Hybrid Neurons in a MicroRNA Mutant Are Putative Evolutionary Intermediates in Insect CO
            <sub>2</sub>
            Sensory Systems

Cayirlioglu, Pelin; Kadow, Ilona C. Grunwald; Zhan, Xiaoli; Okamura, Katsutomo; Suh, Greg S.B.; Gunning, Dorian; Lai, Eric C.; Zipursky, S. Lawrence

doi:10.1126/science.1149483

Cited by 98 publications

(155 citation statements)

References 19 publications

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“…Currently, most studies on insect CO2 receptors are focused on Drosophila or mosquitoes (Cayirlioglu et al 2008;Dahanukar et al 2007;Erdelyan et al 2012;Hartl et al 2011;Jones et al 2007;McMeniman et al 2014;Montell 2013;Turner and Ray 2009) and are aimed at discovering compounds for vector control that can modulate CO2 receptors in mosquitoes (Tauxe et al 2013;Turner and Ray 2009). Little attention has been paid to the CO2 receptors of agricultural pests.…”

Section: Introductionmentioning

confidence: 99%

“…For example, alternatives to heavy insecticide use, such as interfering with CO2 reception, would be helpful for controlling Helicoverpa armigera, which is one of the most destructive agricultural pests known (Sharm 2001). So far, insect CO2 receptors have only been functionally characterised in vivo using transgenic Drosophila, mutated mosquitoes or RNAi techniques (Cayirlioglu et al 2008;Dahanukar et al 2007;Erdelyan et al 2012;Hartl et al 2011;Jones et al 2007;McMeniman et al 2014;Montell 2013;Turner and Ray 2009). These approaches are not established for Lepidoptera.…”

Section: Introductionmentioning

confidence: 99%

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Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Xü

Anderson

2015

Sci Nat

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Carbon dioxide (CO2) is important in insect ecology, eliciting a range of behaviours across different species. Interestingly, the numbers of CO2 gustatory receptors (GRs) vary among insect species. In the model organism Drosophila melanogaster, two GRs (DmelGR21a and DmelGR63a) have been shown to detect CO2. In the butterfly, moth, beetle and mosquito species studied so far, three CO2 GR genes have been identified, while in tsetse flies, four CO2GR genes have been identified. In other species including honeybees, pea aphids, ants, locusts and wasps, no CO2 GR genes have been identified from the genome. These genomic differences may suggest different mechanisms for CO2 detection exist in different insects but, with the exception of Drosophila and mosquitoes, limited attention has been paid to the CO2GRs in insects. Here, we cloned three putative CO2 GR genes from the cotton bollworm Helicoverpa armigera and performed phylogenetic and expression analysis. All three H. armigera CO2 GRs (HarmGR1, HarmGR2 and HarmGR3) are specifically expressed in labial palps, the CO2-sensing tissue of this moth. HarmGR3 is significantly activated by NaHCO3when expressed in insect Sf9 cells but HarmGR1 and HarmGR2 are not. This is the first report characterizing the function of lepidopteran CO2 receptors, which contributes to our general understanding of the molecular mechanisms of insect CO2 gustatory receptors.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Xü

Anderson

2015

Sci Nat

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“…For example, both robo and lola are essential for axon guidance during development of the nervous system (17,18,27,28). Furthermore, mir-279 has been implicated in Drosophila in establishing the identity of CO 2 -detecting chemosensory neurons (29), and more generally, microRNAs have been implicated in neurodevelopment and morphogenesis (29)(30)(31)(32)(33). In addition, mir-317 is predicted to regulate ocelliless (34), which has been implicated in the development of the protocerebral bridge, a component of the central complex associated with locomotion (35).…”

