Mostafa Zarei

Comparison of ERLIC–TiO2, HILIC–TiO2, and SCX–TiO2 for Global Phosphoproteomics Approaches

Reversible phosphorylations play a critical role in most biological pathways. Hence, in signaling studies great effort has been put into identification of a maximum number of phosphosites per experiment. Mass spectrometry (MS)-based phosphoproteomics approaches have been proven to be an ideal analytical method for mapping of phosphosites. However, because of sample complexity, fractionation of phosphopeptides prior to MS analysis is a crucial step. In the current study, we compare the chromatographic strategies electrostatic repulsion-hydrophilic interaction chromatography (ERLIC), hydrophilic interaction liquid chromatography (HILIC), and strong cation exchange chromatography (SCX) for their fractionation behavior of phosphopeptides. In addition, we investigate the use of repetitive TiO(2)-based enrichment steps for a maximum identification of phosphopeptides. On the basis of our results, SCX yields the highest number of identified phosphopeptides, whereas ERLIC is optimal for the identification of multiphosphorylated peptides. Consecutive incubations of fractions and flow-through by TiO(2) beads enrich qualitatively different sets of phosphopeptides, increasing the number of identified phosphopeptides per analysis.

Involvement of mitochondrial dynamics in the segregation of mitochondrial matrix proteins during stationary phase mitophagy

Mitophagy, the autophagic degradation of mitochondria, is an important housekeeping function in eukaryotic cells and defects in mitophagy correlate with ageing phenomena and with several neurodegenerative disorders. A central mechanistic question regarding mitophagy is whether mitochondria are consumed en masse, or whether an active process segregates defective molecules from functional ones within the mitochondrial network, thus allowing a more efficient culling mechanism. Here, we combine a proteomic study with a molecular genetic and cell biology approach to determine whether such a segregation process occurs in yeast mitochondria. We find that different mitochondrial matrix proteins undergo mitophagic degradation at distinctly different rates, supporting the active segregation hypothesis. These differential degradation rates depend on mitochondrial dynamics, suggesting a mechanism coupling weak physical segregation with mitochondrial dynamics to achieve a distillation-like effect. In agreement, the rates of mitophagic degradation strongly correlate with the degree of physical segregation of specific matrix proteins.

Combinatorial use of electrostatic repulsion-hydrophilic interaction chromatography (ERLIC) and strong cation exchange (SCX) chromatography for in-depth phosphoproteome analysis.

In large-scale phosphoproteomics studies, fractionation by strong cation exchange (SCX) or electrostatic repulsion-hydrophilic interaction chromatography (ERLIC) is commonly used to reduce sample complexity, fractionate phosphopeptides from their unmodified counterparts, and increase the dynamic range for phosphopeptide identification. However, these procedures do not succeed to separate, both singly and multiply phosphorylated peptides due to their inverse physicochemical characteristics. Hence, depending on the chosen method only one of the two peptide classes can be efficiently separated. Here, we present a novel strategy based on the combinatorial separation of singly and multiply phosphorylated peptides by SCX and ERLIC for in-depth phosphoproteome analysis. In SCX, mostly singly phosphorylated peptides are retained and fractionated while not-retained multiply phosphorylated peptides are fractionated in a subsequent ERLIC approach (SCX-ERLIC). In ERLIC, multiply phosphorylated peptides are fractionated, while not-retained singly phosphorylated peptides are separated by SCX (ERLIC-SCX). Compared to single step fractionations by SCX, the combinatorial strategies, SCX-ERLIC and ERLIC-SCX, yield up to 48% more phosphopeptide identifications as well as a strong increase in the number of detected multiphosphorylated peptides. Phosphopeptides identified in two subsequent, complementary fractionations had little overlap (5%) indicating that ERLIC and SCX are orthogonal methods ideally suited for in-depth phosphoproteome studies.

On-line nano-HPLC/ESI QTOF MS and tandem MS for separation, detection, and structural elucidation of human erythrocytes neutral glycosphingolipid mixture.

