Anti-peptide monoclonal antibodies generated for immuno-multiple reaction monitoring-mass spectrometry assays have a high probability of supporting Western blot and ELISA

doi:10.1074/mcp.O114.043133

. 2015 Feb;14(2):382-98.

doi: 10.1074/mcp.O114.043133. Epub 2014 Dec 15.

Anti-peptide monoclonal antibodies generated for immuno-multiple reaction monitoring-mass spectrometry assays have a high probability of supporting Western blot and ELISA

Regine M Schoenherr¹, Richard G Saul², Jeffrey R Whiteaker¹, Ping Yan¹, Gordon R Whiteley², Amanda G Paulovich³

Affiliations

¹ From the ‡Fred Hutchinson Cancer Research Center, 1100 Fairview Avenue N., P.O. Box 19024, Seattle, Washington 98109-1024;
² §Leidos Biochemical Research, Inc., Frederick National Laboratory for Cancer Research ATRF, C1014, 8560 Progress Drive, Frederick, Maryland 21701.
³ From the ‡Fred Hutchinson Cancer Research Center, 1100 Fairview Avenue N., P.O. Box 19024, Seattle, Washington 98109-1024; [email protected].

PMID: 25512614
PMCID: PMC4350033
DOI: 10.1074/mcp.O114.043133

Anti-peptide monoclonal antibodies generated for immuno-multiple reaction monitoring-mass spectrometry assays have a high probability of supporting Western blot and ELISA

Regine M Schoenherr et al. Mol Cell Proteomics. 2015 Feb.

. 2015 Feb;14(2):382-98.

doi: 10.1074/mcp.O114.043133. Epub 2014 Dec 15.

Authors

Regine M Schoenherr¹, Richard G Saul², Jeffrey R Whiteaker¹, Ping Yan¹, Gordon R Whiteley², Amanda G Paulovich³

Affiliations

¹ From the ‡Fred Hutchinson Cancer Research Center, 1100 Fairview Avenue N., P.O. Box 19024, Seattle, Washington 98109-1024;
² §Leidos Biochemical Research, Inc., Frederick National Laboratory for Cancer Research ATRF, C1014, 8560 Progress Drive, Frederick, Maryland 21701.
³ From the ‡Fred Hutchinson Cancer Research Center, 1100 Fairview Avenue N., P.O. Box 19024, Seattle, Washington 98109-1024; [email protected].

PMID: 25512614
PMCID: PMC4350033
DOI: 10.1074/mcp.O114.043133

Abstract

Immunoaffinity enrichment of peptides coupled to targeted, multiple reaction monitoring-mass spectrometry (immuno-MRM) has recently been developed for quantitative analysis of peptide and protein expression. As part of this technology, antibodies are generated to short, linear, tryptic peptides that are well-suited for detection by mass spectrometry. Despite its favorable analytical performance, a major obstacle to widespread adoption of immuno-MRM is a lack of validated affinity reagents because commercial antibody suppliers are reluctant to commit resources to producing anti-peptide antibodies for immuno-MRM while the market is much larger for conventional technologies, especially Western blotting and ELISA. Part of this reluctance has been the concern that affinity reagents generated to short, linear, tryptic peptide sequences may not perform well in traditional assays that detect full-length proteins. In this study, we test the feasibility and success rates of generating immuno-MRM monoclonal antibodies (mAbs) (targeting tryptic peptide antigens) that are also compatible with conventional, protein-based immuno-affinity technologies. We generated 40 novel, peptide immuno-MRM assays and determined that the cross-over success rates for using immuno-MRM monoclonals for Western blotting is 58% and for ELISA is 43%, which compare favorably to cross-over success rates amongst conventional immunoassay technologies. These success rates could most likely be increased if conventional and immuno-MRM antigen design strategies were combined, and we suggest a workflow for such a comprehensive approach. Additionally, the 40 novel immuno-MRM assays underwent fit-for-purpose analytical validation, and all mAbs and assays have been made available as a resource to the community via the Clinical Proteomic Tumor Analysis Consortium's (CPTAC) Antibody (http://antibodies.cancer.gov) and Assay Portals (http://assays.cancer.gov), respectively. This study also represents the first determination of the success rate (92%) for generating mAbs for immuno-MRM using a recombinant B cell cloning approach, which is considerably faster than the traditional hybridoma approach.

