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In This Article

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

Summary

In this paper, we describe a protocol to characterize T-dependent and T-independent immunoglobulin (Ig) isotype responses in mice using ELISA. This method used alone or in combination with flow cytometry will allow researchers to identify differences in B cell-mediated Ig isotype responses in mice following T-dependent and T-independent antigen immunization.

Abstract

Antibodies, also termed as immunoglobulins (Ig), secreted by differentiated B lymphocytes, plasmablasts/plasma cells, in humoral immunity provide a formidable defense against invading pathogens via diverse mechanisms. One major goal of vaccination is to induce protective antigen-specific antibodies to prevent life-threatening infections. Both thymus-dependent (TD) and thymus-independent (TI) antigens can elicit robust antigen-specific IgM responses and can also induce the production of isotype-switched antibodies (IgG, IgA and IgE) as well as the generation of memory B cells with the help provided by antigen presenting cells (APCs). Here, we describe a protocol to characterize TD and TI Ig isotype responses in mice using enzyme-linked immunosorbent assay (ELISA). In this protocol, TD and TI Ig responses are elicited in mice by intraperitoneal (i.p.) immunization with hapten-conjugated model antigens TNP-KLH (in alum) and TNP-polysaccharide (in PBS), respectively. To induce TD memory response, a booster immunization of TNP-KLH in alum is given at 3 weeks after the first immunization with the same antigen/adjuvant. Mouse sera are harvested at different time points before and after immunization. Total serum Ig levels and TNP-specific antibodies are subsequently quantified using Ig isotype-specific Sandwich and indirect ELISA, respectively. In order to correctly quantify the serum concentration of each Ig isotype, the samples need to be appropriately diluted to fit within the linear range of the standard curves. Using this protocol, we have consistently obtained reliable results with high specificity and sensitivity. When used in combination with other complementary methods such as flow cytometry, in vitro culture of splenic B cells and immunohistochemical staining (IHC), this protocol will allow researchers to gain a comprehensive understanding of antibody responses in a given experimental setting.

Introduction

B lymphocytes are the principal player in humoral immunity and the only cell type in mammals that are capable of producing antibodies, also termed as immunoglobulins (Ig)1,2. Antibodies secreted by B cells provide a formidable defense against invading pathogens via diverse mechanisms including neutralization, opsonization and complement activation, leading to protective immunity3. Secretion of antibodies by B cells is only achieved after full activation of specific B cells, which normally requires two distinct signals3. Signal 1 is relayed by direct binding of the antigen (Ag) to the B cell receptor (BCR) expressed on the surface of specific naïve B cells3. Depending on the source of Signal 2, B cell activation can be divided into thymus-dependent (TD) or thymus-independent (TI)3,4. In a TD antigen response, Signal 2 is provided by activated cognate CD4 T helper (TH) cells, which express CD154, the ligand for the co-stimulatory receptor CD40 expressed on B cells1,2,3. In a TI antigen response, Signal 2 comes from either engagement of Toll-like receptors (TLRs in the case of type 1 TI Ag) or extensive cross-linking of the BCRs (in the case of type 2 TI Ag) on the B cells3,4. Type 1 TI (TI-1) antigens are microbial ligands of TLRs, including bacterial lipopolysaccharides (LPS), viral RNAs, and microbial CpG DNA4,5. Type 2 TI (TI-2) antigens have highly repetitive structure, and are able to deliver prolonged and persistent signaling to the B cell by multiple cross-linking of the BCRs4,6. Typical examples of TI-2 antigens include pneumococcal polysaccharides and hapten-conjugated polysaccharide6,7. Both TD and TI antigens can elicit robust antigen-specific IgM responses and can also induce the production of isotype-switched antibodies (IgG, IgA and IgE) with the help provided by antigen presenting cells (APCs) such as dendritic cells (DCs)1,2,3. Furthermore, both TD and TI antigens are able to induce memory responses with the help of APCs, but TD antigens are more efficient at inducing memory B cell generation3,8.

