Analysis of host-cell proteins in biotherapeutic proteins by comprehensive online two-dimensional liquid chromatography/mass spectrometry

Assays for identification and quantification of host-cell proteins (HCPs) in biotherapeutic proteins over 5 orders of magnitude in concentration are presented. The HCP assays consist of two types: HCP identification using comprehensive online two-dimensional liquid chromatography coupled with high resolution mass spectrometry (2D-LC/MS), followed by high-throughput HCP quantification by liquid chromatography, multiple reaction monitoring (LC-MRM). The former is described as a “discovery” assay, the latter as a “monitoring” assay. Purified biotherapeutic proteins (e.g., monoclonal antibodies) were digested with trypsin after reduction and alkylation, and the digests were fractionated using reversed-phase (RP) chromatography at high pH (pH 10) by a step gradient in the first dimension, followed by a high-resolution separation at low pH (pH 2.5) in the second dimension. As peptides eluted from the second dimension, a quadrupole time-of-flight mass spectrometer was used to detect the peptides and their fragments simultaneously by alternating the collision cell energy between a low and an elevated energy (MSE methodology). The MSE data was used to identify and quantify the proteins in the mixture using a proven label-free quantification technique (“Hi3” method). The same data set was mined to subsequently develop target peptides and transitions for monitoring the concentration of selected HCPs on a triple quadrupole mass spectrometer in a high-throughput manner (20 min LC-MRM analysis). This analytical methodology was applied to the identification and quantification of low-abundance HCPs in six samples of PTG1, a recombinant chimeric anti-phosphotyrosine monoclonal antibody (mAb). Thirty three HCPs were identified in total from the PTG1 samples among which 21 HCP isoforms were selected for MRM monitoring. The absolute quantification of three selected HCPs was undertaken on two different LC-MRM platforms after spiking isotopically labeled peptides in the samples. Finally, the MRM quantitation results were compared with TOF-based quantification based on the Hi3 peptides, and the TOF and MRM data sets correlated reasonably well. The results show that the assays provide detailed valuable information to understand the relative contributions of purification schemes to the nature and concentrations of HCP impurities in biopharmaceutical samples, and the assays can be used as generic methods for HCP analysis in the biopharmaceutical industry.

[1]  J. Gebler,et al.  Orthogonality of separation in two-dimensional liquid chromatography. , 2005, Analytical chemistry.

[2]  A. Rathore,et al.  Analysis for residual host cell proteins and DNA in process streams of a recombinant protein product expressed in Escherichia coli cells. , 2003, Journal of pharmaceutical and biomedical analysis.

[3]  Paul Dowling,et al.  Recent advances in clinical proteomics using mass spectrometry. , 2010, Bioanalysis.

[4]  P. Righetti,et al.  A new approach for the detection and identification of protein impurities using combinatorial solid phase ligand libraries. , 2006, Journal of proteome research.

[5]  D. Goodlett,et al.  Shotgun collision‐induced dissociation of peptides using a time of flight mass analyzer , 2003, Proteomics.

[6]  W. Hancock,et al.  Proteomic profiling of a high-producing Chinese hamster ovary cell culture. , 2009, Analytical chemistry.

[7]  S. Fenton,et al.  Development of an In-House , Process-Specific ELISA for Detecting HCP in a Therapeutic Antibody , Part 2 , 2011 .

[8]  C. Huber,et al.  Separation, detection, and identification of peptides by ion-pair reversed-phase high-performance liquid chromatography-electrospray ionization mass spectrometry at high and low pH. , 2005, Journal of chromatography. A.

[9]  Jürgen Hubbuch,et al.  High‐throughput screening of packed‐bed chromatography coupled with SELDI‐TOF MS analysis: monoclonal antibodies versus host cell protein , 2007, Biotechnology and bioengineering.

[10]  C. Cooney,et al.  Development of a peptide mapping procedure to identify and quantify methionine oxidation in recombinant human alpha1-antitrypsin. , 2002, Journal of chromatography. A.

[11]  A. Hunter,et al.  Separation of product associating E. coli host cell proteins OppA and DppA from recombinant apolipoprotein A‐IMilano in an industrial HIC unit operation , 2009, Biotechnology progress (Print).

[12]  E. Heinzle,et al.  Two-dimensional reversed-phase x ion-pair reversed-phase HPLC: an alternative approach to high-resolution peptide separation for shotgun proteome analysis. , 2007, Journal of proteome research.

[13]  J. Langridge,et al.  A novel precursor ion discovery method on a hybrid quadrupole orthogonal acceleration time-of-flight (Q-TOF) mass spectrometer for studying protein phosphorylation , 2002, Journal of the American Society for Mass Spectrometry.

[14]  Kelvin H. Lee,et al.  The genomic sequence of the Chinese hamster ovary (CHO)-K1 cell line , 2011, Nature Biotechnology.

