Summary

Identification and Characterization of Immunogenic RNA Species in HDM Allergens that Modulate Eosinophilic Lung Inflammation

Published: May 30, 2020
doi:

Summary

Environmental allergens such as house dust mites (HDM) often contain microbial substances that activate innate immune responses to regulate allergic inflammation. The protocol presented here demonstrates the identification of dsRNA species in HDM allergens and characterization of their immunogenic activities in modulating eosinophilic lung inflammation.

Abstract

Environmental allergens such as house dust mites (HDM) are often in complex forms containing both allergic proteins that drive aberrant type 2 responses and microbial substances that induce innate immune responses. These allergen-associated microbial components play an important role in regulating the development of type 2 inflammatory conditions such as allergic asthma. However, the underlying mechanisms remain largely undefined. The protocol presented here determines the structural characteristics and in vivo activity of allergen-associated immunostimulatory RNA. Specifically, common allergens are examined for the presence of double-stranded RNA (dsRNA) species that can stimulate IFN responses in lungs and restrain the development of severe lung eosinophilia in a mouse model of HDM-induced allergic asthma. Here, we have included the following three assays: Dot blot to show the dsRNA structures in total RNA isolated from allergens including HDM species, RT-qPCR to measure the activities of HDM RNA in interferon stimulating genes (ISGs) expression in mouse lungs and FACS analysis to determine the effects of HDM RNA on the number of eosinophils in BAL and lung, respectively.

Introduction

Based on the hygiene hypothesis originally proposed by Strachan1, early childhood exposure to environmental microbial factors such as endotoxin can protect against the development of allergic disorders2,3. During microbial infections, e.g., viral infections, the innate immune detection of foreign nucleic acids (RNA/DNA) triggers host defense responses4,5,6. However, the existence and prevalence of immunogenic nucleic acids such as long double-stranded RNA (dsRNA) species in house dust mites (HDM) or other insect allergens remain unknown. This protocol was designed to determine whether HDM or insect and non-insect allergens contain long dsRNA species that can activate a protective immune response to counteract the development of severe eosinophilic lung inflammation in a mouse model of allergic asthma. Here, we provide three simple and fast methods to evaluate the structural determinants in HDM total RNA that are required for regulating allergen-induced eosinophilic lung inflammation.

The mucosal immune system is the largest immune organ in the body and serves as the first line of host defense against both microbial infections and allergic insults7,8. The long dsRNA, the replication intermediate of many viruses, is known to function as a pathogen-associated molecular pattern (PAMP) to potently stimulate innate responses via Toll like receptor 3 (TLR3) to induce the expression of interferon stimulated genes (ISGs)9,10,11,12,13,14. We have recently shown that HDM total RNA contained dsRNA structures, which upregulated the expression of ISGs and reduced severe eosinophilic lung inflammation when administered via the intratracheal instillation in a murine model of allergic asthma induced by HDM extracts15. The severity of lung inflammations is determined by analyzing the immune cell types in bronchoalveolar lavage (BAL) and lung tissue via flow cytometry16,17,18,19,20.

This protocol includes three assays: 1) rapid detection of dsRNA structures with RNA dot blot using a mouse monoclonal antibody J2 which specifically binds to the dsRNA (≥40bp) in a sequence-independent manner; 2) quick evaluation for in vivo effects of immunostimulatory RNA in mouse lungs by measuring the induction of ISGs using RT-qPCR; 3) accurate quantification of eosinophils in BAL and lung in the context of HDM-induced lung inflammation using flow cytometry analysis.

The above assays can be used to study not only allergic lung diseases, but also respiratory bacterial and viral infections. For example, the dsRNA specific J2 antibody can also be used in other applications such as immunoaffinity chromatography, immunohistochemistry, enzyme-linked immunosorbent assay (ELISA) and immunostaining21,22,23. In addition, several applications downstream of BAL fluid collection can be utilized for quantifying soluble contents such as cytokines and chemokines using ELISA, and transcriptional profiling of cells in the airways (e.g., alveolar macrophages). Although there are a variety of protocols available in the literature to evaluate lung conditions, most of these protocols often focus on the target validation. The procedures described here can be applied to identify components in environmental allergens that are important for regulating the development of allergic diseases.

