A Drosophila melanogaster cell line (S2) facilitates post-genome functional analysis of receptors and ion channels

The complete sequencing of the genome of the fruit fly Drosophila melanogaster offers the prospect of detailed functional analysis of the extensive gene families in this genetic model organism. Comprehensive functional analysis of family members is facilitated by access to a robust, stable and inducible expression system in a fly cell line. Here we show how the Schneider S2 cell line, derived from the Drosophila embryo, provides such an expression system, with the bonus that radioligand binding studies, second messenger assays, ion imaging, patch-clamp electrophysiology and gene silencing can readily be applied. Drosophila is also ideal for the study of new control strategies for insect pests since the receptors and ion channels that many new animal health drugs and crop protection chemicals target can be expressed in this cell line. In addition, many useful orthologues of human disease genes are emerging from the Drosophila genome and the study of their functions and interactions is another area for postgenome applications of S2 cell lines.     

果蝇蛋白质组学研究进展

蛋白质组学旨在阐明基因组所表达的真正执行生命活动的全部蛋白质的表达规律和生物功能。随着人类基因组学计划的逐渐成熟,分子水平的实验技术不断发展,蛋白质组学的研究被提高到了前所未有的高度。果蝇是生命科学领域最为常用的一种模式生物,长期的系统研究也使果蝇的基因组成为至今注释最好的基因组之一,为功能基因组研究奠定了基础。但由于技术的限制,迄今有关果蝇蛋白质组学研究的报道尚不多见。近年来果蝇蛋白质组学的研究主要包括表达谱、修饰谱、比较蛋白质组学和疾病模型蛋白质组等四个方向,为进一步开展人类疾病临床蛋白质组学研究奠定了基础。     

Characterization of the adenosine deaminase-related growth factor (ADGF) gene family in Drosophila

A novel family of growth factors, with sequence similarity to adenosine deaminase, has been identified in various organisms including flesh fly, tsetse fly, sand fly, mollusk and human. The human homologue, CECR1, is a candidate gene for the genetic disorder cat eye syndrome. Here, we describe six members of this growth factor family in Drosophila and two in vertebrates. The six Drosophila genes, named adenosine deaminase-related growth factors (ADGF), are found at three different chromosomal locations, with one singleton, two in an inverted orientation, and three in a tandem arrangement. These genes show distinct patterns of expression as measured by RT-PCR and Northern blots, indicating gene-specific function. The presence of six ADGF genes in the Drosophila genome suggests that gene duplication and divergence has been important for these growth factors in insect development. Phylogenetic analysis of the 14 extant ADGF-like gene products shows there are at least three major groups, two of which are found in Drosophila. The third appears specific to the vertebrate line. Seven gene duplications are inferred among the ADGF-like genes, most of which occurred long before the origin of Drosophila. Our analysis predicts the existence of several other unsampled ADGF-like genes, both within the species examined here, and in other related invertebrates.     

Using Drosophila as a model insect

The fruit fly Drosophila melanogaster has become such a popular model organism for studying human disease that it is often described as a little person with wings. This view has been strengthened with the sequencing of the Drosophila genome and the discovery that 60% of human disease genes have homologues in the fruit fly. In this review, I discuss the approach of using Drosophila not only as a model for metazoans in general but as a model insect in particular. Specifically, I discuss recent work on the use of Drosophila to study the transmission of disease by insect vectors and to investigate insecticide function and development.     

Of flies and men; p53, a tumour suppressor

The completion of the Drosophila genome sequencing project [Science 287 (2000) 2185] has reconfirmed the fruit fly as a model organism to study human disease. Comparison studies have shown that two thirds of genes implicated in human cancers have counterparts in the fly [Curr. Opin. Genet. Dev. 11 (2001) 274; J. Cell Biol. 150 (2000) F23], including the tumour suppressor, p53. The suitability of the fruit fly to study the function of the tumour suppressor p53 is further exemplified by the lack of p53 family members within the fly genome, i.e., no homologues to p63 and p73 have been identified. Hence, there is no redundancy between family members greatly facilitating the analysis of p53 function. In addition, studying p53 in Drosophila provides an opportunity to learn about the evolution of tumour suppressors. Here, we will discuss what is known about Drosophila p53 in relation to human p53.     

