The Complete and Updated "Rotifer Polyculture Method" for Rearing First Feeding Zebrafish

Podsumowanie

Larval zebrafish are adapted to feed on zooplankton. It is possible to capitalize on this natural feature in the laboratory by growing first feeding fish together in the same system with live saltwater rotifers. This "polyculture" strategy promotes high growth and survival with minimal labor and disturbance to the larvae.

Streszczenie

The zebrafish (Danio rerio) is a model organism of increasing importance in many fields of science. One of the most demanding technical aspects of culture of this species in the laboratory is rearing first-feeding larvae to the juvenile stage with high rates of growth and survival. The central management challenge of this developmental period revolves around delivering highly nutritious feed items to the fish on a nearly continuous basis without compromising water quality. Because larval zebrafish are well-adapted to feed on small zooplankton in the water column, live prey items such as brachionid rotifers, Artemia, and Paramecium are widely recognized as the feeds of choice, at least until the fish reach the juvenile stage and are able to efficiently feed on processed diets. This protocol describes a method whereby newly hatched zebrafish larvae are cultured together with live saltwater rotifers (Brachionus plicatilis) in the same system. This polyculture approach provides fish with an "on-demand", nutrient-rich live food source without producing chemical waste at levels that would otherwise limit performance. Importantly, because the system harnesses both the natural high productivity of the rotifers and the behavioral preferences of the fish, the labor involved with maintenance is low. The following protocol details an updated, step-by-step procedure that incorporates rotifer production (scalable to any desired level) for use in a polyculture of zebrafish larvae and rotifers that promotes maximal performance during the first 5 days of exogenous feeding.

Wprowadzenie

The zebrafish (Danio rerio) is a pre-eminent laboratory animal utilized in a growing number of scientific disciplines, including but not limited to developmental genetics, toxicology, behavior, aquaculture, regenerative biology, and the modeling of many human disorders^1-5. Although the species is relatively easy to maintain in the laboratory, there are a number of management challenges associated with their culture⁶. The most prominent of these is larval rearing, particularly when the fish first begin to feed subsequent to gas bladder inflation⁷. Under normal, controlled conditions, this developmental event occurs at ~5 days post-fertilization (dpf), with the following 3 - 5 days of growth being particularly critical⁷. The central technical difficulty during this stage is to adequately meet the nutritional demands of the first feeding larvae - feed items must be appropriately sized, digestible, attractive, and available on a nearly continuous basis, without creating excessive waste in culturing tanks. Historically this has been achieved typically by delivering numerous small amounts of feed to the fish in tanks, along with routine water exchange^8,9. While these methods are to some degree successful, they are inefficient, require high labor inputs, and return only variable and limited rates of growth and survival¹⁰.

In nature, zebrafish larvae presumably feed on abundant small zooplankton present in the water column¹¹. For this reason, larviculture protocols that incorporate live feeds such as Paramecium, rotifers, and Artemia are typically most efficient⁷. In 2010, Best and co-authors demonstrated that it was possible to grow larval zebrafish in static, brackish water along with saltwater rotifers for the first 5 days of exogenous feeding¹². This approach, which harnesses the natural high productivity of rotifer cultures to provide ample, highly nutritious prey without polluting the water, yields very high rates of larval growth and survival with low labor input^12,13. In recent years, an increasing number of laboratories around the world have adopted variations of this protocol, and many are now culturing rotifers in a continuous fashion to support nursery systems¹⁴.

Over the past several years, methods for both rotifer/zebrafish polyculture and rotifer production have been refined and improved to become more standardized and readily scalable. This article provides step-by-step instructions for 1) continuous and robust rotifer production and 2) the establishment of the rotifer/zebrafish polyculture system used to support robust growth of fish for the first 5 days of exogenous feeding.