In this protocol, TD and TI Ig responses are elicited in mice by intraperitoneal (i.p.) immunization with hapten-conjugated model antigens 2,4,6-trinitrophenyl-keyhole limpet hemocyanin (TNP-KLH) and TNP-polysaccharide (neutral, highly branched and high-mass), respectively9,10,11. TD antigens are usually used with an adjuvant to enhance the production of antibodies12. Here in our protocol, TNP-KLH is injected with alum, a commonly used adjuvant in immunization studies12. Other examples of adjuvants that can be used include complete or incomplete Freund's adjuvant (CFA or IFA), monophosphoryl-lipid A/trehalose dicorynomycolate ("Ribi" adjuvant), and CpG oligodeoxynucleotides, etc.13,14. After immunization, mouse sera are harvested at different time points and TNP-specific antibodies in sera are quantified using Ig isotype-specific enzyme-linked immunosorbent assay (ELISA)9,10,11.

ELISA is a plate-based assay that is widely used as a diagnostic tool in medicine and also as an analytical tool in biomedical research15,16. It is used to detect and quantify analytes including antibodies, hormones, cytokines, chemokines, and various antigens, etc. ELISA can be performed in several different formats, including direct, indirect, sandwich and competitive ELISA15,16. In general, it involves the immobilization of the antigen to a solid surface, usually a 96-well microtiter plate, which is incubated with a primary antibody. After incubation, the unbound antibody is washed away. In a direct ELISA, the primary antibody is directly conjugated to an enzyme (typically horseradish peroxidase or alkaline phosphatase), which can cleave a chromogenic substrate to yield a visible color change detected by a signal-detection instrument such as a spectrophotometer15,16. In contrast, if an enzyme-linked secondary antibody is used to bind the primary antibody, then this is considered as an indirect ELISA15,16. Direct ELISA is faster whereas indirect ELISA is more sensitive15,16. In a sandwich ELISA, the plates are coated with a "capture" antibody used to immobilize the antigen of interest in the samples, and then the captured antigen can be detected by another "detection" antibody in a direct or indirect manner15,16. Sandwich ELISA offers high specificity since the antigen is detected by two different antibodies of the antigen. In a competitive ELISA, the competition is established between the sample antigen and the plate-bound antigen for binding to the primary antibody, and then the antigen concentration in sample is quantified by measuring the reduction in signal from the substrate15,16. Competitive ELISA can be performed using the above mentioned direct or indirect format and is useful for the detection of small antigens with only one epitope15,16.

Alternative techniques for the measurement of antibodies include radio-immunoassay (RIA), electrochemiluminescence (ECL) assay and surface plasmon resonance (SPR) assay17. RIA was the first immunoassay developed that measures the presence of an antigen (or antibody) with high specificity and sensitivity using radiolabeled reagents18,19. However, due to the concerns of radioactive toxicity, disposal costs, shelf-life and special licenses to work with radioactive materials, ELISA is a better and more convenient technique for common uses20,21. ECL is a highly sensitive assay in which chemiluminescent reactions are initiated using electricity to generate highly reactive species from stable precursors on the surface of an electrode, and can be used to measure the amount of analytes (such as antigens or antibodies)22. However, ECL requires a special instrument and thus is not as broadly used as ELISA23. SPR is a direct assay that can be used to measure the binding of ligands (e.g., antibodies) to immobilized molecules (e.g., antigens) on a sensor chip surface24. SPR detects the interactions in real time very specifically and does not require the use of labelled reagents as in ELISA. However, SPR also requires a special equipment and has lower sensitivity than ELISA17. Given the limitations of the alternative methods, ELISA is the most suitable and convenient technique for our purpose in this protocol. Here, we describe the use of sandwich ELISA for the analysis of total Ig isotype levels and the procedures of indirect ELISA for the analysis of antigen-specific Ig isotypes.

Protocol

This protocol follows the guidelines of institutional animal research ethics committee of Rutgers University. All mice are used in accordance with NIH guidelines and under an animal protocol approved by the Institutional Animal Care and Use Committee.