A superior approach involving nano-high-performance liquid chromatography (nano-HPLC) in on-line conjunction to electrospray ionization quadrupole time-of-flight mass spectrometry (ESI QTOF MS) and tandem MS for screening and structural characterization of complex mixtures of neutral glycosphingolipids (GSLs) is here described. Neutral GSLs purified from human erythrocytes were efficiently separated according to the differences in carbohydrate chain length by an optimized nano-HPLC protocol and flow-through detected by ESI QTOF MS at the low femtomole level. Additionally, GSL species were accurately distinguished from the accompanying lipids in the mixture, thus permitting the determination of detailed structural characteristics by data-dependent analysis for identification of GSL constitution within single experiments. An alternative nano-HPLC/ESI QTOF MS approach was designed for dissection of unsaturation/saturation degree of the ceramide moieties defining the hydrophobic portion of GSLs and subsequent localization by nano-HPLC/ESI QTOF MS/MS of the -CH=CH- within the ceramide regions. The method is fast, highly sensitive, and high-throughput amenable and is highlighted as a new and valuable analytical dimension in glycolipidomics.

Quantitative proteomics for the analysis of spatio-temporal protein dynamics during autophagy

Stress-induced autophagy leads to major cellular remodeling. During autophagy, a new organelle, the autophagosome, is formed that shuttles cellular material to lysosomes for degradation. Quantitative mass spectrometry-based proteomics is a powerful research strategy for the description of spatio-temporal protein dynamics during autophagy. This technique allows the identification of protein-protein interactions and of specific post-translational modifications. In addition, current methods enable the in-depth characterization of cellular as well as organellar composition changes and the global analysis of signaling networks. Thus, a plastic picture of the cell can be drawn. In this review we describe recent advances in MS-based proteomics approaches and their implications for autophagy-related research questions.

A sialylation study of mouse brain gangliosides by MALDI a-TOF and o-TOF mass spectrometry.

Matrix-assisted laser desorption/ionization (MALDI) process of sialoglycoconjugates is generally accompanied by different levels of cleavage of sialic acid residues and/or by dehydration, and decarboxylation reactions. Quantitative densitometry of the mouse brain ganglioside (MBG) components separated by high-performance thin layer chromatography (HPTLC) and evidenced by orcinol staining was a basis to verify the ganglioside composition pattern with respect to the relative abundances of individual components in the mixture. A systematic mass spectrometry (MS) sialylation analysis has been carried out to evaluate the feasibility of an axial time-of-flight (a-TOF) MS, equipped with a vacuum MALDI source and an orthogonal-TOF (o-TOF) instrument with an ion source operated at about 1 mbar of N(2). Besides, the esterification by one methyl group of the carboxyl group in sialic acid to increase the stability of the ganglioside species for MALDI MS analysis has been tested and the yield of intact ganglioside species and of the neutral loss of water and carbon dioxide estimated. For the sialylation analysis of native ganglioside mixtures the MALDI o-TOF analysis with 6-azo-2-thiothymine/diammonium citrate (ATT/DAC) as a matrix appears as an optimal approach for ganglioside profiling.

Rapid Combinatorial ERLIC–SCX Solid-Phase Extraction for In-Depth Phosphoproteome Analysis

Protein phosphorylation is an important mechanism of cellular signaling, and many proteins are precisely regulated through the interplay of stimulatory and inhibitory phosphorylation sites. Phosphoproteomics offers great opportunities to unravel this complex interplay, generating a mechanistic understanding of vital cellular processes. However, protein phosphorylation is substoichiometric and, in particular, peptides carrying multiple phosphorylation sites are extremely difficult to detect in a highly complex mixture of abundant nonphosphorylated peptides. Chromatographic methods are employed to reduce sample complexity and thereby significantly increase the number of phosphopeptide identifications. We previously demonstrated that combinatorial strong cation exchange-electrostatic repulsion-hydrophilic interaction chromatography yields a surplus in overall identifications of phosphopeptides compared with single chromatographic approaches. Here we present a simple and rapid strategy implemented as solid-phase extraction not requiring specific instrumentation such as off-line HPLC systems. It is inexpensive, adaptable for high and low amounts of starting material, and saves time by allowing multiplexed sample preparation without any carry-over problem.