Protocol

Experimental procedures described here were approved by the Institutional Animal Care and Use Committee of University of Texas Health San Antonio.

1. Dot blot to show the presence of dsRNA structures in HDM total RNA

  1. Total RNA isolation from allergens, insects, and non-insect allergens
    1. Put HDM, insects, or non-insect animals collected alive or obtained commercially into 50 mL tubes, and quickly freeze with liquid-N2. Then store at -70 °C for subsequent total RNA isolation.
      NOTE: In this experiment, HDM, insect, and non-insect animals were selected because they are known to be common sources of allergens. Further, an immunostimulatory function of their RNAs remain unclear.
    2. Transfer a proper amount (equivalent to 100 μL in volume or less) of HDM, insects or non-insect animals stored at -70 °C into a 2 mL tube containing beads (1.4 mm ceramic spheres), then freeze tubes in a liquid-N2 container for ~10 min.
    3. For the total RNA isolation, add 1 mL of guanidinium thiocyanate-based RNA isolation reagent24 to each tube, then break the insect and non-insect small animals with a high-energy cell disrupter at the maximum speed for 45 s and chill on ice. Repeat this step twice.
    4. Transfer the solution from step 1.1.3 into a new 1.5 mL tube and add 200 μL of chloroform to each tube and vortex. Centrifuge tubes at 14,000 x g for 14 min at 4 °C.
    5. Once centrifugation is completed, transfer the upper aqueous phase (200 μL) into a new 1.5 mL tube containing 500 μL of isopropanol to precipitate RNA pellet. Do not disturb the interphase. The recommended volume ratio of the upper phase versus isopropanol is 1:2.5 ratio.
    6. Mix by gentle vortexing, then centrifuge tubes at 14,000 x g for 14 min at 4 °C.
    7. Aspirate the supernatant with caution then wash the RNA pellet with 500 μL of 75% ethanol and centrifuge at 7,500 x g for 10 min at 4 °C. Remove all liquid with caution, air-dry the pellet and dissolve the RNA pellet with 20-50 μL of RNase-free H2O.
    8. Measure the RNA concentration with a spectrophotometer using the following parameters:
      1. Open the associated software and select the type of nucleic acids to measure. Change the sample type to RNA.
      2. Perform the blank measurement with 1-2 μL of RNase-free H2O. Wipe off the RNase-free H2O. Now, the instrument is ready for the measurement.
      3. Load 1-2 μL of the RNA sample and measure the RNA concentration (μg/μL).
        NOTE: The ratio of the absorbance at 260 and 280 nm (A260/280) at ~2.0 (1.9-2.2) is generally accepted as “pure” for RNA. If not processed immediately, store RNA samples at -70 ˚C and avoid the freeze-thaw cycles to keep the RNA intact.
  2. Detection of dsRNA structure in the total RNA using dsRNA specific J2 antibody
    1. Prepare two 20 μL of RNA samples (200 ng/μL). One with RNase-III treatment (1 μL for 1 μg RNA, incubate at 37 °C for 60 min), and the other without RNase-III treatment.
      NOTE: RNase III is used here to specifically degrade dsRNA, but not single-stranded RNA25.
    2. Use a pencil to draw grids where RNA samples will be blotted on the membrane.
    3. Spot 2 μL of the 200 ng/μL of the RNA sample onto the positively charged nylon membrane.
    4. Crosslink the samples to the membrane at 1,200 microjoules x 100 in a UV crosslinker. Repeat steps 1.2.3 and 1.2.4 two more times in the sample spot place. This will result in total 0.8 μg per blot.
      NOTE: Do not spot more than 2 μL of RNA sample on the membrane at a time.
    5. Block non-specific binding with 5% milk in TBS-T for 1 h with shaking at room temperature. Remove the blocking solution from step 1.2.5 and add the anti-dsRNA J2 antibody at the 1:1,000 dilution in 1% milk in TBS-T and incubate overnight with shaking at 4 °C.
    6. Wash the membrane with TBS-T for 5 min and repeat this step for 3 times. Add the secondary antibody (Alkaline phosphatase-conjugated Anti-Mouse IgG diluted in 1% milk 1:5,000) and incubate for 1 h on a shaker at room temperature. Wash the membrane with TBS-T for 5 min and repeat this step for 3x.
    7. Add the substrate (BCIP/NBT) and incubate for 5-15 min until a desired signal is visible.
    8. Stop the reaction by rinsing the membrane with ddH2O.
    9. Dry the membrane on tissue papers and take a photograph using a smartphone (a representative result is shown in Figure 1).

