squid-colonization.md

Squid colonization

The competition protocol uses the same scaffold as this protocol, so any changes to this protocol may also need to be reflected in that assay.

1. Preparation of Bacterial Inocula

1. Day 0 - Two days prior to squid inoculation, plate the relevant bacterial strains on LBS agar.
2. Incubate bacteria at 25-28°C overnight.
3. Day 1 - Inoculate 3 ml LBS medium in a glass culture tube with one colony of each V. fischeri strain for infection. Prepare duplicate tubes as backup.
4. Day 2 - (Coordinate with squid steps) 1 h prior to inoculation, subculture bacteria 1:80 (37.5 μl) into 3 ml LBS in a glass culture tube and grow for 1 h with aeration.
5. Measure the OD600 of the sample prior to inoculation. Typical measurements are 0.3-0.6 depending on the strain.
6. For a target inoculum of 3-5 x 10³ CFU/ml calculate the inoculum volume as follows: Inoculum volume (μl) = 1.25 / OD600 (e.g., For OD600 = 0.5, the calculated inoculum volume = 1.25/0.5 = 2.5 μl).This amount is added directly to the seawater containing squid in Step 4.1. This calculation may need to be adjusted for different strains of V. fischeri or for inoculation at lower or higher levels than those specified here.

2. Preparation of Agar Plates for Enumeration of the Inocula

1. For each treatment, label LBS plates (2 per treatment) to plate samples of the inoculum in Step 4.1.
2. Add 5 sterile plating beads per plate.

3. Collection of Squid Juveniles

1. Measure the salinity of Instant Ocean using the refractometer and adjust to 35‰.
2. Filter 1 L of Instant Ocean using the filtration unit and an attached vacuum line or vacuum pump, to generate filter-sterilized Instant Ocean (FSIO). Oxygenate the water by swirling vigorously prior to each dispensing. The filter unit can be reused for 2 days.
3. Aliquot 40-50 ml of FSIO into each of two (2) disposable sample bowls. Label one as earlies and one as timelies.
4. Prepare an excess of plastic transfer pipettes for acquiring juvenile squid by cutting the pipette approximately 1 cm from the tip, above the lowest ridges (see Figure 3). This facilitates a wider area through which the squid can pass upon collection. Discard any transfer pipettes in which there is a rough exposed surface.
5. Using prepared transfer pipettes, collect E. scolopes that hatched overnight and transfer to the earlies bowl of FSIO. Early hatchlings have been in the egg system for over 1 h and are susceptible to colonization by contaminating V. fischeri in the egg system. Do not use earlies for sensitive colonization experiments.
6. Check egg tanks every 30-45 min for new hatchlings. Ensure that all hatchlings are cleared during each check. Remove hatchlings with a transfer pipette, and deposit into the timelies bowl of FSIO. Animals collected in a timely fashion are available for colonization experiments.
7. When the collection has finished (~ 45 min after dusk), transfer the squid to the main laboratory. Empirically it is advantageous to colonize the animals under uninterrupted laboratory light conditions for 3 h inoculations.
8. For each treatment, prepare a bowl with 40 ml FSIO. Add squid to the bowls for the assay (maximum n=40 per bowl).
9. Prepare an additional bowl as an aposymbiotic (negative) control.
10. Prepare a dedicated transfer pipette for each treatment.
11. Euthanize extra squid in 2% ethanol.

