Neural Specificity of elav Expression: Defining a Drosophila Promoter for Directing Expression to the Nervous System

Abstract: The Drosophila melanogaster vital gene, embryonic lethal abnormal visual system (elav), is required for the postdeterminative development of the nervous system. Its gene product encodes an RNA binding protein that was found to be expressed in all neurons right after their birth. This specific, ubiquitous, and continuous pattern of neural expression has led to the increasingly popular use of ELAV protein as a neural-specific marker. To understand the molecular basis of this neural-specific expression, we have defined and analyzed the structure of the elav promoter. Cis-acting sequences important for conferring the neural specificity of elav expression were identified by analyzing the reporter gene expression in transformants carrying different elav -β- galactosidase fusion, genes. This analysis delimits a 333-bp region (−92 to +241) that is necessary for specifying the elav pattern of nervous system expression. A 3.5-kb promoter fragment encompassing this region was designed for targeting gene expression specifically to the nervous system and would be a useful tool for the analysis of nervous system function.     

Evidence for 3' untranslated region-dependent autoregulation of the Drosophila gene encoding the neuronal nuclear RNA-binding protein ELAV.

The Drosophila locus embryonic lethal abnormal visual system (elav) encodes a nuclear RNA-binding protein essential for normal neuronal differentiation and maintenance of neurons. ELAV is thought to play its role by binding to RNAs produced by other genes necessary for neuronal differentiation and consequently to affect their metabolism by an as yet unknown mechanism. ELAV structural homologues have been identified in a wide range of organisms, including humans, indicating an important conserved role for the protein. Analysis of elav germline transformants presented here shows that one copy of elav minigenes lacking a complete 3'' untranslated region (3'' UTR) rescues null mutations at elav, but that two copies are lethal. Additional in vivo experiments demonstrate that elav expression is regulated through the 3'' UTR of the gene and indicate that this level of regulation is dependent upon ELAV itself. Because ELAV is an RNA-binding protein, the simplest model to account for these findings is that ELAV binds to the 3'' UTR of its own RNA to autoregulate its expression. I discuss the implications of these results for normal elav function.     

ELAV, a Drosophila neuron-specific protein, mediates the generation of an alternatively spliced neural protein isoform

Background Tissue-specific alternative pre-mRNA splicing is a widely used mechanism for gene regulation and the generation of different protein isoforms, but relatively little is known about the factors and mechanisms that mediate this process. Tissue-specific RNA-binding proteins could mediate alternative pre-mRNA splicing. In Drosophila melanogaster, the RNA-binding protein encoded by the elav (embryonic lethal abnormal visual system) gene is a candidate for such a role. The ELAV protein is expressed exclusively in neurons, and is important for the formation and maintenance of the nervous system.Results In this study, photoreceptor neurons genetically depleted of ELAV, and elav-null central nervous system neurons, were analyzed immunocytochemically for the expression of neural proteins. In both situations, the lack of ELAV corresponded with a decrease in the immunohistochemical signal of the neural-specific isoform of Neuroglian, which is generated by alternative splicing. Furthermore, when ELAV was expressed ectopically in cells that normally express only the non-neural isoform of Neuroglian, we observed the generation of the neural isoform of Neuroglian.ConclusionsDrosophila ELAV promotes the generation of the neuron-specific isoform of Neuroglian by the regulation of pre-mRNA splicing. The findings reported in this paper demonstrate that ELAV is necessary, and the ectopic expression of ELAV in imaginal disc cells is sufficient, to mediate neuron-specific alternative splicing.     

The Drosophila RNA-binding protein ELAV is required for commissural axon midline crossing via control of commissureless mRNA expression in neurons

Drosophila ELAV is the founding member of an evolutionarily conserved family of RNA-binding proteins considered as key inducers of neuronal differentiation. Although several ELAV-specific targets have been identified, little is known about the role of elav during neural development. Here, we report a detailed characterization of the elav mutant commissural phenotype. The reduced number of commissures in elav mutant embryos is not due to loss or misspecification of neural cells but results from defects in commissural axon projections across the midline. We establish a causal relationship between the elav mutant commissural phenotype and a reduction in the expression of commissureless, a key component of the Robo/Slit growth cone repulsive signalling pathway. In the nerve cord of elav mutant embryos, comm mRNA expression is strongly reduced in neurons, but not in midline glial cells. Furthermore, specific expression of an elav transgene in posterior neurons of each segment of an elav mutant nerve cord restores comm mRNA expression in these cells, as well as the formation of posterior commissures. Finally, forced expression of comm in specific commissural neuron subsets rescues the midline crossing defects of these neurons in elav mutant embryos, further indicating that elav acts cell autonomously on comm expression.     

