Your search keyword '"Melani RD"' showing total 7 results

1. Targeted Quantification of Proteoforms in Complex Samples by Proteoform Reaction Monitoring.

Author

Huang CF, Kline JT, Negrão F, Robey MT, Toby TK, Durbin KR, Fellers RT, Friedewald JJ, Levitsky J, Abecassis MMI, Melani RD, Kelleher NL, and Fornelli L

Subjects

Humans, Reproducibility of Results, Mass Spectrometry, Proteomics methods, Protein Processing, Post-Translational, Proteome analysis, Leukocytes, Mononuclear chemistry, Proteins

Abstract

Existing mass spectrometric assays used for sensitive and specific measurements of target proteins across multiple samples, such as selected/multiple reaction monitoring (SRM/MRM) or parallel reaction monitoring (PRM), are peptide-based methods for bottom-up proteomics. Here, we describe an approach based on the principle of PRM for the measurement of intact proteoforms by targeted top-down proteomics, termed proteoform reaction monitoring (PfRM). We explore the ability of our method to circumvent traditional limitations of top-down proteomics, such as sensitivity and reproducibility. We also introduce a new software program, Proteoform Finder (part of ProSight Native), specifically designed for the easy analysis of PfRM data. PfRM was initially benchmarked by quantifying three standard proteins. The linearity of the assay was shown over almost 3 orders of magnitude in the femtomole range, with limits of detection and quantification in the low femtomolar range. We later applied our multiplexed PfRM assay to complex samples to quantify biomarker candidates in peripheral blood mononuclear cells (PBMCs) from liver-transplanted patients, suggesting their possible translational applications. These results demonstrate that PfRM has the potential to contribute to the accurate quantification of protein biomarkers for diagnostic purposes and to improve our understanding of disease etiology at the proteoform level.

Published

2024

2. Isotopic Resolution of Protein Complexes up to 466 kDa Using Individual Ion Mass Spectrometry.

Author

McGee JP, Melani RD, Yip PF, Senko MW, Compton PD, Kafader JO, and Kelleher NL

Subjects

Ions, Mass Spectrometry, Protein Processing, Post-Translational, Proteins

Abstract

Native mass spectrometry involves transferring large biomolecular complexes into the gas phase, enabling the characterization of their composition and stoichiometry. However, the overlap in distributions created by residual solvation, ionic adducts, and post-translational modifications creates a high degree of complexity that typically goes unresolved at masses above ∼150 kDa. Therefore, native mass spectrometry would greatly benefit from higher resolution approaches for intact proteins and their complexes. By recording mass spectra of individual ions via charge detection mass spectrometry, we report isotopic resolution for pyruvate kinase (232 kDa) and β-galactosidase (466 kDa), extending the limits of isotopic resolution for high mass and high m / z by >2.5-fold and >1.6-fold, respectively.

Published

2021

3. Multiplexed mass spectrometry of individual ions improves measurement of proteoforms and their complexes.

Author

Kafader JO, Melani RD, Durbin KR, Ikwuagwu B, Early BP, Fellers RT, Beu SC, Zabrouskov V, Makarov AA, Maze JT, Shinholt DL, Yip PF, Tullman-Ercek D, Senko MW, Compton PD, and Kelleher NL

Subjects

Humans, Mass Spectrometry methods, Proteins chemistry, Proteomics methods

Abstract

An Orbitrap-based ion analysis procedure determines the direct charge for numerous individual protein ions to generate true mass spectra. This individual ion mass spectrometry (I 2 MS) method for charge detection enables the characterization of highly complicated mixtures of proteoforms and their complexes in both denatured and native modes of operation, revealing information not obtainable by typical measurements of ensembles of ions.

Published

2020

4. Native vs Denatured: An in Depth Investigation of Charge State and Isotope Distributions.

Author

Kafader JO, Melani RD, Schachner LF, Ives AN, Patrie SM, Kelleher NL, and Compton PD

Subjects

Animals, Humans, Ions chemistry, Protein Denaturation, Spectrometry, Mass, Electrospray Ionization, Static Electricity, Proteins chemistry

Abstract

New tools and techniques have dramatically accelerated the field of structural biology over the past several decades. One potent and relatively new technique that is now being utilized by an increasing number of laboratories is the combination of so-called "native" electrospray ionization (ESI) with mass spectrometry (MS) for the characterization of proteins and their noncovalent complexes. However, native ESI-MS produces species at increasingly higher m / z with increasing molecular weight, leading to substantial differences when compared to traditional mass spectrometric approaches using denaturing ESI solutions. Herein, these differences are explored both theoretically and experimentally to understand the role that charge state and isotopic distributions have on signal-to-noise (S/N) as a function of complex molecular weight and how the reduced collisional cross sections of proteins electrosprayed under native solution conditions can lead to improved data quality in image current mass analyzers, such as Orbitrap and FT-ICR. Quantifying ion signal differences under native and denatured conditions revealed enhanced S/N and a more gradual decay in S/N with increasing mass under native conditions. Charge state and isotopic S/N models, supported by experimental results, indicate that analysis of proteins under native conditions at 100 kDa will be 17 times more sensitive than analysis under denatured conditions at the same mass. Higher masses produce even larger sensitivity gains. Furthermore, reduced cross sections under native conditions lead to lower levels of ion decay within an Orbitrap scan event over long transient acquisition times, enabling isotopic resolution of species with molecular weights well in excess of those typically resolved under denatured conditions.

