scholarly journals Dissecting the genetic basis of learning, memory, and thermal tolerance in a multi-parental population of fruit flies

2021 ◽  
Author(s):  
◽  
Patricka Williams-Simon
Keyword(s):  
Drosophila Melanogaster ◽  
Candidate Genes ◽  
Learning And Memory ◽  
Thermal Tolerance ◽  
Genetic Basis ◽  
Memory Performance ◽  
Place Learning ◽  
Large Set ◽  
Physiological Mechanisms ◽  
Causal Genes

Learning, memory, and thermal tolerance are complex traits that are fundamental survival skills in many species. For example, small poikilotherms " like Drosophila melanogaster, have evolved physiological mechanisms to learn from and adapt to rapidly warming temperatures because their body temperature reflects that of their surroundings. Along with physiological mechanisms, these animals have also adapted cognitive practices, such as learning and memory, which help them escape extreme temperatures. Although scientific evidence shows that learning, memory, and thermal tolerance have been subjected to natural selection as a means of adapting to warmer temperatures, studies examining both traits (i.e., learning, and thermal tolerance) and how they relate genetically have not been done. Investigating the natural variation of the genes that control these traits is essential if we want to understand better how these traits arise within species. With recent advances in genomic technology, it is now feasible apart - down to a single gene - regions of the genome that influence complex phenotypes. For my Ph.D., I took a quantitative genetics and genomics approach to dissect the genetic basis of learning, memory, and thermal tolerance in Drosophila melanogaster. I hypothesized that there will be a shared and independent genetic locus controlling learning and memory and that there will be a trade-off between learning and thermal tolerance. To genetically dissect learning and memory performance, I used the Drosophila Synthetic Population Resource (DSPR), a multiparent mapping resource, consisting of a large set of recombinant inbred lines (RILs), which allows for high-resolution genome-wide scans, and the identification of loci contributing to naturally occurring genetic variation. Using a highly sensitive apparatus known as the "heat box", I trained flies with temperatures (24 [degrees] C and 41 [degrees] C, which is aversive) to learn to remain on one side of a chamber (place learning) and to remember thiory). An indl that spent most of the time on the side of the chamber associated with 24 [degrees] C will be considered to have high learning and memory. Immediately after, I assayed the flies for thermal tolerance, which is measured as the time to incapacitation at a constant high 41 [degrees] C temperature for 9.5 mins. I identified 16 different loci across the genome that significantly affect place learning and or memory performance, with 5 of these loci affecting both traits and eight loci that influence thermal tolerance. To identify transcriptomic differences associated with learning, memory, and thermal tolerance, I performed RNA-Sequencing (RNA-seq) on pooled samples of seven high-performing and seven low-performing RILs for all three traits and identified hundreds of genes with differences in expression. Integrating our transcriptomic results with the mapping results allowed us to identify nine promising candidate genes that control learning and twenty-one genes that fall between the most significant QTL that is possibly influenci thermal tolerance. I then used a few different methods to identify and validate genetic variants from the list of candidate genes within the most significant QTL (Q6) that influences thermal tolerance. First, I performed a structural variance analysis and found a few structural variants (SV; eg: inserts, deletions, or P-elements) located within candidate genes. Genes that contain SVs are known to influence phenotypic variation, and thus identifying any SV within candidate genes will provide a greater understanding of the genetic basis of a specific complex trait. Second, I functionally validated the candidate genes to identify causal genes using the UAS-GAL4/RNAi system. In this classical genetic system, a specific gene is disrupted through mutagenesis, which allows for the investigation of that gene on a specific phenotype. I then phenotyped lines to determine the phenotypic effect of each gene on thermal tolerance. We screened 20 UAS-RNAi lines (~1900 individuals) that were crossed with both pan neuronal and ubiquitously expressed Gal4 promoters and found 3 lines that were significant. Collectively, these results suggest that learning, memory, and thermal tolerance are highly polygenic and that multiple genes with both large and small effects influence these traits. Future work will aim to validate the function of candidate genes that influence learning and memory and identify the molecular pathways that the causal genes that influence thermal tolerance are associated with.

scholarly journals Multiple genetic loci affect place learning and memory performance in Drosophila melanogaster

2019 ◽  
Author(s):  
P.A. Williams-Simon ◽  
C. Posey ◽  
S. Mitchell ◽  
E. Ng’oma ◽  
J.A. Mrkvicka ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Learning And Memory ◽  
Recombinant Inbred Lines ◽  
Memory Performance ◽  
Place Learning ◽  
Learning Ability ◽  
Large Set ◽  
High Performing ◽  
Place Memory ◽  
Mapping Resource

