Soil Sampling and Isolation of Entomopathogenic Nematodes (Steinernematidae, Heterorhabditidae)

Podsumowanie

Entomopathogenic nematodes are soil-inhabiting roundworms that parasitize a wide range of insects. We demonstrate sampling methods used for the isolation of these nematodes from the soil using two techniques: the insect baiting and the modified White trap, for the recovery of nematodes from soil samples and infected insect cadavers, respectively.

Streszczenie

Entomopathogenic nematodes (a.k.a. EPN) represent a group of soil-inhabiting nematodes that parasitize a wide range of insects. These nematodes belong to two families: Steinernematidae and Heterorhabditidae. Until now, more than 70 species have been described in the Steinernematidae and there are about 20 species in the Heterorhabditidae. The nematodes have a mutualistic partnership with Enterobacteriaceae bacteria and together they act as a potent insecticidal complex that kills a wide range of insect species.

Herein, we focus on the most common techniques considered for collecting EPN from soil. The second part of this presentation focuses on the insect-baiting technique, a widely used approach for the isolation of EPN from soil samples, and the modified White trap technique which is used for the recovery of these nematodes from infected insects. These methods and techniques are key steps for the successful establishment of EPN cultures in the laboratory and also form the basis for other bioassays that consider these nematodes as model organisms for research in other biological disciplines. The techniques shown in this presentation correspond to those performed and/or designed by members of S. P. Stock laboratory as well as those described by various authors.

Wprowadzenie

Many nematodes are associated with insects, and their host interactions range from beneficial to detrimental. Herein, we focus on a group of nematodes that are pathogens of insects, also known as entomopathogenic nematodes (or EPN). Two nematode families belong to this group of nematodes: Steinernematidae and Heterorhabditidae^11,13. Their pathogenic effect is in fact conferred by their interaction with facultative anaerobic enteric bacteria (Xenorhabdus bacteria associate with steinernematids and Photorhabdus bacteria associate with heterorhabditids)². The bacteria are vectored from one insect host to another by the only free living nematode stage, the third-stage infective juvenile (also known as dauer juvenile, infective juvenile or IJ), which lives in the soil. Once inside the insect, the nematodes release the bacteria into the insect’s hemolymph, which kill the insect host by massive septicemia. The bacteria also degrade the insect’s tissues and become the nematodes’ food source, allowing them to mature and multiply. Usually, one or two generations of adult nematodes are produced within the insect cadaver. The progeny of the last adult generation reassociates with a few bacterial cells in a more specialize manner than their previous nutritional relationship, and nurture these cells in their intestines as they move out from the insect carcass into the soil where they will await another insect to parasitize^6,11,14 (Figure 1).

Since their discovery in 1927, EPN have been considered valuable alternatives to chemical pesticides as they can parasitize a wide range of insects that are agricultural pests^3,4,5. However, over the past two decades, these nematodes and their symbiotic bacteria have been recognized as a malleable model system for studying biological, ecological and evolutionary aspects of host-microbe interactions¹⁴.

The goal of this presentation is to show the methods and techniques most commonly used for soil sampling and isolation of EPN. A variety of tools is available and can be used for collecting soil samples including: soil corers, trowels, post-hole diggers, augers, sampling tubes, hand shovels, among others (Figure 2).

Depending on the purpose of the study, two sampling strategies can be considered: a) stratified, b) random sampling (Figure 3). The stratified sampling is usually used as part of an intensive study in a specific or demarked area over a given period of time. In general, a transect is demarked and soil samples are taken at stipulated intervals in the transect over a period of time (Figure 3A)¹⁵. The random sampling is generally employed when focusing on an extensive area. This sampling strategy has been used for studying the diversity of EPN from a large geographic area or region (Figure 3B)¹². A number of factors can be considered depending on the focus of the study including a diverse range of elevations, soil textures and habitats (e.g., cultivated fields, forests, pastures, parks, seashores, riparian areas, etc.).

We show the insect-baiting technique, which was originally described by Bedding and Akhurst¹ and represents a simple and selective alternative for recovering EPN from soil samples. This is a selective procedure that is based on the premise that the nematodes (IJ stage) will be attracted to an insect host and parasitize it. This technique can also be considered for isolation of other insect pathogens such as fungi, and bacteria^8,10.

We also demonstrate the modified White trap technique which is used for retrieving nematode progeny from infected insect hosts^7,14. This is an effortless method that offers the advantage of retrieving a ‘clean’ nematode progeny free of debris from the degrading insect cadavers.

Finally, the techniques described and shown in this article correspond to those conceived and/or performed in our laboratory as well as those described by various colleagues and collaborators.

Protokół

1. Soil Sample Collection

1. Consider covering a minimum area of 2 - 4 m² for each sampling site.
2. Collect soil samples at a depth of at least 15 cm (Figure 4).
3. Take at least 5 random samples within this area.
4. Take 3 subsamples per sample. Depending on the objective of the study, either combine the subsamples or keep them separate.
5. Place each sample in a plastic bag. Consider double-bagging to avoid leaking of samples (Figure 4).
6. Label samples with a waterproof marker. Include the following information from each sampling site: Site information (including locality/area/site name and GPS coordinate information), date, habitat, associated vegetation, temperature, elevation, etc.
   NOTE: If applicable, collect and/or record the presence of insects or other invertebrates collected with the sample for subsequent identification. They may represent potential natural EPN hosts.
7. Clean collecting tools between samples by thoroughly washing with water and/or disinfecting them with 70% ethanol or 0.5% bleach solution.
8. Keep samples in a cooler (8 - 15 °C) during transport to the laboratory.
9. Take a portion of the soil sample for analysis to obtain information on soil composition, texture, moisture, electrical conductivity or other desired soil parameters.