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Figures

**Fig. 1.**
**Characterization of assays and antibody reagents.** Immuno-MRM-MS response curve data in linear A, and log space B, and Western blot C, and ELISA D, data for the monoclonal antibody to peptide target GLQTSQDAR from the protein calreticulin (CALR; target peptide ID SAIC-16D). For the response curves, the heavy-to-light peak area ratios for the peptide's transitions are plotted *versus* the heavy peptide's theoretical concentration; y5 refers to the product ion; SUM refers to the response curve for which the peak areas of all transitions were summed before taking the peak area ratios; the error bars indicate the minimum and maximum (*i.e.* range) of the peak area ratios of the three capture and LC-MRM-MS replicates. For the Western blot, the expected molecular weight of calreticulin is 48 kDa (UniProt). For the ELISA assay, the B_50% value was used as a relative value to assess the different mAbs' performances in these experiments; it indicates the inflection point of the curve and represents the mAb concentration at half of the calculated maximum binding of the mAb.

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References

1. Hoofnagle A. N., Wener M. H. (2009) The fundamental flaws of immunoassays and potential solutions using tandem mass spectrometry. J. Immunol. Methods 347, 3–11 - PMC - PubMed
1. Gillette M. A., Carr S. A. (2013) Quantitative analysis of peptides and proteins in biomedicine by targeted mass spectrometry. Nat. Methods 10, 28–34 - PMC - PubMed
1. Picotti P., Bodenmiller B., Aebersold R. (2013) Proteomics meets the scientific method. Nat. Methods 10, 24–27 - PubMed
1. Kennedy J. J., Abbatiello S. E., Kim K., Yan P., Whiteaker J. R., Lin C., Kim J. S., Zhang Y., Wang X., Ivey R. G., Zhao L., Min H., Lee Y., Yu M. H., Yang E. G., Lee C., Wang P., Rodriguez H., Kim Y., Carr S. A., Paulovich A. G. (2014) Demonstrating the feasibility of large-scale development of standardized assays to quantify human proteins. Nat. Methods 11, 149–155 - PMC - PubMed
1. Addona T. A., Abbatiello S. E., Schilling B., Skates S. J., Mani D. R., Bunk D. M., Spiegelman C. H., Zimmerman L. J., Ham A. J., Keshishian H., Hall S. C., Allen S., Blackman R. K., Borchers C. H., Buck C., Cardasis H. L., Cusack M. P., Dodder N. G., Gibson B. W., Held J. M., Hiltke T., Jackson A., Johansen E. B., Kinsinger C. R., Li J., Mesri M., Neubert T. A., Niles R. K., Pulsipher T. C., Ransohoff D., Rodriguez H., Rudnick P. A., Smith D., Tabb D. L., Tegeler T. J., Variyath A. M., Vega-Montoto L. J., Wahlander A., Waldemarson S., Wang M., Whiteaker J. R., Zhao L., Anderson N. L., Fisher S. J., Liebler D. C., Paulovich A. G., Regnier F. E., Tempst P., Carr S. A. (2009) Multi-site assessment of the precision and reproducibility of multiple reaction monitoring-based measurements of proteins in plasma. Nat. Biotechnol. 27, 633–641 - PMC - PubMed

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[1] Hoofnagle A. N., Wener M. H. (2009) The fundamental flaws of immunoassays and potential solutions using tandem mass spectrometry. J. Immunol. Methods 347, 3–11 - PMC - PubMed

[2] Hoofnagle A. N., Wener M. H. (2009) The fundamental flaws of immunoassays and potential solutions using tandem mass spectrometry. J. Immunol. Methods 347, 3–11 - PMC - PubMed

[3] Gillette M. A., Carr S. A. (2013) Quantitative analysis of peptides and proteins in biomedicine by targeted mass spectrometry. Nat. Methods 10, 28–34 - PMC - PubMed

