The Tol2-mediated Gal4-UAS method for gene and enhancer trapping in zebrafish

The Gal4-UAS system provides powerful tools to analyze the function of genes and cells in vivo and has been extensively employed in Drosophila. The usefulness of this approach relies on the P element-mediated Gal4 enhancer trapping, which can efficiently generate transgenic fly lines expressing Gal4 in specific cells. Similar approaches, however, had not been developed in vertebrate systems due to the lack of an efficient transgenesis method. We have been developing transposon techniques by using the madaka fish Tol2 element. Taking advantage of its ability to generate genome-wide insertions, we developed the Gal4 gene trap and enhancer trap methods in zebrafish that enabled us to create various transgenic fish expressing Gal4 in specific cells. The Gal4-expressing cells can be visualized and manipulated in vivo by crossing the transgenic Gal4 lines with transgenic lines carrying various reporter and effector genes downstream of UAS (upstream activating sequence). Thus, the Gal4 gene trap and enhancer trap methods together with UAS lines now make detailed analyses of genes and cells in zebrafish feasible. Here, we describe the protocols to perform Gal4 gene trap and enhancer trap screens in zebrafish and their application to the studies of vertebrate neural circuits.     

Targeted gene expression by the Gal4-UAS system in zebrafish

Targeted gene expression by the Gal4-UAS system is a powerful methodology for analyzing function of genes and cells in vivo and has been extensively used in genetic studies in Drosophila . On the other hand, the Gal4-UAS system had not been applied effectively to vertebrate systems for a long time mainly due to the lack of an efficient transgenesis method. Recently, a highly efficient transgenesis method using the medaka fish Tol2 transposable element was developed in zebrafish. Taking advantage of the Tol2 transposon system, we and other groups developed the Gal4 gene trap and enhancer trap methods and established various transgenic fish expressing Gal4 in specific cells. By crossing such Gal4 lines with transgenic fish lines harboring various reporter genes and effector genes downstream of UAS (upstream activating sequence), specific cells can be visualized and manipulated in vivo by targeted gene expression. Thus, the Gal4 gene trap and enhancer trap approaches together with various UAS lines should be important tools for investigating roles of genes and cells in vertebrates.     

Development of the bi-partite Gal4-UAS system in the African malaria mosquito, Anopheles gambiae

Functional genetic analysis in Anopheles gambiae would be greatly improved by the development of a binary expression system, which would allow the more rapid and flexible characterisation of genes influencing disease transmission, including those involved in insecticide resistance, parasite interaction, host and mate seeking behaviour. The Gal4-UAS system, widely used in Drosophila melanogaster functional genetics, has been significantly modified to achieve robust application in several different species. Towards this end, previous work generated a series of modified Gal4 constructs that were up to 20 fold more active than the native gene in An. gambiae cells. To examine the Gal4-UAS system in vivo, transgenic An. gambiae driver lines carrying a modified Gal4 gene under the control of the carboxypeptidase promoter, and responder lines carrying UAS regulated luciferase and eYFP reporter genes have been created. Crossing of the Gal4 and UAS lines resulted in progeny that expressed both reporters in the expected midgut specific pattern. Although there was minor variation in reporter gene activity between the different crosses examined, the tissue specific expression pattern was consistent regardless of the genomic location of the transgene cassettes. The results show that the modified Gal4-UAS system can be used to successfully activate expression of transgenes in a robust and tissue specific manner in Anopheles gambiae. The midgut driver and dual reporter responder constructs are the first to be developed and tested successfully in transgenic An. gambiae and provide the basis for further advancement of the system in this and other insect species.     

Characterization of a dorsal‐eye Gal4 Line in Drosophila

In Drosophila, the Gal4‐UAS system is used to drive ectopic gene expression in a tissue‐specific manner. In this system, transgenic flies expressing tissue specific Gal4 are crossed to a line in which the gene to be expressed is under the control of a Gal4‐responsive UAS sequence. The resulting progeny express the gene of interest in the pattern of the particular Gal4 line. Since a given UAS‐transgene can be driven by any Gal4 line, this system is predominantly limited by available Gal4 lines. Here we report the characterization of a novel line, DE‐Gal4, which in the eye is expressed in the dorsal compartment for the majority of development. Furthermore, we use functional tests to show that the DE‐Gal4 line is a useful tool with which to manipulate gene expression in half of the developing eye. genesis 48:3–7, 2010. © 2009 Wiley‐Liss, Inc.     

