Summary

High-Throughput Method for Measuring Alcohol Sedation Time of Individual Drosophila melanogaster

Published: April 20, 2020
doi:

Summary

Current methods to measure alcohol sensitivity in Drosophila are designed to test groups of flies. We present a simple, low-cost, high-throughput assay for assessing alcohol sedation sensitivity in large numbers of single flies. The method does not require specialized tools and can be performed in any laboratory using common materials.

Abstract

Drosophila melanogaster provides an excellent model to study the genetic underpinnings of alcohol sensitivity. In contrast to studies in human populations, the Drosophila model allows strict control over genetic background, and virtually unlimited numbers of individuals of the same genotype can be reared rapidly under well-controlled environmental conditions without regulatory restrictions and at relatively low cost. Flies exposed to ethanol undergo physiological and behavioral changes that resemble human alcohol intoxication, including loss of postural control, sedation, and development of tolerance. Here, we describe a simple, low-cost, high-throughput assay for assessing alcohol sedation sensitivity in large numbers of single flies. The assay is based on video recording of single flies introduced without anesthesia in 24-well cell culture plates in a set-up that enables synchronous initiation of alcohol exposure. The system enables a single person to collect individual ethanol sedation data on as many as 2,000 flies within an 8 h work period. The assay can, in principle, be extended to assess the effects of exposure to any volatile substance and applied to measure effects of acute toxicity of volatiles on other insects, including other fly species.

Introduction

The National Institute on Alcohol Abuse and Alcoholism reports that in 2015 excessive alcohol consumption, designated as "alcohol use disorder", affected an estimated 16 million people in the United States. Alcohol abuse causes a wide range of adverse physiological effects and is a major cause of death in the U.S. In humans, decreased sensitivity, or a low level of response to alcohol, has a strong genetic component and is associated with a higher risk of developing alcohol use disorders1,2,3,4. Genetic risk studies on human populations are challenging because of population admixture, diverse developmental histories and environmental exposures, and reliance on self-reported questionnaires to quantify alcohol-related phenotypes, which are often confounded with other neuropsychiatric conditions.

Drosophila melanogaster provides an excellent model to study the genetic underpinnings of alcohol sensitivity5,6,7,8. The Drosophila model allows strict control over genetic background, and virtually unlimited numbers of individuals of the same genotype can be reared rapidly under well-controlled environmental conditions without regulatory restrictions and at relatively low cost. In addition to publicly available mutations and RNAi lines that target a majority of genes in the genome, the availability of the Drosophila melanogaster Genetic Reference Panel (DGRP), a population of 205 inbred wild-derived lines with complete genome sequences, has enabled genome-wide association studies9,10. Such studies have identified genetic networks associated with effects on development time and viability upon developmental exposure to ethanol11,12. Evolutionary conservation of fundamental biological processes enables translational inferences to be drawn by superimposing human orthologs on their fly counterparts.

Flies exposed to ethanol undergo physiological and behavioral changes that resemble human alcohol intoxication, including loss of postural control8, sedation, and development of tolerance13,14,15. Alcohol induced sedation in Drosophila can be quantified using inebriometers. These are 122 cm long vertical glass columns with slanted mesh partitions to which flies can attach16,17,18. A group of at least 50 flies (sexes can be analyzed separately) are introduced in the top of the column and exposed to ethanol vapors. Flies that lose postural control fall through the column and are collected at 1 min intervals. The mean elution time serves as a measure of sensitivity to alcohol intoxication. When flies are exposed to alcohol a second time after recovering from the first exposure, they can develop tolerance, as evident from a shift in mean elution time13,15,19,20. Whereas inebriometer assays have led to identification of genes, genetic networks, and cellular pathways associated with alcohol sedation sensitivity and development of tolerance12,13,14,21, the assay is time consuming, low-throughput, and ineffective for measuring alcohol sensitivity in single flies.

Alternative ethanol sedation assays that do not require the elaborate inebriometer set-up allow for more convenient measurements but are still limited in throughput and generally require analyses of groups of flies rather than individuals21,22,23,24,25. Assessing single flies minimizes the potential for confounding effects due to group interactions, such as those stemming from social behaviors. Here, we present a simple, low-cost, high-throughput assay for assessing alcohol sedation sensitivity in large numbers of single flies.

