Browsing by Author "Li, Qingyun"
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Item Open Access A Functionally Conserved Gene Regulatory Network Module Governing Olfactory Neuron Diversity.(PLoS Genet, 2016-01) Li, Qingyun; Barish, Scott; Okuwa, Sumie; Maciejewski, Abigail; Brandt, Alicia T; Reinhold, Dominik; Jones, Corbin D; Volkan, Pelin CayirliogluSensory neuron diversity is required for organisms to decipher complex environmental cues. In Drosophila, the olfactory environment is detected by 50 different olfactory receptor neuron (ORN) classes that are clustered in combinations within distinct sensilla subtypes. Each sensilla subtype houses stereotypically clustered 1-4 ORN identities that arise through asymmetric divisions from a single multipotent sensory organ precursor (SOP). How each class of SOPs acquires a unique differentiation potential that accounts for ORN diversity is unknown. Previously, we reported a critical component of SOP diversification program, Rotund (Rn), increases ORN diversity by generating novel developmental trajectories from existing precursors within each independent sensilla type lineages. Here, we show that Rn, along with BarH1/H2 (Bar), Bric-à-brac (Bab), Apterous (Ap) and Dachshund (Dac), constitutes a transcription factor (TF) network that patterns the developing olfactory tissue. This network was previously shown to pattern the segmentation of the leg, which suggests that this network is functionally conserved. In antennal imaginal discs, precursors with diverse ORN differentiation potentials are selected from concentric rings defined by unique combinations of these TFs along the proximodistal axis of the developing antennal disc. The combinatorial code that demarcates each precursor field is set up by cross-regulatory interactions among different factors within the network. Modifications of this network lead to predictable changes in the diversity of sensilla subtypes and ORN pools. In light of our data, we propose a molecular map that defines each unique SOP fate. Our results highlight the importance of the early prepatterning gene regulatory network as a modulator of SOP and terminally differentiated ORN diversity. Finally, our model illustrates how conserved developmental strategies are used to generate neuronal diversity.Item Open Access Chromatin Modulatory Proteins and Olfactory Receptor Signaling in the Refinement and Maintenance of Fruitless Expression in Olfactory Receptor Neurons.(PLoS Biol, 2016-04) Hueston, Catherine E; Olsen, Douglas; Li, Qingyun; Okuwa, Sumie; Peng, Bo; Wu, Jianni; Volkan, Pelin CayirliogluDuring development, sensory neurons must choose identities that allow them to detect specific signals and connect with appropriate target neurons. Ultimately, these sensory neurons will successfully integrate into appropriate neural circuits to generate defined motor outputs, or behavior. This integration requires a developmental coordination between the identity of the neuron and the identity of the circuit. The mechanisms that underlie this coordination are currently unknown. Here, we describe two modes of regulation that coordinate the sensory identities of Drosophila melanogaster olfactory receptor neurons (ORNs) involved in sex-specific behaviors with the sex-specific behavioral circuit identity marker fruitless (fru). The first mode involves a developmental program that coordinately restricts to appropriate ORNs the expression of fru and two olfactory receptors (Or47b and Ir84a) involved in sex-specific behaviors. This regulation requires the chromatin modulatory protein Alhambra (Alh). The second mode relies on the signaling from the olfactory receptors through CamK and histone acetyl transferase p300/CBP to maintain ORN-specific fru expression. Our results highlight two feed-forward regulatory mechanisms with both developmentally hardwired and olfactory receptor activity-dependent components that establish and maintain fru expression in ORNs. Such a dual mechanism of fru regulation in ORNs might be a trait of neurons driving plastic aspects of sex-specific behaviors.Item Open Access Developmental Strategy for Generating Sensory Neuron Diversity(2015) Li, QingyunSensory neuron diversity is a common theme in the animal kingdom. It provides the cellular infrastructure that supports the accurate perception of the external world. Among all sensory systems, the olfactory system demonstrates an extreme in the extraordinarily diversified neuronal classes it holds. The system-wide cellular diversity is in sharp contrast with the individual specialization of olfactory receptor neurons (ORNs) per se. How the nervous system, particularly the olfactory system, uses limited genetic information to generate a huge variety of neurons with distinct properties remains elusive.
