This article describes a behavioral assay that uses male mating drive in Drosophila melanogaster to study motivation. Using this method, researchers can utilize advanced fly neurogenetic techniques to uncover the genetic, molecular, and cellular mechanisms that underlie this motivation.
Despite decades of investigation, the neuronal and molecular bases of motivational states remain mysterious. We have recently developed a novel, reductionist, and scalable system for in-depth investigation of motivation using the mating drive of male Drosophila melanogaster (Drosophila), the methods for which we detail here. The behavioral paradigm centers on the finding that male mating drive decreases alongside fertility over the course of repeated copulations and recovers over ~3 d. In this system, the powerful neurogenetic tools available in the fly converge with the genetic accessibility and putative wiring diagram available for sexual behavior. This convergence allows rapid isolation and interrogation of small neuronal populations with specific motivational functions. Here we detail the design and execution of the satiety assay that is used to measure and alter courtship motivation in the male fly. Using this assay, we also demonstrate that low male mating drive can be overcome by stimulating dopaminergic neurons. The satiety assay is simple, affordable, and robust to influences of genetic background. We expect the satiety assay to generate many new insights into the neurobiology of motivational states.
Work in Drosophila has provided deep and pioneering insight into many biological phenomena, including the nature of the gene1, principles of embryonic development2, circadian rhythms3, and the development and wiring of the nervous system4,5,6. Motivation remains far less well understood than these phenomena, perhaps because of the limitations on the systems that have been studied thus far. Motivation in the fly is primarily studied in the context of hunger, which presents many challenges due to their vanishingly small food intake per feeding bout and exoskeleton which precludes overt signs of fat deposition. Consequently, there is a need to expand the systems used to study motivation in the fly.
We describe a behavioral framework for the study of mating drive in Drosophila. This system takes advantage of the neurogenetic tools in the fly as well as the accessibility7,8,9,10,11,12 and the putative connectome of its sexually dimorphic circuitry8,13. In addition, much of the innate14,15,16,17,18,19,20,21 and learned22,23,24 sensory-motor circuitry controlling courtship has been worked out in detail, providing a rare opportunity to locate the exact circuit node upon which motivation impinges. We recently reported that, in the fly, as in humans, dopamine levels are central to mating drive25,26,27. We have gained genetic access to the relevant dopamine-producing and receiving neurons in the fly, facilitating detailed molecular- and circuit-level analyses of this conserved phenomenon using the assays we describe here25.
We add to the behavioral assays in Zhang et al.25 a new flat behavioral arena that allows video scoring, which we call a 2-dimensional (2-D) satiety assay, an important improvement over previous methods. Consequently, the new assay is more scalable and quantifiable, and therefore more suitable for genetic screens of genes and neurons involved in motivation. We use this new assay, together with courtship assays and neurogenetic manipulations, to demonstrate how to measure and alter mating drive in the fly.
NOTE: This protocol describes the preparation (Sections 1 – 3), execution (Section 4), and analysis (Section 4) of 2-D satiety assays. Then, using dopaminergic stimulation as an example, Section 5 shows how to combine thermogenetic stimulation with 2-D satiety assays to induce hypersexuality. Section 6 describes 3 ways to verify the results of 2-D satiety assays. Finally, Section 7 shows how to measure the recovery of mating drive in male flies.
1. Fabricating 8- and 32-chamber Behavioral Arenas
NOTE: Each behavioral arena consists of several layers of laser-cut plastic sheets held together by hex screws and thumb nuts at each of the four corners (Figure 1A).
2. Food Preparation for 2-D Satiety Assay
NOTE: Because a 2-D satiety assay spans 4.5 h, fly food is used in the arena to provide nutrition and water. This protocol uses, but is not restricted to, the conventional cornmeal-agar fly food.
3. Preparing Virgin Females for Behavioral Assays
NOTE: 2-D satiety assays use large numbers of virgin female flies (~120 – 160 for a full behavioral arena) that are difficult to collect using standard methods. This section describes an alternative approach using the hs-hid transgene on the Y chromosome28, which has been used successfully in courtship assays25,29. The stock used to generate white-eyed virgin females has the genotype w1118(X)/hs-hid(Y);+/+;+/+ (Bloomington stock number 24638).
4. Performing and Scoring 2-D Satiety Assays
NOTE: It is important to control the age of the male flies as mating drive changes with age. This protocol uses males that are 3 – 4 d old25.
5. Using Thermogenetic Manipulation to Reverse Satiety in 2-D Satiety Assays
NOTE: This protocol tests whether thermogenetic stimulation of a defined neuronal population can overcome satiety. The experimental flies express the heat-sensitive cation channel TrpA1 in defined populations of neurons (UAS-TrpA1). The steps below apply to the stimulation of dopaminergic neurons (TH-Gal4), which have been shown to promote mating drive25. These steps can be used in conjunction with other neuronal drivers to discover other populations that promote mating drive.