Concentration and Localization of Coexpressed ELAV/Hu Proteins Control Specificity of mRNA Processing

Neuronally coexpressed ELAV/Hu proteins comprise a family of highly related RNA binding proteins which bind to very similar cognate sequences. How this redundancy is linked to in vivo function and how gene-specific regulation is achieved have not been clear. Analysis of mutants in Drosophila ELAV/Hu family proteins ELAV, FNE, and RBP9 and of genetic interactions among them indicates that they have mostly independent roles in neuronal development and function but have converging roles in the regulation of synaptic plasticity. Conversely, ELAV, FNE, RBP9, and human HuR bind ELAV target RNA in vitro with similar affinities. Likewise, all can regulate alternative splicing of ELAV target genes in nonneuronal wing disc cells and substitute for ELAV in eye development upon artificially increased expression; they can also substantially restore ELAV''s biological functions when expressed under the control of the elav gene. Furthermore, ELAV-related Sex-lethal can regulate ELAV targets, and ELAV/Hu proteins can interfere with sexual differentiation. An ancient relationship to Sex-lethal is revealed by gonadal expression of RBP9, providing a maternal fail-safe for dosage compensation. Our results indicate that highly related ELAV/Hu RNA binding proteins select targets for mRNA processing through alteration of their expression levels and subcellular localization but only minimally by altered RNA binding specificity.     

Two Distinct Temperature-Sensitive Alleles at the Elav Locus of Drosophila Are Suppressed Nonsense Mutations of the Same Tryptophan Codon

The Drosophila gene elav encodes a 483-amino-acid-long nuclear RNA binding protein required for normal neuronal differentiation and maintenance. We molecularly analyzed the three known viable alleles of the gene, namely elav(ts1), elav(FliJ1), and elav(FliJ2), which manifest temperature-sensitive phenotypes. The modification of the elav(FliJ1) allele corresponds to the change of glycine(426) (GGA) into a glutamic acid (GAA). Surprisingly, elav(ts1) and elav(FliJ2) were both found to have tryptophan(419) (TGG) changed into two different stop codons, TAG and TGA, respectively. Unexpectedly, protein analysis from elav(ts1) and elav(FliJ2) reveals not only the predicted 45-kD truncated ELAV protein due to translational truncation, but also a predominant full-size 50-kD ELAV protein, both at permissive and nonpermissive temperatures. The full-length protein present in elav(ts1) and elav(FliJ2) can a priori be explained by one of several mechanisms leading to functional suppression of the nonsense mutation or by detection of a previously unrecognized ELAV isoform of similar size resulting from alternative splicing and unaffected by the stop codon. Experiments described in this article support the functional suppression of the nonsense mutation as the mechanism responsible for the full-length protein.     

Organizational analysis of elav gene and functional analysis of ELAV protein of Drosophila melanogaster and Drosophila virilis.

Drosophila virilis genomic DNA corresponding to the D. melanogaster embryonic lethal abnormal visual system (elav) locus was cloned. DNA sequence analysis of a 3.8-kb genomic piece allowed identification of (i) an open reading frame (ORF) with striking homology to the previously identified D. melanogaster ORF and (ii) conserved sequence elements of possible regulatory relevance within and flanking the second intron. Conceptual translation of the D. virilis ORF predicts a 519-amino-acid-long ribonucleoprotein consensus sequence-type protein. Similar to D. melanogaster ELAV protein, it contains three tandem RNA-binding domains and an alanine/glutamine-rich amino-terminal region. The sequence throughout the RNA-binding domains, comprising the carboxy-terminal 346 amino acids, shows an extraordinary 100% identity at the amino acid level, indicating a strong structural constraint for this functional domain. The amino-terminal region is 36 amino acids longer in D. virilis, and the conservation is 66%. In in vivo functional tests, the D. virilis ORF was indistinguishable from the D. melanogaster ORF. Furthermore, a D. melanogaster ORF encoding an ELAV protein with a 40-amino-acid deletion within the alanine/glutamine-rich region was also able to supply elav function in vivo. Thus, the divergence of the amino-terminal region of the ELAV protein reflects lowered functional constraint rather than species-specific functional specification.     

