Hyperactive piggyBac Transposase-mediated Germline Transformation in the Fall Armyworm, Spodoptera frugiperda

Podsumowanie

Successful germline transformation in the fall armyworm, Spodoptera frugiperda, was achieved using mRNA of hyperactive piggyBac transposase.

Streszczenie

Stable insertion of genetic cargo into insect genomes using transposable elements is a powerful tool for functional genomic studies and developing genetic pest management strategies. The most used transposable element in insect transformation is piggyBac, and piggyBac-based germline transformation has been successfully conducted in model insects. However, it is still challenging to employ this technology in non-model insects that include agricultural pests. This paper reports on germline transformation of a global agricultural pest, the fall armyworm (FAW), Spodoptera frugiperda, using the hyperactive piggyBac transposase (hyPBase).

In this work, the hyPBase mRNA was produced and used in place of helper plasmid in embryo microinjections. This change led to the successful generation of transgenic FAW. Furthermore, the methods of screening transgenic animals, PCR-based rapid detection of transgene insertion, and thermal asymmetric interlaced PCR (TAIL-PCR)-based determination of the integration site, are also described. Thus, this paper presents a protocol to produce transgenic FAW, which will facilitate piggyBac-based transgenesis in FAW and other lepidopteran insects.

Wprowadzenie

The fall armyworm (FAW), Spodoptera frugiperda, is native to tropical and subtropical regions of America. Currently, this is a devastating insect herbivore in more than 100 countries worldwide¹. FAW larvae feed on more than 350 host plants, including some important staple food crops². The strong migration ability of FAW adults contributes to its recent rapid spread from the Americas to other places^1,2. As a result, this insect is now threatening food security internationally. Applying new technologies may facilitate advanced studies in FAW and provide novel strategies to manage this pest.

Insect germline transformation has been used to study gene function and generate transgenic insects for use in genetic control^3,4. Among the various methods used to achieve genetic transformation in insects, the piggyBac element-based method is the most used method⁵. However, due to the low rate of transposition, it is still challenging to conduct transgenesis in non-model insects. Recently, a hyperactive version of piggyBac transposase (hyPBase) was developed^6,7. Germline transformation was achieved in FAW recently⁸, which is the first report that used the hyPBase in lepidopteran insects. In this report, detailed information on employing hyPBase mRNA in generating transgenic FAW is described. The method described here could be applied to achieve the transformation of other lepidopteran insects.

Protokół

1. In vitro synthesis of hyPBase mRNA

NOTE: The complete coding sequence of the hyPBase sequence was synthesized and inserted into a pTD1-Cas9 vector (see the Table of Materials) to produce the pTD1-hyPBase construct, which contains a hyPBase-expressing cassette, T7 promoter: polyhedrin-5' UTR: hyPBase: polyhedrin-3' UTR: poly (A). The full sequence of the pTD1-hyPBase construct is provided in the Supplementary Material.

