A Novel Method of Drug Administration to Multiple Zebrafish (Danio rerio) and the Quantification of Withdrawal

Podsumowanie

A novel method for reducing variability when exposing fish to drugs is explained. Fish exposed to various patterns of ethanol exposure were found to have altered anxiety levels during withdrawal in a light/dark scototaxic assay.

Streszczenie

Anxiety testing in zebrafish is often studied in combination with the application of pharmacological substances. In these studies, fish are routinely netted and transported between home aquaria and dosing tanks. In order to enhance the ease of compound administration, a novel method for transferring fish between tanks for drug administration was developed. Inserts that are designed for spawning were used to transfer groups of fish into the drug solution, allowing accurate dosing of all fish in the group. This increases the precision and efficiency of dosing, which becomes very important in long schedules of repeated drug administration. We implemented this procedure for use in a study examining the behavior of zebrafish in the light/dark test after administering ethanol with differing 21 day schedules. In fish exposed to daily-moderate amounts of alcohol there was a significant difference in location preference after 2 days of withdrawal when compared to the control group. However, a significant difference in location preference in a group exposed to weekly-binge administration was not observed.

This protocol can be generalized for use with all types of compounds that are water-soluble and may be used in any situation when the behavior of fish during or after long schedules of drug administration is being examined. The light/dark test is also a valuable method of assessing withdrawal-induced changes in anxiety.

Wprowadzenie

The zebrafish (Danio rerio) is a small teleost species originating in India that is a useful model organism for behavioral¹ and medical research^2,3. Zebrafish are also commonly used in the testing of various pharmacological substances in order to characterize their impact on behavior. Various dosages and schedules of drug administration have been used to investigate the behavior of the zebrafish after the administration of compounds such as stimulants⁴, anxiolytics⁵ and ethanol^6-8.

Our lab has investigated the effects of differing schedules of ethanol administration on zebrafish anxiety and locomotion in the well-validated light/dark assay^9,20, also commonly referred to as the scototaxic assay. A new method of ethanol administration was developed to increase efficiency for repetitive, daily administration over a long period of time (21 days)⁶. Previously used methods were practical, however, we sought to develop a method that reduced netting, with its associated time costs, and allowed simultaneous, precisely timed administration of the drug of interest to large numbers of fish. In traditional research using ethanol, zebrafish are netted and transferred from one tank to another containing the appropriate mixture of ethanol and water^10-12. While this method is widely accepted, netting zebrafish may increase the variability in the time taken to introduce and remove the fish from the drug solution. Therefore, the exact exposure to the compound of interest may vary over the course of an experiment involving repeated dosing. A method that reduces sources of error stemming from variability in transport times is thus desirable. With our method we are able to move all fish simultaneously, resulting in identical dosing time in each fish. Following ethanol exposure (described here), zebrafish can be tested in any number of behavioral assays, including those that assess anxiety. Dosing groups of fish using the new method has practical uses beyond the ability to accurately replicate and standardize dosing between subjects and across groups of fish. The advent of new software that allows for the tracking of multiple fish at once may see researchers utilize our methods to ensure replicability and accuracy in their experiments. Considering the widespread use of zebrafish as a model organism for behavioral neuroscience, this method will increase efficiency and practicality in future pharmacological studies.

In the present paradigm, a repeated dosing schedule was employed that approximately mirrors human drinking schedules. Fish were randomly assigned to one of three groups: control, daily-moderate, or weekly-binge. The dosing schedule was 21 days in duration, chosen because it significantly exceeded exposure times in previous studies⁷. Control fish received zero alcohol, daily-moderate fish received 0.2% alcohol once per day, and weekly-binge fish received 1.4% alcohol once per week. The light/dark task was used to assess anxiety after 2 days of withdrawal. This is a relatively simple test to administer which uses a rectangular arena in which the walls on one side are white and on the other side are dark⁹. Adult zebrafish robustly prefer the dark side of the arena under control conditions^6,9,13. Increased anxiety is operationally defined as significantly more time spent in the dark zone, and decreased anxiety can be assumed when the fish spends relatively more time spent in the light zone. With motion-tracking software, other informative variables can also be quantified, including average velocity, immobility, meandering, and zone transitions¹⁴.