AbstractLearning and memory are critical functions for all animals, giving individuals the ability to respond to changes in their environment. Within populations, individuals vary, however the mechanisms underlying this variation in performance are largely unknown. Thus, it remains to be determined what genetic factors cause an individual to have high learning ability, and what factors determine how well an individual will remember what they have learned. To genetically dissect learning and memory performance, we used the DSPR, a multiparent mapping resource in the model system Drosophila melanogaster, consisting of a large set of recombinant inbred lines (RILs) that naturally vary in these and other traits. Fruit flies can be trained in a “heat box” to learn to remain on one side of a chamber (place learning), and can remember this (place memory) over short timescales. Using this paradigm, we measured place learning and memory for ∼49,000 individual flies from over 700 DSPR RILs. We identified 16 different loci across the genome that significantly affect place learning and/or memory performance, with 5 of these loci affecting both traits. To identify transcriptomic differences associated with performance, we performed RNA-Seq on pooled samples of 7 high performing and 7 low performing RILs for both learning and memory and identified hundreds of genes with differences in expression in the two sets. Integrating our transcriptomic results with the mapping results allowed us to identify nine promising candidate genes, advancing our understanding of the genetic basis underlying natural variation in learning and memory performance.

scholarly journals Multiple genetic loci affect place learning and memory performance in Drosophila melanogaster

2019 ◽  
Vol 18 (7) ◽  
Author(s):  
Patricka A. Williams‐Simon ◽  
Christopher Posey ◽  
Samuel Mitchell ◽  
Enoch Ng'oma ◽  
James A. Mrkvicka ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Learning And Memory ◽  
Memory Performance ◽  
Place Learning ◽  
Genetic Loci

scholarly journals Genetic architecture of natural variation in visual senescence in Drosophila

2016 ◽  
Vol 113 (43) ◽  
pp. E6620-E6629 ◽  
Author(s):  
Mary Anna Carbone ◽  
Akihiko Yamamoto ◽  
Wen Huang ◽  
Rachel A. Lyman ◽  
Tess Brune Meadors ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Genetic Variation ◽  
Life Span ◽  
Candidate Genes ◽  
Natural Variation ◽  
Genetic Basis ◽  
Nervous System Development ◽  
Interindividual Variation ◽  
Human Populations ◽  
Age Dependent

Senescence, i.e., functional decline with age, is a major determinant of health span in a rapidly aging population, but the genetic basis of interindividual variation in senescence remains largely unknown. Visual decline and age-related eye disorders are common manifestations of senescence, but disentangling age-dependent visual decline in human populations is challenging due to inability to control genetic background and variation in histories of environmental exposures. We assessed the genetic basis of natural variation in visual senescence by measuring age-dependent decline in phototaxis using Drosophila melanogaster as a genetic model system. We quantified phototaxis at 1, 2, and 4 wk of age in the sequenced, inbred lines of the Drosophila melanogaster Genetic Reference Panel (DGRP) and found an average decline in phototaxis with age. We observed significant genetic variation for phototaxis at each age and significant genetic variation in senescence of phototaxis that is only partly correlated with phototaxis. Genome-wide association analyses in the DGRP and a DGRP-derived outbred, advanced intercross population identified candidate genes and genetic networks associated with eye and nervous system development and function, including seven genes with human orthologs previously associated with eye diseases. Ninety percent of candidate genes were functionally validated with targeted RNAi-mediated suppression of gene expression. Absence of candidate genes previously implicated with longevity indicates physiological systems may undergo senescence independent of organismal life span. Furthermore, we show that genes that shape early developmental processes also contribute to senescence, demonstrating that senescence is part of a genetic continuum that acts throughout the life span.

scholarly journals Identification, characterization and use of novel thermogenetic tools in drosophilia melanogaster

2019 ◽  
Author(s):  
◽  
Aditi Mishra
Keyword(s):  
Drosophila Melanogaster ◽  
Learning And Memory ◽  
Avoidance Behavior ◽  
Dopaminergic Neurons ◽  
Temperature Response ◽  
Place Learning ◽  
Temperature Sensitive ◽  
Gustatory Receptors ◽  
Response Properties ◽  
Different Temperatures