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Protokół

1. Rotifer Culture

1. Basic Components of a Culture System using a 100 L Culture Vessel
   1. Gather all the components for the rotifer culture setup . The rotifer culture setup consists of a culture vessel (CV) to grow the rotifers; a similar vessel to maintain feedout rotifers (feedout culture vessel, FCV); a round-bottomed hatching jar (Feed Reservoir, FR) for storage of the algae feed mixture (AFM); an air supply (AS) to aerate the CV, FCV and the FR; a peristaltic pump with a metering timer (PMT) to control delivery of algae feed into the CV and FCV; and a floss particle filter (FPF) that sits inside the CV.
      NOTE: A complete list of supplies and components is provided in the Materials List.
2. Configuration
   1. Elevate the CV and FCV on a stand or table so that the cultures may be easily harvested via a drain fitting into a collection container (Figure 1). Use flexible air supply tubing to connect the AS to a length of rigid tubing in each culture vessel. Make sure that the tubing is long enough to deliver air to the bottom of the CV or FCV.
   2. Use a small-capacity air line to connect the AS to a length of rigid tubing that extends to the bottom of the FR that contains the AFM. Install a valve into each air line to regulate air flow. Connect the FR to the PMT with feed delivery tubing, and run the tubing from the PMT into a hole drilled into the side of the CV/FCV, near the top. Figure 1.
3. Startup
   1. Fill the culture vessel to 90% of the available volume with Reverse Osmosis water (RO). If RO is not available, use clean, dechlorinated municipal water; however, a biosecurity risk assessment should be performed to ensure that no potentially pathogenic organisms are present in the source water. NOTE: Such an analysis can be performed by any qualified water testing laboratory.
   2. Dose the culture vessel water with aquarium salt to reach a salinity of 15 g/L. Set the air flow into the vessel so that it maintains a "rolling boil", and then slowly add the measured amount of salt to the culture vessel until it is completely dissolved by the aeration. Continue aerating the water for >1 hr to ensure that it is fully oxygenated.
   3. Make the algae feed mixture. To 3 L of clean, dechlorinated fresh (0 ppm) water add 100 g of NaHCO₃ and 100 g of ammonia neutralizer (sodium hydroxymethylsulfonate). This last reagent provides the additional benefit of neutralizing any residual chlorine from tap water or bleach residues from sanitizing of culture equipment. It is critical to ensure that these compounds are fully dissolved. Then add 1 L of algae concentrate (biomass dry weight ~15%). Add the feed mixture to the FR and store at 4 °C.
   4. Add a starter culture of 5 - 10 million Brachionus plicatilis rotifers to the CV containing the aerated 15 g/L salinity water. If the rotifers have been chilled during shipping or storage, they should be gradually (during 30 min or longer) acclimated to the temperature of the water in the culture vessel (25 - 27 °C).
   5. Turn on the PMT and begin pumping the algae feed into the rotifer culture vessel. Using the timer feature of the PMT, set the delivery rate of algae feed mixture so that ~1.6 ml of algae feed mixture is delivered per million rotifers in the culture, per day. Distribute the feedings in small portions at regular intervals over the course of a 24 hr period; the more frequent the feedings, the better.
   6. Calibrate the delivery rate of the pump by manually turning on the PMT for a set period (e.g., 1 min) and collect the algae that it pumps during this interval into a graduated cylinder or beaker. For example, if the PMT doses 5 ml of algae in 1 min, then the dose rate would be 5 ml algae/min.
   7. Calculate the required daily feeding rate by multiplying the number of rotifers present, in millions, by 1.6 ml. For example, a rotifer culture with a population size of 100 million rotifers would require ~160 ml of feed per day (100 x 1.6 ml).
   8. Set the PMT to dose the total daily feed requirement at regular intervals throughout a 24 hr period. For example, delivery of a total daily feed amount of 160 ml could be delivered in portions once every 3 hr over a 24 hr period using a PMT set with a dosing pump rate of 5 ml/min for 4 min, 8 times daily (5 ml/min x 4 min = 20 ml x 8 feedings = 160 ml).
   9. Allow the culture to grow until it generates the required population, typically for 48 - 72 hr, before harvesting. At 24 h post-start up, add the floss particle filters to the culture vessel and begin normal maintenance.
4. Maintenance
   NOTE: The culture operates on a continuous basis and requires routine maintenance that ideally should be performed at the same time each day, in the following sequence.
   1. Fill the FCV to 90% of available volume with clean, dechlorinated fresh water, dosed with 10 g/L aquarium salts. Ensure that the water is well mixed, and that all of the salt is fully dissolved. Set the air flow into the vessel so that it maintains a "rolling boil". Measure the salinity with a refractometer and ensure that the salinity is 10 g/L. It is critical to meet this target and not to exceed it.
   2. Sample the rotifers in the CV: Ensure that the culture is well-mixed, then collect 3 samples of a 2 - 3 ml each using a transfer pipette or autopipettor, from different parts of the culture. Combine these samples in a tube or vial of convenient size (e.g., 10 ml).
   3. Transfer 1 - 2 ml of the combined sample onto a petri dish so that it can be visualized under a dissecting microscope. Check the quality of the culture (swimming behavior of the rotifers, presence of detached eggs, contaminating protozoa).
   4. Immobilize the rotifers in the remaining combined sample by adding 100 µl of 50% Lugols iodine solution to the sample. Within seconds after addition of the Lugols, observe the rotifers to stop swimming. Now, easily count the rotifers .
      NOTE: Ethanol, diluted bleach, or vinegar can be used in place of Lugols. Vinegar (2 drops/10 ml) has the advantages of being non-hazardous, not losing strength in storage as bleach and iodine solutions can, and not making the rotifers contract, so the corona of cilia and the "foot" remain extended and the animals look more natural.
   5. Ensure that the sample is well mixed (immobilized rotifers will settle rapidly), then quickly take a ~2 ml subsample in a plastic pipet and dispense 1 ml into a Sedgewick-Rafter counting slide (20 x 50 1-mm squares) (Figure 2). Using a dissecting or compound microscope, count the intact rotifers and the total number of eggs attached to these rotifers (Figure 2). Count as much of the slide area as necessary to count ~100 rotifers. Calculate the number of rotifers per ml, and record this in a spreadsheet or logbook.
   6. Harvest ~30% of the volume of the rotifers in the CV: Remove the air supply and floss filter, slowly open the valve at the bottom of the CV and allow the water to flow into a plankton collector with a 53 µm mesh screen. Collect the water flowing out of the bottom of the collector after filtering into a bucket or drain. Use a gentle to moderate flow to avoid damaging the rotifers. Do not allow the rotifers to dry on the screen.
   7. For consistency reasons, it is advisable to establish the FCV with a standard number of rotifers each day.  Therefore, based on the known CV rotifer density and harvest volume, adjust the FCV total volume to achieve a consistent final density (e.g., 1,500 rotifers/ml). Add the harvested rotifers to the FCV: Gently transfer the rotifers from the collection screen using a wash bottle filled with clean salt water (10 - 15 g/L). Invert the screen over the FCV and wash the rotifers into the FCV with a gentle stream of salt water. Start the PMT to deliver feed (~1.57 ml per million rotifers per day) to the FCV.
   8. Scrub the entire inside of the CV with a clean, soft nylon brush or scrub pad.
   9. Make a new mix of 15 g/L water by adding the appropriate amount of salt to a measured amount of clean RO water in a 5 gallon bucket to replace the volume of water lost to harvest. Add the salt to the water in the bucket and stir vigorously until it is completely dissolved, and then add to the CV.
   10. Using a high-pressure spray in a sink, rinse the floss filter until it is free of debris, and then return it to the CV.
   11. Adjust feed rates of algae delivered to the CV by changing the duration of each dosing event, according to the daily count of rotifers/ml. Use the calculations provided in step 1.3.8, above to determine the appropriate amount of feed to be delivered.
   12. Approximately 24 hr later, repeat the process. Start by harvesting the rotifers remaining in the FCV (that were not needed for the previous day) in the same manner as described above (steps 1.4.2 - 1.4.10). Concentrate them in 2 L of fresh, clean dechlorinated water (5 g/L salt). These can be stored at 4 °C as a backup supply, or used to feed later stages of fish, beyond what is described in this protocol.
       NOTE: This protocol permits up to 2 - 3 days of reduced culture maintenance (with normal automatic feeding), because the rotifers in the CV can tolerate omission of harvests without serious consequences.