Protocol

1. Construction of the testing apparatus

  1. Create a cardboard template the size of a 24-well cell culture plate by tracing around the plate on cardboard and cutting out the designated area.
  2. Cut a piece of small insect screen mesh the size of the cell culture plate using the cardboard template from step 1.1.
  3. Prepare a 24-well cell culture plate by placing a small line of hot glue around the perimeter of the top of the plate using a hot glue gun and affixing the screen mesh on top of the open wells.
  4. Secure a wooden craft stick to each of three sides of the same cell culture plate from step 1.3 using a hot glue gun. The modified cell culture plate should now resemble the plate diagram shown in Figure 1A and the experimental setup shown in Figure 2.
    NOTE: Prepare at least as many cell culture plates as will fit in the filming chambers (see below).

Figure 1
Figure 1: Diagram of the testing apparatus and filming chamber. (A) Upper Diagrams. The top, side, and front views of the testing apparatus are shown, respectively. A screen mesh lays flat on top of a 24-well cell culture plate. The wooden craft sticks, represented by the arrowheads, are attached to three adjacent sides for stability and alignment aid, two on the side of the well plate with six wells and one on the side of the plate with four wells. All attachments are hot glued onto the apparatus. (B) Lower Diagrams. The top, side, and front views of the assay set-up are shown, respectively. A slit is cut in the right side of the box, from the opening for the lid to the back of the opening, with the bottom of the slit level to the inner surface. The hole on the top of the box, the surface parallel to the ground, is centered for maximum video exposure. The shaded box represents the video camera. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Photograph of the assay system. The video camera is placed on top of the polystyrene chamber, with the lens inserted in the cut-out hole, illustrated in the diagrams of Figure 1B. Two sets of modified 24-well cell culture plates rest on top of an illumination pad that is inserted in a slit through the side of the chamber. Please click here to view a larger version of this figure.

2. Construction of the filming chamber

  1. Create a filming chamber by cutting a hole the size of the video camera lens on the side of a polystyrene box. Cut an additional slit the width of the illumination pad in the opposite side of the polystyrene box. The filming chamber should resemble the filming chamber shown in Figure 1B and Figure 2.
  2. Prepare the filming chamber for use by inserting the illumination pad into the slit and positioning the camera in the lens hole above the illumination pad.
  3. Place all materials and perform all subsequent testing in a controlled environment, preferably a behavioral chamber with approximately 30% humidity, 25 °C temperature, uniform airflow, and noise levels less than 65 dB.

3. Preparation of the testing apparatus and flies

  1. Pipette 1 mL of 100% ethanol through the screen mesh into each well.
  2. Dry the screen mesh with a piece of cheesecloth.
  3. Cut two pieces of cheesecloth the dimensions of the cell culture plate using the cardboard template created in step 1.1. Place them on top of the dry screen mesh of the modified cell culture plate containing ethanol from step 3.2.
  4. Create a small piece of thin, flexible plastic cutting board by tracing around the cardboard template created in step 1.1 as a general guide and expanding the traced area by 1–2 cm on one of the short sides. Cut out the expanded traced area from the thin, flexible plastic cutting board. After cutting, ensure that the plastic still fits between the three wooden craft sticks on the testing apparatus, but hangs off one end by 1–2 cm.
  5. (Optional) If an aspirator needs to be created, assemble an aspirator like the one shown in Figure 3 by first cutting a P1000 pipette tip in half. Insert the piece with a larger diameter into one end of a ~30 cm piece of flexible tubing to serve as a mouthpiece.

Figure 3
Figure 3: A fly aspirator in which flies are collected with an interchangeable mouthpiece attached to flexible tubing and a wide bore serological pipette with a cotton gauze stopper. The operator can aspirate a single fly into the pipette for transfer without anesthesia. Please click here to view a larger version of this figure.

  1. (Optional) To complete the aspirator assembly, cover the wide end of a 10 cm piece of serological pipette with gauze to prevent flies from getting into the tubing and insert the pipette, gauze first, into the open end of the tubing to serve as a fly chamber. The aspirator should resemble that shown in Figure 3.
  2. Using an aspirator (Figure 3, steps 3.5 and 3.6), aspirate one fly per well into a separate 24-well cell culture plate. Use the flexible plastic to cover any wells containing previously aspirated flies. Record the well position and any relevant genotype or phenotype information of each fly.
  3. Hold the flexible plastic flush with the top of the cell culture plate containing the flies to prevent their escape and invert the plate onto the top of the modified cell culture plate with the ethanol. The sheet of flexible plastic should be resting on top of the sheets of cheesecloth. Align the inverted cell culture plate containing flies using the craft sticks to ensure each well with ethanol aligns with each well containing a fly.
  4. The experimental setup should resemble Figure 2.

