Hendrik Neubert

Targeted Peptide Measurements in Biology and Medicine: Best Practices for Mass Spectrometry-based Assay Development Using a Fit-for-Purpose Approach

Adoption of targeted mass spectrometry (MS) approaches such as multiple reaction monitoring (MRM) to study biological and biomedical questions is well underway in the proteomics community. Successful application depends on the ability to generate reliable assays that uniquely and confidently identify target peptides in a sample. Unfortunately, there is a wide range of criteria being applied to say that an assay has been successfully developed. There is no consensus on what criteria are acceptable and little understanding of the impact of variable criteria on the quality of the results generated. Publications describing targeted MS assays for peptides frequently do not contain sufficient information for readers to establish confidence that the tests work as intended or to be able to apply the tests described in their own labs. Guidance must be developed so that targeted MS assays with established performance can be made widely distributed and applied by many labs worldwide. To begin to address the problems and their solutions, a workshop was held at the National Institutes of Health with representatives from the multiple communities developing and employing targeted MS assays. Participants discussed the analytical goals of their experiments and the experimental evidence needed to establish that the assays they develop work as intended and are achieving the required levels of performance. Using this “fit-for-purpose” approach, the group defined three tiers of assays distinguished by their performance and extent of analytical characterization. Computational and statistical tools useful for the analysis of targeted MS results were described. Participants also detailed the information that authors need to provide in their manuscripts to enable reviewers and readers to clearly understand what procedures were performed and to evaluate the reliability of the peptide or protein quantification measurements reported. This paper presents a summary of the meeting and recommendations.

Online High-Flow Peptide Immunoaffinity Enrichment and Nanoflow LC-MS/MS: Assay Development for Total Salivary Pepsin/Pepsinogen

BACKGROUND Detection limit challenges associated with measuring low-abundance protein biomarkers can be addressed with hybrid immunoaffinity-mass spectrometric assays, such as antipeptide antibody capture followed by liquid chromatography/tandem mass spectrometry (LC-MS/MS). Popular assay formats use magnetic bead-based immunoaffinity enrichment and nanoflow LC-MS/MS or high-flow immunoaffinity chromatography coupled online to conventional LC-MS/MS. As a proof of principle, we describe a novel online immunoaffinity LC-MS/MS configuration that combines high-flow peptide immunoaffinity enrichment and nanoflow LC-MS/MS. METHODS We configured and validated an assay for the measurement of total pepsin/pepsinogen from human saliva that uses a pepsinogen standard. Saliva was heat-inactivated to quench residual enzymatic activity and then digested with endoproteinase AspN. Online immunoaffinity enrichment using an antipeptide antibody directed against the pepsin C-terminal sequence, DRANNQVGLAPVA, was linked to nanoflow liquid chromatography and selected reaction monitoring mass spectrometry. We used the assay to measure pepsin/pepsinogen concentrations in human saliva from presumed healthy volunteers. RESULTS Heat inactivation at 100 degrees C for 25 min stabilized the target peptide. The final assay had <15% interassay relative error and <15% interassay CV across a range of 4.08-2980 pmol/L human pepsinogen (0.165-120 microg/L). Low but quantifiable signals were observed in some samples from presumed normal healthy volunteers ranging from 4.3 to 16.6 pmol/L (0.17-0.67 microg/L) total salivary pepsin/pepsinogen. CONCLUSIONS This assay approach provides a high-sensitivity platform for protein bioanalysis in the low picomolar range. It bears the potential to deliver additional data on the salivary occurrence of pepsin/pepsinogen with greater confidence than previously.

Targeted Quantitative Proteomics for the Analysis of 14 UGT1As and -2Bs in Human Liver Using NanoUPLC–MS/MS with Selected Reaction Monitoring

Targeted quantitative proteomics using heavy isotope dilution techniques is increasingly being utilized to quantify proteins, including UGT enzymes, in biological matrices. Here we present a multiplexed method using nanoLC-MS/MS and multiple reaction monitoring (MRM) to quantify 14 UGT1As and UGT2Bs in liver matrices. Where feasible, we employ two or more proteotypic peptides per protein, with only four proteins quantified with only one proteotypic peptide. We apply the method to analysis of a library of 60 human liver microsome (HLM) and matching S9 samples. Ten of the UGT isoforms could be detected in liver, and the expression of each was consistent with mRNA expression reported in the literature. UGT2B17 was unusual in that ∼30% of liver microsomes had no or little (<0.5 pmol/mg protein) content, consistent with a known common polymorphism. Liver S9 UGT concentrations were approximately 10-15% those of microsomes. The method was robust, precise, and reproducible and provides novel UGT expression data in human liver that will benefit rational approaches to evaluate metabolism in drug development.