1. Preparation of the template for in vitro synthesis
   1. Perform a PCR reaction to amplify the hyPBase-expressing cassette using a forward primer, 5'- atgcggtgtgaaataccgcacagatgcg-3', and a reverse primer 5'- tagaggccccaaggggttatgctag-3', high-fidelity polymerase, and pTD1-hyPBase plasmid as a template.
      NOTE: The PCR reaction (final volume of 50 µL) contains 5.0 µL of 10x Reaction buffer, 4.0 µL of 10 mM deoxynucleoside triphosphate (dNTP), 1.0 µL of plasmid (50 µg/µL), 1.0 µL of high-fidelity polymerase, 1.0 µL each of 10 µM forward and reverse primers, and 33 µL of nuclease-free water. The settings were as follows: an initial incubation of 95 °C for 3 min, followed by 35 cycles of 98 °C for 10 s, 60 °C for 15 s, and 68 °C for 2 min.
   2. Check the PCR product on a 1% agarose gel at 120 V in fresh Tris-acetate-ethylenediamine tetraacetic acid (TAE) buffer for 30 min and purify the product with the gel extraction kit.
      NOTE: Do not use the PCR product purification kit. Even a trace amount of the pTD1-hyPBase plasmid significantly decreases the efficiency of in vitro synthesis.
2. In vitro synthesis of hyPBase mRNA using a commercial kit
   1. Completely thaw the frozen reagents, keep the enzyme and 2x NTP/CAP solution on ice, and leave the thawed 10x Reaction buffer at room temperature.
   2. Assemble the reaction at room temperature by adding the following components: 2x NTP/CAP solution: 10 µL; 10x Reaction buffer: 2 µL; Template DNA: 0.1-0.2 µg; Enzyme mix: 2 µL; Nuclease-free water to 20 µL.
   3. Mix the reagents thoroughly by gently pipetting the mixture up and down and incubate at 37 °C for 2-4 h.
3. Recovery of synthesized mRNA by lithium chloride precipitation
   1. Add 30 µL of LiCl Precipitation Solution, mix thoroughly by flicking the tube, and then keep at -20 °C for ≥ 30 min.
   2. Centrifuge at 4 °C for 15 min at the maximum speed, and carefully remove the supernatant.
   3. Wash the pellet once with 1 mL of 70% ethanol, re-centrifuge, and remove the supernatant carefully.
   4. Dry the pellet at room temperature for 1-2 min, and then resuspend the pellet with 20-40 µL of nuclease-free water.
   5. Dilute 1 µL of mRNA solution with 9 µL of nuclease-free water. Take 2 µL to determine the mRNA concentration and use 8 µL to check the mRNA quality on a 1% agarose gel at 100 V in fresh TAE buffer for 40 min.
   6. Aliquot the mRNA solution and store frozen at -70 °C for up to one year.
      ​NOTE: Do not completely dry the mRNA pellet; it may be harder to dissolve it in water.

2. Microinjection

1. Egg collection
   1. Place 12 male pupae and 12 female pupae in a 15 cm x 15 cm x 10 cm box. Cover the box with a paper towel. Place a 10% sucrose solution in the box for feeding adults.
   2. On day 2 post eclosion, expose the adults to intense light overnight.
   3. On day 3 post eclosion, transfer the adults from step 2.1.2 to a dark place. Collect the embryos within 2 h after oviposition.
   4. Add drops of water to the piece of a paper towel with fresh eggs kept in a Petri dish on ice. Transfer the eggs gently to a glass slide with a fine brush and align them one by one on a glass slide. Keep the glass slides with the aligned eggs on ice before microinjection.
2. Microinjection setup
   1. Inject a mixture of a transgenic enhanced green fluorescent protein (EGFP)-expressing plasmid (200 ng/µL), pBac: hr5ie1-EGFP-SV40, hyPBase mRNA (200 ng/µL), and sterile distilled water into the eggs, using the compensation pressure of the automated microinjector (see the Table of Materials).
   2. Keep the injected eggs at 27 ± 1 °C, 60 ± 10% relative humidity until hatching.
   3. Feed the hatched larvae on an artificial diet, and transfer each larva to one small cup at the early 3^rd instar stage (~6 mm in length, and body-color turns black).

3. Fluorescence screening and genetic crossing

1. Collect the pupae and place ~150 female pupae and ~150 male pupae in a 35 cm x 35 cm x 35 cm cage. Hang several pieces of paper towels (~30 cm x 15 cm) in the cage to collect the eggs.
2. Collect the paper towels with eggs daily, and keep the eggs at 27 ± 1 °C, 60 ± 10% relative humidity until hatching.
3. Keep the neonate larvae at 4 °C for 5 min to immobilize them, and then transfer them onto an ice-cold plate.
4. Screen the immobilized neonate larvae under a fluorescence stereomicroscope. Select the EGFP-positive neonates, raise them to the pupal stage in ~2 weeks at 27 ± 1 °C, and separate them by sex according to the phenotype differences at the ventral abdomen segments.
   NOTE: The female pupa has a slit-like genital opening on the eighth abdominal segment and the cephalic margins of the ninth and tenth segments curving toward the genital opening. The genital opening of the male pupa has a slight elevation on the ninth abdominal segment.
5. Place the EGFP-positive pupae and the wild-type pupae of the opposite sex in a male: female ratio of 1:1 in a cage. Sib-cross the EGFP-expressing adults to produce the following generations.