6. Using Courtship and Locomotion to Verify Satiety
NOTE: This section describes 3 optional methods that can be used to verify the results of 2-D satiety assays. They are not required for every assay.
7. Recovering Mating Drive after 2-D Satiety Assay
To characterize Drosophila mating drive, 3-day-old, WT Canton-S males were tested in a 2-D satiety assay. Over the course of the assay (4.5 h), males mate an average of 4.8 ±0.3 (mean ±standard error of mean, SEM) times. Matings initiate mostly in the first 2 h (78%) (Figure 6A, 6B) and become less frequent as the assay progresses (Figure 6A, 6B). This decrease is not due to the lack of mating partners (74% females remain unmated throughout the assay) or physical fatigue (Figure 6F). Rather, this effect is likely explained by a decrease in the male's courtship during the assay, from 42.6 ±8.0% (mean ±SEM) (1st h) to 2.0 ±0.7% (mean ±SEM) (last hour) of nonmating time (Figure 6C). This decline in courtship is also seen when the males are tested in courtship assays with new females (Figure 6D, 6E), and recovers after the males have been isolated from females for 3 d (Figure 6G, 6H). These results show that internally maintained mating drive in male flies can be satiated in a 2-D satiety assay and can recover over time.
The 2-D satiety assay can also be easily combined with Drosophila neural manipulations. We recently reported that thermogenetic stimulation of dopaminergic neurons reverses mating drive in satiated male flies25. Using 2-D satiety assays, we find that dopaminergic stimulation (TH>TrpA1, 28.5 °C) at the end of the satiety assay increased both courtship (Figure 7A, 7C, red) and copulation (Figure 7A, 7B, red). The reversal effects are not observed with parental control genotypes (Figure 7A – 7C, black and gray). All of these results are consistent with the recent study25 and suggest that the 2-D satiety assay, along with the auxiliary assays (courtship and locomotion), can be used to dissect molecular and neuronal components of mating drive.
Figure 1. Designing and Assembling Behavioral Arenas. An 8-chamber arena (used for 2-D satiety assays) consists of 6 layers held together by thumb nuts and hex screws (A). A 32-chamber arena (used for courtship assays) is manufactured similarly, but without the food wall (layer 4). The arena parts are cut out with a laser cutter and the layers are numbered as (B) for 8-chamber and (C) for 32-chamber. The assembled 8-chamber arenas are shown in (D) (front view) and (E) (side view with numbered layers). The assembled 32-chamber arenas assembled in a similar fashion (F, G), but Layer 4 (food wall) is omitted (G) since no fly food is in the arena for courtship assays. Please click here to view a larger version of this figure.
Figure 2. Preparing 2-D Satiety Assays with Food. Standard Drosophila food is placed in a microwave-safe jar with water (A). The food is microwaved until melted (B). A blunted pipette tip (C, arrow) is used to transfer food to chambers of a partially assembled behavioral arena (D). The food is re-solidified at 4 °C (E) before the behavioral arena is completely assembled (F). Please click here to view a larger version of this figure.
Figure 3: Generating Virgin Females from the w1118(X)/hs-hid(Y) Stock. Fly bottles should be heat shocked when 50 – 80% of the pupae are uneclosed as indicated by their opaqueness (A). The inset image shows samples of uneclosed (top) and eclosed (bottom) pupae (A). Bottles are weighed down and submerged in 37 °C hot water bath for 1 h with water level just above the bottom of the bottle stoppers to ensure even heating (B). See the black arrow in (A) for waterline. Please click here to view a larger version of this figure.
Figure 4: Loading Flies into a Behavioral Arena. Gently aspirate and hold 15 – 20 females in the aspirator (A). The pipette tip is used to open the rotating door (B), and the flies gently released into the chamber (C). Use the aspirator to close the rotating door (D). Please click here to view a larger version of this figure.
Figure 5: Performing and Recording a 2-D Satiety Assay. (A) A standard consumer camcorder (a) is used to record the assay in an incubator set to the desired temperature. The incubator contains a flask of water (b) and a humidity detector (c) to ensure the appropriate humidity level (>30%). The prepared 2-D satiety assay is filmed under the camcorder (B). Please click here to view a larger version of this figure.
Figure 6: Satiation and Recovery of Fy Mating Drive. In a 2-D satiety assay, male flies mate frequently during the first 2 hours of the assay (A, B) but decrease their courtship (C) and matings (B) as the assay progresses. The progressive decrease in courtship behavior is maintained when males are transferred to a courtship assay with new females after completing a 2-D satiety assay of 0 h, or 1 h, or 4.5 h (D, E). Red arrows point to males exhibiting courtship and mating behaviors, while orange arrows point to non-mating, non-courting flies (A, D). The decline in sexual behaviors is not a result of physical exhaustion, as males show equivalent levels of locomotor activity before and after the 2-D satiety assay (F). Males gradually recover their mating (G) and courtship (H) levels over 3 d of isolation from females. In this figure, ***p <0.001, **p <0.01, n.s. not significant for t-test (C, F) and one-way ANOVA with Tukey post-test (E, G, H). N = 15 – 16 for each condition for all experiments. Error bars represent standard error of the mean (SEM). Please click here to view a larger version of this figure.