An immunoaffinity liquid chromatography–tandem mass spectrometry assay for the quantitation of matrix metalloproteinase 9 in mouse serum

An immunoaffinity liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was developed for the quantitation of the zinc endopeptidase matrix metalloproteinase 9 (MMP-9) from mouse serum. Sample preparation for the assay included magnetic bead-based enrichment using an MMP-9 antibody and was performed in a 96-well plate format using a liquid-handling robotic platform. The surrogate peptide GSPLQGPFLTAR derived from MMP-9 by trypsin digestion was monitored using an on-line capillary flow trap-release chromatography setup incorporating a series of trap columns (C18, strong cation exchange, and another C18) prior to nanoflow chromatography and nanospray ionization with selected reaction monitoring (SRM) detection. The assay was fit-for-purpose validated and found to be accurate (<15% interbatch relative error) and precise (<15% interbatch coefficient of variation) across a range from 0.03 to 7.3nM mouse MMP-9. Finally, the method was employed to measure MMP-9 concentrations in 30 naïve mouse serum samples, and results were compared with those obtained by an immunoassay.

Recommendations for the Generation, Quantification, Storage, and Handling of Peptides Used for Mass Spectrometry-Based Assays.

BACKGROUND For many years, basic and clinical researchers have taken advantage of the analytical sensitivity and specificity afforded by mass spectrometry in the measurement of proteins. Clinical laboratories are now beginning to deploy these work flows as well. For assays that use proteolysis to generate peptides for protein quantification and characterization, synthetic stable isotope-labeled internal standard peptides are of central importance. No general recommendations are currently available surrounding the use of peptides in protein mass spectrometric assays. CONTENT The Clinical Proteomic Tumor Analysis Consortium of the National Cancer Institute has collaborated with clinical laboratorians, peptide manufacturers, metrologists, representatives of the pharmaceutical industry, and other professionals to develop a consensus set of recommendations for peptide procurement, characterization, storage, and handling, as well as approaches to the interpretation of the data generated by mass spectrometric protein assays. Additionally, the importance of carefully characterized reference materials-in particular, peptide standards for the improved concordance of amino acid analysis methods across the industry-is highlighted. The alignment of practices around the use of peptides and the transparency of sample preparation protocols should allow for the harmonization of peptide and protein quantification in research and clinical care.

Targeted precise quantification of 12 human recombinant uridine-diphosphate glucuronosyl transferase 1A and 2B isoforms using nano-ultra-high-performance liquid chromatography/tandem mass spectrometry with selected reaction monitoring

Quantification methods employing stable isotope-labeled peptide standards and liquid chromatography–tandem mass spectrometry are increasingly being used to measure enzyme amounts in biologic samples. Isoform concentrations, combined with catalytic information, can be used in absorption, distribution, metabolism, and excretion studies to improve accuracy of in vitro/in vivo predictions. We quantified isoforms of uridine-diphosphate glucuronosyltransferase (UGT) 1A and 2B in 12 commercially available recombinant UGTs (recUGTs) (n = 49 samples) using nano-ultra-high-performance liquid chromatography–tandem mass spectrometry with selected reaction monitoring). Samples were trypsin-digested and analyzed using our previously published method. Two MRMs were collected per peptide and averaged. Where available, at least two peptides were measured per UGT isoform. The assay could detect UGTs in all recombinant preparations: recUGTs 1A1, 1A3, 1A4, 1A6, 1A7, 1A8, 1A9, 1A10, 2B4, 2B7, 2B15, and 2B17, with limit of detection below 1.0 pmol/mg protein for all isoforms. The assay had excellent linearity in the range observed (2–15.5 pmol/mg, after dilution). Examples of concentrations determined were 1465, 537, 538, 944, 865, 698, 604, 791, 382, 1149, 307, and 740 pmol/mg protein for the respective isoforms. There was a 6.9-fold difference between the maximum and minimum recUGT concentrations. The range of concentrations determined indicates that catalytic rates per mg total protein in vitro will not accurately reflect isoform inherent specific activity for a particular drug candidate. This is the first report of a targeted precise quantification of commercially available recUGTs. The assay has potential for use in comparing UGT amounts with catalytic activity determined using probe substrates, thus allowing representation of catalysis as per pmol of UGT isoform.

