A High Throughput MHC II Binding Assay for Quantitative Analysis of Peptide Epitopes

Podsumowanie

Biochemical assays with recombinant human MHC II molecules can provide rapid, quantitative insights into immunogenic epitope identification, deletion, or design.  Here, a peptide-MHC II binding assay scaled to 384-well plates is described. This cost effective format should prove useful in the fields of protein deimmunization and vaccine design and development.

Streszczenie

Biochemical assays with recombinant human MHC II molecules can provide rapid, quantitative insights into immunogenic epitope identification, deletion, or design^1,2. Here, a peptide-MHC II binding assay is scaled to 384-well format. The scaled down protocol reduces reagent costs by 75% and is higher throughput than previously described 96-well protocols^1,3-5. Specifically, the experimental design permits robust and reproducible analysis of up to 15 peptides against one MHC II allele per 384-well ELISA plate. Using a single liquid handling robot, this method allows one researcher to analyze approximately ninety test peptides in triplicate over a range of eight concentrations and four MHC II allele types in less than 48 hr. Others working in the fields of protein deimmunization or vaccine design and development may find the protocol to be useful in facilitating their own work. In particular, the step-by-step instructions and the visual format of JoVE should allow other users to quickly and easily establish this methodology in their own labs.

Wprowadzenie

Proteins are the fastest growing class of therapeutic agents⁶, and the rapid expansion of biotherapeutic pipelines has focused increasing attention on the challenges associated with development and use of protein drugs. One unique consideration stems from the fact that, in a healthy and functioning immune system, all extracellular proteins are sampled by antigen presenting cells (APCs). Once internalized by APCs, a protein is cleaved into small peptide fragments, and putative immunogenic segments are loaded into the groove of class II major histocompatibility complex proteins (MHC II). The peptide-MHC II complexes are then displayed on the APC surface, and true immunogenic peptides, termed T cell epitopes, form ternary MHC II-peptide-T cell receptor complexes with cognate CD4 T cell surface receptors⁷. This critical molecular recognition event initiates a complex signaling cascade, which results in T cell activation, the release of cytokines, CD4 T cell-mediated B cell maturation, and ultimately production of circulating IgG antibodies that bind to and clear the offending exogenous protein. Thus, immunogenic proteins might be deimmunized by identifying constituent T cell epitopes and mutating key residues responsible for MHC II complex formation. It bears noting, however, that T cell epitopes can be numerous and broadly distributed throughout immunogenic proteins, and the majority of epitope-deleting mutations are likely to cause an inadvertent loss of protein function or stability. Therefore, engineering deimmunized biotherapies can be a complex and technically challenging objective, but there exist several examples of successful T cell epitope deletion projects^3,5,8-12. Unlike grafting-based "humanization", which is largely restricted to antibody therapeutics, epitope deletion can be applied to essentially any protein target regardless of sequence, structure, function, or the availability of homologous human scaffolds. The first step to implementing such an approach is identification of key peptide epitopes embedded within the target protein sequence.

High throughput biochemical assays using synthetic peptides and recombinant human MHC II molecules can provide rapid preliminary insights into epitope identification and mitigation^1,3-5. These ELISA type assays can be a powerful complement to other protein/vaccine design and development tools. For example, one well established experimental approach to epitope mapping relies on time, labor, and resource intensive ex vivo cell proliferation assays ¹⁵. Briefly, the primary sequence of a target protein is first divided into a panel of overlapping peptides, often 15-mers with 12 residues overlap between adjacent peptides. The peptide panel is chemically synthesized and the immunogenicity of each peptide is tested in one of several different immunoassays that employ peripheral blood mononuclear cells (PBMC) isolated from human donors^13,14. To provide greater confidence in results, peptides are typically tested in replicate with PBMC from 50 or more different donors. In cases where deimmunization is the ultimate objective, the work is compounded further by the need to produce additional panels of mutated peptides and test the new peptide panels in PBMC assays before introducing any deimmunizing mutations into the full length protein for subsequent functional analysis¹⁰. While these cellular assays remain the gold standard for assessing immunogenic potential in human patients, the efficiency of such an exhaustive approach might be improved by prefiltering putative immunogenic epitopes using a rapid and high throughput MHC II-peptide binding assay.