DroPhEA: Drosophila phenotype enrichment analysis for insect functional genomics

SUMMARY: DroPhEA is a core module of a web application that facilitates research in insect functional genomics through enrichment analysis on mutant phenotypes of fruit fly (Drosophila melanogaster). The phenotypes investigated in the analyses can be predefined by FlyBase or customized by users. DroPhEA allows users to specify mutation or ortholog types, displays enriched term results in a hierarchical structure and supports analyses on gene sets of all insect species with a fully sequenced genome.     

CRISPR/Cas9 and Genome Editing in Drosophila

Recent advances in our ability to design DNA binding factors with specificity for desired sequences have resulted in a revolution in genetic engineering, enabling directed changes to the genome to be made relatively easily. Traditional techniques for generating genetic mutations in most organisms have relied on selection from large pools of randomly induced mutations for those of particular interest, or time-consuming gene targeting by homologous recombination. Drosophila melanogaster has always been at the forefront of genetic analysis, and application of these new genome editing techniques to this organism will revolutionise our approach to performing analysis of gene function in the future. We discuss the recent techniques that apply the CRISPR/Cas9 system to Drosophila, highlight potential uses for this technology and speculate upon the future of genome engineering in this model organism.     

Functional analysis of Drosophila melanogaster BRCA2 in DNA repair

The human BRCA2 cancer susceptibility protein functions in double-strand DNA break repair by homologous recombination and this pathway is conserved in the fly Drosophila melanogaster. Although a potential Drosophila melanogaster BRCA2 orthologue (dmbrca2; CG30169) has been identified by sequence similarity, no functional data addressing the role of this protein in DNA repair is available. Here, we demonstrate that depletion of dmbrca2 from Drosophila cells induces sensitivity to DNA damage induced by irradiation or treatment with hydroxyurea. Dmbrca2 physically interacts with dmrad51 (spnA) and the two proteins become recruited to nuclear foci after DNA damage. A functional assay for DNA repair demonstrated that in flies dmbrca2 plays a role in double-strand break repair by gene conversion. Finally, we show that depletion of dmbrca2 in cells is synthetically lethal with deficiency in other DNA repair proteins including dmparp. The conservation of the function of BRCA2 in Drosophila will allow the analysis of this key DNA repair protein in a genetically tractable organism potentially illuminating mechanisms of carcinogenesis and aiding the development of therapeutic agents.     

Approach for functional analysis of glycan using RNA interference

The elucidation of the biological role of glycan is one of the most important issues to be resolved following the genome project. RNA interference is becoming an efficient reverse genetic tool for studying gene function in model organisms, including C.elegans and Drosophila melanogaster. Our molecular evolutionary study has shown that a prototype of glycosyltransferases, which synthesize a variety of glycan structures in the Golgi apparatus, was conserved between mammals and Drosophila. For analyses of the basic physiological functions of glycans, we established the Drosophila inducible RNAi knockdown system and applied it to one glycosyltransferase and one transporter, proteoglycan UDP-galactose: beta-xylose beta1,4galactosyltransferase I and the PAPS-transporter, respectively. If on the silencing of each gene induced ubiquitously under the control of a cytoplasmic actin promoter, the RNAi knockdown fly died, then the protein was indispensable for life. The expression of the target gene was disrupted specifically and the degree of interference was well correlated with the phenotype. The inducible RNAi knockdown fly obtained using the GAL4-UAS system will pave the way for the functional analysis of glycans.     

