in this study offers a practical means for mosaic analysis of germline mutations in the hematopoietic system. genesis 50:543–551, 2012. © 2011 Wiley Periodicals, Inc.     

Domain specific genetic mosaic system in the Drosophila eye

Genetic mosaic approach is commonly used in the Drosophila eye by completely abolishing or misexpressing a gene within a subset of cells to unravel its role during development. Classical genetic mosaic approach involves random clone generation in all developing fields. Consequently, a large sample size needs to be screened to generate and analyze clones in specific domains of the developing eye. To address domain specific functions of genes during axial patterning, we have developed a system for generating mosaic clones by combining Gal4/UAS and flippase (FLP)/FRT system which will allow generation of loss‐of‐function as well as gain‐of‐function clones on the dorsal and ventral eye margins. We used the bifid‐Gal4 driver to drive expression of UAS‐FLP. This reagent can have multiple applications in (i) studying spatio‐temporal function of a gene during dorso‐ventral (DV) axis specification in the eye, (ii) analyzing genetic epistasis of genes involved in DV patterning, and (iii) conducting genome wide screens in a domain specific manner. genesis 51:68–74, 2013. © 2012 Wiley Periodicals, Inc.     

The development and function of the female germ line in Drosophila melanogaster: a cell lineage study.

X-ray-induced mitotic recombination was used to follow the development and function of the female germ line in Drosophila melanogaster. Clones marked by maternal effect mutations which alter the morphology of the egg [fs(1)K10] or the phenotype of the resulting progeny (maroonlike) were produced in trans-heterozygotes irradiated during embryonic, larval, or pupal development or as 5-day-old adults. Judging from the size of clones induced at the blastoderm stage, only five to ten of the pole cells observed on the surface of the embryo contribute to the germ line. Most of the K10 clones induced during embryonic and larval development were associated with mal twin spots, indicating that both daughters of the irradiated germ cell remained in the germ line and gave rise to eggs in the adult. During larval life the number of cells increases logarithmically and reaches a maximum of 110 at 24 hr after pupation. The same value was obtained for 5-day-old adults. In contrast to the mosaic females produced as embryos and larvae, mosaics obtained after pupal and adult irradiations were of two types, those laying only one K10 egg and those laying several K10 eggs distributed over the lifespan of the adult. This result indicates that the stem cell divisions characteristic of the adult period have begun shortly after pupation. About 9 to 11 days are required for an irradiated stem cell to produce its first clonal K10 egg, and two-thirds of this time is spent in the germarium. Each ovariole possesses on the average two to three functioning stem cells. This multiplicity of stem cells was confirmed by the recovery of mosaic ovarioles when mal heterozygotes irradiated as adults or late larvae were stained for aldehyde oxidase activity.     

The Notch locus of Drosophila is required in epidermal cells for epidermal development

The Notch locus of Drosophila plays an important role in cell fate decisions within the neurogenic ectoderm, a role thought to involve interactions at the cell surface. We have assayed the requirement for Notch gene expression in epidermal cells by two kinds of genetic mosaics. First, with gynandromorphs, we removed the wild-type gene long before the critical developmental events to produce large mutant clones. The genotype of cells in large clones was scored by means of an antibody to the Notch protein. Second, using mitotic recombination, we removed the gene at successively later times after completion of the mitotically active early cleavage stages, to produce small clones. These clones were detected by means of a linked mutation of cuticle pattern, armadillo. The results of both experiments demonstrate a requirement for Notch expression by epidermal cells, and thus argue against the model that the Notch product acts as a signal required only in the neuroblast to influence neighboring epidermal cells. The mitotic recombination experiment revealed that Notch product is required by epidermal cells subsequent to neuroblast delamination. This result implies that the Notch gene functions to maintain the determined state of epidermal cells, possibly by mediating cell surface interactions within the epidermis.     

Genetic engineering of mammalian cells by direct delivery of FLP recombinase protein

Protein transduction is based on the ability of certain peptides, designated as cell penetrating peptides (CPPs), to intracellularly deliver cargo molecules, such as peptides and proteins. In combination with site specific recombination, CPP-mediated delivery of recombinases enables a precise and highly efficient control of gene expression in cultured cells and mice. Herein, we provide detailed protocols for engineering and purification of a cell-permeant FLP recombinase protein. Two examples describe the use of cell permeant FLP for excising prespecified fragments from transgenes expressed in fibroblasts and mouse embryonic stem cells. A third example describes the combined use of cell-permeant Cre and FLP recombinases to reversibly induce transgenes in embryonic stem cells. We anticipate that the protocols described herein will be widely used for various genetic interventions addressing complex biological questions.     

Behaviour of cells mutant for an EGF receptor homologue of Drosophila in genetic mosaics

The Drosophila homologue of the epidermal growth factor receptor (DEGFr or DER, also called torpedo or top) has many mutant alleles that cause either embryonic lethality (both early and late), pupal lethality or female sterility, possibly corresponding to degrees of hypomorphism. We have studied the clonal behaviour of some lethal alleles in genetic mosaics in the imaginal development of thorax, head and tergite epidermis. These alleles cause reduced cell viability to different degrees (measured in frequency and size of clones), smaller cell sizes, abnormal patterning of sensory-organ differentiation and lack of differentiation of macro-chaetae and veins. These effects are cell-autonomous but also cause abnormal differentiation in wild-type cells surrounding the clones. In addition, we have studied the phenotypes of double mutant combinations of viable top alleles with wing-pattern mutants, some related to other Drosophila proto-oncogenes, to reveal gene interactions in the role(s) of DER in cell proliferation and differentiation. We discuss how those complex cell-behaviour phenotypes and genetic interactions are related to the molecular nature of the DER.     

Gonosomal mosaicism in myotonic dystrophy patients: involvement of mitotic events in (CTG)n repeat variation and selection against extreme expansion in sperm.

Myotonic dystrophy (DM) is caused by abnormal expansion of a polymorphic (CTG)n repeat, located in the DM protein kinase gene. We determined the (CTG)n repeat lengths in a broad range of tissue DNAs from patients with mild, classical, or congenital manifestation of DM. Differences in the repeat length were seen in somatic tissues from single DM individuals and twins. Repeats appeared to expand to a similar extent in tissues originating from the same embryonal origin. In most male patients carrying intermediate- or small-sized expansions in blood, the repeat lengths covered a markedly wider range in sperm. In contrast, male patients with large allele expansions in blood (> 700 CTGs) had similar or smaller repeats in sperm, when detectable. Sperm alleles with > 1,000 CTGs were not seen. We conclude that DM patients can be considered gonosomal mosaics, i.e., combined somatic and germ-line tissue mosaics. Most remarkably, we observed multiple cases where the length distributions of intermediate- or small-sized alleles in fathers'' sperm were significantly different from that in their offspring''s blood. Our combined findings indicate that intergenerational length changes in the unstable CTG repeat are most likely to occur during early embryonic mitotic divisions in both somatic and germ-line tissue formation. Both the initial CTG length, the overall number of cell divisions involved in tissue formation, and perhaps a specific selection process in spermatogenesis may influence the dynamics of this process. A model explaining mitotic instability and sex-dependent segregation phenomena in DM manifestation is discussed.