Optimizing the Rearing Procedure of Germ-Free Wasps

Podsumowanie

Nasonia wasp embryos were dissected from Lucillia sericata pupae after parasitization for 12-24 h and washed with alcohol and 10% sodium hypochlorite solution to obtain germ-free embryos. After rearing the germ-free embryos and supplying them with Nasonia rearing medium to grow and develop in vitro, germ-free Nasonia adults were obtained.

Streszczenie

Aseptic rearing technology is a method of culturing insects under sterile or almost sterile conditions, which can effectively eliminate the influence of external microorganisms on insect microbiota and thus promote the rapid development of insect microbiota research. Nasonia (wasp genus) is a parasitic wasp insect that has many advantages, such as a short lifespan, high genetic variation, easy operation, etc., and is widely used as an insect model system. Unlike antibiotic treatment, which can only reduce the number of microorganisms in animals, aseptic rearing techniques can control both the composition and quantity of microorganisms in animals, further facilitating the study of host-microbe interactions. However, previous versions of Nasonia rearing medium (NRM) have some defects and problems, such as a complex and time-consuming preparation process, easy contamination by bacteria or fungi, and short storage time. Therefore, this study solves these problems by optimizing the tools used in the NRM preparation process, storage conditions, and component ratios. The optimized medium could allow storage at -20 °C for at least 3 months and eliminate the possibility of NRM contamination during feeding sterile wasps. This further improves the survival rate and health level of aseptic Nasonia, which is important for using Nasonia as a model for microbial research.

Wprowadzenie

Germ-free animals are animals that have no detectable living microorganisms and parasites¹. Germ-free embryos can be obtained by dissecting the mother under aseptic conditions and subsequently raised in barrier systems². Such animals can be used to study the effects of microorganisms on animals, such as on the intestinal microbiota, immune system, and metabolism¹. With certain technical means, many insects and even mammals can be rendered sterile^3,4. Germ-free animals have a unique role and have been widely used in various aspects of microbiology research⁵. For example, the use of germ-free Nasonia wasps has revealed that microorganisms can help hosts adapt to new environments under long-term exogenous environmental stress^6,7.

Nasonia parasitoids are small parasitic wasps that inject their eggs into the pupae of flies⁴. There are four known species of Nasonia, including Nasonia vitripennis, Nasonia longicornis, Nasonia giraulti, and Nasonia oneida⁸. N. vitripennis can be found worldwide, while the other three species have limited ranges in North America⁴. Nasonia parasitoid wasps are regarded as ideal model insects because of their characteristics, such as easy cultivation, short reproduction cycle, sequenced genome, and long term diapause^8,9. They can be used to study various aspects of insect evolution, genetics, development, behavior, and symbiosis¹⁰. Moreover, Nasonia parasitoid wasps can also help control harmful flies in agriculture and disease¹¹. The successful establishment of a sterile insect system involves two major steps: (1) sterilization of the embryos and (2) provision of sterile food to the larvae in vitro. In order to obtain sterile food, Brucker and Bordenstein¹² developed Nasonia rearing medium (NRMv1) in 2012 by using chemicals such as antibiotics, bleach, and fetal bovine serum to kill bacteria¹². However, the chemical sterilization method resulted in low survival and eclosion rates of N. vitripennis¹³. Then, in 2016, Shropshire et al. developed NRMv2 by using a filter sterilization method instead of a chemical sterilization method to eliminate the hazards of antibiotics and other substances, and optimized the breeding process¹³. Unfortunately, this method still has some disadvantages, such as the challenges associated with preparing and using the medium, as well as the risks of drowning, underfeeding, or dehydration for the embryos, larvae, and closed pupae¹⁴. Wang and Brucker¹⁴ recently improved the Nasonia rearing media version 3 (NRMv3) and the germ-free rearing version 2 (GFRv2) protocols. These improvements reduced the cost and media consumption. However, the NRMv3 has a very short storage time and is highly susceptible to contamination.