2. RT-qPCR to measure the ability of HDM total RNA in stimulating lung ISGs expression

  1. RNA isolation from mice lung tissues
    NOTE: Mice (female, 8-12 weeks old, C57BL/6J) were maintained under specific pathogen-free conditions.
    1. Briefly anesthetize the animal with isoflurane and administer via the intratracheal instillation with 5 μg (diluted in 80 μL PBS) of HDM RNAs treated with or without RNase III.
    2. After 16-18 h post HDM RNA treatment, sacrifice the mouse by CO2 inhalation for a few minutes. Then, place the mouse on a platform and pin limbs with needles.
    3. Disinfect the mouse with 70% ethanol then cut the skin starting from abdomen to the neck with a sterilized scissor.
    4. Fix the skin with needles and cut the ribs to expose the lungs. Remove the whole lungs and wash them with cold PBS. Place the lungs on tissue papers and excise one small piece of each lung-lobe into a 2 mL tube containing beads (200-300 μL in volume, 1.4 mm ceramic spheres).
      NOTE: The purpose of using ceramic beads is to grind whole lung tissues
    5. Freeze the lung samples by placing tubes into a liquid-N2 container for ~10 min.
    6. Add 500 μL of guanidinium thiocyanate-based RNA isolation reagent to each tube and break the lung tissues with a homogenizer for 45 s. Chill on ice between each step. Repeat this step twice.
    7. Follow the steps 1.1.4- 1.1.7 for lung RNA isolation.
    8. Air-dry the pellet and dissolve the RNA pellet with proper amount of RNase-free H2O (~20-30 μL).
    9. Measure the RNA concentration as described in step 1.1.8.
  2. RT-qPCR to determine the ability of HDM RNA in stimulating lung gene expression.
    1. Using 100 ng/μL of RNA extracted from lung tissues as the template, perform the cDNA synthesis according to the referenced protocol26.
    2. Set up an RT-qPCR reaction at 10 μL/well for a 384-well plate using cDNA generated above and the gene-specific primer pairs (Table 1 and Table 2).
    3. Seal the wells tightly with a transparent adhesive film and vortex the plate for 30 s. Spin the plate at 1,000 x g for 30 s to collect samples at the bottom of the wells.
    4. Load the plate onto a RT-qPCR machine and start to run the RT-qPCR reaction using the thermal cycler protocol (Table 3).
    5. Export the results into a spreadsheet file or analyze the data using the software provided by the manufacture after the program is completed (a representative result is shown in Figure 2).