2. Polyculture

1. Setup
   1. Collect zebrafish embryos from a spawning event by pouring spawned embryos through a tea-strainer and then gently rinsing with sterile fish water (or any other non-contaminated source of appropriately conditioned solution; e.g., embryo medium, E3, etc.) from a wash bottle into petri dishes.
   2. Incubate the embryos at 25 - 28 °C in petri dishes at a density of 40 - 50 embryos per dish for 5 days.
   3. Begin the polyculture phase on day 5 post-fertilization, or when greater than 90% of the hatched larvae are actively swimming up in the water column.
2. Inoculation
   1. Add 500 ml of rotifer culture directly from the FCV to a 3.5 L nursery tank; inclusion of rotifer culture water provides algal feed that maintains the nutritional content of the rotifers during polyculture.
   2. Gently pour the larvae from one petri dish into the nursery tank. Ensure that no larvae remain in the dish.
   3. Add 500 ml of clean, conditioned fish water from a recirculating system or dedicated water source to the tank to reach a final volume of 1 L and a final salinity of 5 g/L.
      NOTE: This salinity is critical because zebrafish larvae survival will be negatively impacted if salinity is >7 g/L and rotifer survival will be negatively impacted if salinity <2 g/L.
3. Polyculture phase
   NOTE: The polyculture phase should last for up to 4 days post-inoculation (a total of 5 days, corresponding to days 5-9 post-fertilization).
   1. Observe the polyculture tank at least once per day during this period to ensure that rotifers and fish are present and growing. Ensure that the rotifers are visible throughout the water column. Ensure that the the fishs are also visible within the water column, swimming among the rotifers.
   2. Start normal water flow through the tank. Place a screen or baffle over the drain port to ensure that larvae are not flushed out of the tank.
      NOTE: At the end of this phase, the fish will be large enough to consume larger prey items such as Artemia nauplii or processed feed items in the size range of 75 - 125 µm.
      NOTE: The rotifer population dynamics within a representative polyculture tank were measured by sampling/counting rotifers from the tank in the same manner as described in steps 1.4.2 - 1.4.5. This was done once per day from the beginning of the polyculture phase until it was completed.

