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 JoVE Biology

Antibody Profiling by Luciferase Immunoprecipitation Systems (LIPS)

1, 1, 1, 1

1Neurobiology and Pain Therapeutics Section, National Institute of Dental and Craniofacial Research, National Institutes of Health

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    Summary

    The technical aspects of performing LIPS (Luciferase Immunoprecipitation Systems) are described. The overall approach involves expressing chimeric genes encoding antigens fused to Renilla luciferase (Ruc) in mammalian cells. Crude Ruc-antigen extracts are then prepared and, without purification, employed in immunoprecipitation assays to quantify antibodies.

    Date Published: 10/07/2009, Issue 32; doi: 10.3791/1549

    Cite this Article

    Burbelo, P. D., Ching, K. H., Klimavicz, C. M., Iadarola, M. J. Antibody Profiling by Luciferase Immunoprecipitation Systems (LIPS). J. Vis. Exp. (32), e1549, doi:10.3791/1549 (2009).

    Abstract

    Technologies for comprehensively understanding and quantifying antibody profiles to autoantigens and infectious agents may yield new insights into disease mechanisms and may elucidate new markers to substratify disease with different clinical features and better understand pathogenesis. We have developed a highly quantitative method called Luciferase Immunoprecipitation Systems (LIPS) for profiling patient sera antibody responses to autoantigens and pathogen antigens associated with infection. Unlike ELISAs, the highly sensitive LIPS is easily implemented to survey humoral serological response profiles to different antigens in a universal format and produces dynamic antibody titer ranges up to 6 log10 for some antigens. In these studies, quantitative profiling by LIPS of patient humoral responses against panels of antigens or even the entire proteome of some pathogens (i.e. HIV), is typically more informative than testing a single antigen by ELISA In addition, LIPS also eliminates time and effort needed to produce highly purified antigens as well as the labor-intensive assay optimization steps needed for standard ELISAs. Here we provide a detailed protocol describing the technical aspects of performing LIPS assays for readily profiling antibody responses to single or multiple antigens.

    Protocol

    1. Schematic Overview:

    This video demonstrates the steps involved in performing the LIPS assay. Antigens are expressed in Cos1 cells as recombinant Renilla luciferase (Ruc)-antigen fusions, and crude extracts are obtained and used without purification. The LIPS assay is initiated by incubating crude Ruc-antigen extracts with patient sera in microtiter wells. The antibody-antigen mixture is then transferred to a 96-well filter plate containing protein A/G beads to capture IgG molecules. After washing the filter plate containing the protein A/G beads, antibody bound Ruc-antigen is measured by the addition of coelenterazine substrate and light units are measured with a luminometer.

    PART 1: Transfection of Plasmids for production of Renilla-Antigen Fusion Proteins

    Set-up: Cos1 cells are cultured in DMEM-10% FCS using standard tissue culture protocols. Plasmids for Renilla luciferase fusions have been described previously1. DNA for these plasmids is prepared using a Midiprep kit from Qiagen. The yield should be approximately 1 -3 mg. Measure the DNA concentration and store as a 1000 μg/ml stock solution at -20°C.

    Procedure:

    1. One day before transfection, split Cos-1 cells into new 100 x 20 mm dishes at approximately 2 X 106 per plate and incubate at 37 °C.
    2. On the following day, the Cos-1 cells should be 80-95% confluent Label 1.5 ml polypropylene microfuge tubes for each plasmid DNA to be transfected Allow the FuGENE-6 transfection reagent, which is stored at 4° C, to warm up to room temp.
    3. Add 94 μl of Opti-MEM media to each microfuge tube. Next add 6 μl of FuGENE 6 to the Opti-MEM media without touching the side wall.
    4. Incubate the mixture for 5 minutes at room temperature.
    5. Add 1-2 μg (from 1mg/ml DNA stock) of plasmid for Renilla luciferase antigen fusion construct. Mix and then incubate the mixture for 15 minutes at room temperature.
    6. Transfer the DNA-FuGENE 6-Opti-MEM solution to the cells by dripping it evenly into the media of the Cos1 cells.