4. Testing the flies

  1. Ensure the illumination pad is lit at full brightness for maximum visual contrast. Start recording with the video camera.
  2. To expose the flies to ethanol, carefully remove the plastic from between the well plate and testing apparatus, taking care not to dislodge the cheesecloth.
  3. Terminate the video recording once all flies have lost postural control. Once it is suspected that all flies have lost postural control, tap firmly in the center of the plate to ensure that all flies have complete loss of postural control. If there is movement, continue to record. Continue to tap periodically (every 1–2 min) until no movement occurs.
  4. (Optional) To quickly recover the flies, remove only the top plate from the testing apparatus, revealing sedated flies resting on the cheesecloth. Aspirate individual flies into chosen containers for recovery.
  5. Replace the ethanol in the modified cell culture plates with 1 mL of fresh 100% ethanol at least 1x every hour to control for evaporation and humidification of the ethanol and to maintain consistent ethanol exposure throughout the assay. Dry the screen mesh with cheesecloth.
  6. Repeat for as many samples as desired.
    NOTE: For highest throughput, aspirate the next round of flies into new cell culture plates during the video recording. The protocol can be paused here, as the video recording can be reviewed later.

5. Determination of fly sedation time

  1. Record sedation time for each individual fly by watching the video recording. Sedation time is defined as the moment a fly loses complete postural control and locomotor ability. It is recommended to watch the film in reverse and record the time that the fly begins to move to ensure accuracy.

Representative Results

Two 24-well microtiter plates could generate data simultaneously on 48 individual flies within as little as 10 min. Table 1 lists measurements of ethanol sedation times for 48 individual flies, males and females separately, of two DGRP lines with different sensitivities to alcohol exposure on development time and viability13. Flies of line RAL_555 were less sensitive than line RAL_177 (Figure 4, Table 2; p < 0.0001, ANOVA). Males and females of RAL_177 showed no sexually dimorphic effect (Figure 4, Table 2; p > 0.1, ANOVA), whereas females of line RAL_555 were less sensitive to ethanol exposure than the males (Figure 4, Table 2; p < 0.006, ANOVA). The large number of flies that can be measured simultaneously and the ability to measure sexes and different lines contemporaneously can increase accuracy by reducing error due to environmental variation.

A. Ethanol Sedation Time (s) B. Ethanol Sedation Time (s)
Females Males Females Males
414 365 477 423 568 309 937 742 622 460 331 498
201 384 498 411 523 626 791 619 197 467 455 562
228 364 333 440 403 267 504 744 513 570 582 506
440 416 404 408 422 384 970 540 369 865 533 492
888 283 285 322 369 287 595 550 606 392 544 345
1079 519 315 393 376 284 418 709 553 308 477 388
718 287 432 275 206 411 366 564 558 385 576 377
598 337 398 279 631 372 437 692 578 460 511 412
241 398 364 347 374 808 665 729 484 532 425 354
229 423 534 386 396 628 312 576 305 334 531 506
388 488 451 523 322 533 682 638 420 560 548 379
252 529 375 427 330 540 1045 741 708 832 509 472
674 401 303 401 307 311 394 675 381 477 449 784
303 453 351 429 525 262 540 690 520 556 495 226
258 483 302 389 562 319 356 615 336 454 524 590
346 426 385 416 596 287 626 678 840 634 677 509

Table 1: Measurements of ethanol sedation times (s) of individual flies of (A) DGRP lines RAL_177 and (B) RAL_555 for separate sexes (n = 48). See also Table 2, Figure 4.

Figure 4
Figure 4: Alcohol sedation times of DGRP lines RAL_177 and RAL_555. The bars represent means and the error bars SEM (n = 48). Sedation times for RAL_177 flies were less than those for RAL_55 flies (p < 0.0001, ANOVA). Individual data points are indicated in Table 1. Additional statistically significant differences between sexes and lines are indicated in the text and in Table 2. Please click here to view a larger version of this figure.