Building on NRMv3, the NRM preparation tool storage method and nutrient ratio were optimized in this study. This methodological refinement facilitates using N. vitripennis as a model for microbiome studies. Compared with the NRMv3 developed by Wang et al.¹⁴, the improved tool for squeezing Sarcophaga bullata pupa, one of the NRM raw materials, greatly enhances the production efficiency of S. bullata pupa tissue fluid compared with the 60 mL syringe with a bottom hole used by Wang et al.¹⁴. We adjusted the nutrient ratio of NRM, which led to a certain increase in the survival rate of germ-free Nasonia wasps without affecting their development time. In addition, the NRM was packed into small-capacity centrifuge tubes (1.5 mL) and frozen in a -20 °C refrigerator to extend the storage time. It is worth noting that while we used the housefly Lucilia sericata as the host and source for NRM preparation, this protocol can likely be adapted for other Nasonia hosts that are available in the laboratory.

Protokół

1. Preparation of germ-free Nasonia rearing medium

1. Place the commercially available L. sericata pupae (see Table of Materials) on a surface that can accommodate all the pupae, such as a tray or a sheet of paper. Discard any underdeveloped larvae, dark old pupae, empty pupal shells, sawdust, or other impurities. Keep only young pupae that are brownish-red in color and transfer them to a beaker (approximately 3,000-4,000 pupae).
   NOTE: After conducting many experiments, it was found that the medium made from the dark old pupae easily turned dark and stopped the development of germ-free wasps. This phenomenon did not occur when using the young brownish-red pupae to produce medium. The reason for this is still unclear and requires further investigation to verify it.
2. Add enough deionized water to the beaker to cover the entire surface of the pupae. Wrap the mouth of the beaker with tinfoil or gauze, shake the beaker to clean the impurities on the surface of the pupae, and then pour out the water. Repeat three to five times.
3. Place the cleaned L. sericata pupae in the filter tank of a garlic press, squeeze hard, and collect the tissue fluid of the L. sericata pupae in a 50 mL sterile centrifuge tube. Then, pour out the pupa dregs and put new pupae in the filter tank of the garlic press until all are squeezed.
   NOTE: Compared to the needle extrusion device used by Wang et al.¹⁴, the garlic press is more convenient and can separate the interstitial fluid more thoroughly. This advancement lays the foundation for large-scale production and long-term storage of NRM.
4. Centrifuge the mixture at 4 °C (25,000 x g) for 10 min. After centrifugation, the mixture will be separated into three layers from bottom to top: sediment layer, protein layer, and fat layer (Figure 1).
5. To prevent clogging during filtration, aspirate the protein layer using a 18 G sterile needle and transfer it to a new 50 mL conical sterile polypropylene centrifuge tube.
6. Add commercial liquid Drosophila medium (see Table of Materials) to the protein extract at a 1:1 ratio.
   NOTE: More convenient commercialized L. sericata was used as the host and NRM raw material, compared with NRMv3. Therefore, the nutritional ratio was adjusted from 1:2 to 1:1 based on NRMv3, which was more suitable for the growth and development of sterile Nasonia (Figure 2).
7. Filter the mixed medium (Drosophila medium and protein extract of L. sericata pupa) using a vacuum filtration system with different pore sizes (8, 1.2, 0.8, and 0.45 µm; see Table of Materials) to remove particles of different sizes. To prevent clogging, change the filter paper when the flow slows down.
   NOTE: The use of a new 50 mL sterile centrifuge tube is required for each filtration.
8. Centrifuge the liquid again at 4 °C (15,000 x g) for 10 min and sterilize the supernatant medium through a 0.22 µm syringe filter. Repeat the above steps once.
9. Store the culture medium at -20 °C after aliquoting (Figure 3A) for long-term storage.
   ​NOTE: To prevent contamination and repeated freezing and thawing, it is recommended to open each tube of NRM only once when using the culture medium after packaging (Figure 3A).