1. Preparation of Mice and Collection of Naïve Mouse Sera

  1. Keep all mice for immunization experiments in a specific pathogen-free animal facility.
  2. Use gender-matched, young adult (8–12 weeks old) knockout and littermate control mice that share the same parents and cages for immunization studies.
  3. Plan the immunization and serum collection schedules as depicted in Figure 1.
  4. Harvest naïve serum of each mouse at 7 days (-7 days) before immunization. Follow the retro-orbital bleeding and serum preparation procedures as detailed below in step 4.

2. Preparation of TNP-polysaccharide (a TI Antigen) and TNP-KLH (a TD Antigen)

  1. Dissolve the antigen powders in sterile PBS (pH 7.4) thoroughly to make 0.5 mg/mL of TNP-polysaccharide stock and 1 mg/mL of TNP-KLH stock solutions. Aliquot each antigen stock solution into sterile microfuge tubes at 0.5 mL/tube, and keep the aliquots at -80 °C for long-term storage. Avoid multiple freeze and thaw of the antigen aliquots.
  2. On the injection day, calculate the volume of TNP-polysaccharide (50 µg/100 µL/mouse) or TNP-KLH (100 µg/100 µL/mouse) needed according to the number of mice to be injected. Thaw appropriate number of TNP-polysaccharide or TNP-KLH aliquots at room temperature (RT).
  3. For TNP-KLH injection, first dilute the alum adjuvant (40 mg/mL) with 3 volumes of sterile PBS to a final concentration of 10 mg/mL. Make sure that the alum adjuvant mixture is well-suspended before dilution.
  4. Combine equal volume of 10 mg/mL alum adjuvant slurry from step 2.3 and the thawed TNP-KLH solution (1 mg/mL) into a 5 mL polypropylene tube, mix well, and incubate at 37 °C for 30 min. Prepare this TNP-KLH/alum mix freshly prior to the injection.

3. Immunization of Mice

  1. Perform intraperitoneal (i.p.) injection of TNP-polysaccharide or TNP-KLH/alum to immunize the mice with 1 mL insulin syringes in a biosafety cabinet. Insert the needle at approximately 30° angle preferably in the lower right quadrant of each mouse to prevent injection into the internal organs.
  2. Inject i.p. 100 µL of TNP-polysaccharide per mouse on day 0 for TI Ag immunization (Figure 1A).
  3. Inject i.p. 200 µL of the TNP-KLH/alum mix (freshly prepared in step 2.4) per mouse on day 0 for TD Ag immunization. Repeat the same injection on day 21 as a booster immunization for memory studies (Figure 1B).
  4. After the injection, return each mouse to its cage and keep all the injected mice in specific pathogen-free condition.

4. Retro-orbital Bleeding and Serum Preparation

  1. Harvest mouse sera at different time points: for TNP-polysaccharide immunization, collect mouse sera on day -7 and 7 (Figure 1A); for TNP-KLH/alum immunization, collect mouse sera on day -7, 7, 14 and 28 (Figure 1B).
  2. For Retro-orbital bleeding, anesthetize each mouse with 5% isoflurane for 1–2 min in a biosafety cabinet25. Perform pedal reflex to ensure adequate anesthesia of each mouse.
  3. Hold the anesthetized mouse in one hand with the forefinger and thumb pulling the skin around the eyeball back so that the eyeball protrudes out of the socket25. Insert a non-heparinized Pasteur pipette or capillary tube at an angle of 45° into the inner corner of the eye socket underneath the eyeball25.
  4. Apply gentle downward pressure and rotate the pipette or tube gently to break into the vein and collect 150–200 µL of blood in the pipette or tube. Immediately transfer the blood to a sterile 1.5 mL microfuge tube and return the mouse to its cage to recover.
  5. Let the blood samples sit at RT for 1–2 h to coagulate.
  6. Centrifuge the coagulated blood samples at 13,000 x g for 10 min at 4 °C. Transfer the clear serum on top of the blood clot to a new sterile 1.5 mL microfuge tube.
  7. Repeat step 4.6 one more time to remove residual blood clot and collect the clear serum.
  8. Aliquot the serum into sterile 1.5 mL microfuge tubes at 50 µL/tube, and store the sera at -80 °C.
  9. Alternate the eye for bleeding at different time points so that each eye is bled at most twice for the whole experiment. At the terminal bleeding, collect up to 1 mL of blood from each mouse before euthanasia. Euthanize the mouse with 5% CO2 followed by cervical dislocation.
    NOTE: Splenic B cells can be harvested for flow cytometric analyses and in vitro culture studies. We also prepare genomic DNA from splenocytes to verify the genotype of each mouse.