The dosing method developed in our laboratory can apply to any research in which water-soluble compounds are administered to one or more zebrafish. Many other pharmacological agents which may benefit from this methodology are currently being tested in zebrafish. Commonly tested compounds include nicotine, chlordiazepoxide, buspirone, and scopolamine, which are dissolved in a similar manner to ethanol; by mixing the appropriate amount of the chemical into water. Therefore, the general scope of this procedure is much wider and not limited to ethanol. Furthermore, after dosing with drugs for multiple days, the light/dark task is only one of many behavioral tests that could be employed. After drug administration or during withdrawal, other popular assays that can be utilized include the novel tank diving test¹⁵ and tests of social behavior such as shoaling¹⁶. The following procedure will outline an efficient method of repeatedly transferring groups of fish or individual fish into solutions containing a pharmacological compound of interest. Additionally, the process of testing anxiety with the light/dark test in groups of fish who are in withdrawal after being exposed to long schedules of alcohol administration will be described.

Protokół

All procedures and behavioral testing were approved by MacEwan University’s Animal Research Ethics Board under protocol number 06-11-12, which is in compliance with the Canadian Council for Animal Care’s guidelines for the care and use of experimental animals.

1. Prepare Dosing Tanks, Solutions, and Administration Schedule

1. Prepare an administration schedule such that the animals are dosed in the same environment and during the same time of day to avoid any confounds of time or biasing to visual stimuli.
2. Obtain as many identical, 1.5 L, clear polypropylene spawning tanks as necessary for the number of group sizes. Use groups of 8 fish per tank, which allows for 2 groups of fish to be tested per day later on in the procedure (see step 3). Use one holding tank and one dosing tank per group (2x total number of groups).
   1. Place 400 µm spawning inserts in all holding tanks. Fill the tanks with habitat water or reverse osmosis water at the correct temperature (for zebrafish, 25-28 °C) that is consistent with the temperature fish are normally housed at.
      NOTE: There can be undesired chemical interactions between some drugs and the chemical components of buffered habitat water. In this situation, use reverse osmosis water buffered with minimal or no aquarium salts for drug administration, as well as for the control groups.
   2. Ensure that the tanks are in a neutral environment to avoid conditioning fish to external visual stimuli during dosing.
3. Prepare the drug solution. Mix the appropriate amount of the drug with habitat water in the spawning tanks. Prepare the 0.2% ethanol solution by combining 3 ml of a high grade ethanol (95% non-denatured ethanol) with 1,497 ml of water. Prepare the 1.4% ethanol solution by combining 21 ml of ethanol with 1,479 ml of water.

2. Netting Fish and Ethanol Administration Procedure

1. Carefully net fish from their habitat tanks and transfer into the appropriate holding tank containing the spawning insert. Ideally, house the fish in the spawning insert to eliminate netting altogether.
2. With all fish in their respective holding tanks, gently lift the spawning insert out of the holding tank and place it into the appropriate drug solution tank (Figure 1A).
   1. Record the dosing time as required. Use 30 min in the ethanol solution for the procedure described here.
   2. If possible, have assistants help with the transfer of all experimental groups to the drug solution simultaneously to ensure precise dosing time. Alternatively, transfer one group at a time and keep track of individual groups’ dosing times (Figure 1A).
3. At the end of the requisite dosing period, remove the fish from the ethanol solution by carefully lifting the spawning insert out of the drug solution and placing gently back into the holding tank.
4. Gently net the fish in the holding tanks and place them back into their habitats until the next scheduled dosing time, or place the spawning insert back into the holding tank to eliminate netting.
5. As mentioned previously, if possible within the parameters of animal housing equipment, house the animals in the same tank and spawning insert that is used as the holding tank. This will eliminate netting altogether during the administration procedure.