Likewise, biochemical peptide-MHC II binding assays can be combined with predictive in silico methods to radically accelerate the epitope identification process. There exist a variety of computational tools for T cell epitope prediction; examples include ProPred¹⁶, MHCPred¹⁷, SVRMHC¹⁸, ARB¹⁹, SMM-align²⁰, NetMHCIIpan²¹ as well as proprietary tools such as EpiMatrix by EpiVax²². Likewise, epitope predictors have recently been combined with other bioinformatics and molecular modeling tools to yield integrated protein deimmunization algorithms designed to mitigate the risk that deimmunizing mutations might disrupt protein structure and function^23-26. While several epitope predictors have proven to be reasonably accurate^27,28, computational results invariably require experimental validation. Rapid, high throughput, and cost effective experimental methods are best suited as a preliminary filter for in silico epitope predictions.

In a similar vein, epitope predictors can drive antigen selection for reverse vaccinology^29,30. For example, advances in bioinformatics have yielded whole genome screens that rapidly identify vaccine candidates in the form of whole proteins or peptide epitopes extracted from pathogen proteomes. While this enabling technology is reshaping discovery and development of protective vaccines, it introduces a new challenge in the form of intractably large lists of immunogenic vaccine candidates. High throughput peptide-MHC II binding assays can guide epitope selection by quantifying peptide binding affinity and binding promiscuity among multiple MHC II alleles. As with protein deimmunization, such experimental methods are ultimately required to validate computational prediction of promising vaccine leads.

Here, a peptide-MHC II binding assay scaled to 384-well format is described. The protocol is highly parallelized and reduces reagent costs by 75% compared to previously described 96-well plate formats^1,3-5. Using a single liquid handling robot, this method allows one researcher to easily analyze approximately ninety test peptides in triplicate over a range of eight concentrations and four MHC II allele types in less than 48 hr. This article describes the setup of one 384-well ELISA plate for analysis of seven experimental peptides against one MHC II allele, but spread sheet calculators are provided as supplemental material so as to easily scale the experiment to any number of desired peptides and/or MHC II molecules.

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Protokół

Four major activities comprise the peptide-MHC II binding assay: 1-Binding: Test peptides compete with labeled control peptides for solution phase binding of soluble MHC II proteins. Binding is measured over a wide range of test peptide concentrations. 2-Capture: After the binding reaction approaches equilibrium, peptide-MHC II complexes are captured and separated from unbound peptide and protein by conformation-dependent recognition with an immobilized antibody. 3-Detection: Captured control peptide is quantitatively detected using time-resolved fluorescence. 4-Analysis: Spectroscopic data are processed, plotted and analyzed to ascertain dose-dependent binding properties of test peptide and MHC II proteins.

At various steps in the procedure below, the use of a liquid handling robot is recommended if one is available. Particularly in a 384-well format, automated dispensing and dilution of liquids minimizes user error, results in more consistent well-to-well volumes, and yields narrower 95% confidence intervals for IC₅₀ values compared to manual 96-well assays (data not shown). If a liquid handling robot is not available, the steps annotated with "(liquid handling robot)" may be done by hand. Similarly, if possible, an automated plate washer that is compatible with the 384-well format is recommended. This effectively standardizes the plate washing process. If a plate washer is not available, the steps annotated with "(plate washer)" may be done by hand.

1. Coat the ELISA Plate (Day 1)

1. Dilute L243 antibody stock (0.5 mg/ml) in Borate Buffer to a working concentration of 10 µg/ml.
   1. To coat a single 384-well plate, add 200 µl of stock antibody to 9.8 ml of Borate Buffer. (See supplemental spreadsheet calculator for alternative scaling).
2. Add 25 µl of the L243 antibody solution to each well of a 384-well high-binding white ELISA plate. (liquid handling robot)
3. Seal the plate with a polyester film and incubate overnight at 4 °C.
   Note: Each 384-well ELISA plate can accommodate up to 15 test peptides at eight dilutions for one MHC II allele, as well as the positive and negative controls. This will ultimately yield triplicate measurements.