5. Mouse Ig Isotype-specific ELISA

  1. Prepare the buffers and solutions before ELISA.
    1. Prepare 500 mL of Coupling Buffer (PBS, pH 7.4).
    2. Prepare 500 mL of Wash Solution (PBS-T (0.05% Tween 20), pH 7.4).
    3. Prepare 100 mL of Blocking Buffer (1% BSA in PBS, pH 7.4, stored at 4 °C).
    4. Prepare 1 L of Substrate Buffer (1 M diethanolamine, pH 9.8 (97 mL of diethanolamine in 1 L of H2O, pH adjusted using 10 M HCl) and 0.5 mM MgCl2). Protect the Substrate Buffer from light by wrapping the bottle with aluminum foil. Store at 4 °C.
    5. Prepare 100 mL of Stop solution (3 M NaOH).
  2. Coat the ELISA plates:
    1. For total serum Ig isotype ELISA, coat 96-well immuno plates with 10 µg/mL of isotype-specific capturing polyclonal goat anti-mouse Ig (M, G1, G2a, G2b, G3, A, or E) Abs in Coupling Buffer (PBS) at 100 µL/well.
    2. For TNP-specific Ig isotype ELISA, coat 96-well immuno plates with 10 µg/mL of TNP(38)-BSA in PBS at 100 µL/well.
    3. For high affinity TNP-specific Ig isotype ELISA, coat 96-well immuno plates with 10 µg/mL of TNP(3)-BSA in PBS at 100 µL/well26. Incubate the plates at 4 °C overnight.
  3. After coating incubation, wash the plates 2 times with 200 µL/well of PBS-T. Discard the Wash Buffer and blot dry the plates (tap each plate upside down on a stack of paper towels) after each wash.
  4. Block the plates: add 200 µL/well of Blocking Buffer (1% BSA in PBS) into the coated plates, and incubate the plates for 1 h at RT.
  5. While the plates are blocking, prepare dilutions of Ig isotype standards and serum samples in Blocking Buffer in a separate, untreated 96-well plate at 150 µL/well.
    1. Prepare 250 ng/mL Ig isotype standards as the starting standard concentration (St01) and make 7 to 10 of 1:2 serial dilutions of the Ig standards (St02 to St07 or St10, Figure 2A).
    2. Prepare mouse serum samples at a 1:100 or 1:500 dilution factor as the starting dilution and make 3 or 4 of 1:10 serial dilutions for total Ig isotype or 1:5 serial dilutions for TNP-specific Ig isotype of each serum sample (Figure 2A). For IgE ELISA, prepare mouse serum samples at a 1:2 dilution factor as the starting dilution, and make 3 of 1:5 serial dilutions of each serum sample.
  6. After blocking, wash the plates from step 5.4 three times with 200 µL/well of PBS-T and blot dry the plates after each wash.
  7. Transfer 100 µL/well of diluted Ig isotype standards (appropriate for the capture and detection Abs) and diluted serum samples from step 5.5 to the plates prepared in step 5.6. Incubate the plates with the standards and samples at 4 °C overnight.
  8. Wash the plates 3 times with 200 µL/well of PBS-T and blot dry the plates after each wash.
  9. In each plate, add 100 µL/well of 10 µg/mL of an appropriate alkaline phosphatase (AP)-conjugated isotype-specific goat anti-mouse Ig (M, G1, G2a, G2b, G3, A, or E) Abs diluted in Blocking Buffer.
