High Coverage Process Specific HCP Identification and ... · • Venn diagrams showing degree of...
Transcript of High Coverage Process Specific HCP Identification and ... · • Venn diagrams showing degree of...
High Coverage Process Specific HCP Identification and Quantification Using Mass Spectrometry
HCP IDENTIFICATION
Digestion of proteins to peptides (Trypsin enzyme)
Extensive peptide fractionation (Two orthogonal methods)
LC-MS/MS analysis (High resolution Q Exactive mass spectrometer)
1. Electronic Data Report: List of identified HCPs, including spectral counts for relative quantification.
2. Written Report: Summary study design, methods, results discussion and conclusions.
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LC-MS/MS Identification & Relative Quantification of HCP
Identification of HCP (Match detected peptides to HCP
sequences in corresponding HCP database)
Harvest In-process
step 1 In-process
step 2 …
In-process step N
DS
Highly characterized, defined mixture of ~50 human proteins spiked with and without DS. Process blank also used.
Monitoring of general MS instrument sensitivity, reproducibility and stability
Assessment of impact of DS on sensitivity
Routinely obtain LOD range 5-20ppm, can be as low as 1ppm
Deliverables:
Process Quality Controls (PQC)
Custom Database
Client process-specific sequences
DS sequences
Host proteome (ex: CHO, E.coli, human, yeast)
Process-specific additives
Caprion-specific sequences
PQC protein mixture and associated additives
Common laboratory contaminants
• Monoclonal Ab • Recombinant
protein • Fusion proteins • Peptide drugs
Mass Spectrometry Platform Features and Applications for HCP
HCP Identification
Extensive Fractionation •Enables specific detection of low level HCP in presence of high DS concentration
•Increased sensitivity for coverage of low level HCPs
LC-MS/MS Analysis •DS and in-process samples
•Process-specific custom HCP database for comprehensive HCP identification
•Relative quantitation of identified HCPs
HCP Quantification
Multiplexed MRM Assay •HCPs selected from previous HCP identification studies, may include ‘problematic’ HCPs
•Assay developed using isotope-labeled standards for specific and accurate performance
Assay qualification •Absolute quantitation of individual HCPs (ppm)
•LLOQ, ULOQ, CV, recovery
• Monitoring of purification process • Demonstration of HCP Clearance • Compare culture media, process improvements • Evaluation of batch reproducibility and scale-up
Applications for Process Development and Manufacturing
BACKGROUND
Regulatory trend towards increasingly deeper HCP characterization • Regulatory framework: 42 USC 262, ICH Q6B, ICH Q8 • Current practice of using immunoassays has well-recognized gaps; little is known about individual HCPs • Post-market commitments for development of an HCP assay with improved coverage was required for
3 of 8 BLAs approved in 2014 due to insufficient characterization of HCPs
Mass spectrometry is playing a greater role in characterization of HCPs • “Immunoassay and (increasingly) mass spectrometry are highly complementary and the most
powerful methods for monitoring residual HCP levels in samples and confirming their absence in final DSs.” - USP 1132
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Extensive Fractionation Provides Increased HCP Coverage
CHO: 53 HCPs E.coli: 36 HCPs
Yeast: 31 HCPs Human: 25 HCPs
• Use of two orthogonal fractionation methods typically provides 30-50% more HCP peptide identifications and 5-20% more protein identifications
• Venn diagrams showing degree of non-overlap from use of two different fractionation methods on different DS in various host systems (protein level)
Fractionation Method 1
Fractionation Method 2
Method 1 2
For this example, the increased HCP coverage at the peptide level provides increased confidence at the protein identification level
92 48 67 7 24 24
11 14 28 32 2 2
19 25
• Prioritize list of HCPs • Select ≤5 signature
peptides per HCP
MSAIQAAWPSGTECIAKYNFHGTAEQDLPFCKGDVLTIVAVTKDPNWYKAKNKVGREGIIPANYVQKREGVKAGTKLSLMPWFHGKITREQAERLLYPPETGLFLVRESTNYPGDYTLCVSCDGKVEHYRIMYHASKLSIDEEVYFENLKMQLVEHYTSDADGLCTRLIKPKVMEGTVAAQDEFYRSGWALNMKELKLLQTIGKGEFGDVMLGDYRGNKVAVKCIKNDATA…
• Use synthetic isotope-labeled peptides to develop LC-MRM/MS assay conditions
Targeted Multiplexed LC-MRM/MS Assay Development
inte
nsi
ty
RT
• Final optimized assay monitors two fragments (transitions) per peptide
HCP protein sequence, trypsin digestion Peptide detection (MS) Fragmentation Fragment detection (MS/MS)
HCP QUANTIFICATION (ABSOLUTE)
• Data shows successful clearance of two individual HCPs across the purification process
• Two peptides from the same protein yield similar results
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Step 1 Step 2 Step 3 DrugProduct
ppm
(ng
HCP
/ m
g D
S)
Purification Step
HCP Protein 1
Peptide 1
Peptide 2
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Step 1 Step 2 Step 3 DrugProduct
ppm
(ng
HCP
/ m
g D
S)
Purification Step
HCP Protein 2
Peptide 1
Peptide 2
Quantitative Assessment of HCP Clearance
*Sensitivity of detection routinely achieved in the 1ppm range
SUMMARY
Caprions’ Mass Spectrometry Platform has been used for the following types of HCP client studies: • Characterization of in-process samples and DS • Demonstration of HCP clearance • Characterization of HCP from DS expressed in various host expression systems • Comparability studies of Biosimilars to Innovators
Absolute Quantification of HCP using LC-MRM/MS
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No light peptide spike (endogenous only)
Spike light peptides: (Low, Mid, High)
Desalt / MRM analysis
Endogenous levels, (Concentration back-calculated
using calibration curve)
Spike light peptides:
Calibration curve (Peak area ratio as a function of
nominal concentration)
(≥7 non-zero standards)
Digestion
Study samples (Individual DS)
Precision and Accuracy (Concentration back-calculated
using calibration curve)
Calibration curves (BSA or pooled DS)
Spike SIL peptides (fixed concentration)
QC samples (pooled DS)
Demonstration of HCP Clearance During DS Purification
• Use of mass spectrometry shows a decreasing number and concentration of HCPs across the purification process. Protein (A) and spectra (B) data shown.
A B
Comparison of HCP content in Biosimilars vs Innovators
• Data shown from two experiments comparing Biosimilars vs Innovators using either different manufacturing replicates (A) or lots (B).
A B
Caprion Biosciences Inc, Montreal, Canada [email protected]