3. FACS analysis to determine the effects of HDM RNA on the infiltration of eosinophils in BAL and lung

  1. BAL fluid collection for FACS analysis
    1. Euthanize mice (female, 8-12 weeks old, C57BL/6J) that were treated with HDM allergen extracts (according to the experimental design shown in Figure 3B) by CO2 inhalation.
    2. Place the mouse on a platform and pin limbs with needles.
    3. Disinfect the mouse with 70% ethanol. Use scissors to cut the skin from the upper area of the abdomen to the neck.
    4. Gently, pull the salivary glands and the sternohyoid muscle carefully apart using the forceps to expose the trachea. Place a nylon string (~10 cm) under the trachea using forceps.
    5. Make an incision in the trachea (~2 mm under the larynx) just enough to insert a cannula. Do not cut through the trachea. Knot the string around trachea and cannula.
    6. Load the syringe with 1 mL of PBS+EDTA and attach it to the end of the cannula. Inject 1 mL of PBS+EDTA into the lung and completely aspirate the solution. Detach the syringe from the cannula carefully and transfer the solution into a 15 mL tube on ice.
    7. Reload the syringe with the fresh PBS+EDTA and repeat this step 2x.
    8. Centrifuge the tube containing the pooled BAL obtained in step 3.1.7 to pellet the cells at 500 x g for 7 min at 4 °C. Record the volume of BAL fluid then transfer the supernatant to two 1.5 mL tubes without disturbing the pellet.
      NOTE: The supernatant of BAL can be stored at -70 °C for future analysis e.g., ELISA.
    9. In case there are RBCs present in the pellet due to severe lung inflammation, after removing the supernatant, add 500 μL of RBC lysis buffer and mix well by resuspension. Transfer the solution into a new 1.5 mL tube and centrifuge for 7 min at the speed of 500 x g at 4 °C.
    10. Remove the supernatant and resuspend the pellet in 150 μL of FACS buffer.
    11. Transfer the 150 μL of the resuspended sample into 96-well plate and centrifuge the plate for 7 min at the speed of 500 x g at 4 °C.
    12. Quickly, invert the plate on tissue papers to collect the cells residing at the bottom of the wells.
    13. Stain the cells with antibodies in FACS buffer in the presence of 2.4G2 blocking antibody (2.5 μg / 100 μL). Incubate the plate at room temperature for 30 min in a dark place.
    14. After staining, centrifuge the plate to pellet the cells at 500 x g for 7 min at 4 °C.
    15. Remove the staining solution by inverting the plate on tissue paper then wash by resuspending with 100 μL of FACS buffer. Next, centrifuge the plate again at 500 x g for 7 min at 4 °C and remove the FACS buffer by inverting the plate on tissue paper.
    16. Resuspend samples into 150 μL of FACS buffer and transfer samples to the FACS tubes containing 350 μL of FACS buffer. Add 25 μL of counting beads to each sample. Samples are now ready for flow cytometry analysis.
      NOTE: Various cell types in BAL fluid were labeled with antibodies as indicated. Counting beads were added before the FACS run. Flow cytometry data were analyzed using a commercially available software. Refer to Figure 3 and Table 4 for gating strategy.
  2. Lung tissue digestion for the FACS analysis
    1. Follow steps 3.1.1 – 3.1.3.
    2. Cut the skin starting from abdomen to the neck with a sterilized scissor. Fix the skin with needles and cut the ribs to expose the lungs.
    3. Remove the whole lungs and wash them with cold PBS. Place samples in the 1.5 mL tube containing 50 μL of lung digestion solution.
    4. Mince the lung tissues into small pieces with a curved scissor. Transfer the lung tissues into a 6-well plate, then add 8 mL of lung digestion solution. Place the plate on a shaker in 37 °C incubator for 45 min.
    5. After incubation, use the top of 1.5 mL tube to grind the lung tissues. Place a 70 µm strainers on a new 6-well plate and apply the sample through 0.22 µm filter.
    6. Transfer the filtered solution into a 15 mL tube, then centrifuge the tubes at 500 x g for 7 min at 4 °C. Aspirate the supernatant and resuspend the pellet in 1 mL of RBC lysis buffer and leave it on ice for 3 min.
    7. Transfer the sample into 1.5 mL tube and centrifuge at 500 x g for 7 min at 4 °C. Repeat 2x
    8. Wash the lung cells 2x with 1 mL FACS buffer. Aspirate the supernatant and resuspend the pellet in 1 mL of FACS buffer, and then transfer 100 μL of the sample into 96 well plate.
    9. Centrifuge the plate for 7 min at the speed of 500 x g at 4 °C. Follow the steps described in BAL fluid collection for FACS analysis (3.1.13 to 3.1.16) to stain the cells of digested lung tissue samples.
      NOTE: Eosinophils in the lungs were labeled with antibodies as indicated, then mixed with counting beads for further FACS analysis. Flow cytometry data were analyzed using associated software. Refer to Figure 3 for evaluating HDM RNA-induced immune responses.