  10. Incubate the plates with AP-conjugated Abs for 1 - 2 h at RT. For IgE detection, incubate the plates for 1–2 h at 37 °C.
  11. Prepare 1 mg/mL of Substrate Solution by dissolving two tablets of 5 mg phosphatase substrate in 10 mL of Substrate Buffer.
  12. Wash each plate 5 times with 200 µL/well of PBS-T and blot dry the plates after each wash.
  13. Add 100 µL/well of Substrate Solution into each plate. Allow the reaction to develop at RT, which usually takes only a few minutes.
  14. Read each plate at 405 nm using a microplate reader with its associated software.
    1. Click "Settings" to set the wavelengths "Lm1" at "405 nm" and click "OK".
    2. Click "Template" to assign "Blank" wells, "Standards" wells and "Unknown" wells according to the 96-well plate setup.
    3. For "Standards" wells, click "Series" to set the "First Sample" as "St01", select "Start From" at "Top", and set "Replicates" as "2". Check "Sample Descriptor" and input "Standard Value": select "Units" as "ng/mL", set "Starting value" as "250", set "Step by" as "2". Click "OK".
    4. Click "Read" to read the plate when the most concentrated standard reaches an optical density (OD) of ~1.
    5. Click the "File" menu and click "Save" to save the file.
    6. Click "Read" to read the plate again when the most concentrated standard approaches OD405 of ~1.5, 2, and 2.5, respectively.
  15. Stop the reaction by adding 25 µL/well of 3M NaOH. Complete steps 5.12 to 5.15 for one plate at a time.
  16. Analyze ELISA data using the software associated with the microplate reader:
    1. Check the OD405 values of the Ig isotype standards of read files and select an appropriate reading with good linear range of the standards for detailed data analysis.
    2. Select the 4-Parameter fitting program to plot standard curves. Check the co-efficient of the standard curve (R2), which is required to be > 0.98 to ensure good data quality.
    3. Check whether the OD405 values of each sample decrease with increasing dilution factors. Retrieve the concentration of all diluted sample wells by clicking "Unknowns".
    4. Select an appropriate well of each sample with OD405 in the linear range of the Ig isotype standard curve for concentration calculation.
    5. Calculate the serum Ig isotype concentration of each sample using the formula: serum Ig concentration = selected well concentration x dilution factor.
  17. Plot graphs and perform statistical analyses using an appropriate software9,10,11. Make vertical scatter plots of serum Ig isotype levels to compare the Ig responses at the same time point. For TD memory response studies, make the time-course response curves to examine the Ig isotype responses before and after the booster immunization. Use error bars to show standard deviation (SD) of each group of samples. To compare Ig isotype responses between two genotypes of mice, use the unpaired t test for two-tailed data to determine the statistical significance. Set the p value < 0.05 as significantly different.

