Statistical characterization of therapeutic protein modifications.

Peptide mapping with liquid chromatography-tandem mass spectrometry (LC-MS/MS) is an important analytical method for characterization of post-translational and chemical modifications in therapeutic proteins. Despite its importance, there is currently no consensus on the statistical analysis of the resulting data. In this manuscript, we distinguish three statistical goals for therapeutic protein characterization: (1) estimation of site occupancy of modifications in one condition, (2) detection of differential site occupancy between conditions, and (3) estimation of combined site occupancy across multiple modification sites. We propose an approach, which addresses these goals in terms of summarizing the quantitative information from the mass spectra, statistical modeling, and model-based analysis of LC-MS/MS data. We illustrate the approach using an LC-MS/MS experiment from an antibody-drug conjugate and its monoclonal antibody intermediate. The performance was compared to a 'naïve' data analysis approach, by using computer simulation, evaluation of differential site occupancy in positive and negative controls, and comparisons of estimated site occupancy with orthogonal experimental measurements of N-linked glycoforms and total oxidation. The results demonstrated the importance of replicated studies of protein characterization, and of appropriate statistical modeling, for reproducible, accurate and efficient site occupancy estimation and differential analysis.

A clinical biomarker assay to quantitate thymic stromal lymphopoietin in human plasma at sub-pg/ml level.

BACKGROUND: Thymic stromal lymphopoietin (TSLP) is an attractive therapeutic target for the treatment of allergic diseases, and plasma TSLP is a potential patient selection marker in the development of therapeutic agents. RESULTS: We developed and validated an ultrasensitive electrochemiluminescence assay for measurement of TSLP in plasma with a lower limit of quantitation of 0.12 pg/ml, which allowed the quantitation of TSLP in approximately 90% of human plasma samples tested. The assay demonstrated excellent performance characteristics, including precision, accuracy, sensitivity and dilution linearity. Stability and biological variability of TSLP in plasma were also assessed for clinical sample analysis and data interpretation. CONCLUSION: The validated TSLP assay enables assessment of circulating TSLP as a patient selection marker in the development of therapeutics to treat atopic diseases.

Identification and Characterization of Small-Molecule Inhibitors of the R132H/R132H Mutant Isocitrate Dehydrogenase 1 Homodimer and R132H/Wild-Type Heterodimer.

Recurrent genetic mutations in isocitrate dehydrogenase 1 and 2 (IDH1 and IDH2) have been identified in multiple tumor types. The most frequent mutation, IDH1 R132H, is a gain-of-function mutation resulting in an enzyme-catalyzing conversion of α-ketoglutarate (α-KG) to 2-hydroxyglutarate (2-HG). A high-throughput assay quantifying consumption of NADPH by IDH1 R132H has been optimized and implemented to screen 3 million compounds in 1536-well formats. The primary high-throughput screening hits were further characterized by RapidFire-mass spectrometry measuring 2-HG directly. Multiple distinct chemotypes were identified with nanomolar potencies (6-300 nM). All inhibitors were found to be inactive against the wild-type IDH1 homodimers. An IDH1 heterodimer between wild-type and R132H mutant is capable of catalyzing conversion of α-KG to 2-HG and isocitrate to α-KG. Interestingly, one of the inhibitors, EXEL-9324, was found to inhibit both conversions by the IDH1 heterodimer. This indicates the R132H/WT heterodimer may adopt conformations distinct from that of the R132H/R132H homodimer. Further enzymatic studies support this conclusion as the heterodimer exhibited a significantly lower apparent Michaelis-Menten constant for α-KG (K(m)=110 µM) compared with the R132H homodimer (K(m)= 1200 µM). The enhanced apparent affinity for α-KG suggests R132H/WT heterodimeric IDH1 can produce 2-HG more efficiently at normal intracellular levels of α-KG (approximately 100 µM).

Phosphorylation triggers domain separation in the DNA binding response regulator NarL.

DNA binding proteins of two-component signal transduction systems in microorganisms are activated by phosphorylation through an unknown mechanism. NarL is an example from the nitrate/nitrite signal transduction system of Escherichia coli. NarL consists of N- and C-terminal domains, the latter of which contains the DNA binding elements. To explore the mechanism of activation, single nitroxide side chains were introduced, one at a time, at nine different sites throughout the C-terminal domain to monitor the tertiary structure and the status of the surface in contact with the N-terminal domain. In addition, three pairs of doubly labeled proteins were prepared to monitor the interdomain distance using the magnetic dipolar interaction. The results of these site-directed spin-labeling studies reveal that phosphorylation at a distant site in the N-terminal domain triggers domain separation, likely by a hinge-bending motion. This in turn presents key elements of the C-terminal domain for docking to the DNA target in the configuration described in the recent crystal structure. The data also imply that a single conformation of unphosphorylated NarL exists in solution, and there is no detectable equilibrium between the closed and open conformations.