4. Statistical analysis

  1. Perform statistical analysis using a commercially available software.
  2. Determine the p values by unpaired two-tailed Student t test for the comparison of two groups.
  3. Calculate the absolute numbers of eosinophils based on reference beads (top panel) using the formula

Equation 1

  1. Determine the p values by two-way ANOVA and Sidak’s multiple comparisons test for the comparison of more than two groups.
  2. Consider a p value smaller than 0.05 as statistically significant. The p values are indicated on plots as *p <0.05, **p<0.01, ***p<0.001, and ****p<0.0001.
    NOTE: All buffer recipes are provided in Table 5.

Representative Results

The presence of long dsRNA structures in HDM, insects and non-insect small animals was examined by dot blot using a dsRNA-specific mouse monoclonal antibody J2 (≥ 40bp). RNase III was used to digest dsRNA into 12–15 bp dsRNA fragments, which were undetectable by J2 (Figure 1).

The ability of HDM total RNA to stimulate an innate immune response in mouse lungs in a dose-dependent manner was analyzed by RT-qPCR (Figure 2, upper). The RNase III treatment abolished the immunostimulatory activity of HDM total RNA, indicating that dsRNA structures in HDM total RNA is essential for innate immune activity in the lungs (Figure 2, lower).

The inhibitory effects of HDM total RNA on the development of a severe type 2 lung inflammation were evaluated with the FACS analysis (Figure 3A). In this study, the eosinophilic lung inflammation was induced by HDM extracts, which were treated with or without RNase III as depicted in the experimental design (Figure 3B). RNase III treatment was used to remove long dsRNA species from HDM extracts. As expected, the degradation of long dsRNA species resulted in severe type 2 lung inflammation reflected by the increased eosinophils numbers in BAL and lungs. Notably, the number of eosinophils in the HDM total RNA-treated group is comparable to the group treated with the original HDM extract that endogenously contains the long dsRNA species (Figure 3B).

Figure 1
Figure 1: Detection of the dsRNA structures in HDM RNAs by dsRNA specific J2 Ab using dot blot. Total RNA from different aeroallergens including Dermatophagoides farinae (D.f.) and Dermatophagoides pteronyssinus (D.p.) was blotted on a nylon membrane for the detection of dsRNA (left panel). HDM (D.f. and D.p.) RNA was left untreated (-), treated with RNase III (dsRNA-specific nuclease) and RNase T1 (ssRNA-specific nuclease) (right panel). This figure is reprinted from She et al.15. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Induction of ISG mRNA expression by total RNA from HDM (D.f.) was measured by RT-PCR. When delivered into mouse lungs, HDM RNA was able to stimulate the expression of ISGs in a dose-dependent manner (upper panel). RNase III treatment eliminated the immune stimulating activity of HDM RNA (lower panel). This figure is reprinted from She et al.15. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Characterization of specific cell types in the airways and evaluation of BAL fluid and lung eosinophils. (A) Gating strategy used to identify cells recovered from BAL fluid were stained for cell surface markers as indicated. (B) Administration of HDM (D.f.) RNA at 5 μg/mouse (blue bar) versus control mouse lung RNA (red bar). HDM (D.f.) RNA but not dsRNA-depleted HDM extract decreased the number of eosinophils in both airways and lungs of animals treated with HDM extract. This figure is reprinted from She et al.15. Please click here to view a larger version of this figure.