3. Behavioral Testing

1. Obtain a light/dark arena 9.5 cm wide by 55 cm long and 9.5 cm deep with a white waterproof floor (Figure 1B). Affix white and black waterproof non-reflective paper to the inside walls of the arena using velcro, with half of the arena covered in white and half covered in black. Fill the arena to a depth of 5 cm with habitat water at a temperature of 25-28 °C. Maintain this temperature throughout testing.
2. Minimalize external visual stimuli by constructing a white three-sided enclosure for the arena to be situated in. Ensure the testing area has diffuse overhead lighting that does not cause reflections on the water surface, yet is sufficiently bright for the movement tracking software, or post-hoc manual quantification from video images.
3. Place the arena in the enclosure and set the recording and movement analysis parameters of the behavior tracking software. Set the trial duration to 5-15 min, depending on the research question.
   NOTE: Here, we used 5 min.
4. Transport the group of fish to be tested to the research area in the habitat tank and place them outside of the arena enclosure. Acclimate the fish for 10 min.
5. Gently net a fish from the appropriate group and place in the center of the light/dark arena, being sure to release the fish when it is positioned parallel to the long axis of the arena to avoid biasing the fish to the light or dark zone.
6. Begin recording behavior immediately after the animal is released. Watch for any software problems with tracking the fish or for fish jumping or freezing. Rotate the arena 180° after half of the subjects have been tested to prevent any confounds due to biases resulting from which end of the arena is oriented toward the open end of the enclosure.
7. After the trial has ended, gently net and remove the fish from the arena to a holding tank or habitat tank.

4. Analysis

1. Examine time spent in light versus dark zones. For each group and each fish, obtain the relative time spent in the light and dark zones and analyze using a one sample t-test (or Wilcoxon signed rank test for nonparametric data; difference from (half of the total trial time) 150 sec) to determine if groups significantly prefer one area over the other.
2. To compare preferences, calculate a preference index by subtracting the time spent in the light zone from the time spent in the dark zone and compare differences between groups. t-tests can be used to compare two groups. Compare multiple groups with a one-way analysis of variance utilizing Tukey’s HSD post hoc test where necessary (or Kruskal-Wallis test with Dunn’s multiple comparison post hoc test for nonparametric data).
3. Compare velocity, number of zone transitions, meandering, and immobility across groups. Use one-way analysis of variance utilizing Tukey’s HSD post hoc test where necessary (or Kruskal-Wallis test with Dunn’s multiple comparison post hoc test for nonparametric data).

Wyniki

To maintain accuracy and control in pharmacological studies with zebrafish it is important to time the duration of ethanol administration consistently and accurately as described above. Our procedure can increase the ease and throughput of the dosing procedure. The administration of ethanol on either a weekly-binge or daily-moderate schedule resulted in altered anxiety levels, measured with the light/dark test, compared to controls. When tested two days after the last dosing, zebrafish in the control group (who received ...

Dyskusje

Previous studies involving drug administration in zebrafish have simply relied on netting fish to transport them from their home tank into the drug solution^12,16. Netting is not always consistent and often takes longer than expected due to the escape response of the zebrafish, which has significant individual variability. Traditional transfer methods, while useful, can be improved upon by decreasing the amount of total time the fish spend outside of water, as well as decreasing the amount of variability in tra...

Materiały

Name	Company	Catalog Number	Comments
Three shelf benchtop housing system	Aquatic Habitats	N/A
1.5 L Spawning tank w/400 μm baffle	Aquatic Habitats	N/A
Pure Grain Ethanol	Luxco, INC	N/A
Ethovision XT Motion tracking software	Noldus Information Technology
Pipette	Eppendorf Canada
Light/Dark Arena	Custom		Construct as per procedure description. 9.5 cm wide, 9.5 cm deep, 55 cm long.