4. PCR detection of transgenic insertion

1. Extract genomic DNA from the wild-type and EGFP-positive individual larvae using any commercial genomic DNA extraction kit following the manufacturer's instructions.
2. Perform a PCR reaction using the genomic DNA as a template; a forward primer, 5'- acgtacgctcctcgtgttccgttc-3' located in the ie1 promoter region; and a reverse primer, 5'- aagcactgcacgccgtaggtcag-3' located in the EGFP region of the transformation vector.
3. Set up each PCR reaction (final volume of 40 µL) to contain 20 µL of the polymerase mixture, 1.0 µL of genomic DNA (40 µg/µL), 1.0 µL each of 10 µM forward and reverse primers, and 17 µL of nuclease-free water. Use the following settings: an initial incubation of 95 °C for 3 min, followed by 35 cycles of 95 °C for 20 s, 56 °C for 20 s, and 68 °C for 40 s settings.
4. Check the PCR products on a 1% agarose gel at 120 V for 30 min.

5. Determination of the transgenic insertion site

1. Perform high-efficiency TAIL-PCR using genomic DNA as a template to determine the integration site of transgene insertion in the EGFP-positive insects.
   1. Perform the PCR reactions following the steps described elsewhere⁹.
      1. Use three primers, P1: 5'-atcagtgacacttaccgcattgacaagcacgcc-3', P2: 5'-tcacgggagctccaagcggcgactg-3', and P3: 5'-atgtcctaaatgcacagcgacggattcgcgct-3', which are specific to the piggyBac vector, in the 3 rounds of PCR reaction, respectively.
2. Sequence the final PCR products to determine the integration site.

Wyniki

A construct for the expression of hyPBase-containing T7 promoter: polyhedrin-5'UTR: hyPBase: polyhedrin-3'UTR: poly (A) signal was generated (Figure 1A) and amplified as a ~2.2 kb PCR fragment to synthesize hyPBase mRNA in vitro (Figure 1B). Then, the hyPBase mRNA was produced and subjected to agarose gel electrophoresis. The mRNA of the expected size (~1.1 kb band) was detected on a 1% agarose gel (Figure 1C).

...

Dyskusje

The low rate of transposition and difficulty of delivering transgenic components into fresh embryos limit the success of germline transformation in many non-model insects, especially those from order, Lepidoptera. To increase the germline transformation rate, a hyperactive version of the most widely used piggyBac transposase (hyPBase) was developed^7,10. To date, successful germline transformation in lepidopteran insects is mainly reported in the model in...

Materiały

Name	Company	Catalog Number	Comments
1.5" Dental Cotton Rolls	PlastCare USA	8542025591	REARING
1 oz Souffle Cup Lids	DART	PL1N
1 oz Souffle Cups	DART	P100N	REARING
48 oz Plastic Deli Containers	Genpack	AD48	REARING
Add-on Filter Set (Green)	NightSea LLC	SFA-BLFS-GR	SCREENING
Borosilicate Glass	Sutter Instruments	BF100-50-10	INJECTION
Borosilicate Glass	SUTTER INSTRUMENT	BF-100-50-10
Dissecting Scope	Nikon	SMZ745T	SCREENING
Featherweight Forceps	BioQuip	4750	REARING
Gutter Guard	ThermWell Products	VX620	REARING
Inverted Microscope	Olympus	IX71	INJECTION
Microinjector	Narishige	IM-300	INJECTION
Micropipette Puller	Sutter Instruments	P-1000	INJECTION
Microscope Slides	VWR	16004-22	INJECTION
NightSea Full System	NightSea LLC	SFA-RB-DIM	SCREENING
Nitrogen Gas	AWG/Scott-Gross	NI 225	INJECTION
Paper Towels	Bounty	43217-45074	REARING
Spodoptera frugiperda Artificial Diet	Southland Products, Inc	N/A [Request Species/Quantity]	REARING
Spodoptera frugiperda Eggs	Benzon Research, Inc	N/A [Request Species/Quantity]	REARING
Taq MasterMix			polymerase mixture