    PART 2: Harvesting Renilla-antigen Fusions

    1. Two days after transfection, the Cos-1 cells are harvested. This is initiated by removing the media and then rinsing the cells with 6 ml of PBS. After decanting the PBS, pipette away any residual PBS from the tissue culture dish.
    2. Add 1.4 ml of cold lysis buffer composed of 50 mM Tris, pH 7.5, 100 mM NaCl, 5 mM MgCl2, 1% Triton X-100, 50% glycerol and protease inhibitors (2 tablets of complete miniprotease inhibitor cocktail per 50 ml of lysis buffer). Harvest cells with a cell scrapper and quickly transfer half of the lysate to each of two 1.5 ml microfuge tubes on ice.
    3. A Branson Sonifier 150 is used to break the cells open. Place the microcentrifuge tube containing the cell lysate on ice and pulse for 5 sec, 5 sec and 5 sec with sonication settings of 2, 2 and 4, respectively.
    4. Centrifuge the cell lysate at 12,500 RPM for two 4 minute spins at 4 ° C. After the first spin, gently invert the tubes to remove the loosely attached debris from the sidewall of the tube. After the second spin, carefully transfer the supernatant, without disrupting the pellet, from the two tubes to a new microfuge tube on ice.
    5. Calculate the light units (LU) per μl of lysate. To measure the LU, dilute 1 μl of lysate with 8 μl of PBS in a new microfuge tube. Directly add 100 μl of 1X coelenterazine substrate to the diluted mixture and immediately measure luminescence in the tube using a tube luminometer (20/20n Turner Scientific) with a 5 second read.
    6. Store the Ruc-antigen lysate at -20° C for 1-2 days or store for longer period of times in aliquots at -80° C.

    PART 3: Preparing a Sera Master Plate

    1. Make a sera master plate by first adding 450 μl of buffer A (50 mM Tris, pH 7.5, 100 mM NaCl, 5 mM MgCl2, 1% Triton X-100) to each well of a 96-deep-well polypropylene microtiter plate. At this step, a dye, Phenol Red, can also be included in buffer A (final concentration is 0.2 μg/ml in Buffer A) to act as a tracer for monitoring future sera sample addition and other steps of the LIPS assay.
    2. Next add 50 μl of sera from each sample to the different wells containing 450 μl of buffer A. Note this is a 1:10 dilution of the sera in buffer A. Typically sera is not added to the last two wells of the master plate because this is reserved for the buffer blanks.
    3. Before using the master plate, it is extensively shaken (1-2 hours) on a rotator platform. The serum in the master plate is stable for at least 1 month (or longer) at 4° C, if stored correctly to prevent evaporation.
    4. As described below, this master plate provides 10 μl of diluted sera to be repeatedly removed for profiling of the sera against multiple antigens. Larger and smaller master plates can also be employed. Seal the plate well with Parafilm when it is not being used.

    PART 4: LIPS assay

    1. Polypropylene 96-shallow well microtiter plates are used to test sera. In the first step, add 40 μl of buffer A to each well of the 96-well plate using an 8 channel micropipette.
    2. Next take 10 μl of diluted sera (1 μl sera equivalent) from the master plate and add it directly to each well of the working plate using an 8 channel micropipette.
    3. A master mix containing the Ruc-antigen extract is next formulated such that 1 X 107 light units (LU) is added in 50 μl of buffer A to each well. Lower inputs (as little as 1 X 106) can also be used, but result in a lower dynamic range. Make this master mixture and pipette 50 μl of Ruc-antigen mixture to each well.
    4. Incubate the plate on a rotary shaker for 1 hour at room temperature.
    5. During the incubation, add 5 μl of a 30% suspension of Ultralink protein A/G beads (Pierce Biotechnology, Rockford, IL) in PBS to the bottom of each well of a new 96 well filter HTS plate (Millipore, Bedford, MA).
    6. After the 1 hour incubation, transfer the 100 μl Ruc-antigen antibody reaction mixture to 96 well filter HTS plates containing the protein A/G beads using an 8 channel micropipette.
    7. Incubate the 96-well filter plate on a rotary shaker for 1 additional hour at room temperature.
    8. Next wash the filter plate on a vacuum manifold. Each well is washed 8 times with 100 μl of Buffer A, followed by two times with 100 μl of PBS. This can be performed manually or with a robotic pipetting workstation.
    9. Following the last wash, the vacuum is turned off. Remove the filter plate and blot it dry using a stack of paper towels or filter paper making sure to remove moisture on the top and bottom of the plate.

    PART 5: Measuring Luminescence and data analysis

    Set-up:

    A Berthold LB 960 Centro microplate luminometer is used for determining luminescence in each well using a single injector. Once the machine is on, rinse the injector with distilled H2O using the injector wash cycle. Coelenterazine substrate is prepared using the Promega Renilla substrate kit as described by the manufacturer. Typically 6 ml of 1X coelenterazine substrate mix (i.e. 60 μl coelenterazine stock plus 6 ml of 1X buffer) is prepared for priming the machine and running one full 96-well plate. Before analyzing the plate, the Berthold LB 960 Centro microplate luminometer is primed with 1X coelenterazine substrate. Open a program file containing the setting for injecting the substrate and reading the plate. For these measurements, 50 μl of coelenterazine substrate is injected, the plate is shaken for 2 sec, followed by a 5 sec read of luminescence.