Figure 7: Thermogenetic Satiety Reversal in Male Flies. As in the standard 2-D satiety assay, males show a decrease in matings over the course of the experiment, but thermogenetic stimulation of dopaminergic neurons (TH>TrpA1, red), but not in parental-control genotypes (black and gray), reinstates mating drive in satiated males (A). No matings are scored when the X-axis is broken in (A). This reversal of mating drive can be quantified using either mating numbers (B) or courtship (C). X-axis numbers in (B) and (C) refer to time in (A). Orange background color indicates thermogenetic stimulation (A – C). In this figure, ***p <0.001, n.s. not significant for interactions between genotype and temperature in two-way ANOVA with Bonferroni post-test (B, C). N = 8 for each genotype (B, C). Error bars represent SEM. Please click here to view a larger version of this figure.
Supplemental Material 1. Please click here to download this file.
Supplemental Material 2. Please click here to download this file.
Motivational states can be satiated, maintained, and recovered34. We present a 2-D satiety assay that quickly and robustly measures all of these aspects of mating drive in the fly. This assay opens up the possibility of using advanced fly genetic manipulations to study the molecular and circuit components of a motivated behavior.
The satiety assay relies on the male's ability to successfully court and copulate, and to terminate copulations at the appropriate time. Though hyposexual flies court less, low-courtship flies are not necessarily hyposexual; they may, for example, have trouble recognizing or tracking the females35. For this reason, the satiety assay is best suited for testing hypersexuality, a phenotype that cannot be reliably observed in a standard courtship assay because naïve wild-type males show courtship indices approaching 1. Hypersexuality in the satiety assay should be considered relative to the age of the male-in our experience, older males tend to mate slightly more frequently than the 3-day-old males used here.
We used thermogenetic stimulation of dopaminergic neurons to exemplify the neurogenetic manipulations that can be used in this system to investigate the components underlying motivation. In addition, researchers can also use thermogenetic stimulation throughout a 2-D satiety assay and look for hypersexual males that are slower to reach satiety. Of course, satiety assays can also be combined with neuronal silencing tools36,37, optogenetics38, genetic mutations39,40,41, RNAi knockdown28,42,43,44, etc. These resources make possible a thorough interrogation of motivation in the fly that is currently unachievable in other systems.
The satiety assay is affordable and scalable. Each arena can be manufactured for ~10 U.S. dollars' worth of materials (plus laser cutting costs, if any) and occupies less space than a paperback book. Scoring the videos is also a relatively simple task. A trained experimenter can score a 4.5 h video with 8 male flies in ~1.5 h. For more high-throughput screening, one can score only the last 2 h, when normal flies show very low levels of mating drive. Alternatively, one can spot check the assays every 30 min, as this will capture the majority of the ~20 min-long matings.
We hope this system will be widely adapted and will contribute to the emergence of Drosophila as a powerful system for unlocking the secrets of motivation.
The authors have nothing to disclose.
The authors thank Mike Crickmore, Dragana Rogulja, and Michelle Frank for comments on the manuscript. Pavel Gorelik provided technical support for manufacturing the behavioral arenas. This work was conducted in Mike Crickmore’s lab and is also supported by the Whitehall Foundation (Principal Investigator: Dragana Rogulja). S.X.Z. is a Stuart H.Q. and Victoria Quan Fellow at Harvard Medical School.
1/16 inch clear acrylic | McMaster-Carr | 8589K12 | Used to make arenas; see Supplemental Material 1 for designs. |
1/8 inch clear acrylic | McMaster-Carr | 8589K42 | Used to make arenas; see Supplemental Material 1 for designs. |
3/16 inch clear acrylic | McMaster-Carr | 8560K219 | Used to make arenas; see Supplemental Material 1 for designs. |
1/32 inch black delrin | McMaster-Carr | 8575K132 | Used to make arenas; see Supplemental Material 1 for designs. |
Hex screws, 1 inch long (50x) | McMaster-Carr | 92314A115 | Used to make arenas. Can be replaced by 3/4 inch screws (92314A113, McMaster-Carr) for 32-chamber arenas. |
Thumb nuts (25x) | McMaster-Carr | 92741A100 | Used to make arenas. Can be replaced by regular hex nuts (90480A005, McMaster-Carr). |
Camcorder | Canon | Vixia HF R700 | Can be replaced by any consumer comcorder. |