Automated normal phase nano high performance liquid chromatography/matrix assisted laser desorption/ionization mass spectrometry for analysis of neutral and acidic glycosphingolipids

AbstractThe coupling of nano high-performance liquid chromatography (nanoHPLC) with matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS) via an automatic spotting roboter was developed and adapted for the first time for the analysis of complex mixtures of glycosphingolipids (GSLs). The 2,5-dihydroxybenzoic acid and 6-azo-2-thiothymine matrix systems were adjusted to concurrently meet the requirements for reproducible and homogeneous crystal formation with the liquid chromatography (LC) eluent under the variable LC solvent composition over the course gradient and high ionization efficiency of the GSL species, without the need for recrystallization. Precise adjustment of the automatic spotting parameters in terms of matrix flow rate, on-tip collection time of the matrix/LC eluent solution and the matrix spotting mode, i.e., continuous and discontinuous, was accomplished to collect individually nanoHPLC-separated species within distinct spots and consequently recover by MALDI MS screening all major and minor GSL species in the mixtures. The nanoHPLC/MALDI MS coupling protocol was developed and applied to a mixture of neutral GSLs purified from human erythrocytes and a monosialoganglioside mixture expressed by the murine MDAY-D2 cell line. Additionally, on-line nanoHPLC/MALDI doping with lithium cations of individually separated neutral GSLs was introduced to enhance data interpretation of the GSL MS pattern, while preserving the same level of information and ultimately to enhance structural assignment of components of interest. The method is demonstrated to be highly sensitive, reaching the low femtomole level of detection of individual GSL species and is highlighted as a versatile analytical tool for glycolipidomic studies. FigureAutomatic LC/MALDI MS profiling of glycosphingolipids

Fast and easy phosphopeptide fractionation by combinatorial ERLIC-SCX solid-phase extraction for in-depth phosphoproteome analysis

Mass spectrometry–based phosphoproteomic analysis is a powerful method for gaining a global, unbiased understanding of cellular signaling. Its accuracy and comprehensiveness stands or falls with the quality and choice of the applied phosphopeptide prefractionation strategy. This protocol covers a powerful but simple and rapid strategy for phosphopeptide prefractionation. The combinatorial use of two distinct chromatographic techniques that address the inverse physicochemical properties of peptides allows for superior fractionation efficiency of multiple phosphorylated peptides. In the first step, multiphosphorylated peptides are separated according to the number of negatively charged phosphosites by electrostatic repulsion-hydrophilic interaction chromatography (ERLIC). A subsequent strong cation exchange (SCX) step separates mostly singly phosphorylated peptides in the ERLIC flow-through according to their positive charge. The presented strategy is inexpensive and adaptable to large and small amounts of starting material, and it allows highly multiplexed sample preparation. Because of its implementation as solid-phase extraction, the entire workflow takes only 2 h to complete.

Hydrophobic Interaction Chromatography for Bottom-Up Proteomics Analysis of Single Proteins and Protein Complexes

Hydrophobic interaction chromatography (HIC) is a robust standard analytical method to purify proteins while preserving their biological activity. It is widely used to study post-translational modifications of proteins and drug-protein interactions. In the current manuscript we employed HIC to separate proteins, followed by bottom-up LC-MS/MS experiments. We used this approach to fractionate antibody species followed by comprehensive peptide mapping as well as to study protein complexes in human cells. HIC-reversed-phase chromatography (RPC)-mass spectrometry (MS) is a powerful alternative to fractionate proteins for bottom-up proteomics experiments making use of their distinct hydrophobic properties.