Utility of a human FcRn transgenic mouse model in drug discovery for early assessment and prediction of human pharmacokinetics of monoclonal antibodies

ABSTRACT Therapeutic antibodies continue to develop as an emerging drug class, with a need for preclinical tools to better predict in vivo characteristics. Transgenic mice expressing human neonatal Fc receptor (hFcRn) have potential as a preclinical pharmacokinetic (PK) model to project human PK of monoclonal antibodies (mAbs). Using a panel of 27 mAbs with a broad PK range, we sought to characterize and establish utility of this preclinical animal model and provide guidance for its application in drug development of mAbs. This set of mAbs was administered to both hemizygous and homozygous hFcRn transgenic mice (Tg32) at a single intravenous dose, and PK parameters were derived. Higher hFcRn protein tissue expression was confirmed by liquid chromatography-high resolution tandem mass spectrometry in Tg32 homozygous versus hemizygous mice. Clearance (CL) was calculated using non-compartmental analysis and correlations were assessed to historical data in wild-type mouse, non-human primate (NHP), and human. Results show that mAb CL in hFcRn Tg32 homozygous mouse correlate with human (r2 = 0.83, r = 0.91, p < 0.01) better than NHP (r2 = 0.67, r = 0.82, p < 0.01) for this dataset. Applying simple allometric scaling using an empirically derived best-fit exponent of 0.93 enabled the prediction of human CL from the Tg32 homozygous mouse within 2-fold error for 100% of mAbs tested. Implementing the Tg32 homozygous mouse model in discovery and preclinical drug development to predict human CL may result in an overall decreased usage of monkeys for PK studies, enhancement of the early selection of lead molecules, and ultimately a decrease in the time for a drug candidate to reach the clinic.

Online capillary weak cation exchange enrichment hyphenated to nanospray mass spectrometry for quantitation of a basic pegvisomant derived peptide.

A multidimensional LC-MS/MS configuration is described for targeted quantitation of a highly basic peptide chemically derived from pegvisomant as a surrogate for the intact protein. The method developed for an immunogenicity assay employed orthogonal separation of the target peptide commencing with flowing microgram quantities of total digests from a protein G extraction of human serum through a weak cation exchange (WCX) monolithic trap column. The basic peptide of interest was retained on the WCX column. Following a washing procedure, peptides were eluted with acetic acid and retained on a down-stream reverse phase trap compatible with online nanoflow LC-MS/MS. Such a LC configuration including the use of other sorbents such as strong cation exchange media is proposed as an enabling tool in assay development for quantitative protein bioanalysis by LC-MS/MS.

Reduced serum myostatin concentrations associated with genetic muscle disease progression

Myostatin is a highly conserved protein secreted primarily from skeletal muscle that can potently suppress muscle growth. This ability to regulate skeletal muscle mass has sparked intense interest in the development of anti-myostatin therapies for a wide array of muscle disorders including sarcopenia, cachexia and genetic neuromuscular diseases. While a number of studies have examined the circulating myostatin concentrations in healthy and sarcopenic populations, very little data are available from inherited muscle disease patients. Here, we have measured the myostatin concentration in serum from seven genetic neuromuscular disorder patient populations using immunoaffinity LC–MS/MS. Average serum concentrations of myostatin in all seven muscle disease patient groups were significantly less than those measured in healthy controls. Furthermore, circulating myostatin concentrations correlated with clinical measures of disease progression for five of the muscle disease patient populations. These findings greatly expand the understanding of myostatin in neuromuscular disease and suggest its potential utility as a biomarker of disease progression.

Quantitative measurements of GDF-8 using immunoaffinity LC-MS/MS

Growth and differentiation factor 8 (GDF‐8) is a negative regulator of skeletal muscle mass and targeted by inhibitors to treat diseases associated with muscle loss. In order to enable clinical and translational investigations of GDF‐8 inhibitors, specific and sensitive measurements of GDF‐8 are necessary.