The adult Drosophila olfactory system is an excellent model to address this question due to its conserved organizational principles and reduced complexity. The fly olfactory appendages contain 50 ORN classes, each of which expresses a single receptor gene from a family of ~80 genes. Stereotyped clusters of 1-4 ORN classes define about 20 sensilla subtypes, belonging to 3 major morphological types. All cellular components within a sensillum are born by a single sensory organ precursor (SOP) via asymmetric divisions. The molecular mechanisms that determine SOP differentiation potentials to develop into distinct sensilla subtypes and the associated ORN classes are unknown.
From a genetic screen, we identified two mutant alleles in the rotund (rn) gene locus, which has a critical function in diversifying ORN classes. Rn is required in a subset of SOPs to confer novel sensilla subtype differentiation potentials from otherwise default ones within each sensilla type lineage. In rn mutants, ORNs in rn-positive sensilla subtypes are converted to lineage-specific default rn-negative fates, resulting in only half of the normal ORN diversity. This work is described in Chapter 2.
Based on an unbiased time-course transcriptome analysis, we discovered two critical downstream targets of Rn, Bric-à-brac (Bab) and Bar. In light of the knowledge about leg development, we found these genes, along with Apterous (Ap) and Dachshund (Dac), are part of the conserved proximal-distal (PD) gene network that play a crucial role in patterning the antennal precursor field prior to proneural gene-mediated SOP selection. Interactions between these PD genes under the influence of morphogen gradients separate the developing antennal disc into 7 concentric domains. Each ring is represented by a unique combination of the aforementioned transcription factors, coding the differentiation potentials for a limited number of sensilla subtypes. Genetic perturbations of the network lead to predictable changes in the ratios of different sensilla subtypes and corresponding ORN classes. In addition, using CRISPR/Cas9 technology, we were able to add tags to specific rn isoforms in the endogenous locus, and show positive regulation of Bab and negative regulation of Bar by the direct binding of Rn to the promoters in vivo. This work is presented in Chapter 3.
We proposed a three-step mechanism to explain ORN diversification, starting from pre-patterning of the precursor field by PD genes, followed by SOP selection by proneural genes, and ended with Notch-mediated neurogenesis. The final outcomes are greatly determined by the pre-patterning phase, which may be modified during evolution to compensate special olfactory needs by individual species. In our model, each step serves a single purpose, which displays context-dependent functions. By changing contexts, reassembly of the same logical steps may guide neuronal diversification in parallel systems with completely different identities. This step-wise mechanism seems to be a common strategy that is used by many other systems to generate neuronal diversity.
Item Open Access Examination of Endogenous Rotund Expression and Function in Developing Drosophila Olfactory System Using CRISPR-Cas9-Mediated Protein Tagging.(G3 (Bethesda), 2015-10-23) Li, Qingyun; Barish, Scott; Okuwa, Sumie; Volkan, Pelin CThe zinc-finger protein Rotund (Rn) plays a critical role in controlling the development of the fly olfactory system. However, little is known about its molecular function in vivo. Here, we added protein tags to the rn locus using CRISPR-Cas9 technology in Drosophila to investigate its subcellular localization and the genes that it regulates . We previously used a reporter construct to show that rn is expressed in a subset of olfactory receptor neuron (ORN) precursors and it is required for the diversification of ORN fates. Here, we show that tagged endogenous Rn protein is functional based on the analysis of ORN phenotypes. Using this method, we also mapped the expression pattern of the endogenous isoform-specific tags in vivo with increased precision. Comparison of the Rn expression pattern from this study with previously published results using GAL4 reporters showed that Rn is mainly present in early steps in antennal disc patterning, but not in pupal stages when ORNs are born. Finally, using chromatin immunoprecipitation, we showed a direct binding of Rotund to a previously identified regulatory element upstream of the bric-a-brac gene locus in the developing antennal disc.