Mouse Primers Sequence (Forward-Reverse, 5’→3’)
RPL19 AAATCGCCAATGCCAACTC;
TCTTCCCTATGCCCATATGC
IL1β TCTATACCTGTCCTGTGTAATG;
GCTTGTGCTCTGCTTGTG
IFIT3 TGGCCTACATAAAGCACCTAGATGG;
CGCAAACTTTTGGCAAACTTGTCT
ISG15 GAGCTAGAGCCTGCAGCAAT;
TTCTGGGCAATCTGCTTCTT
Mx1 TCTGAGGAGAGCCAGACGAT;
ACTCTGGTCCCCAATGACAG
OASL2 GGATGCCTGGGAGAGAATCG;
TCGCCTGCTCTTCGAAACTG
TNFα CCTCCCTCTCATCAGTTCTATGG;
GGCTACAGGCTTGTCACTCG

Table 1: RT-qPCR Primers.

Reagents Volume (10 μl)
Universal SYBR Green supermix (2x) 5 μl
Forward and reverse primers (5 μM) 1 μl
cDNA template 0.4 μl
DNase- and RNase-free H2O 3.6 μl

Table 2: Master mix setup for RT-qPCR.

Steps Temperature Time
Step 1 95 oC 3 minutes
Step 2 95 oC 10 seconds
Step 3 55 oC 30 seconds
Step 4 Go to step 2, (Repeat 2-3 for 39 cycles)
Step 5 (Melt Curve) 55 oC to 95 oC 0.5 oC, increments (hold time is 5 seconds)

Table 3: Program for running the RT-qPCR.

1. Create a plot composed of forward (FSC) and side scatter (SSC).
2. Create a small plot for counting beads (FSC low, FITC high).
3. Create a plot to only gate for live cells while excluding dead cells using BV510 dye.
4. Live cells can then be separated into CD11c high and CD11c low populations.
5. From CD11c high population gate for macrophages (SiglecF high MHCII low) and DCs (SiglecF low, MHCII high).
6. From CD11c low gate for T cells (CD3/19 high, MHCII low), and B cells (CD3/19 high, MHCII high).
7. From CD11c low CD3/19null cell population, gate for neutrophils (CD11b high, Ly-6G high) and Eosinophils (CD11b high, Ly-6G low, SiglecF high).
8. For gating strategy of Eosinophils in the lung tissues, use these markers aftere excluding dead cells using BV510 dye (CD45, SiglecF, CD11C).

Table 4: FACS running

TBS:
20 mm Tris-HCl
150 mm NaCl
pH 7.5
TBS-T:
0.05% Tween-20 in TBS
Blocking Buffer
5% non-fat milk diluted in TBS-T
Antibody dilution Buffer
1% non-fat milk diluted in TBS-T
PBS+EDTA
1x PBS + 0.1 mM EDTA
FACS buffer
2% Fetal Calf Serum (FCS) in 1x PBS
Total cell medium
RPMI 1640, 1X Glutamax, 10% FCS, 50 µM 2-mercaptoethanol and Penicillin-Streptomycin.
Lung digestion solution
Total cell medium plus Liberase (50 µg/ml) and DNase I (1 µg/ml)

Table 5: Recipes for buffers and solution

Discussion

The current protocol describes how to evaluate the immunostimulatory properties of allergen-associated microbial RNA and their impacts on the development of eosinophilic lung inflammation in a mouse model of allergic asthma. Although long dsRNAs are known as the replication intermediates of many viruses that can potently activate interferon responses in mammalian cells, their presences in HDM allergens have been unknown until our recent work15. The combination of RNA dot blot, RT-qPCR and FACS analysis presented in this manuscript may provide a good example to dissect innate components such as the dsRNA species in environmental allergens that are critically involved in regulating allergen-induced eosinophilic inflammation.

