GFP labeling of neurosecretory cells with the GAL4/UAS system in the silkmoth brain enables selective intracellular staining of neurons

The microbrain of the silkmoth, Bombyx mori, is a model system for analyzing the neural mechanisms underlying stimulus-driven behavior, and numerous studies using physiological and morphological methods have accumulated. However, one of the limitations of this system is a lack of methodology for labeling specific subsets of neurons. Targeted gene expression with the GAL4/UAS system, which was recently developed, may overcome this disadvantage. To test the GAL4/UAS system in the silkmoth brain, we generated two GAL4 driver lines in which GAL4 expression was under the control of either the bombyxin or prothoracicotropic hormone (PTTH) promoter. Crosses of moths from these lines with a UAS-GFP line showed that green fluorescent protein (GFP) was exclusively expressed in bombyxin or PTTH neurosecretory brain cells. Using these lines, we developed a visually guided method to selectively insert an electrode into and intracellulary stain GFP-expressing cells using fluorescence as a landmark. This work provides a novel method to visualize specific subsets of neurons in the silkmoth brain and to observe detailed structures in a single identified neuron from different individuals.     

Conversion of lacZ enhancer trap lines to GAL4 lines using targeted transposition in Drosophila melanogaster

Since the development of the enhancer trap technique, many large libraries of nuclear localized lacZ P-element stocks have been generated. These lines can lend themselves to the molecular and biological characterization of new genes. However they are not as useful for the study of development of cellular morphologies. With the advent of the GAL4 expression system, enhancer traps have a far greater potential for utility in biological studies. Yet generation of GAL4 lines by standard random mobilization has been reported to have a low efficiency. To avoid this problem we have employed targeted transposition to generate glial-specific GAL4 lines for the study of glial cellular development. Targeted transposition is the precise exchange of one P element for another. We report the successful and complete replacement of two glial enhancer trap P[lacZ, ry+] elements with the P[GAL4, w+] element. The frequencies of transposition to the target loci were 1.3% and 0.4%. We have thus found it more efficient to generate GAL4 lines from preexisting P-element lines than to obtain tissue-specific expression of GAL4 by random P-element mobilization. It is likely that similar screens can be performed to convert many other P-element lines to the GAL4 system.     

Spatial and Temporal Control of Gene Expression in Drosophila Using the Inducible GeneSwitch GAL4 System. I. Screen for Larval Nervous System Drivers

There is a critical need for genetic methods for the inducible expression of transgenes in specific cells during development. A promising approach for this is the GeneSwitch GAL4 system of Drosophila. With GeneSwitch GAL4 the expression of upstream activating sequence (UAS) effector lines is controlled by a chimeric GAL4 protein that becomes active in the presence of the steroid RU486 (mifepristone). To improve the utility of this expression system, we performed a large-scale enhancer-trap screen for insertions that yielded nervous system expression. A total of 204 GeneSwitch GAL4 lines with various larval expression patterns in neurons, glia, and/or muscle fibers were identified for chromosomes I-III. All of the retained lines show increased activity when induced with RU486. Many of the lines reveal novel patterns of sensory neurons, interneurons, and glia. There were some tissue-specific differences in background expression, with muscles and glia being more likely to show activity in the absence of the inducing agent. However, >90% of the neuron-specific driver lines showed little or no background activity, making them particularly useful for inducible expression studies.     

GAL4 GFP enhancer trap lines for analysis of stomatal guard cell development and gene expression

To facilitate the monitoring of guard cells during developmentand isolation, a population of 704 GAL4 GFP enhancer trap lineswas screened and four single insert lines with guard cell GFPexpression and one with developmentally-regulated guard cellGFP expression were identified. The location of the T-DNA inserts,the expression of the flanking genes, and the promoter activityof the genomic DNA upstream of the T-DNA were characterized.The results indicated that the GFP expression pattern in atleast one of the lines was due to elements in the intergenicDNA immediately upstream of the T-DNA, rather than due to theactivity of the promoters of genes flanking the insert, andprovide evidence for the involvement of Dof elements in regulatingguard cell gene expression. It is shown further that the GAL4GFP lines can be used to track the contribution of guard cellmaterial in vitro, and this method was used to assess the purityof guard cell samples obtained using two methods of guard cellisolation. Key words: Arabidopsis, development, enhancer trap, GFP, guard cells, stomata, T-DNA Received 21 July 2008; Revised 7 October 2008 Accepted 16 October 2008     

GAL4/UAS系统在转基因技术中的应用研究进展

GAL4/UAS系统是一种转基因技术体系,其原理是利用特定的启动子或增强子,以组织特异性的方式激活酵母转录激活子GAL4的表达,GAL4又以同样的方式引起GAL4反应元件(UAS)-靶基因的转录。GAL4/UAS系统的关键点在于:GAL4基因和UAS-靶基因分别存在于两个转基因系中。GAL4转基因系中有转录激活子,但没有靶基因;在UAS-靶基因系中,转录激活子不存在,因而靶基因处于沉默状态,只有将GAL4转基因系与UAS-靶基因系进行杂交,才可能产生表达靶基因的后代。本文综述了GAL4/UAS系统的建立及其研究应用。     

Effects of Single P-Element Insertions on Olfactory Behavior in Drosophila Melanogaster

Single P-element (P[lArB]) insertional mutagenesis of an isogenic strain was used to identify autosomal loci affecting odor-guided behavior of Drosophila melanogaster. The avoidance response to benzaldehyde of 379 homozygous P[lArB] element-containing insert lines was evaluated quantitatively. Fourteen smell impaired (smi) lines were identified in which P[lArB] element insertion caused different degrees of hyposmia in one or both sexes. The smi loci map to different cytological locations and probably are novel olfactory genes. Enhancer trap analysis of the smi lines indicates that expression of at least 10 smi genes is controlled by olfactory tissue-specific promoter/enhancer elements.