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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol demonstrates how to use the plant host to detect salivary proteins of leafhopper and plant viral proteins released by leafhopper vectors.

Abstract

Insect vectors horizontally transmit many plant viruses of agricultural importance. More than one-half of plant viruses are transmitted by hemipteran insects that have piercing-sucking mouthparts. During viral transmission, the insect saliva bridges the virus-vector-host because the saliva vectors viruses, and the insect proteins, trigger or suppress the immune response of plants from insects into plant hosts. The identification and functional analyses of salivary proteins are becoming a new area of focus in the research field of arbovirus-host interactions. This protocol provides a system to detect proteins in the saliva of leafhoppers using the plant host. The leafhopper vector Nephotettix cincticeps infected with rice dwarf virus (RDV) serves as an example. The vitellogenin and major outer capsid protein P8 of RDV vectored by the saliva of N. cincticeps can be detected simultaneously in the rice plant that N. cincticeps feeds on. This method is applicable for testing the salivary proteins that are transiently retained in the plant host after insect feeding. It is believed that this system of detection will benefit the study of hemipteran-virus-plant or hemipteran-plant interactions.

Introduction

The vector-host transmission mode of arboviruses, a fundamental problem, is at the frontier of biological science. Many plant viruses of agricultural importance are horizontally transmitted by insect vectors1. More than one-half of plant viruses are vectored by hemipteran insects, including aphids, whiteflies, leafhoppers, planthoppers, and thrips. These insects have distinct features that enable them to efficiently transmit plant viruses1. They possess piercing-sucking mouthparts and feed on the sap from phloem and xylem, and secrete their saliva1,2,3,4. With the development and improvement of techniques, the identification and functional analyses of salivary components are becoming a new focus of intensive research. The known salivary proteins in saliva include numerous enzymes, such as pectinesterase, cellulase, peroxidase, alkaline phosphatase, polyphenol oxidase, and sucrase, among others5,6,7,8,9,10,11,12,13. The proteins in saliva also include elicitors that trigger the host defense response, thereby altering the performance of insects, and effectors that suppress the host defense, which enhances insect fitness and components that induce host pathological responses14,15,16,17. Therefore, saliva proteins are vital materials for communication between insects and hosts. During the transmission of viruses, the saliva secreted by the salivary glands of piercing-sucking viruliferous insects also contains viral proteins. Viral components utilize the flow of saliva to release them from the insect to the plant host. Therefore, the insect saliva bridges the virus-vector-host tritrophic interaction. Investigating the biological function of saliva proteins secreted by viruliferous insects helps to understand the relationship of virus-vector-host.

For animal viruses, it is reported that the saliva of mosquitoes mediates the transmission and pathogenicity of West Nile virus (WNV) and Dengue virus (DENV). The saliva protein AaSG34 promotes dengue-2 virus replication and transmission, while the saliva protein AaVA-1 promotes DENV and Zika virus (ZIKV) transmission by activating autophagy18,19. The saliva protein D7 of mosquitoes can inhibit DENV infection in vitro and in vivo via direct interaction with the DENV virions and recombinant DENV envelope protein20. In plant viruses, the begomovirus tomato yellow leaf curl virus (TYLCV) induces the whitefly salivary protein Bsp9, which suppresses the WRKY33-mediated immunity of plant host, to increase the preference and performance of whiteflies, eventually increasing the transmission of viruses21. Because studies of the role that insect salivary proteins play in plant hosts have lagged behind those of animal hosts, a stable and reliable system to detect the salivary proteins in plant hosts is urgently required.

