Craig A. Gelfand

Free-flow electrophoresis for top-down proteomics by Fourier transform ion cyclotron resonance mass spectrometry.

High‐efficiency prefractionation of complex protein mixtures is critical for top‐down proteomics, i.e., the analysis of intact proteins by MS. Free‐flow electrophoresis (FFE) can be used for IEF to separate proteins within a pH gradient according to their pIs. In an FFE system, this separation is performed entirely in the liquid phase, without the need for particulate chromatographic media, gels, or membranes. Herein, we demonstrated the compatibility of IEF‐FFE with ESI‐Fourier transform ICR MS (ESI‐FTICR‐MS) for top‐down experiments. We demonstrated that IEF‐FFE of intact proteins were highly reproducible between FFE instruments, between laboratories, and between analyses. Applying native (0.2% hydroxypropylmethyl cellulose) IEF‐FFE to an enzyme resulted in no decrease in enzyme activity; applying either native or denaturing (8 M urea) IEF‐FFE to a four‐protein mixture with different pIs resulted in isolation of each protein into separate fractions in a 96‐well plate. After desalting, each protein was sequenced by top‐down MS/MS. As an application of this technique, chicken erythrocyte histone H2A‐IV and its major modified forms were enriched by IEF‐FFE. Top‐down analysis revealed Lys‐5 to be a major acetylation site, in addition to N‐terminal acetylation.

Thrombin induces broad spectrum proteolysis in human serum samples.

Abstract Background: During clotting, α thrombin cleaves fibrinogen releasing fibrinopeptide A (FPA). FPA is easily identified in serum using matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS). Using MALDI-TOF MS, we observed multiple, progressively shorter fragments of serum FPA. Following ambient incubation of serum, variations in the content of FPA fragments occur over time. Denaturation of α thrombin by heating the serum sample appears to minimize this variation. These observations suggest that intrinsic proteolytic and peptidolytic activity is elevated in serum and perhaps originates from the coagulation cascade enzymes themselves, especially α thrombin. Methods: Extrinsic addition of α thrombin to a subset (3–30 kDa) of plasma proteins was carried out to induce proteolysis and to examine the resultant peptides to reveal α thrombin susceptible parent proteins. One of these identified proteins, hemopexin, was directly digested by α thrombin and the peptides examined to confirm the observations from the initial plasma protein digestion. Results: Extrinsic addition of α thrombin to a subset (3–30 kDa) of plasma proteins results in wide-spread digestion of proteins unrelated to coagulation, revealing a substrate range encompassing more than fibrinogen. Direct digestion of one of these proteins, hemopexin, by α thrombin confirms these observations. Conclusions: The resulting peptides indicate broad tolerance beyond the consensus R-G cleavage site of fibrinogen; in fact, there appears to be no bias for the amino acid following the R/K residue. These data support our hypothesis that the enzymatic activities inherent to coagulation, or at least to thrombin, contribute to destabilization of the protein and peptide content of serum. Clin Chem Lab Med 2009;47:685–93.

Minimizing Preanalytical Variation of Plasma Samples by Proper Blood Collection and Handling

Blood samples collected for proteome studies are subject to a variety of preanalytical instability, among which intrinsic proteolysis activities cause a broad spectrum of protein and peptide degradation. This chapter describes two MALDI MS-based methods for plasma peptidomic analyses; a direct MALDI-TOF MS and an LC MALDI-TOF MS. Using these methods, we compared peptides and their time-dependent changes in traditional serum, four plasma samples with different anticoagulants and additives: EDTA-based, citrate-based, or heparin-based, and EDTA-based with protease inhibitors. For minimizing plasma sample instability and preanalytical variation, we suggest using an optimized blood collection device, minimizing the dwell time during blood collection and handling, controlling centrifugation and handling at room temperature, and saving plasma samples for use at most one freeze/thaw cycle. We have optimized our protocol to achieve reproducibility in peptidomic analyses of plasma samples using MALDI-TOF MS by minimizing preanalytical and analytical variability.

Top-down proteomics on a high-field Fourier transform ion cyclotron resonance mass spectrometer.