2. Make the Test Peptide Dilutions (Day 1)

1. Starting with a 10 mM stock of each test peptide in DMSO, make the following dilution series in Citrate Phosphate Buffer using 384-well polypropylene plates (Table 1). (liquid handling robot)
   Note: A full 384-well polypropylene plate requires three separate ELISA plates. One third of a polypropylene plate will require only one ELISA plate (Figure 1).

Dilution Number	Volume to take from prior dilution/stock	Volume Citrate Buffer to add	Conc. of Dilution	Conc. in Binding Reaction	Conc. in Neutralized ELISA
	(μl)	(μl)	(μM)	(μM)	(μM)
1	0.7	35.1	195.531	97.765	48.883
2	14.3	14.3	97.765	48.883	24.441
3	7.1	28.7	19.389	9.695	4.847
4	14.3	14.3	9.695	4.847	2.424
5	7.1	28.7	1.923	0.961	0.481
6	14.3	14.3	0.961	0.481	0.24
7	7.1	28.7	0.191	0.095	0.048
8	14.3	14.3	0.095	0.048	0.024
Remove and discard 7.1 μl of peptide solution from dilution number 8.

Table 1. Preparation of test peptide dilution series.

Figure 1. Plate Map of Peptide Binding Assay. (A) Map of the peptide dilutions in polypropylene 384-well plates. Each polypropylene plate can accommodate three groups of 15 peptides in competition binding reactions against a single MHC II allele. (B) After the binding reaction approaches equilibrium, each peptide group is transferred, in triplicate, to a separate 384-well ELISA plate that has been precoated with anti-MHC II antibody.

3. Prepare the MHC II Master Mix (Day 1)

1. Make the Reaction Buffer
   1. Add 80 µl of 1 mM Pefa Bloc and 60 µg of octyl-β-D-glucopyranaside to 3,920 µl of Citrate Phosphate Buffer. (See supplemental spreadsheet calculator for alternative scaling).
2. Dilute selected MHC II stock solutions to 101 nM in Reaction Buffer using a 15 ml conical tube (Table 2).
   Note: MHC II concentration will ultimately be 50 nM in the binding reaction and 25 nM in the neutralized ELISA assay. The MHC II stock concentrations will vary depending on manufacturer lot number. (See supplemental spreadsheet calculator).

MHC II Allele DRB1*:	1501
MHC II Stock Concentration (mg/ml)	1.3
MHC II Stock Concentration (µM)	20
Vol. MHC II Stock to Add (µl)	14.65
Vol. Reaction Buffer to Add (µl):	2885.35
MHC II Master Mix Concentration (nM)	101

Table 2. Preparation of MHC II master mix.

4. Prepare the Negative and Positive Controls (Day 1)

1. Add 21.5 µl of Citrate Phosphate Buffer to the "negative control" well of the 384-well polypropylene plate from step 2.1 (Figure 1A).
2. Add 21.5 µl of Citrate Phosphate Buffer to the "positive control" well of the 384-well polypropylene plate.
   Note: the "positive control" will be completed in section 5, below.
3. Remove 49.5 µl of the MHC II Master Mix from step 3.2 and pipette into a 1.5 ml Eppendorf tube.
4. Add 0.5 µl of Citrate Buffer to the 49.5 µl of the MHC II Master Mix from step 4.3.
5. Add 21.5 µl of the concentration adjusted MHC II Master Mix from step 4.4 to the "negative control" well of the 384-well polypropylene plate (Figure 1A).
   Note: this sample represents the zero-signal negative control containing MHC II protein, NO control peptide, and NO test peptide.