The plant virus known as rice dwarf virus (RDV) is transmitted by the leafhopper Nephotettix cincticeps (Hemiptera: Cicadellidae) with high efficiency and in a persistently propagative manner22,23. RDV was first reported to be transmitted by an insect vector and causes a severe disease of rice in Asia24,25. The virion is icosahedral and double-layered spherical, and the outer layer contains the P8 outer capsid protein22. The circulative transmission period of RDV in N. cincticeps is 14 days26,27,28,29,30. When the RDV arrives at salivary glands, virions are released into saliva-stored cavities in the salivary glands via an exocytosis-like mechanism23. The vitellogenin (Vg) is the yolk protein precursor essential for oocyte development in female insects31,32,33. Most insect species have at least one Vg transcript of 6-7 kb, which encodes a precursor protein of approximately 220 kDa. The protein precursors of Vg can usually be cleaved into large (140 to 190 kDa) and small (<50 kDa) fragments before entering the ovary18,19. Previous proteomic analysis revealed the presence of the peptides derived from Vg in the secreted saliva of the leafhopper Recilia dorsalis, although their function is unknown (unpublished data). It is newly reported that Vg, which is orally secreted from planthoppers, functions as an effector to damage the defenses of plants34. It is unknown whether the Vg of N. cincticeps could also be released to the plant host with salivary flow, and then could play a role in the plant to interfere with plant defenses. To address whether N. cincticeps exploits salivary proteins, such as Vg, to inhibit or activate plant defenses, the first step is identifying proteins released to the plant during feeding. Understanding the method to identify the salivary proteins present in the plant is potentially essential to explain the function of saliva proteins and the interactions between Hemiptera and plants.

In the protocol presented here, N. cincticeps is used as an example to provide a method to examine the presence of salivary proteins in the plant host introduced through insect feeding. The protocol primarily details the collection and detection of salivary proteins and is helpful for further investigation on most hemipterans.

Protocol

The non-viruliferous adult leafhoppers were propagated in the Vector-borne Virus Research Center in Fujian Agriculture and Forestry University, China.

1. Nonviruliferous insect rearing

  1. Rear the adults on rice seedlings in a cube cage that is 40 cm x 35 cm x 20 cm (length x width x height). Keep one side of the cage covered with an insect-proof net for ventilation.
    1. Keep the cages with leafhoppers in an incubator that contains an in-built humidity controller at 26 °C with a relative humidity of 60-75% under a photoperiod of 16 h light and 8 h dark.
  2. Use an aspirator to gently transfer all the adults from their cage into a new cage that contains fresh rice seedlings each week.
    1. Let more than 200 adults mate and lay eggs in the rice.
    2. Retain the old rice seedlings for the nymphs to emerge. Rear these new nonviruliferous nymphs to the 2-instar stage.

2. Virus acquisition and the collection of viruliferous insects

  1. Carefully transfer the 2-instar nonviruliferous nymphs to a glass culture tube (2.5 cm in diameter by 15 cm high) for 1-2 h for starvation using the aspirator.
    1. Release the nymphs to a cage that contains an RDV-infected rice plant grown in a pot.
    2. Allow the nymphs to feed on the infected rice plant for 2 days.
      NOTE: Carefully water the rice plant and avoid washing away the nymphs. The 2-instar nymphs are approximately 1.6-2 mm long.
  2. Carefully transfer these nymphs to a new cage that contains fresh virus-free rice seedlings with a relative humidity of 60-75% under a photoperiod of 16 h light and 8 h dark. Allow the nymphs to feed on the infected rice plant for 12 days to complete the circulative transmission period of RDV.

3. Collection of salivary proteins using a feeding cage

  1. Prepare five small pipe-like feeding cages (2.5 cm in diameter by 4 cm high) in which one end is covered with insect-proof netting.
  2. Confine 15-20 leafhoppers in each feeding cage, and then cover the other end of the cage with a thin foam mat.
    1. Fix one rice seedling (5-6 cm high) between the end of cage and a foam mat with tapes. Ensure that the leafhoppers in the feeding cage can feed on the rice seedlings exposed to the interior of the cage.
  3. Immerse the seedling roots in water so that the rice plant will remain alive. Allow the leafhoppers to feed on them for 2 days.
  4. Remove the leafhoppers from their feeding cages and collect the rice seedlings on which they fed. Cut the parts of seedlings outside of the cage and recover the feeding regions of seedlings.
    ​NOTE: This sample can be stored at -80 °C for 3 months at the most, if it is not instantly used for detection.