Glycobiology on the fly: developmental and mechanistic insights from Drosophila

Drosophila melanogaster offers many unique advantages for deciphering the complexities of glycan biosynthesis and function. The completion of the Drosophila genome sequencing project as well as the comprehensive catalogue of existing mutations and phenotypes have lead to a prolific database where many of the genes involved in glycan synthesis, assembly, modification, and recognition have been identified and characterized. Recent biochemical and molecular studies have elucidated the structure of the glycans present in Drosophila. Powerful genetic approaches have uncovered a number of critical biological roles for glycans during development that impact on our understanding of their function during mammalian development. Here, we summarize key recent findings and provide evidence for the usefulness of this model organism in unraveling the complexities of glycobiology across many species.     

Progress inDrosophila genome manipulation

The introduction of cloned and manipulated genetic material into the germline of an experimental organism is one of the most powerful tools of modern biology. In the case of the fruit fly,Drosophila melanogaster, there is also an unparalleled range of sophisticated genetic tools to facilitate subsequent analysis. In consequence,Drosophila remains a most favourable model organism for the dissection of gene structure and functionin vivo. In this review we look at some of the achievements to date inDrosophila genome manipulation, and at what may be possible in the near future.     

Using the P[wHy] hybrid transposable element to disrupt genes in region 54D-55B in Drosophila melanogaster

Understanding the function of each gene in the genome of a model organism such as Drosophila melanogaster is an important goal. The development of improved methods for uncovering the mutant phenotypes of specific genes can accelerate achievement of this goal. The P[wHy] hybrid transposable element can be used to generate nested sets of precisely mapped deletions in a given region of the Drosophila genome. Here we use the P[wHy] method to generate overlapping, molecularly defined deletions from a set of three P[wHy] insertions in the 54E-F region of chromosome 2. Deletions that span a total of 0.5 Mb were identified and molecularly mapped precisely. Using overlapping deletions, the mutant phenotypes of nine previously uncharacterized genes in a 101-kb region were determined, including identification of new loci required for viability and female fertility. In addition, the deletions were used to molecularly map previously isolated lethal mutations. Thus, the P[wHy] method provides an efficient method for systematically determining the phenotypes of genes in a given region of the fly genome.     

Transposable elements as tools for genomics and genetics in Drosophila.

The P-element has been the workhorse of Drosophila genetics since it was developed as a tool for transgenesis in 1982; the subsequent development of a variety of systems based on the transposon have provided a range of powerful and flexible tools for genetics and genomics applications. P-element insertions are frequently used as starting-points for generating chromosomal deletions to remove flanking genes, either by screening for imprecise excision events or by selecting for male recombination events. Elements that utilise the yeast FLP/FLP recombination target (FRT) site-specific recombination system have been widely used to generate molecularly marked mitotic clones for mosaic analysis, extending the reach of this powerful genetic tool to virtually all areas of developmental biology. P-elements are still widely used as traditional mutagenesis reagents and form the backbone of projects aimed at generating insertions in every predicted gene in the fly genome. In addition, vectors based on the FLP/FRT system are being used for genome-wide applications, including the development of molecularly-mapped deletion and duplication kits. In addition to these 'traditional' genetic approaches, a variety of engineered elements have been developed for a wide range of transgenic applications, including enhancer trapping, gene-tagging, targeted misexpression, RNA interference (RNAi) delivery and homologous recombination/gene replacement. To complement the use of P-elements, alternative transposon vectors have been developed. The most widely used of these are the lepidopteran element piggyBac and a Drosophila hydei transposon, Minos. In total, a range of transposon vectors offers the Drosophila biologist considerable flexibility and sophistication in manipulating the genome of the fly and has allowed rapid advances in all areas of developmental biology and genome science.     