    1. Although the plate luminometer has the capacity to read the entire plate, a partial read of the plate can also be selected (under the read menu). Start the program, which initiates reading of the plate.
    2. After the run, remove the microtiter filter plate promptly to prevent spillage in the luminometer. Export the data generated with the MikroWin program into an Excel format for analysis.
    3. We recommend evaluating the sera from two independent runs. Data is then averaged to generate the LU titer values for each sample. These values can further be adjusted to subtract the buffer blanks.
    4. Additional data analysis such as determining the cutoff can be calculated by taking the mean plus 3 or 5 standard deviations of the control values.

    Discussion

    LIPS requires minimal assay optimization and, due to its simplicity, high quality data can typically be generated using LIPS in under two weeks for any given antigen. The most time consuming steps are cloning and generating the appropriate plasmid expression vector containing the Ruc-antigen fusion. Once these plasmids are generated, single or multiple antigens can be rapidly tested with LIPS as described above. It should be noted that LIPS is quite versatile such that sera can also be tested in a tube format or alternatively on a microtiter filter plate with the aid of a BIOMEK robotic workstation2 or a plate washer with vacuum filtration. This highly scalable system allows for the parallel LIPS profiling of a panel of human autoantigens3 or the whole proteome of a virus4. It is likely that many different antibody profiles generated by LIPS will be useful for diagnostics3-9, antigen discovery9, following the course of a treatment10, vaccine monitoring and has broad implications for specific disease states and for public health in general.

    Disclosures

    Acknowledgements

    This research was supported by the Intramural Research Program of the NIDCR.

    Materials

    Name Company Catalog Number Comments
    HiSpeed Plasmid Midi KIt Qiagen 12643
    100 x 20 mm tissue culture dishes Fisher Scientific 353003
    Opti-MEM Invitrogen 31985
    FuGENE 6 Roche Group 1814443
    Complete, Mini protease inhibitor cocktail Roche Group 11836153001
    Polypropylene 96 DeepWell 1 ml plate Fisher Scientific 12-566-120 Deep well plate with lid and seal with Parafilm
    Polypropylene microtiter plate Fisher Scientific 12-566-120
    HTS Filter plate EMD Millipore MSBVN1B50
    Ultralink Immobilized Protein A/G Pierce, Thermo Scientific 53133 (10ml)
    Renilla Luciferase Assay System Promega Corp. E2820 For 2000 assays
    Centro microplate luminometer Berthold Technologies LB 960

    References

    1. Burbelo, P. D., Goldman, R., Mattson, T. L. A simplified immunoprecipitation method for quantitatively measuring antibody responses in clinical sera samples by using mammalian-produced Renilla luciferase-antigen fusion proteins. BMC Biotechnol. 5, 22-22 (2005).
    2. Burbelo, P. D., Leahy, H. P., Iadarola, M. J., Nutman, T. B. A Four-Antigen Mixture for Rapid Assessment of Onchocerca volvulus Infection. PLoS Negl Trop Dis. 3, e438-e438 (2009).
    3. Burbelo, P. D. Sensitive and robust luminescent profiling of anti-La and other autoantibodies in Sj gren’s syndrome. Autoimmunity. 139, 241-245 (2009).
    4. Burbelo, P. D. Rapid antibody quantification and generation of whole proteome antibody response profiles using LIPS (luciferase immunoprecipitation systems). Biochem Biophys Res Commun. 352, 889-895 (2007).
    5. Burbelo, P. D., Groot, S., Dalakas, M. C., Iadarola, M. J. High definition profiling of autoantibodies to glutamic acid decarboxylases GAD65/GAD67 in stiff-person syndrome. Biochem Biophys Res Commun. 366, 1-7 (2008).
    6. Burbelo, P. D. A new luminescence assay for autoantibodies to mammalian cell-prepared insulinoma-associated protein 2. Diabetes Care. 31, 1824-1826 (2008).
    7. Burbelo, P. D. Serological diagnosis of human herpes simplex virus type 1 and 2 infections by luciferase immunoprecipitation system assay. Clin Vaccine Immunol. 16, 366-371 (2009).
    8. Burbelo, P. D. Highly quantitative serological detection of anti-cytomegalovirus (CMV) antibodies. Virol J. 6, 45-45 (2009).
    9. Burbelo, P. D. Four-antigen mixture containing v-cyclin for serological screening of human herpesvirus 8 infection. Clin Vaccine Immunol. 16, 621-627 (2009).
    10. Ramanathan, R. A luciferase immunoprecipitation systems assay enhances the sensitivity and specificity of diagnosis of Strongyloides stercoralis infection. J Infect Dis. 198, 444-451 (2008).

    Comments

    2 Comments

    I need diagrammatic illustrations on how luciferase immunoprecipitation system can be carried out as related to serological determination of antibodies
    Reply

    Posted by: AnonymousSeptember 7, 2010, 5:41 AM

    I need diagrammatic illustrations on how luciferase immunoprecipitation system can be carried out as related to serological determination of antibodies
    Reply

    Posted by: AnonymousSeptember 7, 2010, 5:43 AM

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