Extrinsic control of neural activity is necessary to decipher the neural mechanisms underlying behavior. Molecular tools that employ light (optogenetics) or temperature (thermogenetics) are primarily used for extrinsic manipulation of neurons. While the available tools offer precise temporal and spatial resolution, their caveats lie in the limited number of tools that can be used simultaneously to alter neuronal activity. The overlapping spectrum of activation of optogenetic tools prevents their simultaneous use in preparations. Similarly, the lack of thermogenetic tools that can function in the physiological range of organisms has restricted their use. The use of thermogenetic tools is limited to two members from the Transient receptor family of proteins, TrpA1 and TrpM8 to activate neurons, and one protein that reduces synaptic output, Shibirets. A major drawback to the Trp channels is their response to both temperature and voltage changes. Hence, the discovery of a new temperature sensitive Gustatory Receptor protein provided an opportunity to mine for other temperature sensitive proteins and develop novel thermogenetic tools. In this thesis we report the identification of several thermosensitive proteins, their characterization, and use in studying the learning and memory of freely moving flies. In the first chapter, we probed several Gustatory receptors for their temperature sensitivity using the heat box. The heat box is a high throughput system that enables us to test and track the behavior of single flies in response to temperature. The top and bottom of heat box chamber has Peltier elements that allow for control of temperature with a resolution of 1[degrees]C. We overexpressed several Gustatory receptors one at a time pan neuronally in Drosophila melanogaster and exposed them to various assays. Our initials results imply that at least 2 Drosophila melanogaster Gustatory receptors other than Gr28bD are temperature sensitive. To increase the repertoire of thermosensitive proteins, we assayed for temperature response properties of Gr28bD orthologs from 5 other Drosophila species that occupy different habitats in the world. We rationalized that flies in different habitats will have Gr28bD orthologs with unique temperature response properties designed to sustain in that habitat. Of the 5 proteins we tested, we found that 4 proteins are temperature sensitive at different temperatures. While pan-neuronal overexpression is a robust method to determine the temperature responsiveness of a protein, it does not recapitulate the natural environment the protein is present in. In D. melanogaster, Gr28bD is present in specialized heat sensing cells in the antenna, called Hot Cells. There are 3 Hot cells on each of the two antennae. There is however no physiological information on the where the orthologs are expressed. Since Gr28bD is used for rapid heat avoidance in flies, we rationalized that its orthologs too sever a similar function in their host species and are expressed in the peripheral regions. Hence, in the second chapter, we tested for the avoidance behavior of flies using two choice assays. We made mutant flies that lacked Gr28b proteins, including Gr28bD in the antennae. We then examined the ability of the orthologs to rescue the heat avoidance behavior in these mutants. We found that all the orthologs respond to temperature differences albeit, at different temperatures. Above a threshold temperature, flies rescued with some orthologs could not differentiate between small temperature differences, suggesting that the activity of the orthologs might saturate beyond certain temperatures. Some homologs responded to temperature only when expressed in Hot Cells, thus leading us to examine the presence of accessory proteins it the hot cells that might be enhancing the thermosensitive properties of these homologs. We found several candidate proteins that can studied further to determine their role in the temperature sensing in the hot cells. When used as thermogenetic tools, thermosensitive proteins are in localized environments in small cluster of cells. In the third chapter, we expressed Gr28bD in small clusters of dopaminergic neurons in the fly brain with an aim to understand the role of activation of dopaminergic neurons in operant place learning and memory paradigm. In addition to examining their learning scores at different temperatures, we investigated other behaviors of the flies during the training. Contrary to previous results from our lab that showed that dopaminergic neurons are not important for place learning and memory, we found that activation of a specific subset of dopaminergic neurons does alter place learning and memory. Our findings new laid the groundwork for more experiments to investigate dopaminergic modulation of place learning and memory.

scholarly journals Genetic Basis of Natural Variation in Spontaneous Grooming in Drosophila melanogaster

2020 ◽  
Vol 10 (9) ◽  
pp. 3453-3460
Author(s):  
Aya Yanagawa ◽  
Wen Huang ◽  
Akihiko Yamamoto ◽  
Ayako Wada-Katsumata ◽  
Coby Schal ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Candidate Genes ◽  
Natural Variation ◽  
Genetic Basis ◽  
Genetic Interaction ◽  
Interaction Network ◽  
Repetitive Behaviors ◽  
Grooming Behavior ◽  
Association Analyses ◽  
Neuropsychiatric Diseases

Abstract Spontaneous grooming behavior is a component of insect fitness. We quantified spontaneous grooming behavior in 201 sequenced lines of the Drosophila melanogaster Genetic Reference Panel and observed significant genetic variation in spontaneous grooming, with broad-sense heritabilities of 0.25 and 0.24 in females and males, respectively. Although grooming behavior is highly correlated between males and females, we observed significant sex by genotype interactions, indicating that the genetic basis of spontaneous grooming is partially distinct in the two sexes. We performed genome-wide association analyses of grooming behavior, and mapped 107 molecular polymorphisms associated with spontaneous grooming behavior, of which 73 were in or near 70 genes and 34 were over 1 kilobase from the nearest gene. The candidate genes were associated with a wide variety of gene ontology terms, and several of the candidate genes were significantly enriched in a genetic interaction network. We performed functional assessments of 29 candidate genes using RNA interference, and found that 11 affected spontaneous grooming behavior. The genes associated with natural variation in Drosophila grooming are involved with glutamate metabolism (Gdh) and transport (Eaat); interact genetically with (CCKLR-17  D1) or are in the same gene family as (PGRP-LA) genes previously implicated in grooming behavior; are involved in the development of the nervous system and other tissues; or regulate the Notch and Epidermal growth factor receptor signaling pathways. Several DGRP lines exhibited extreme grooming behavior. Excessive grooming behavior can serve as a model for repetitive behaviors diagnostic of several human neuropsychiatric diseases.

Genetic Basis for Repeated Mating in Drosophila melanogaster

1981 ◽  
Vol 117 (2) ◽  
pp. 133-146 ◽  
Author(s):  
Donald W. Pyle ◽  
Mark H. Gromko
Keyword(s):  
Drosophila Melanogaster ◽  
Genetic Basis ◽  
Repeated Mating
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