4. Reagent preparation

  1. Dissolve 15.1 g of Tris-base, 94 g of glycine, and 5 g of SDS in 1 L of sterile water to prepare 5xTris-glycine buffer. Dilute 200 mL of 5xTris-glycine buffer with 800 mL of sterile water to prepare 1xTris-glycine buffer (see Table 1 for buffer composition).
  2. Dissolve 80 g of NaCl, 30 g of Tris-base, and 2 g of KCl in 1 L of sterile water to prepare 10xTris-buffered saline (TBS) buffer. Autoclave the solution at 121 °C for 15 min.
  3. Dissolve 8 g of SDS, 4 mL of ß-mercaptoethanol, 0.02 g of bromophenol blue, and 40 mL of glycerol in 40 mL of 0.1 M Tris-HCl (pH 6.8) to prepare 4x protein sample buffer.
  4. Mix 800 mL Tris-glycine buffer with 200 mL methanol to prepare the transfer buffer.
  5. Add 100 mL 10xTBS solution and 3 mL Tween 20 to 900 mL sterile water to prepare the TBS buffer with Tween 20 (TBST) solution.

5. Western blotting to detect the saliva and viral proteins

  1. Grind 0.1 g of the rice samples with liquid nitrogen until the tissue becomes a powder. Add 200 µL of 4x protein sample buffer to the sample and boil it for 10 min. Centrifuge the samples at 12,000 x g for 10 min at room temperature.
    1. Remove the supernatant and place it in a new vial. Load 10 µL of the sample into an SDS-PAGE gel, and run it in Tris-glycine buffer at 150 V for 45-60 min.
      NOTE: The residue after centrifugation can be discarded.
  2. Put a 0.45 µm nitrocellulose membrane and other sandwich supplies in the Transfer buffer for 30 min.
    NOTE: This step can be done before the gel has completed its run.
  3. Sandwich the gel and transfer it for 90-120 min at 100 V in the Transfer buffer.
  4. Take the membrane and place it in 7% non-fat dry milk blocking solution in TBST solution for 20 min. Add the specific antibody against RDV P8 or Vg to a 7% solution of non-fat dry milk in TBST. Incubate with the antibody for staining the membrane for 2 h or overnight.
  5. Wash the membrane with TBST solution three times, with 5 min washing each time.
  6. Add the goat anti-rabbit IgG as a secondary antibody to 7% non-fat dry milk with TBST. Incubate with the antibody for 60-90 min at room temperature.
  7. Wash the membrane with TBST solution three times for 5 min each time.
  8. Use the ECL Western kit for the chemiluminescent method. Mix Detection Reagents 1 and 2 in the kit at a ratio of 1:1 in a tube. Put the mixed reagent onto the membrane and incubate the blot for 5 min.
  9. Drain the excess reagent and take a colorimetric picture of the chemiluminescent picture. Combine them to see the ladder with protein bands.

Results

Figure 1 illustrates all of the steps in this protocol: insect rearing, virus acquisition, the collection of salivary proteins via rice feeding, and the western blot. The western blots results showed that specific and expected bands of approximately 220 kDa were observed in the samples of feeding rice and salivary glands of insects on the membrane incubated with antibodies against Vg. In contrast, no band was observed in the non-feeding rice sample. The result in

Discussion

The saliva directly secreted by the salivary glands of the piercing-sucking insects plays a pivotal role because it predigests and detoxifies the host tissues and vectors' cross-kingdom biological factors into the hosts1,3,4. The cross-kingdom biological factors, including elicitors, effectors, and small RNA, are critical for insect-host communication14,15,

Disclosures

The authors have nothing to disclose.

Acknowledgements

This work was supported by grants from the National Natural Science Foundation of China (31772124 and 31972239) and Fujian Agriculture and Forestry University (Grant KSYLX014).