Analysis Source of Variation df SS F-Value P-value
Full Model Pooled Line 1 769627 34.869 <0.0001
Sex 1 105001 4.757 0.0304
Line x Sex 1 86021 3.897 0.0498
Error 188 4149491
Reduced Model Females Line 1 685126 23.58 <0.0001
Error 94 2730718
Reduced Model Males Line 1 170522 11.3 0.0011
Error 94 1418774
Reduced Model RAL_177 Sex 1 473 0.023 0.8800
Error 94 1943741
Reduced Model RAL_555 Sex 1 190549 8.12 0.0054
Error 94 2205751

Table 2: Analyses of variance for sedation time across sex and DGRP line. The model used was Y = µ + L + S + LxS + ε, where µ is the overall mean, L is the fixed effect of the DGRP line (RAL_177, RAL_555), S is the fixed effect of sex (male, female), LxS is the interaction term (fixed), and ε is the error term. The models Y = µ + L + ε and Y = µ + S + ε were used for the reduced models. Line, Sex, and the Line x Sex interaction term were all significant in the full model at α < 0.05. Reduced models by sex and DGRP line RAL_555 were also significant at α < 0.01. See also Table 1, Figure 4. df = degrees of freedom, SS = Type I Sums of Squares.

Discussion

Here, we present a simple, inexpensive, and high-throughput method for assessing sedation time due to ethanol exposure in Drosophila melanogaster. Unlike many current methods, which require group analyses, this assay enables a single person to collect individual sedation time data for ~2,000 flies within an 8 h work period. We found that a single person can score 48 flies for sedation time in about 5 min. At this rate, 2,000 flies can be scored in approximately 4 h, though scoring can be conducted later. With our assay, the recorded sedation time for most flies ranges from 5–15 min at an exposure to 1 mL of 100% ethanol. Lower concentrations of ethanol or smaller delivery volumes will result in longer sedation times.

Current methods for assessing sedation time require testing large numbers of flies without readily enabling measurements on single individuals15,16,17,18,19,20,21,22,23,24,25,26. Many current sedation and sensitivity assays rely upon ST5022,23,24, the timepoint at which 50% of the flies are sedated as a result of ethanol exposure. Although obtaining the ST50 for groups of flies was not the primary motivation for developing this assay, the video recordings demonstrate higher utility compared to current methods, as the recordings can be used to ascertain the ST50 for groups of individually tested flies and to measure the percentage of flies that satisfy a given criterion (e.g., loss of postural control) at any time point. It should be noted that such video analyses would require additional time.

Unlike current inebriometer assays, the method we describe does not require specialized tools to set up and can be performed in any laboratory using common materials. Using this method, we have obtained reliable and consistent sedation times for individual flies. The assay can, in principle, be extended to assess the effects of exposure to any volatile substance. The assay can also be applied to measure effects of acute toxicity of volatiles on other insects, including other fly species. Individual sedation time data can be used to assess the extent of phenotypic variation within a population, such as the DGRP.

We used small insect screen mesh to prevent direct contact with the ethanol solution while allowing adequate quantities of ethanol vapors to reach the fly. The layer of white cheesecloth on top of the screen mesh provides visual contrast between the fly and the surface below and ensures that flies do not get caught in the screen mesh, which could lead to ambiguous determination of loss of postural control. Commercially available membranes that are porous to water and air gave inconsistent results and were insufficiently penetrable to ethanol vapors. We intentionally used small insect screen mesh because it is a uniformly porous material that minimizes variation in ethanol exposure as a result of fly position within a well. Modifications can be made to this protocol based on available materials, although we recommend a controlled behavioral chamber, access to 90%–100% ethanol close to the fly, and uniform ethanol exposure.

Fly position within the cell culture plates should be randomized between replicates to avoid positional bias. For larger experiments that require use of this assay across multiple days and are therefore subject to environmental variation that could influence assay results (e.g., changes in barometric pressure)27, we strongly recommend that flies be tested at the same time each day and randomized both within and across days, especially if different lines and/or sexes are to be compared against one another.