[4] Gillette M. A., Carr S. A. (2013) Quantitative analysis of peptides and proteins in biomedicine by targeted mass spectrometry. Nat. Methods 10, 28–34 - PMC - PubMed

[5] Picotti P., Bodenmiller B., Aebersold R. (2013) Proteomics meets the scientific method. Nat. Methods 10, 24–27 - PubMed

[6] Picotti P., Bodenmiller B., Aebersold R. (2013) Proteomics meets the scientific method. Nat. Methods 10, 24–27 - PubMed

[7] Kennedy J. J., Abbatiello S. E., Kim K., Yan P., Whiteaker J. R., Lin C., Kim J. S., Zhang Y., Wang X., Ivey R. G., Zhao L., Min H., Lee Y., Yu M. H., Yang E. G., Lee C., Wang P., Rodriguez H., Kim Y., Carr S. A., Paulovich A. G. (2014) Demonstrating the feasibility of large-scale development of standardized assays to quantify human proteins. Nat. Methods 11, 149–155 - PMC - PubMed

[8] Kennedy J. J., Abbatiello S. E., Kim K., Yan P., Whiteaker J. R., Lin C., Kim J. S., Zhang Y., Wang X., Ivey R. G., Zhao L., Min H., Lee Y., Yu M. H., Yang E. G., Lee C., Wang P., Rodriguez H., Kim Y., Carr S. A., Paulovich A. G. (2014) Demonstrating the feasibility of large-scale development of standardized assays to quantify human proteins. Nat. Methods 11, 149–155 - PMC - PubMed

[9] Addona T. A., Abbatiello S. E., Schilling B., Skates S. J., Mani D. R., Bunk D. M., Spiegelman C. H., Zimmerman L. J., Ham A. J., Keshishian H., Hall S. C., Allen S., Blackman R. K., Borchers C. H., Buck C., Cardasis H. L., Cusack M. P., Dodder N. G., Gibson B. W., Held J. M., Hiltke T., Jackson A., Johansen E. B., Kinsinger C. R., Li J., Mesri M., Neubert T. A., Niles R. K., Pulsipher T. C., Ransohoff D., Rodriguez H., Rudnick P. A., Smith D., Tabb D. L., Tegeler T. J., Variyath A. M., Vega-Montoto L. J., Wahlander A., Waldemarson S., Wang M., Whiteaker J. R., Zhao L., Anderson N. L., Fisher S. J., Liebler D. C., Paulovich A. G., Regnier F. E., Tempst P., Carr S. A. (2009) Multi-site assessment of the precision and reproducibility of multiple reaction monitoring-based measurements of proteins in plasma. Nat. Biotechnol. 27, 633–641 - PMC - PubMed

[10] Addona T. A., Abbatiello S. E., Schilling B., Skates S. J., Mani D. R., Bunk D. M., Spiegelman C. H., Zimmerman L. J., Ham A. J., Keshishian H., Hall S. C., Allen S., Blackman R. K., Borchers C. H., Buck C., Cardasis H. L., Cusack M. P., Dodder N. G., Gibson B. W., Held J. M., Hiltke T., Jackson A., Johansen E. B., Kinsinger C. R., Li J., Mesri M., Neubert T. A., Niles R. K., Pulsipher T. C., Ransohoff D., Rodriguez H., Rudnick P. A., Smith D., Tabb D. L., Tegeler T. J., Variyath A. M., Vega-Montoto L. J., Wahlander A., Waldemarson S., Wang M., Whiteaker J. R., Zhao L., Anderson N. L., Fisher S. J., Liebler D. C., Paulovich A. G., Regnier F. E., Tempst P., Carr S. A. (2009) Multi-site assessment of the precision and reproducibility of multiple reaction monitoring-based measurements of proteins in plasma. Nat. Biotechnol. 27, 633–641 - PMC - PubMed

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Anti-peptide monoclonal antibodies generated for immuno-multiple reaction monitoring-mass spectrometry assays have a high probability of supporting Western blot and ELISA

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Anti-peptide monoclonal antibodies generated for immuno-multiple reaction monitoring-mass spectrometry assays have a high probability of supporting Western blot and ELISA

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