Results

We have used this protocol to investigate the roles of a critical regulator of the immune system, TRAF3, in TI and TD Ig isotype responses9,10,11. TRAF3 directly or indirectly regulates the signal transduction of a number of innate and adaptive immune receptors, including the TNF receptor superfamily, Toll-like receptors and T cell receptor/CD28, among others27,...

Discussion

Here, we describe the protocol for the characterization of TD and TI Ig isotype responses in mice using ELISA. Successful implementation of this protocol requires the use of materials specified in Table 1, including ELISA assay plates, immunization Ags, mouse Ig isotype-specific antibodies and standards. Care should be taken to avoid using tissue culture treated plates for ELISA. Dilutions of the standards and serum samples should be done in separate untreated plates (round-bottom) and then added into th...

Disclosures

The authors have no competing financial interests.

Acknowledgements

This study was supported by the National Institutes of Health grants R01 CA158402 (P. Xie) and R21 AI128264 (P. Xie), the Department of Defense grant W81XWH-13-1-0242 (P. Xie), a Pilot Award from the Cancer Institute of New Jersey through Grant Number P30CA072720 from the National Cancer Institute (P. Xie), a Busch Biomedical Grant (P. Xie), a Victor Stollar Fellowship (A. Lalani), and an Anne B. and James B. Leathem Fellowship (S. Zhu).

Materials

NameCompanyCatalog NumberComments
VersaMax Tunable Microplate ReaderMDS Analytical TechnologiesVERSAMAXEquipment to read the plates
SOFTmax PRO 5.3MDS Analytical TechnologiesSOFTmax PRO 5.3Software for the plate reader
GraphPad PrismGraphPadPrismSoftware for graphing and statistics
TNP-AECM-polysaccharide (FICOLL)Biosearch TechnologiesF-1300-10A TI Ag for immunization
TNP-KLHBiosearch TechnologiesT-5060-5A TD Ag for immunization
TNP(38)-BSABiosearch TechnologiesT-5050-10 (conjugation ratio: 38)Coating Ag for TNP-specific ELISA
TNP(3)-BSABiosearch TechnologiesT-5050-10 (conjugation ratio: 3)Coating Ag for high affinity TNP-specific Ig
Imject AlumFisher Scientific PI-77161Alum adjuvant for immunization
Falcon Polypropylene tubesFisher Scientific 14-959-11AFor incubation of TNP-KLH/alum
BD Insulin SyringeFisher Scientific 14-829-1BFor i.p. injection of mice
Immuno 96-Well Plates, Flat-BottomFisher Scientific 14-245-61For ELISA
Untreated 96-Well Microplates, Round-BottomVWR82050-622For serial dilutions of standards and samples
Phosphatase substrate, 5 mg TabletsSigmaS0942-200TABAP substrate
DiethanolamineVWRIC15251690A component of AP substrate buffer
Goat anti-mouse IgMSouthernBiotech1020-01Capture Ab for mouse IgM
Goat anti-mouse IgG1SouthernBiotech1070-01Capture Ab for mouse IgG1
Goat anti-mouse IgG2aSouthernBiotech1080-01Capture Ab for mouse IgG2a
Goat anti-mouse IgG2bSouthernBiotech1090-01Capture Ab for mouse IgG2b
Goat anti-mouse IgG3SouthernBiotech1100-01Capture Ab for mouse IgG3
Goat anti-mouse IgASouthernBiotech1040-01Capture Ab for mouse IgA
Goat anti-mouse IgESouthernBiotech1110-01Capture Ab for mouse IgE
AP-Goat anti-mouse IgMSouthernBiotech1020-04Detection Ab for mouse IgM
AP-Goat anti-mouse IgG1SouthernBiotech1070-04Detection Ab for mouse IgG1
AP-Goat anti-mouse IgG2aSouthernBiotech1080-04Detection Ab for mouse IgG2a
AP-Goat anti-mouse IgG2bSouthernBiotech1090-04Detection Ab for mouse IgG2b
AP-Goat anti-mouse IgG3SouthernBiotech1100-04Detection Ab for mouse IgG3
AP-Goat anti-mouse IgASouthernBiotech1040-04Detection Ab for mouse IgA
AP-Goat anti-mouse IgESouthernBiotech1110-04Detection Ab for mouse IgE
Mouse IgM standardBD Biosciences553472TNP-specific IgM, Clone  G155-228
Mouse IgG1 standardBD Biosciences554054TNP-specific IgG1, Clone  107.3
Mouse IgG2a standardBD Biosciences556651TNP-specific IgG2a, Clone  G155-178
Mouse IgG2b standardBD Biosciences554055TNP-specific IgG2b, Clone  49.2
Mouse IgG3 standardBD Biosciences553486KLH-specific IgG3, Clone  A112-3
Mouse IgA standardBD Biosciences550924Mineral oil-induced IgA, Clone  MOPC-320
Mouse IgE standardBD Biosciences557079TNP-specific IgE, Clone  C38-2

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