In this protocol, the RNA dot blot has been employed to detect the presence of dsRNA structures in natural allergens using a mouse monoclonal antibody J2, which specifically binds to the dsRNA (≥40bp) independent of sequence. This method is highly reliable because J2 antibody can still recognize dsRNA samples pretreated with RNase T1 (single stranded RNA-specific endonuclease), but not samples pretreated with RNase III (a dsRNA-specific endonuclease). However, it is worth pointing out that a widely used synthetic analogue of dsRNA, Polyinosinic:polycytidylic acid [Poly(I:C)], has been reported to preferentially bind to another anti-dsRNA monoclonal antibody K1, instead of J221,22,23. Therefore, the use of J2 antibody for the detection of Poly(I:C) is not recommended.

Cell type analysis on samples collected from BAL or lung tissues is useful for assessing the progression of allergic lung inflammation. Although BAL procedure is a common technique, the results may vary among research laboratories. Numerous factors may cause these variations such as the amount of bronchoalveolar lavage collected. The ideal volume of BAL recovered from an 8-12 weeks old mice is ~3 ml19. Another factor that may contribute to the lack of reproducibility is how deep the catheter should be inserted into the trachea (~0.5 cm is optimal) because deeper insertion of the catheters may cause damage to the trachea. In addition, researchers should also consider other factors such as the age, strain, and gender of the mice as these factors can greatly impact the experiment results27,28,29.

Here, we provide a technical protocol to characterize immunomodulatory effects of HDM RNA in vitro and in vivo using RNA dot blot, RT-qPCR and FACS analysis of BAL and lung tissues. Proper practices can ensure successful reproducibility of results obtained when performing these techniques. For instance, try to avoid the contamination of RNases when performing RNA dot blot. Also, the centrifugation speed should be properly adjusted since the unnecessary higher centrifugation speed may compromise cell viability. Finally, cells used for the FACS analysis should be fixed if not analyzed on the same day.

Since innate immunity plays a pivotal role in host defense and inflammation2,3, the techniques and methods described in this paper will be very useful for studying the immunomodulatory role of other innate immune components such as microbial DNA in natural allergens in the development of type 2 inflammation.

Divulgaciones

The authors have nothing to disclose.

Acknowledgements

We thank Ms. Karla Gorena for technical assistance in flow cytometry. L.S. is supported by the China Scholarship Council and Hunan Provincial Innovation Foundation for Postgraduate (CX201713068). H.H.A. is supported by the Department of Clinical Laboratory Sciences, College of Applied Medical Sciences, Jouf University, Sakaka, Saudi Arabia. X.D.L. is supported by the UT Health San Antonio School of Medicine Startup Fund and the Max and Minnei Voelcker Fund.