Mass spectrometry is the tool of choice for sequencing peptides and determining the sites of posttranslational modifications; however, this bottom-up approach lacks in providing global information about the modification states of proteins including the number and types of isoforms and their stoichiometry. Recently, various techniques and mass spectrometers, such as high-field Fourier Transform Ion Cyclotron Resonance (FTICR) mass spectrometers, have been developed to study intact proteins (top-down proteomics). While the protein molecular mass and the qualitative and quantitative information about protein isoforms can be revealed by FTICR-MS analysis, their primary structure (including the identification of modifications and their exact locations in the amino acid sequence) can directly be determined using the MS/MS capability offered by the FTICR mass spectrometer. The distinct advantage of top-down methods are that modifications can be determined for a specific protein isoform rather than for peptides belonging to one or several isoforms. In this chapter, we describe different top-down proteomic approaches enabled by high-field (7, 9.4, and 12 T) FTICR mass spectrometers, and their applicability to answer biological and biomedical questions. We also describe the use of the free flow electrophoresis (FFE) to separate proteins prior to top-down mass spectrometric characterization.

Investigation of peptide biomarker stability in plasma samples using time-course MS analysis.

Peptide biomarkers in plasma or serum are subject to proteolytic degradation caused by intrinsic peptidase activities, resulting in a potential barrier in translating a discovered biomarker into clinical application. This chapter describes a method using time-course MALDI-TOF MS analysis to investigate the stability of a plasma peptide biomarker under a variety of preanalytical situations. A synthesized peptide with the same primary sequence as a potential endogenous biomarker is spiked into a blood sample, and the sample is incubated over time at r.t. (25  ±  1°C) or other preanalytical situations. At a specific period of incubation time, the sample is quenched with the addition of acid with or without an internal control peptide. The spiked peptides in the sample are extracted with one of three procedures for highly soluble, moderately soluble, or essentially insoluble peptides. The peptide samples are then analyzed using MALDI-TOF MS. The abundance changes of the peptide biomarker are monitored by time-course changes of the mass spectra. These changes over-time are measured and fitted to a first-order degradation reaction so that stability of the peptide biomarker (half-life) can be calculated. Kinetics analysis of both parent and shorter (daughter) peptides are also possible by fitting to a sequential multiple-step reaction (SMSR) model. This optimized method facilitates evaluation of biomarker stability, and helps to define sample handling and analytical processing steps that contribute to instability of measured peptide biomarker(s).

Application of free flow electrophoresis to the analysis of the urine proteome.

Urine is a complex fluid, which is thought to contain valuable diagnostic information regarding general health. In particular, there is great diagnostic potential in the peptide and/or protein content of urine, but the information is present in low abundance. Most traditional proteomic techniques lack sufficient sensitivity/dynamic range, especially for dilute and/or complex samples. However, orthogonal separation methods can be applied prior to protein/peptide analysis to increase the success rate of urine proteomic studies and access this potentially valuable information. In this chapter, we describe isoelectric focusing (IEF) of intact urine proteins, via free flow electrophoresis (FFE), prior to typical peptide-based mass spectrometry analysis, facilitating the deep analysis of urine protein detection and identification, for biomarker discovery. Our work demonstrates that such an approach can be used as a preprocessing step and can be integrated into a workflow for the successful identification of protein components (biomarkers) from urine.

Resolution of adiponectin oligomers in human plasma using free flow electrophoresis

Adiponectin is an important adipocytokine hormone which circulates in blood as homo-oligomers (trimer, hexamer and high molecular weight (HMW) forms) as well as a truncated form corresponding to the globular domain. Free flow electrophoresis (FFE) used in zone electrophoresis mode revealed the presence of isoforms within these oligomeric forms in plasma. HMW adiponectin oligomer showed two isoforms which carry different charge density at pH 4.7, only one of which is susceptible to dissociation by SDS. The adiponectin hexamer was shown to consist of a doublet and also shown to have at least two isoforms. A truncated form of adiponectin was identified as the main constituent of adiponectin in plasma and appeared to circulate bound to a basic protein, potentially one of the chemokines reported to bind to the globular domain. Analysis of the monomer composition of the oligomers revealed differences in monomeric isoforms used to build up the oligomers.

Time-Dependent and Sample-to-Sample Variations in Human Plasma Peptidome are Both Minimized Through Use of Protease Inhibitors

Abstract In the current study, we have developed a method to measure relative peptide stability over time in different blood collection tubes. Reversed-phase chromatography and liquid chromatography–matrix-assisted laser desorption/ionization were performed on three subjects to facilitate a deeper look into the plasma peptidome. The data further support the importance of protease inhibitors in stabilizing plasma samples. Significantly, we have revealed subject-to-subject variability in the intrinsic damage over time that is possible in standard EDTA plasma, with such variations extensively minimized by protease inhibitors. We conclude that protease inhibitors can simultaneously improve time-dependent and individual-dependent preanalytical variables in human plasma samples.