2. Nematode Isolation from Soil Samples: Insect-baiting Technique

1. Remove any debris (i.e., rocks, pieces of wood or bark, leaves, etc.) collected with your samples to avoid contamination with saprobic microorganisms.
2. Add water to moisten the soil and facilitate the movement of nematodes.
   NOTE: Use a spray bottle to slowly increase the moisture level of the soil.
3. Place approximately 200 to 250 ml of moist soil in a clean plastic container with a lid.
4. Add insect baits. Consider 5 to 10 insects to the soil surface of each sample (Figure 5).
5. Cover the container with a lid and turn containers upside down.
6. Maintain containers in the dark and at RT (usually 22 - 25 °C).
7. Check containers every 2 - 3 days and remove dead insects.
   NOTE: add additional healthy insects to each container for further baiting of the soil sample.
8. Remove dead insects from the containers. NOTE: Cadavers with a brown or ochre coloration are usually parasitized by steinernematids, whereas brick red to dark purple cadavers are parasitized by heterorhabditids.
9. Rinse cadavers in sterile water.
10. Place cadavers in a modified White trap for recovery of nematode progeny (see procedure below).

3. Nematode Recovery from Infected Cadavers: Modified White Trap

1. Place the top of a 50 (or 60) mm diam. Petri dish inside a larger dish (100 mm).
2. Set one single circular filter paper (Whatman #1) inside the smaller dish.
3. Place cadavers on the filter paper of the smaller dish making sure cadavers do not touch each other to avoid any contamination.
4. Fill the outer (larger) Petri dish with ca. 20 ml of sterile distilled water. Do not add water in the dish that holds the cadavers.
5. Cover the large Petri dish and its contents with the lid (Figure 6).
6. Label dishes accordingly. Add the following information: Nematode name (species/isolate), infection date (date infection was set) and trap date (this is the date the trap is set up).
7. Keep trap at RT until emergence of infective juvenile stages (IJs) occurs. This process can take between 10 - 25 days depending on the nematode species and/or strain considered.
8. Harvest water with IJs by removing the larger dish of the trap and pouring water with nematodes into a beaker.
9. Allow nematodes to decant to the bottom of the beaker. This process may take a few minutes.
10. Pour water carefully, making sure nematodes remain in the bottom of the beaker.
11. Rinse nematodes by adding more water and allowing nematodes to decant. This step can be repeated 2 - 3 times until water is clean.
12. Place nematode suspension in a tissue culture flask (250 ml). Keep concentration of the suspension to 1,000 - 3,000 nematodes/ml.
13. Store flask with nematode suspension in a cold room or in incubator between 10 - 20 °C.
    NOTE: check stored flasks periodically as shelf life of EPN is variable. Usually steinernematids can be stored for 6 - 12 months without the need of subculturing, whereas heterorhabditids may require more periodic check-ups.

Wyniki

Soil Sample Collection

Third-stage infective juveniles of EPN are the only free living stages in these nematodes’ life cycle which reside in the soil (Figure 1). Therefore, collecting soil samples is a very efficient method to recover of these nematodes. Figure 4 shows a soil profile indicating the depth at which samples should be taken. Preserving the moisture of a sample is a key factor for survival of the nematodes. Consequently, it is important to ke...

Dyskusje

This demonstration is the first of two presentations that describe a number of techniques that are commonly used for studying EPN and their symbiotic bacteria. These techniques represent key steps for the successful establishment of EPN cultures in the laboratory and also form the basis for other bioassays that employ EPN as model organisms for research.

Various soil surveys of EPN have shown that their abundance and distribution can vary across seasons, habitats and geographic regions^{4, ...}

Materiały

Name	Company	Catalog Number	Comments
Galleria mellonella	Timberline	http://www.timberlinefisheries.com/ProductDetails.asp?ProductCode=WAXLG	For insect baiting technique
Filter paper, 55 mm Grade 1 Cellulose	Whatman/VWR	28450-048	Infection chamber and White trap assembly
60 x 15 mm Petri dishes	VWR	25384-092	Infection chamber and White trap assembly
100 x 15 mm Petri dishes	VWR	25384-088	Infection chamber and White trap assembly
ZIPloc plastic bags	Ace Hardware or local hardware store		Soil sampling
Mechanical pipettor P1000, P200 ml	VWR	89130-562; 89130-566	Infection chamber and White trap assembly
Pippetor tips 1000ml, 200 ml	VWR	16466-004 ; 53510	Infection chamber and White trap assembly
Bleach	Ace Hardware or local hardware store		Soil sampling , disinfecting
Sodium hypochlorite	Ace Hardware or local hardware store		Soil sampling , disinfecting
70% Ethyl alochol	AAPER	17212945	Soil sampling , disinfecting
Shovels	Ace Hardware or local hardware store	N/A	Soil sampling
Tubular soil sampler	Accuproducts		Soil sampling
Soil probe, long handle	Nupla	PRB4T 69401 Classic	Soil sampling
Measuring tape	Ace Hardware or local hardware store		Soil sampling
Flagging tape, various colors	Ace Hardware or local hardware store		Soil sampling
Tissue culture flasks	VWR	Falcon, 29185-304	White trap, collection of EPN
Wash bottles, polyethylene, wide mouth	VWR	16650-107	White trap, collection of EPN