The locus elav of Drosophila melanogaster is expressed in neurons at all developmental stages

The locus elav (ella-vee) of Drosophila melanogaster, which is necessary for the proper development of the embryonic and adult nervous systems, has been characterized both genetically and molecularly. This locus has been shown to be transcribed exclusively within, and ubiquitously throughout, the developing nervous system during Hours 6 to 12 of embryogenesis. We present in situ RNA localization data which demonstrate that elav is expressed in the central nervous system as well as the peripheral nervous system of embryos, larvae, pupae, and adults. We also demonstrate that elav is not transcribed in embryonic or larval neuroblasts (the neuronal progenitor cells), or in at least one type of glial cell. These data provide evidence that the requirement for elav function is not limited to the 6- to 12-hr embryonic nervous system and the adult eye and developing optic lobe, but that its function is required for the development and continued maintenance of all neurons of the organism.     

黑腹果蝇头部中RNA结合蛋白RBP9的互作蛋白筛选

【目的】筛选RNA结合蛋白RBP9在黑腹果蝇Drosophila melanogaster头部中的互作蛋白。【方法】利用CRISPR/Cas9基因组编辑技术,分别将3×Flag和V5标签编码序列插入到黑腹果蝇成虫头中RBP9和FNE基因起始密码子ATG的后面,构建黑腹果蝇转基因品系3×Flag-RBP 9/3×Flag-RBP9(3FRBP9)和V5-FNE/V5-FNE(VFNE);利用免疫沉淀和质谱法鉴定黑腹果蝇3FRBP9和野生型品系成虫头部中RBP9的互作蛋白并进行生物信息学分析。利用免疫共沉淀方法检测RBP9与FNE蛋白之间的相互作用。【结果】质谱法从黑腹果蝇成虫头部共鉴定了190个与RBP9相互作用的蛋白,其中包括ELAV和FNE。KEGG富集分析显示这些蛋白的基因主要参与核糖体、碳代谢、三羧酸循环、氨基酸生物合成等通路。免疫共沉淀实验结果验证了RBP9与FNE蛋白之间存在相互作用。【结论】RNA结合蛋白ELAV家族成员在黑腹果蝇成虫头部中具有相互作用。本研究为RBP9在果蝇神经系统发育中的功能研究提供了重要实验依据。     

ELAV multimerizes on conserved AU4-6 motifs important for ewg splicing regulation

ELAV is a gene-specific regulator of alternative pre-mRNA processing in Drosophila neurons. Since ELAV/Hu proteins preferentially bind to AU-rich regions that are generally abundant in introns and untranslated regions, it has not been clear how gene specificity is achieved. Here we used a combination of in vitro biochemical experiments together with phylogenetic comparisons and in vivo analysis of Drosophila transgenes to study ELAV binding to the last ewg intron and splicing regulation. In vitro binding studies of ELAV show that ELAV multimerizes on the ewg binding site and forms a defined and saturable complex. Further, sizing of the ELAV-RNA complex and a series of titration experiments indicate that ELAV forms a dodecameric complex on 135 nucleotides in the last ewg intron. Analysis of the substrate RNA requirements for ELAV binding and complex formation indicates that a series of AU(4-6) motifs spread over the entire binding site are important, but not a strictly defined sequence element. The importance of AU(4-6) motifs, but not spacing between them, is further supported by evolutionary conservation in several melanogaster species subgroups. Finally, using transgenes we demonstrate in fly neurons that ELAV-mediated regulation of ewg intron 6 splicing requires several AU(4-6) motifs and that introduction of spacer sequence between conserved AU(4-6) motifs has a minimal effect on splicing. Collectively, our results suggest that ELAV multimerization and binding to multiple AU(4-6) motifs contribute to target RNA recognition and processing in a complex cellular environment.