The method we developed is best suited for measuring the effect of acute alcohol exposure but is not suitable for obtaining consumption data or modeling addiction. Alcohol sedation sensitivity data obtained from this assay can, however, be integrated with other measures of alcohol-related phenotypes. One limitation of the system is that the vertical height of standard cell culture plates allows for vertical fly movement that cannot be readily tracked by video for detailed assessment of overall activity or locomotion. However, this limitation does not affect accurate assessment of sedation time. When using flies of different genotypes (e.g., in DGRP-derived outbred populations28), this assay also enables retrieval of individual flies to collect pools of flies with contrasting phenotypes for bulk DNA sequencing and extreme QTL mapping29,30. Overall, this assay permits rapid, inexpensive collection of alcohol sedation data on large numbers of single flies.

Disclosures

The authors have nothing to disclose.

Acknowledgements

This work was supported by grants DA041613 and GM128974 from the National Institutes of Health to TFCM and RRHA.

Materials

24-well Cell Culture Plates Corning 3526 Flat-bottomed; will house flies throughout assay
Aspirator
Cheesecloth Genesee Scientific 53-100 Widely available.
Ethanol Decon Labs V1001 Widely available.
Flexible Plastic Cutting Board (Plate Cover) Walmart 550098612 Any flat plastic that can slide easily and cover a 24-well plate completely. Flexible plastic cutting board works well.
Gauze (for aspirator) Honeywell North 67622 Widely available.
Illumination Pad Amazon (AGPtek) ASIN B00YA9GP0G Any light pad to provide contrast is suitable.
Jumbo Craft Sticks Michaels 10334892 Any craft stick at least 7 cm long is suitable.
P1000 Pipette Tip (for aspirator) Genesee Scientific 24-165RL Any P1000 pipette tip is suitable.
Serological Pipette (for aspirator) Genesee Scientific 12-104
Small Insect Screen Mesh Lowe's (Saint-Gobain ADFORS) 89322 Any small insect screen mesh is suitable.
Testing Chamber Interior space dimension big enough to encompass light pad. Can be constructed from a polystyrene box.
Tygon Tubing (for aspirator) Grainger 9CUG7 Widely available.
Video Camera Canon 1959C001AA Any video camera is suitable.