Section: Number Of Linesmentioning

confidence: 99%

Neurogenetic networks for startle-induced locomotion in Drosophila melanogaster

Yamamoto

Zwarts

Callaerts

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

103

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Understanding how the genome empowers the nervous system to express behaviors remains a critical challenge in behavioral genetics. The startle response is an attractive behavioral model for studies on the relationship between genes, brain, and behavior, as the ability to respond rapidly to harmful changes in the environment is a universal survival trait. Drosophila melanogaster provides a powerful system in which genetic studies on individuals with controlled genetic backgrounds and reared under controlled environmental conditions can be combined with neuroanatomical studies to analyze behaviors. In a screen of 720 lines of D. melanogaster, carrying single P[GT1] transposon insertions, we found 267 lines that showed significant changes in startle-induced locomotor behavior. Excision of the transposon reversed this effect in five lines out of six tested. We infer that most of the 267 lines show mutant effects on startle-induced locomotion that are caused by the transposon insertions. We selected a subset of 15 insertions in the same genetic background in autosomal genes with strong mutant effects and crossed them to generate all 105 possible nonreciprocal double heterozygotes. These hybrids revealed an extensive network of epistatic interactions on the behavioral trait. In addition, we observed changes in neuroanatomy that were caused by these 15 mutations, individually and in their double heterozygotes. We find that behavioral and neuroanatomical phenotypes are determined by a common set of genes that are organized as partially overlapping genetic networks.behavioral genetics ͉ epistasis ͉ sensorimotor integration ͉ startle behavior ͉ P-element insertional mutagenesis A major goal of behavioral genetics is to understand the relationship between the genome and the nervous system. From a neuroscience perspective, behaviors represent the ultimate expression of the nervous system. From a genetics perspective, behaviors are complex traits for which natural variation is caused by many interacting genetic variants, with allelic effects that depend on social and external environments, sex, and genetic background (1, 2). To date, most studies that have attempted to relate genetic variation to the neural regulation of behavior have adopted a ''one gene at a time'' approach. Such studies have made important contributions and generated significant insights. However, recent genomic approaches, in which candidate genes affecting behaviors are identified by comparing whole-genome expression profiles of genetically divergent strains, have implicated large numbers of coregulated genes affecting behaviors that have pleiotropic effects on other traits, and that would not have been a priori predicted to affect behavior (3-10). In the current study, we used quantitative genetic approaches to analyze the genes-brain-behavior relationship at the level of genetic networks rather than at the level of single genes.We used startle-induced locomotion to a mechanical disturbance in Drosophila melanogaster as a model behavior. Previously, we...

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“…We note that misexpression of an antennal receptor in the maxillary palp was found to alter the chemosensory behavior of a fly (Shiraiwa 2008), illustrating the possibility that a change in organ specificity of Or expression could confer a selective advantage to the animal. Moreover, CO 2 reception apparently moved from one organ to the other during the evolution of the Dipterans; it also moved following experimental mutation of a microRNA in Drosophila (Cayirlioglu et al 2008). …”

Section: Discussionmentioning

confidence: 99%

Regulation of Odor Receptor Genes in Trichoid Sensilla of the Drosophila Antenna

Miller

Carlson

2010

Genetics

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This study concerns the problem of odor receptor gene choice in the fruit fly Drosophila melanogaster. From a family of 60 Odor receptor genes, only one or a small number are selected for expression by each olfactory receptor neuron. Little is known about how an olfactory receptor neuron selects a receptor, or how the nucleotide sequences flanking a receptor gene dictate its expression in a particular neuron. Previous investigation has primarily concerned the maxillary palp, the simpler of the fly's two olfactory organs. Here we focus on genes encoding four antennal receptors that respond to fly odors in an in vivo expression system. To investigate the logic of odor receptor expression, we carry out a genetic analysis of their upstream regulatory sequences. Deletion analysis reveals that relatively short regulatory regions are sufficient to confer expression in the appropriate neurons, with limited if any misexpression. We find evidence for both positive and negative regulation. Multiple repressive functions restrict expression to the antenna, to a region of the antenna, and to neurons. Through deletion and base substitution mutagenesis we identify GCAATTA elements and find evidence that they act in both positive and negative regulation.

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Hybrid Neurons in a MicroRNA Mutant Are Putative Evolutionary Intermediates in Insect CO ₂ Sensory Systems

Cited by 98 publications

References 19 publications

Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Neurogenetic networks for startle-induced locomotion in Drosophila melanogaster

Regulation of Odor Receptor Genes in Trichoid Sensilla of the Drosophila Antenna

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Hybrid Neurons in a MicroRNA Mutant Are Putative Evolutionary Intermediates in Insect CO 2 Sensory Systems

Cited by 98 publications

References 19 publications

Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Carbon dioxide receptor genes in cotton bollworm Helicoverpa armigera

Neurogenetic networks for startle-induced locomotion in Drosophila melanogaster

Regulation of Odor Receptor Genes in Trichoid Sensilla of the Drosophila Antenna

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Hybrid Neurons in a MicroRNA Mutant Are Putative Evolutionary Intermediates in Insect CO ₂ Sensory Systems