Gal80~(ts)与Gal4组合灵敏控制果蝇中UAS转基因的表达水平

【目的】Gal80~(ts)与Gal4组合驱动UAS转基因表达是黑腹果蝇Drosophila melanogaster研究中常用的转基因过表达遗传学工具,通过温度控制实现对UAS转基因表达的灵活开关。Gal80~(ts)是一种温度敏感型蛋白,低温下(18℃)与Gal4蛋白结合并抑制其转录活力,高温下(29℃)解除对Gal4的抑制,从而允许Gal4结合UAS位点,启动UAS转基因的表达。但是从18~29℃的开关只能强烈过表达UAS转基因,而不能灵活调控转基因的表达水平。本实验系统研究一系列温度下转基因的表达水平,从而实现该体系对转基因的表达水平的灵活控制。【方法】以果蝇翅芽这一常用器官组织为研究模型,以2种Gal4品系(dpp-Gal4和en-Gal4,分别由decapentaplgic和engrailed基因的启动子驱动)分别与tub-Gal80~(ts)(微管蛋白基因tubulin启动子驱动)基因重组后,再分别与UAS-wg(wingless)转基因品系杂交;在一系列温度(18,25,27.5,28,28.5和30℃)下进行子代幼虫培养,通过免疫组化染色揭示并量化分析转基因wg在3龄幼虫翅芽上的表达水平。【结果】18~25℃培养条件下,Gal80~(ts)与Gal4组合系统中的UAS转基因不能表达;30℃时培养,转基因强烈地过表达;在25~30℃区间内,随着温度升高,转基因表达水平逐渐上升。【结论】在25~30℃之间的温度调控可以实现对Gal80~(ts)与Gal4组合系统中的UAS转基因表达水平的调控。本研究结果对调控转基因表达程度有重要价值。     

Efficient activation of gene expression using a heat-shock inducible Gal4/Vp16-UAS system in medaka

Background

Genetic interference by DNA, mRNA or morpholino injection is a widely used approach to study gene function in developmental biology. However, the lack of temporal control over the activity of interfering molecules often hampers investigation of gene function required during later stages of embryogenesis. To elucidate the roles of genes during embryogenesis a precise temporal control of transgene expression levels in the developing organism is on demand.

Results

We have generated a transgenic Gal4/Vp16 activator line that is heat-shock inducible, thereby providing a tool to drive the expression of specific effector genes via Gal4/Vp16. Merging the Gal4/Vp16-UAS system with the I-SceI meganuclease and the Sleeping Beauty transposon system allows inducible gene expression in an entirely uniform manner without the need to generate transgenic effector lines. Combination of this system with fluorescent protein reporters furthermore facilitates the direct visualization of transgene expressing cells in live embryos.

Conclusion

The combinatorial properties of this expression system provide a powerful tool for the analysis of gene function during embryonic and larval development in fish by ectopic expression of gene products.

     

Behavioral responses to odorants in drosophila require nervous system expression of the beta integrin gene myospheroid

Integrins are cell adhesion molecules that mediate numerous developmental processes in addition to a variety of acute physiological events. Two reports implicate a Drosophila beta integrin, betaPS, in olfactory behavior. To further investigate the role of integrins in Drosophila olfaction, we used Gal4-driven expression of RNA interference (RNAi) transgenes to knock down expression of myospheroid (mys), the gene that encodes betaPS. Expression of mys-RNAi transgenes in the wing reduced betaPS immunostaining and produced morphological defects associated with loss-of-function mutations in mys, demonstrating that this strategy knocked down mys function. Expression of mys-RNAi transgenes in the antennae, antennal lobes, and mushroom bodies via two Gal4 lines, H24 and MT14, disrupted olfactory behavior but did not alter locomotor abilities or central nervous system structure. Olfactory behavior was normal in flies that expressed mys-RNAi transgenes via other Gal4 lines that specifically targeted the antennae, the projection neurons, the mushroom bodies, bitter and sweet gustatory neurons, or Pox neuro neurons. Our studies confirm that mys is important for the development or function of the Drosophila olfactory system. Additionally, our studies demonstrate that mys is required for normal behavioral responses to both aversive and attractive odorants. Our results are consistent with a model in which betaPS mediates events within the antennal lobes that influence odorant sensitivity.     

Transgene expression in zebrafish: A comparison of retroviral-vector and DNA-injection approaches.

To assess alternative methods for introducing expressing transgenes into the germ line of zebrafish, transgenic fish that express a nuclear-targeted, enhanced, green fluorescent protein (eGFP) gene were produced using both pseudotyped retroviral vector infection and DNA microinjection of embryos. Germ-line transgenic founders were identified and the embryonic progeny of these founders were evaluated for the extent and pattern of eGFP expression. To compare the two modes of transgenesis, both vectors used the Xenopus translational elongation factor 1-alpha enhancer/promoter regulatory cassette. Several transgenic founder fish which transferred eGFP expression to their progeny were identified. The gene expression patterns are described and compared for the two modes of gene transfer. Transient expression of eGFP was detected 1 day after introducing the transgenes via either DNA microinjection or retroviral vector infection. In both cases of gene transfer, transgenic females produced eGFP-positive progeny even before the zygotic genome was turned on. Therefore, GFP was being provided by the oocyte before fertilization. A transgenic female revealed eGFP expression in her ovarian follicles. The qualitative patterns of gene expression in the transgenic progeny embryos after zygotic induction of gene expression were similar and independent of the mode of transgenesis. The appearance of newly synthesized GFP is detectable within 5-7 h after fertilization. The variability of the extent of eGFP expression from transgenic founder to transgenic founder was wider for the DNA-injection transgenics than for the retroviral vector-produced transgenics. The ability to provide expressing germ-line transgenic progeny via retroviral vector infection provides both an alternative mode of transgenesis for zebrafish work and a possible means of easily assessing the insertional mutagenesis frequency of retroviral vector infection of zebrafish embryos. However, because of the transfer of GFP from oocyte to embryo, the stability of GFP may create problems of analysis in embryos which develop as quickly as those of zebrafish.