Materials

NameCompanyCatalog NumberComments
Reagents
Tris baseRocheD609K69032For 5×Tris-glycine buffer and 10×TBS buffer preparation
glycineSigma-AldrichWXBD0677VFor 5×Tris-glycine buffer preparation
SDSSigma-AldrichSLCB4394For 5×Tris-glycine buffer preparation
NaClSinopharm Chemical Reagent Co., Ltd10019318For 10×TBS buffer preparation
KClSinopharm Chemical Reagent Co., Ltd10016318For 10×TBS buffer preparation
ß-mercaptoethanolXiya ReagentB14492For 4× protein sample buffer preparation
bromophenol blueSigma-AldrichSHBL3668For 4× protein sample buffer preparation
glycerolSinopharm Chemical Reagent Co., Ltd10010618For 4× protein sample buffer preparation
methanolSinopharm Chemical Reagent Co., Ltd10014118For transfer buffer preparation
Tween 20Coolaber SCIENCE&TeCHNoLoGYCT30111220For TBST preparation
non-fat dry milkBecton.Dickinso and company252038For membrane blocking, antibodies dilution
goat anti-rabbit IgGSangon BiotechD110058-0001Recognization of the primary andtibody
ECL Western kitThermoFisher Scientific32209Chemiluminescent substrate
nitrocellulose membranePall Corporation25312915For proteins transfer
Buffers and Solutions
BufferCompositionComments/Description
 5×Tris-glycine buffer15.1 g Tris base
94 g glycine
 5 g SDS in 1 L sterile water		 Stock solution
1×Tris-glycine buffer200 mL of 5×Tris-glycine buffer
800 mL sterile water		Work solution, for SDS-PAGE
10×Tris-buffered saline (TBS) buffer80 g NaCl
30 g Tris base
2 g KCl
in 1 L sterile water		Stock solution
TBS with Tween 20 (TBST) solution100 mL 10×TBS solution
3 mL Tween 20
900 mL sterile water		Work solution
4× protein sample buffer8 g SDS
4 mL ß-mercaptoethanol
0.02 g bromophenol blue
40 mL glycerol
in 40 mL 0.1 M Tris-HCl (pH 6.8)		For protein extraction
Transfer buffer800 mL Tris-glycine buffer
200 mL methanol		For protein transfer
Instruments
Bromophenol blueSigma-AldrichSHBL3668For 4x protein sample buffer preparation
Constant temperature incubatorNingbo Saifu Experimental Instrument Co., Ltd.PRX-1200BFor rearing leafhoppers
ElectrophoresisTanon Science & Technology Co.,Ltd.Tanon EP300For SDS-PAGE
Electrophoretic transfer core moduleBIO-RAD1703935For SDS-PAGE
glycerolSinopharm Chemical Reagent Co., Ltd10010618For 4x protein sample buffer preparation
glycineSigma-AldrichWXBD0677VFor 5x Tris-glycine buffer preparation
goat anti-rabbit IgGSangon BiotechD110058-0001Recognization of the primary andtibody
High-pass tissue grinding instrumentShanghai Jingxin Industrial Development Co., Ltd.JXFSIPRP-24For grinding plant tissues
KClSinopharm Chemical Reagent Co., Ltd10016318For 10x TBS buffer preparation
methanolSinopharm Chemical Reagent Co., Ltd10014118For transfer buffer preparation
Mini wet heat transfer troughBIO-RAD1703930For SDS-PAGE
NaClSinopharm Chemical Reagent Co., Ltd10019318For 10x TBS buffer preparation
nitrocellulose membranePall Corporation25312915For proteins transfer
non-fat dry milkBecton.Dickinso and company252038For membrane blocking, antibodies dilution
Pierce ECL Western kitThermoFisher Scientific32209Chemiluminescent substrate
Protein color instrumentGE Healthcare bio-sciences ABAmersham lmager 600For detecting proteins
SDSSigma-AldrichSLCB4394For 5x Tris-glycine buffer preparation
Tris baseRocheD609K69032For 5x Tris-glycine buffer and 10×TBS buffer preparation
Tween 20Coolaber SCIENCE&TeCHNoLoGYCT30111220For TBST preparation
Vertical plate electrophoresis tankBIO-RAD1658001For SDS-PAGE
Water bathShanghai Jinghong Experimental equipment Co., Ltd.XMTD-8222For boil the protein samples
β-mercaptoethanolXiya ReagentB14492For 4x protein sample buffer preparation

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LeafhopperSalivary ProteinsRice SeedlingsPlant HostsVirus DetectionHemiptera DetectionNon viruliferous NymphsRice Dwarf VirusCirculative TransmissionFeeding CagesProtocolIncubation Conditions

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