4. Squid Colonization

1. Day 2 - Using a P10 Pipetman, dispense the calculated aliquot of bacteria (Step 1.5) into each squid bowl (Step 3.8) for each treatment. Start a 3 h timer immediately after the first inoculation.
2. For each treatment, create a "vortex" in the bowl with the dedicated transfer pipette by placing the pipette near the edge of the bowl and pipetting up and down repeatedly to mix the water and squid for approximately 10 sec. Thorough mixing is critical.
3. Plate 50 μl from each bowl onto an LBS agar plate from Step 2.2 (for technical replicates, plate two 50 μl plates per treatment). Incubate at 25-28°C overnight.
4. Prepare wash bowls (100 ml FSIO/ea) for each treatment.
5. Prepare Drosophila vials (4 ml FSIO/ea) for each squid.
6. After exactly 3 h, transfer the squid to their respective wash bowls (complete for all treatment). This stops the inoculation.
7. Proceed to transfer each individual squid to its own Drosophila vial with FSIO. Use a designated transfer pipette for each treatment.
8. Move trays of Drosophila vials to the squid facility to return to the day/night light cycle the animals experienced during embryogenesis.
9. Day 3 - Prepare Drosophila vials (4 ml FSIO/ea) for each squid.
10. Prior to dusk at 22-24 h post-inoculation, transfer each squid to a new Drosophila vial. Use a designated transfer pipette for each treatment.
11. Day 4 - Prepare labelled 1.5 ml microcentrifuge tubes (1/squid).
12. Prior to dusk at 46-48 h post-inoculation, measure and record the luminescence of each squid in the Drosophila vial (luminometer set for 6 s integration and auto-read on lid closure).
13. As a negative control for background luminescence, measure a vial with FSIO that does not contain any squid.
14. Transfer each squid in a volume of approximately 700 μl to a 1.5 ml microcentrifuge tube from Step 4.12. Move to a cardboard freezer box. Once the lid is placed on the box, do not remove it as the light cues for bacteria expulsion are not well-understood.
15. Freeze microcentrifuge tubes at -80°C overnight.

5. Determination of Colonization Levels

1. For each squid, prepare two (2) microcentrifuge tubes, each with 475 μl FSIO (or autoclaved 70% Instant Ocean).
2. Prepare pestles by first using a Kimwipe to clean the pestle and remove gross debris and/or tissue.
3. Place pestles tip-down in a 50 ml beaker containing 95% ethanol. Ethanol should be added to a height of approximately 3 cm.
4. For each pestle, remove from the beaker and wipe the tip with a Kimwipe.
5. Dip pestle back into the ethanol bath, remove and insert (tip up) into an microcentrifuge tube rack and allow to air dry completely for approximately 15 minutes.
6. Thaw squid in a microcentrifuge tube rack (maximum n=8).
7. If necessary, adjust the volume to 700 μl.
8. Using a pestle from Step 5.5, disrupt the animal tissue until the ink sac ruptures (the water will turn a murky grey color).
9. Remove the pestle and ensure all tissue remains in the tube.
10. Vortex the tissue briefly for exactly 10 seconds (use a timer).
11. Allow the tissue to rest for 10 min. The tissue will settle and the bacteria and ink remain in solution For the calculations that follow, the bacteria/ink solution is the [A] dilution (i.e. the E. scolopes light organ homogenate in 700 μl). Serial 1:20 dilutions ([B], [C]) are described below.
12. For the [B] dilution, add 25 μl [A] to one of the microcentrifuge tubes prepared in Step 5.1. Vortex.
13. For the [C] dilution, add 25 μl [B] to one of the microcentrifuge tubes prepared in Step 5.1. Vortex.
14. Plate 50 μl of each dilution onto LBS agar, 2 replicates per treatment.
15. Incubate the plates at 25-28°C overnight.

6. Data Analysis

1. To calculate the CFU/light organ (LO), count colonies on the plate for each treatment in which 10-400 colonies are present, and use the appropriate formula:

• CFU/LO = (colonies on [A] plate) x 14; or
• CFU/LO = (colonies on [B] plate) x 280; or
• CFU/LO = (colonies on [C] plate) x 5600.

1. Plot individual data points and medians on a logarithmic scale.
2. The data are often not normally distributed, with different variances, and the outliers may contain biologically meaningfully information. Therefore, non-parametric tests provide a useful method to determine whether the treatments differ significantly.
3. Use GraphPad Prism software for statistical analysis. For two treatments, use the Wilcoxon Rank Sum test. For comparisons among greater than two treatments, use the Kruskal-Wallis test with appropriate post-tests.

Citation: Naughton LM, Mandel MJ. 2012. Colonization of Euprymna scolopes squid by Vibrio fischeri. J Vis Exp 61:e3758, doi: 10.3791/3758.