Published

2020

5. Voltage Rollercoaster Filtering of Low-Mass Contaminants During Native Protein Analysis.

Author

McGee JP, Melani RD, Goodwin M, McAlister G, Huguet R, Senko MW, Compton PD, and Kelleher NL

Subjects

Animals, Antibodies, Monoclonal chemistry, Equipment Design, Humans, Mass Spectrometry instrumentation, Pyruvate Kinase chemistry, Filtration instrumentation, Polyethylene Glycols isolation & purification, Proteins chemistry

Abstract

Intact protein mass spectrometry (MS) via electrospray-based methods is often degraded by low-mass contaminants, which can suppress the spectral quality of the analyte of interest via space-charge effects. Consequently, selective removal of contaminants by their mobilities would benefit native MS if achieved without additional hardware and before the mass analyzer regions used for selection, analyte readout, or tandem MS. Here, we use the high-pressure multipole within the source of an Orbitrap Tribrid as the foundation for a coarse ion filter. Using this method, we show complete filtration of 2 mM polyethylene glycol (PEG-1000) during native MS of SILu mAb antibody present at a 200× lower concentration. We also show the generality of the process by rescuing 10 μM tetrameric pyruvate kinase from 2 mM PEG-1000, asserting this voltage rollercoaster filtering (VRF) method for use in native MS as an efficient alternative to conventional purification methods.

Published

2020

6. Standard Proteoforms and Their Complexes for Native Mass Spectrometry.

Author

Schachner LF, Ives AN, McGee JP, Melani RD, Kafader JO, Compton PD, Patrie SM, and Kelleher NL

Subjects

Alcohol Dehydrogenase chemistry, Animals, Carbonic Anhydrases chemistry, Cattle, Models, Molecular, Pyruvate Kinase chemistry, Rabbits, Reproducibility of Results, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, Mass Spectrometry methods, Protein Multimerization, Proteins chemistry

Abstract

Native mass spectrometry (nMS) is a technique growing at the interface of analytical chemistry, structural biology, and proteomics that enables the detection and partial characterization of non-covalent protein assemblies. Currently, the standardization and dissemination of nMS is hampered by technical challenges associated with instrument operation, benchmarking, and optimization over time. Here, we provide a standard operating procedure for acquiring high-quality native mass spectra of 30-300 kDa proteins using an Orbitrap mass spectrometer. By describing reproducible sample preparation, loading, ionization, and nMS analysis, we forward two proteoforms and three complexes as possible standards to advance training and longitudinal assessment of instrument performance. Spectral data for five standards can guide assessment of instrument parameters, data production, and data analysis. By introducing this set of standards and protocols, we aim to help normalize native mass spectrometry practices across labs and provide benchmarks for reproducibility and high-quality data production in the years ahead. Graphical abstract.

Published

2019

7. Measurement of Individual Ions Sharply Increases the Resolution of Orbitrap Mass Spectra of Proteins.

Author

Kafader JO, Melani RD, Senko MW, Makarov AA, Kelleher NL, and Compton PD

Subjects

Animals, Carbonic Anhydrases analysis, Fourier Analysis, Humans, Ions analysis, Myoglobin analysis, Phosphopyruvate Hydratase analysis, Transferrin analysis, Ubiquitin analysis, Mass Spectrometry methods, Proteins analysis

Abstract

It is well-known that with Orbitrap-based Fourier-transform-mass-spectrometry (FT-MS) analysis, longer-time-domain signals are needed to better resolve species of interest. Unfortunately, increasing the signal-acquisition period comes at the expense of increasing ion decay, which lowers signal-to-noise ratios and ultimately limits resolution. This is especially problematic for intact proteins, including antibodies, which demonstrate rapid decay because of their larger collisional cross-sections, and result in more frequent collisions with background gas molecules. Provided here is a method that utilizes numerous low-ion-count spectra and single-ion processing to reconstruct a conventional m/ z spectrum. This technique has been applied to proteins varying in molecular weight from 8 to 150 kDa, with a resolving power of 677 000 achieved for transients of carbonic anhydrase (29 kDa) with a duration of only ∼250 ms. A resolution improvement ranging from 10- to 20-fold was observed for all proteins, providing isotopic resolution where none was previously present.

Published

2019