5. Add the Appropriate Control Peptide to the MHC II Master Mix (Day 1)

MHC II Allele DRB1*	Biotinylated Control Peptide	(residues)	Sequence
0101	Flu-HA-B	(306-318)	Biotin-(Ahx)(Ahx)PRYVKQNTLKLAT-amide
0301	Myoglobin	(137-148)	Biotin-(Ahx)-(Ahx)-LFRKDIAAKYKE-OH
0401	YAR-B	(1-14)	Biotin-(Ahx)(Ahx)YARFQSQTTLKQKT-OH
0701	TetTox-B	(830-843)	Biotin-(Ahx)(Ahx)QYIKANSKFIGITE-OH
1101	Flu-HA-B	(306-318)	Biotin-(Ahx)(Ahx)PRYVKQNTLKLAT-amide
1501	MBP-B	(84-102)	Biotin-(Ahx)(Ahx)NPVVHFFKNIVTPRTPPPS-OH

*We recommend ordering 10 mg scale for economy.
Table 3. Control Peptides for Various MHC II Alleles.*

1. Dilute the Control peptide (stored at 400 µM in DMSO) 1:20 in fresh DMSO to yield a diluted stock at 20 µM.
   1. Add 25 µl 400 µM control peptide to 475 µl DMSO. Note: this is a large excess, but allows accurate handling of viscous DMSO solutions.
2. Further dilute the Control Peptide from step 5.1 (20 µM) 1:100 into the MHC II Master Mix from step 3.2.
   1. Add 28.8 µl of Control Peptide diluted in step 5.2 to the remaining 2,850.5 µl of the MHC II Master Mix.
3. Add 21.5 µl of the MHC II Master Mix with control peptide (step 5.2) to the positive control well of the 384-well polypropylene plate (step 4.2) (Figure 1A). Note: this sample represents the high-signal positive control containing MHC II protein, control peptide, and NO test peptide.

6. Make the Binding Reaction (Day 1)

1. Add the MHC II Master Mix containing Control Peptide (step 5.2) to each of the Test Peptide dilutions (step 2.1) at a 1:1 ratio to create the Binding Reaction.
   1. Add 21.5 µl of MHC II Master Mix containing Control Peptide from step 5.2 to 21.5 µl of each Test Peptide dilution from step 2.1. (liquid handling robot)
2. Seal the Binding Reaction with a polyester film and incubate 12-24 hr in a non-CO₂ controlled incubator at 37 °C without shaking.

7. Neutralize and Transfer the Binding Reaction (Day 2)

1. Remove the 384-well polypropylene plate containing the Binding Reaction (step 6.2) from the 37 °C incubator.
2. Dilute the Binding Reaction 1:1 with Neutralization Buffer. (liquid handling robot)
   1. Add 43 µl of the Neutralization Buffer to each Binding Reaction well.
3. Remove the ELISA plate (step 1.3) from 4 °C and wash 3x with 60 ml/well of PBS-0.05% Tween 20. (plate washer)
4. Transfer 25 μl of each neutralized Binding Reaction from step 7.2 into triplicate wells of the antibody-coated 384-well ELISA plate from step 7.3. (Figure 1) (liquid handling robot)
5. Cover the ELISA plate with a polyester film and place in a 37 °C incubator for 2.5 hr or in a 4 °C refrigerator overnight.