2. Germ-free egg collection

1. To ensure a stable male-to-female ratio in offspring, place the pupae in a Drosophila vial during the pupal stage at a ratio of 50 females to 15 males because of their haploid genetic characteristics (males develop from haploid cells, while females develop from diploid cells that result from fertilized eggs)^4,15.
   1. After emerging to adults, allow the males and females to mate for 1.5 days, and then put about 40 L. sericata pupae into the vial. Within 12-24 h after parasitization, use a sterile dissecting needle to carefully open one end of the pupal shell under a stereomicroscope (Figure 4).
   2. Hold the other end by hand and find the wasp embryos. Use a dissecting needle to transfer embryos from the surface of the L. sericata pupa tissue to a sterile cell strainer with phosphate-buffered saline (PBS)¹⁴.
      NOTE: Older L. sericata pupae should be used for parasitism because the dry L. sericata pupa tissue is easier to transfer embryos. In order to ensure the smooth transfer of eggs from the L. sericata pupa tissue surface, try to be careful not to puncture the tissue when the dissecting needle opens the pupal case so that the interstitial fluid does not flow out.
2. Place 20-30 embryos on a cell strainer and wash them evenly with 1,000 µL of 10% commercial sodium hypochlorite solution (see Table of Materials), followed by another wash with 1,000 µL of 1x sterile PBS. Then, wash once with 1,000 µL of 70% ethanol solution and wash three times with 1,000 µL of 1x sterile PBS.
3. First, place a 5 mm diameter polypropylene mesh sheet (see Table of Materials) that has been pre-wetted with 1x PBS into a 24-well plate. Then, using a sterilized small brush, gently brush the wasp embryos on the cell strainer onto the polypropylene mesh sheet. This can be done for all four wells in a vertical column of the 24-well plate.

3. Germ-free wasp rearing

1. Add 50 µL of NRM to each well in a laminar flow hood. To maintain a humid environment for growth, add 1 mL of sterile water between each well in the 24-well plate. A small beaker containing 30 mL of sterile water can also be placed in the 5 L sterile plastic box with the 24-well plate.
   1. Throughout the entire experiment, keep the sterile plastic box and the 24-well plate in a climate chamber at a constant temperature of 25 ± 2 °C and under constant light.
2. Before transferring and adding NRM every day, thaw the frozen NRM on a laminar flow bench. In a sterile environment, use alcohol-disinfected tweezers to transfer the polypropylene mesh with larvae on it from one well to another. Lastly, add 50 µL of NRM that has been equilibrated to room temperature (Figure 3B). Repeat the above operations every day until pupae are observed.
   NOTE: With the development of wasps, the amount of NRM should be increased appropriately to ensure that the germ-free wasps have sufficient nutrition. For example, the fourth instar larvae were supplied with 60 to 70 µL of NRM. Since different developmental stages may coexist in the same well, use a sterilized brush to transfer out the pupae. Add a small amount of NRM to the remaining larvae. Use aseptic techniques to avoid microbial invasion and pollution.
3. After feeding for 9 to 11 days, more than 80% of the larvae develop into white or yellow pupae. At this time, move the filter to a clean well plate and stop adding culture medium to wait for eclosion.

Wyniki

The preparation efficiency of NRM was greatly improved by improving the preparation tools. In addition, the problem of NRM pollution in the feeding process was eliminated by optimizing the strategy and preservation method. At the same time, the adjusted NRM had a more suitable nutritional ratio for the growth and development of germ-free wasps with L. sericata as hosts. The survival rate of germ-free wasps from larvae to pupae was significantly improved compared to germ-free wasps reared with NRMv3 using GFRv2 (...

Dyskusje

With the application of high-throughput detection technologies such as genomics and metabolomics, researchers have gradually realized that there is huge genetic diversity and metabolic complexity in the gut microbiota¹⁶. These symbiotic bacteria are closely related to various physiological or pathological states, such as host nutritional metabolism, tumors, immunity, and aging through complex interactions with the host¹⁷. However, the research related to the network of the ...

Materiały

Name	Company	Catalog Number	Comments
0.22 Sterile vacuum filter	NEST	331011
10% SodiumHypochlorite	LIRCON	XB-84BS-1
1x PBS solution	Solarbio	P1020
200 mesh nylon net	BIOBYING	BY-378Z
24 well-plate	NEST	702001
8, 1.2, 0.8, and 0.45 µm filters	Shanghai Xingya Purification Material Factory	HN-AA-JT-10079
Absolute ethyl alcohol	Macklin	E809057-500ml
Cell Strainer	BIOLOGIX	15-1100
Commercial Drosophila Medium	Boer	B645446-500ml
Dissecting needle	Bioroyee	17-9140
Garlic press	Taobao	No Catalog numbers	Purchase on Taobao
Lucillia sericata pupae	Hefei Dayuan Biotechnology Co., Ltd.	No Catalog numbers	Purchase on Taobao
Small writing brush	Cestidur	BL0508
Stereoscope	SOPTOP	RX50
Tweezers	SALMART	A109001-56