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Wyniki

The continuous rotifer culture system described here is dynamic, and it is normal for rotifer numbers to fluctuate to a small extent over time if there are variations in daily feeding and harvest rates. The population of the rotifers in one of the active cultures in the aquaculture facilities at Boston Children's Hospital, maintained in the manner described above, was monitored for 30 days (Figure 3). The mean culture density during this period was 932 rotifers/mL, wi...

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Dyskusje

Successful implementation of the rotifer polyculture method for feeding early larval zebrafish requires effective protocols for two tasks: the establishment and maintenance of a continuous rotifer culture system to feed the fish, and culturing first-feeding zebrafish larvae along with rotifers in the same tank.

The setup for a continuous saltwater rotifer production system for zebrafish laboratories first described by Lawrence and co-authors¹⁴ has been modified and enhanced in a num...

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Materiały

Name	Company	Catalog Number	Comments
Rotifer Culture Infrastructure
100 L Culture Vessel	Aquaneering	Custom	Polycarbonate culture vessel, conical bottomed, with drain valve
5 Gallon Culture Bucket Kit	Reed Mariculture	CCS Starter Kit	Small volume culture vessel for small facilities
Rigid Clear Tubing 1/2" O.D., 36”	Pentair Aquatic Ecosystems	16025	Rigid clear tubing for air delivery
Mesh tube	Pentair Aquatic Ecosystems	RT444X	Mesh tube support for floss filter
Rotifer Floss	Reed Mariculture	Rotifer floss 12” x 42”	Particulate waste trap
Peristaltic Metering Timer Pump, 5 GPD	Grainger	38M003	Metering pump with timer for dosing feed to rotifers
Peristaltic Metering Timer Pump, 1-100 mL/hr (for smaller-scale culture)	Coral Vue	SKU: IC-LQD-DSR	Metering pump with timer for dosing feed to rotifers
Silicone Tubing	Cole Parmer		Tubing for algae delivery to rotifer vessel
Rigid Clear Tubing " O.D.,36”	Pentair Aquatic Ecosystems	16025	Rigid clear tubing for air delivery to algae paste
Rigid Clear Tubing O.D., 36”	Pentair Aquatic Ecosystems	16025	Rigid clear tubing for algae delivery
Rotifers
Live Rotifers Brachionus plicatilis Type L	Reed Mariculture	Type L 5 million	Rotifer stock culture for system startup
Rotifer Feed
Sodium hydroxymethylsulfonate	Reed Mariculture	ClorAm-X® 1lb tub	Ammonia reducer for algae feed mix
Sodium Bicarbonate	Fisher Scientific	S25533B	pH buffer for algae feed mix
Microalgae concentrate	Reed Mariculture	Rotigrow Plus® 1 liter bag	Nutritionally optimized rotifer feed
RG Complete	Reed Mariculture	RG Complete 6 oz bottle	All in one microalgae based feed for small scale cultures
Water Preparation
Reef Crystals Reef Salt	That Fish Place	198210	Salt for making culture water (NOTE: this item is an example only; any contaminant free salt formulations may be used).
Refractometer	Pentair Aquatic Ecosystems	SR6	measuring salinity
Rotifer Culture Equipment
Plankton Collectors 12" Dia, 53 microns	Pentair Aquatic Ecosystems	BBPC20	Mesh screen for collecting rotifers
Scrub Pads	Pentair Aquatic Ecosystems	SCR-58	Scrub pad for cleaning inside of culturing vessels
Scrub Brush
Bucket	Grainger Supply	43Y530	Graduated bucket for mixing culture water
Hatching Jar	Pentair Aquatic Ecosystems	J30	Storage of algae feed mix
Lugol’s Solution, Dilute	Fisher Scientific	S99481	Agent used to immobilize live rotifers for counting
Sedgewick-Rafter plankton counting slide with grid	Pentair Aquatic Eco-Systems	M415	Counting rotifers
Miscelleneous
Tea Strainer	Kitchenworks	971972	Used for collecting zebrafish embryos after spawning