[15]  B. Pramanik,et al.  LC-MS for protein characterization: current capabilities and future trends , 2008, Expert review of proteomics.

[16]  A. Chakraborty,et al.  Comparison of 1‐D and 2‐D LC MS/MS methods for proteomic analysis of human serum , 2009, Electrophoresis.

[17]  Huub Schellekens,et al.  Biosimilar therapeutics—what do we need to consider? , 2009, NDT plus.

[18]  Y. Oda,et al.  Evaluation of comprehensive multidimensional separations using reversed-phase, reversed-phase liquid chromatography/mass spectrometry for shotgun proteomics. , 2008, Journal of proteome research.

[19]  M. Dunn,et al.  A proteomic study of cMyc improvement of CHO culture , 2010, BMC biotechnology.

[20]  M. Gorenstein,et al.  Absolute Quantification of Proteins by LCMSE , 2006, Molecular & Cellular Proteomics.

[21]  M. Gorenstein,et al.  Simultaneous Qualitative and Quantitative Analysis of theEscherichia coli Proteome , 2006, Molecular & Cellular Proteomics.

[22]  J. Gebler,et al.  Two-dimensional separation of peptides using RP-RP-HPLC system with different pH in first and second separation dimensions. , 2005, Journal of separation science.

[23]  B. Warrack,et al.  Characterization of protein therapeutics by mass spectrometry: recent developments and future directions. , 2011, Drug discovery today.

[24]  A. Capriotti,et al.  Evaluation of different two-dimensional chromatographic techniques for proteomic analysis of mouse cardiac tissue. , 2011, Biomedical chromatography : BMC.

[25]  Ronald J. Moore,et al.  Reversed‐phase chromatography with multiple fraction concatenation strategy for proteome profiling of human MCF10A cells , 2011, Proteomics.

[26]  Xinning Jiang,et al.  Reversed-phase-reversed-phase liquid chromatography approach with high orthogonality for multidimensional separation of phosphopeptides. , 2010, Analytical chemistry.

[27]  N. Mozier,et al.  Improved HCP Quantitation By Minimizing Antibody Cross-Reactivity to Target Proteins , 2010 .

[28]  Dan Golick,et al.  Database searching and accounting of multiplexed precursor and product ion spectra from the data independent analysis of simple and complex peptide mixtures , 2009, Proteomics.

[29]  John Hickey,et al.  Profiling of host cell proteins by two‐dimensional difference gel electrophoresis (2D‐DIGE): Implications for downstream process development , 2010, Biotechnology and bioengineering.

[30]  Guodong Chen,et al.  Application of LC/MS to proteomics studies: current status and future prospects. , 2009, Drug discovery today.

[31]  K. Sandra,et al.  Tryptic digest analysis by comprehensive reversed phasextwo reversed phase liquid chromatography (RP-LCx2RP-LC) at different pH's. , 2009, Journal of separation science.

[32]  A. Hunter,et al.  Host cell proteins in biologics development: Identification, quantitation and risk assessment , 2009, Biotechnology and bioengineering.

[33]  Lingjun Li,et al.  Comparison of two-dimensional fractionation techniques for shotgun proteomics. , 2008, Analytical chemistry.

[34]  A. Lim,et al.  Applications of mass spectrometry for the structural characterization of recombinant protein pharmaceuticals. , 2007, Mass spectrometry reviews.

[35]  E. Novellino,et al.  Online comprehensive RPLC × RPLC with mass spectrometry detection for the analysis of proteome samples. , 2011, Analytical chemistry.

[36]  J. Yates,et al.  Large-scale analysis of the yeast proteome by multidimensional protein identification technology , 2001, Nature Biotechnology.

[37]  Kelvin H. Lee,et al.  A two‐dimensional electrophoresis map of Chinese hamster ovary cell proteins based on fluorescence staining , 2004, Electrophoresis.

[38]  L. Zolla,et al.  Capturing and amplifying impurities from purified recombinant monoclonal antibodies via peptide library beads: A proteomic study , 2007, Proteomics.

[39]  M. Gorenstein,et al.  Quantitative proteomic analysis by accurate mass retention time pairs. , 2005, Analytical chemistry.

[40]  Susan E Abbatiello,et al.  Effect of collision energy optimization on the measurement of peptides by selected reaction monitoring (SRM) mass spectrometry. , 2010, Analytical chemistry.

[41]  S. Ficarro,et al.  Online nanoflow RP-RP-MS reveals dynamics of multicomponent Ku complex in response to DNA damage. , 2010, Journal of proteome research.

[42]  Kathleen Champion,et al.  Defining Your Product Profile and Maintaining Control Over It , Part 2 Challenges of Monitoring Host Cell Protein Impurities , 2005 .

[43]  M. Gorenstein,et al.  The detection, correlation, and comparison of peptide precursor and product ions from data independent LC‐MS with data dependant LC‐MS/MS , 2009, Proteomics.