References

  1. Heath, A. C., et al. Genetic differences in alcohol sensitivity and the inheritance of alcoholism risk. Psychological Medicine. 29 (5), 1069-1081 (1999).
  2. Schuckit, M. A., Smith, T. L. The relationships of a family history of alcohol dependence, a low level of response to alcohol and six domains of life functioning to the development of alcohol use disorders. Journal of Studies on Alcohol. 61 (6), 827-835 (2000).
  3. Trim, R. S., Schuckit, M. A., Smith, T. L. The relationships of the level of response to alcohol and additional characteristics to alcohol use disorders across adulthood: a discrete-time survival analysis. Alcoholism: Clinical and Experimental Research. 33 (9), 1562-1570 (2009).
  4. Schuckit, M. A., Smith, T. L. Onset and course of alcoholism over 25 years in middle class men. Drug and Alcohol Dependence. 113 (1), 21-28 (2011).
  5. Morozova, T. V., Mackay, T. F. C., Anholt, R. R. H. Genetics and genomics of alcohol sensitivity. Molecular Genetics and Genomics. 289 (3), 253-269 (2014).
  6. Heberlein, U., Wolf, F. W., Rothenfluh, A., Guarnieri, D. J. Molecular genetic analysis of ethanol intoxication in Drosophila melanogaster. Integrative and Comparative Biology. 44 (4), 269-274 (2004).
  7. Engel, G. L., Taber, K., Vinton, E., Crocker, A. J. Studying alcohol use disorder using Drosophila melanogaster in the era of ‘Big Data’. Behavioral and Brain Functions. 15 (1), 7 (2019).
  8. Singh, C. M., Heberlein, U. Genetic control of acute ethanol-induced behaviors in Drosophila. Alcoholism: Clinical and Experimental Research. 24 (8), 1127-1136 (2000).
  9. Mackay, T. F. C., et al. The Drosophila melanogaster Genetic Reference Panel. Nature. 482 (7384), 173-178 (2012).
  10. Huang, W., et al. Natural variation in genome architecture among 205 Drosophila melanogaster Genetic Reference Panel lines. Genome Research. 24 (7), 1193-1208 (2014).
  11. Morozova, T. V., et al. A Cyclin E centered genetic network contributes to alcohol-induced variation in Drosophila development. G3. 8 (8), 2643-2653 (2018).
  12. Morozova, T. V., et al. Polymorphisms in early neurodevelopmental genes affect natural variation in alcohol sensitivity in adult drosophila. BMC Genomics. 16, 865 (2015).
  13. Scholz, H., Ramond, J., Singh, C. M., Heberlein, U. Functional ethanol tolerance in Drosophila. Neuron. 28 (1), 261-271 (2000).
  14. Berger, K. H., Heberlein, U., Moore, M. S. Rapid and chronic: two distinct forms of ethanol tolerance in Drosophila. Alcoholism: Clinical and Experimental Research. 28 (10), 1469-1480 (2004).
  15. Morozova, T. V., Anholt, R. R. H., Mackay, T. F. C. Transcriptional response to alcohol exposure in Drosophila melanogaster. Genome Biology. 7 (10), 95 (2006).
  16. Weber, K. E. An apparatus for measurement of resistance to gas-phase agents. Drosophila Information Service. 67, 91-93 (1988).
  17. Weber, K. E., Diggins, L. T. Increased selection response in larger populations. II. Selection for ethanol vapor resistance in Drosophila melanogaster at two population sizes. 遗传学. 125 (3), 585-597 (1990).
  18. Cohan, F. M., Graf, J. D. Latitudinal cline in Drosophila melanogaster for knockdown resistance to ethanol fumes and for rates of response to selection for further resistance. Evolution. 39 (2), 278-293 (1985).
  19. Scholz, H., Franz, M., Heberlein, U. The hangover gene defines a stress pathway required for ethanol tolerance development. Nature. 436 (7052), 845-847 (2005).
  20. Morozova, T. V., Anholt, R. R. H., Mackay, T. F. C. Phenotypic and transcriptional response to selection for alcohol sensitivity in Drosophila melanogaster. Genome Biology. 8 (10), 231 (2007).
  21. Morozova, T. V., et al. Alcohol sensitivity in Drosophila: Translational potential of systems genetics. 遗传学. 83, 733-745 (2009).
  22. Bhandari, P., Kendler, K. S., Bettinger, J. C., Davies, A. G., Grotewiel, M. An assay for evoked locomotor behavior in Drosophila reveals a role for integrins in ethanol sensitivity and rapid ethanol tolerance. Alcoholism: Clinical and Experimental Research. 33 (10), 1794-1805 (2009).
  23. Sandhu, S., Kollah, A. P., Lewellyn, L., Chan, R. F., Grotewiel, M. An inexpensive, scalable behavioral assay for measuring ethanol sedation sensitivity and rapid tolerance in Drosophila. Journal of Visualized Experiments. (98), e52676 (2015).
  24. Urizar, N. L., Yang, Z., Edenberg, H. J., Davis, R. L. Drosophila homer is required in a small set of neurons including the ellipsoid body for normal ethanol sensitivity and tolerance. The Journal of Neuroscience. 27 (17), 4541-4551 (2007).
  25. Wolf, F. W., Rodan, A. R., Tsai, L. T., Heberlein, U. High-resolution analysis of ethanol-induced locomotor stimulation in Drosophila. The Journal of Neuroscience. 22 (24), 11035-11044 (2002).
  26. Cohan, F. M., Hoffmann, A. A. Genetic divergence under uniform selection. II. Different responses to selection for knockdown resistance to ethanol among Drosophila melanogaster populations and their replicate lines. 遗传学. 114 (1), 145-164 (1986).
  27. Pohl, J. B., et al. Circadian genes differentially affect tolerance to ethanol in Drosophila. Alcoholism: Clinical and Experimental Research. 37 (11), 1862-1871 (2013).
  28. Huang, W., et al. Epistasis dominates the genetic architecture of Drosophila quantitative traits. Proceedings of the National Academy of Sciences of the United States of America. 109, 15553-15559 (2012).
  29. Ehrenreich, I. M., et al. Dissection of genetically complex traits with extremely large pools of yeast segregants. Nature. 464 (7291), 1039-1042 (2010).
  30. Anholt, R. R. H., Mackay, T. F. C. The road less traveled: From genotype to phenotype in flies and humans. Mammalian Genome. 29, 5-23 (2018).

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Cite This Article
Sass, T. N., MacPherson, R. A., Mackay, T. F. C., Anholt, R. R. H. High-Throughput Method for Measuring Alcohol Sedation Time of Individual Drosophila melanogaster. J. Vis. Exp. (158), e61108, doi:10.3791/61108 (2020).

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