Materials

0.40 µm Falcon Cell Strainer Thermo Fisher Scientific 08-771-1
1 mL syringes Henke Sass Wolf 5010.200V0
15 mL Tube TH.Geyer 7696702
50 mL Tube TH.Geyer 7696705
70% ethanol Decon Labs 2701
Absolute Counting Beads Life Technologies Europe B.V. C36950
ACK-RBC lysing buffer Lonza 10-548E
Amersham Hybond-N+ Membrane GE Healthcare RPN203B
Ant San Antonio Note: Locally collected
Antibody dilution buffer (see Table 5 for recipe)
Anti-Mouse CD11b V450 Rat (clone M1/70) BD Bioscience 560456 1 to 200 dilution
Anti-Mouse CD11c PE-Cy7 (clone N418) BioLegend 117317 1 to 200 dilution
Anti-Mouse CD19 Alexa Flour 647 (clone 1D3) eBioscience 15-0193-81 1 to 200 dilution
Anti-Mouse CD3e APC (clone 145-2C11) Invitrogen 15-0031-81 1 to 200 dilution
Anti-Mouse CD45 APC-Cy7 (clone: 30-F11) BioLegend 103130 1 to 200 dilution
Anti-Mouse Fixable Viabillity Dye eFluor 506 Invitrogen 65-0866-14 1 to 200 dilution
Anti-Mouse IgG (H+L), AP Conjugate Promega S3721
Anti-Mouse Ly-6G FITC (clone RB6-8C5) Invitrogen 11-5931-82 1 to 200 dilution
Anti-Mouse MHC II APC-eFluor 780 (clone M5/114.15.2) eBioscience 47-5321-80 1 to 200 dilution
Anti-Mouse Siglec-F PE (clone E50-2440) BD Pharmingen 552126 1 to 200 dilution
BCIP/NBT substrate Thermo Fisher Scientific PI34042
Blocking Buffer (see Table 5 for recipe)
Cannual, 20G X 1.5” CADENCE SCIENCE 9920
Centrifuge Thermo Fisher Scientific 75004030
CFX384 Touch Real-Time PCR Detection System Bio-Rad Laboratories 1855485
Chloroform Thermo Fisher Scientific C298-500
Cockroach Greer Laboratories B26
Counting beads Thermo Fisher Scientific 01-1234-42
D. farinae Greer Laboratories B81
D. pteronyssinus Greer Laboratories B82
Denville Cell Culture Plates with lid, 96 well cell culture plate Thomas Scientific 1156F03
Digital Dry Bath – Four Blocks Universal Medical, Inc. BSH1004
Earthworm San Antonio Note: Locally collected
Ethylenediaminetetraacetic acid (EDTA) Sigma-Aldrich E6511
FACS buffer (see recipe in Table 5)
Falcon Round-Bottom Polypropylene Tubes, 5 mL STEMCELLTM TECHNOLOGIES 38056
Flow cytometer (BD FACS Celesta) BD Biosciences
Fly Greer Laboratories B8
Forceps Roboz Surgical Instrument RS-5135
Hemocytometer Hausser Scientific 3110
HT-DNA Sigma D6898
In Vivo MAb anti-mouse CD16/CD32 (clone: 2.4G2) Bio X Cell BE0307
iScript cDNA Synthesis Kit Bio-Rad Laboratories 1708891
Isoflurane Abbott Labs sc-363629Rx
Isopropanol Thermo Fisher Scientific BP2618500
J2 anti-dsRNA monoclonal antibody SCICONS 10010200
Lung digestion solution (see recipe in Table 5)
Lysing Matrix D MP Biomedicals 116913050-CF
Lysing Matrix D, 2 mL tube MP Biomedicals SKU:116913100
Mice (female, 8-12 weeks old, C57BL/6J) Jackson Laboratory #000664
Microcentrifuge tube 1.5 mL Sigma-Aldrich 30120.094
Microscope Olympus CK30
Mini-BeadBeater Homogenizers SKU:BS:607
Mini-Beadbeater-16 Biospec 607
Mosquito Greer Laboratories B55
NanoDrop 2000C Thermo Scientific Spectophotometer Medex Supply TSCND2000C
Needle, 21 G x 1 1/2 in BD Biosciences 305167
Non-fat milk Bio-Rad Laboratories 1706404
Nylon string Dynarex 3243
Phosphate-buffered Saline (PBS) Lonza BE17-516F
RNase III Thermo Fisher Scientific AM2290
RNase T1 Thermo Fisher Scientific AM2283
Scissors Roboz Surgical Instrument RS-6802
Shaker or Small laboratory mixer Boekel Scientific 201100
SPHERO AccuCount Fluorescent Spherotech ACFP-70-5 1 to 10 dilution
Spider San Antonio Note: Locally collected
TBS (see recipe in Table 5)
TBS-T (see recipe in Table 5)
Total cell medium (see recipe in Table 5)
TRIzol Reagent Thermo Fisher Scientific 15596018
Tween 20 Sigma-Aldrich P9416
UV Stratalinker 2400 UV LabX 20447
Wasp San Antonio Note: Locally collected

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Alanazi, H. H., She, L., Li, X. Identification and Characterization of Immunogenic RNA Species in HDM Allergens that Modulate Eosinophilic Lung Inflammation. J. Vis. Exp. (159), e61183, doi:10.3791/61183 (2020).

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