Genome, evolution, Drosophila and beyond: the new dimensions

A century ago a little fly with red eyes was first used for genetic studies. That insignificant fly, called at that time Drosophila ampelophila, revolutionized biology while becoming the model we know today under the name of Drosophila melanogaster. Since then its study has never ceased, but the field of interest has somewhat changed during the century. To caricature a little, today we essentially learn from Drosophila meetings that the fly has a brain! It is true that the fly is a tremendous model organism for neurobiology. But this fly is, in fact, an appropriate and recognized model for the whole of biology. Indeed, Drosophila meetings are exceptional opportunities to gather biologists of diverse backgrounds together. There we not only learn about the latest improvements in our field of interest, but surely appreciate learning another bit of biology. From this biological melting pot has emerged a culture very specific to the fly community. Thus besides neurobiology, cell biology and development, a diversity of other research fields exist; they all have their own place in the cultural and historical dimension of the "drosophila" model. Several communications from those diverse research fields were presented at the 8th Japanese Drosophila Research Conference (JDRC8) and are briefly covered here. We believe it more judicious to call the model "drosophila" without a capital initial, as the model has never really been limited to only the Drosophila genus. The vernacular name "drosophila" is currently used to designate any fly of the Drosophilidae family and we believe the term more appropriate than "small fruit fly" or "vinegar fly" to better include the species and ecological diversity of the model.     

Drosophila, an emerging model for cardiac disease

A variety of studies that are currently underway may validate the fruit fly as an in vivo model for analyzing genes involved in cardiac function. Many mutations in conserved genetic pathways have been found, including those controlling development and physiology. Because homologous genes control early developmental events as well as functional components of the Drosophila and vertebrate hearts, the fly is the simplest existing model system that can be used to assay genes involved in human congenital heart disease (CHD). The wide variety of genetic tools available to Drosophila researchers offers many technical advantages for rapidly screening through large numbers of candidate genes. Thus, an important future and long-term direction is likely to be the use of Drosophila as a vehicle for analyzing polygenic traits as an aid in human genetics. One can anticipate a time in the not too distant future when mutant lines exist for every gene in vertebrate systems, such as mice and zebrafish. However, one of the enduring problems that will not easily be addressed by such resources will be the tracking of complex traits defined by polygenic variants. For this level of genetic analysis, simple genetic model systems including yeast, Caenorhabditis elegans, and Drosophila melanogaster will undoubtedly play a crucial ongoing role. Of them, Drosophila will be critical for examining gene networks involved in organogenesis and is clearly the system of choice for studying cardiac development, function and aging, since among the simple genetic models it is the only one with a fluid pumping heart.     

Bacillus species proteins involved in spore formation and degradation: from identification in the genome,to sequence analysis,and determination of function and structure

The members of Bacillus species are Gram-positive, ubiquitous spore-forming bacilli. Several genomic sequences have been made available during recent years, including Bacillus subtilis, a model organism among this genus, Bacillus anthracis, and their analyses provided a wealth of information about spore-forming bacteria. Some members of this species can cause serious diseases in livestock and humans. An important pathogen in this group of organisms is B. anthracis, which is the causative agent of anthrax. A summary of the B. subtilis genome information, based on the publicly released sequence, that allowed for the identification and characterization of new and novel proteins of this organism as well as similar proteins from other members of Bacillus species is provided. The primary goal for this work is to present a review of the genome sequence-identified genes that encode proteins involved in the sporulation, germination, and outgrowth processes. These three processes are essential for spore development and later its transformation into a vegetative cell. Additionally, for a few selected examples of the protein products of the identified genes, the application of bioinformatics and modeling tools is illustrated in order to determine their likely structure and function. Two three-dimensional models of the structures of such proteins, PrfA endonuclease and phosphatase PhoE, are presented together with the structure-based functional conclusions. The review of such studies provides an example of how the genomic sequence can be utilized in order to elucidate the structure and function of proteins, in particular proteins of the Bacillus species. Because only a limited number of proteins of Bacillus species organisms are involved in the synthesis and degradation of spores and have been characterized to date, this genome-based analysis may provide new insights into the developmental processes of bacterial organism.