8. ELISA Development (Day 2 or 3)

1. Remove the ELISA plate from step 7.5, wash 3 times with 60 µl/well of PBS-0.05% Tween. (plate washer)
2. Dilute Streptavidin-Europium stock solution (0.1 mg/ml streptavidin, 7 Eu³⁺/streptavidin) 1,000-fold in the DELFIA Assay Buffer.
   1. For one 384-well plate, dilute 10 µl Streptavidin-Europium in 10 ml Assay Buffer.
3. Add 25 µl of the diluted Streptavidin-Europium to each well of the 384-well ELISA plate from step 8.1. (liquid handling robot)
4. Cover the plate with a polyester film and place in the dark at room temperature for 1 hr. Note: During the 1 hr incubation, remove the Enhancement Solution from the refrigerator and set aside 10 ml/plate in the dark at room temperature.
5. Following the 1-hr incubation, wash the 384-well ELISA plate from step 8.3 3x with 60 µl/well of PBS-0.05% Tween. (plate washer)
6. Add 25 µl of Enhancement Solution to each well of the 384-well ELISA plate from step 8.5. (liquid handling robot)
7. Cover the 384-well ELISA plate with a polyester film and allow the plate to sit in the dark at room temperature for 10-15 min.
8. Following the 10-15 min incubation, read the fluorescence of the 384-well ELISA plate from step 8.7 using a time resolved fluorescent plate reader with Europium settings (for example, Start Int: 200, Stop Int: 1,000, Ex. 340, Em. 615, Cutoff: None, PMT: Auto, Reads/Well: 50).

9. Data Analysis

1. Enter data in XY format graph with 3 replicate values in side-by-side columns (X=test peptide concentration; Y=fluorescence measurement).
2. Log transform the X values for all data: X=log(X)
3. Fit the log transformed data with the one-site competitive binding model to extract the IC₅₀ value.
4. Constrain the bottom value to the average negative control value.
5. Globally fit the top value and insure that the global fit parameter is below or equal to the positive control.

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Wyniki

The mature peptide sequence of Enterobacter cloacae P99 beta-lactamase (BLA) (Genbank ID# X07274.1) was analyzed with ProPred¹⁶ for putative peptide binders to MHC II allele DRB1*1501 (Table 4). ProPred identified 117 nonamer peptides with an obligatory P1 anchor residue (i.e. an M, L, I, V, F, Y, or W at position 1, which is required for MHC II binding³¹). At a 5% threshold, only peptides with scores greater than or equal to 2.6 are likely binders. Thus, at the 5%...

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Dyskusje

Biotherapeutics have established themselves as a cornerstone of modern medicine, representing four of the top five selling drugs in 2012³². The biopharmaceutics sector has shown sustained growth for several years⁶, and the ongoing development of novel agents as well as the emergence of biosimilars has expanded biopharmaceutical pipelines. Looking to the future, assessing and mitigating the immunogenicity of protein therapeutics will become an integral part of early stage biotherapeutic development. ...

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Materiały

Name	Company	Catalog Number	Comments
Sodium Tetraborate Decahydrate	Sigma	221732
Citric Acid	Sigma	C1901
Dibasic Sodium Phosphate	Sigma	S7907
Trizma HCl	OmniPur	9310
Tween-20	Sigma	P7949
100% DMSO	Sigma	D8418
Octyl-β-D-Glucopyranaside	Fischer	29836-26-8
Pefa Bloc SCF	Roche	1158591600
Dulbecco’s 10x Phosphate Buffered Saline	Invitrogen	14200-166
DELFIA Assay Buffer	Perkin Elmer	4002-0010
DELFIA Enhancement Buffer	Perkin Elmer	4001-0010
Europium Labelled Streptavidin	Perkin Elmer	1244-360
L243 anti-HLA-DR antibody	Biolegend	307602
Biotinylated tracer peptides	21st Century Biochemicals	Custom Order
Test peptides (1-4 mg, 85% purity)	Genscript	Custom Order
Purified HLA-DRB1 monomers (non-biotinylated)	Benaroya Research Institute*	Custom Order
384-well white EIA/RIA plate	Thermo	460372
Polypropylene 384-well plate	Costar	3656
Film, AxySeal, 80 µm, ELISA Applicator	Axygen Ascientific	PCR-SP
MilliQ Water	N/A	N/A
Epimotion Liquid Handler (or similar)	Eppendorf	5075
Select TS Plate Washer (or similar)	BioTek	405
SpectraMax Gemini Microplate Reader (or similar)	Molecular Devices	N/A
*Recombinant human MHC II molecules can be obtained from the Benaroya Tetramer Core Laboratory.  See: https://www.benaroyaresearch.org/our-research/core-resources/tetramer-core-laboratory