The ability of concentrated
formic acid to formylate reactive amino
acid residues is known from previous reports. In contrast, solvents
containing a low concentration of formic acid are generally recognized
as a safe environment for proteomic applications. The primary objective
of this study was to explain the excessive formylation rate in tryptic
peptides that did not come into contact with concentrated formic acid.
We found out that the peptide formylation was associated with dissolving
the peptides in a solvent containing mere 0.1% formic acid. Similar
conclusions were drawn after analyzing publicly available proteomic
data. We further demonstrated that these unwanted modifications can
be averted via handling the samples at a low temperature or, obviously,
via replacing formic acid in the solvent with trifluoroacetic acid.
These simple countermeasures can contribute to a reduction in the
part of the MS/MS spectra that remain unassigned to a peptide sequence.
Elevated
column temperature represents a simple means for improving
chromatographic separation of peptides. Here, we demonstrated the
advantages of the column temperature in peptide separation using state-of-the-art
columns. More importantly, we also determined how temperature can
impair proteomic bottom-up analyses. We found that an elevated temperature
in combination with the acidic pH of the mobile phase induced in-column
peptide hydrolysis with high specificity to Asp and accelerated five
modification reactions of amino acids. The positive effects of temperature
dominated in the 30 min long gradients since the column operated at
90 °C provided the largest number of identified peptides and
proteins. However, the adverse effects of temperature on peptide integrity
in longer liquid chromatography–mass spectrometry (LC–MS)
analyses required its reduction to obtain optimum results. The largest
number of peptides was identified using the column maintained at 75
°C in 60 min long gradients, at 60 °C in 120 min long gradients,
and at 45 °C in 240 min long gradients. Our results indicate
that no universal column temperature exists for bottom-up LC–MS
analyses. Quite the contrary, the temperature setting must be selected
rationally to exploit the full capabilities of the state-of-the-art
mass spectrometers in proteomic LC–MS analyses, with the gradient
time being a critical factor.
Matrix-assisted laser desorption/ionization coupled with Orbitrap mass spectrometry (MALDI-Orbitrap-MS) is used for the clinical study of patients with renal cell carcinoma (RCC), as the most common type of kidney cancer. Significant changes in sulfoglycosphingolipid abundances between tumor and autologous normal kidney tissues are observed. First, sulfoglycosphingolipid species in studied RCC samples are identified using high mass accuracy full scan and tandem mass spectra. Subsequently, optimization, method validation, and statistical evaluation of MALDI-MS data for 158 tissues of 80 patients are discussed. More than 120 sulfoglycosphingolipids containing one to five hexosyl units are identified in human RCC samples based on the systematic study of their fragmentation behavior. Many of them are recorded here for the first time. Multivariate data analysis (MDA) methods, i.e., unsupervised principal component analysis (PCA) and supervised orthogonal partial least square discriminant analysis (OPLS-DA), are used for the visualization of differences between normal and tumor samples to reveal the most up- and downregulated lipids in tumor tissues. Obtained results are closely correlated with MALDI mass spectrometry imaging (MSI) and histologic staining. Important steps of the present MALDI-Orbitrap-MS approach are also discussed, such as the selection of best matrix, correct normalization, validation for semiquantitative study, and problems with possible isobaric interferences on closed masses in full scan mass spectra. Graphical Abstract ᅟ.
The performance of the current bottom-up liquid chromatography hyphenated with mass spectrometry (LC-MS) analyses has undoubtedly been fueled by spectacular progress in mass spectrometry. It is thus not surprising that the MS instrument attracts the most attention during LC-MS method development, whereas optimizing conditions for peptide separation using reversed-phase liquid chromatography (RPLC) remains somewhat in its shadow. Consequently, the wisdom of the fundaments of chromatography is slowly vanishing from some laboratories. However, the full potential of advanced MS instruments cannot be achieved without highly efficient RPLC. This is impossible to attain without understanding fundamental processes in the chromatographic system and the properties of peptides important for their chromatographic behavior. We wrote this tutorial intending to give practitioners an overview of critical aspects of peptide separation using RPLC to facilitate setting the LC parameters so that they can leverage the full capabilities of their MS instruments. After briefly introducing the gradient separation of peptides, we discuss their properties that affect the quality of LC-MS chromatograms the most. Next, we address the in-column and extra-column broadening. The last section is devoted to key parameters of LC-MS methods. We also extracted trends in practice from recent bottom-up proteomics studies and correlated them with the current knowledge on peptide RPLC separation.
Negative-ion hydrophilic liquid chromatography-electrospray ionization mass spectrometry (HILIC/ESI-MS) method has been optimized for the quantitative analysis of ganglioside (GM3) and other polar lipid classes, such as sulfohexosylceramides (SulfoHexCer), sulfodihexosylceramides (SulfoHex2Cer), phosphatidylglycerols (PG), phosphatidylinositols (PI), lysophosphatidylinositols (LPI), and phosphatidylserines (PS). The method is fully validated for the quantitation of the studied lipids in kidney normal and tumor tissues of renal cell carcinoma (RCC) patients based on the lipid class separation and the coelution of lipid class internal standard with the species from the same lipid class. The raw data are semi-automatically processed using our software LipidQuant and statistically evaluated using multivariate data analysis (MDA) methods, which allows the complete differentiation of both groups with 100% specificity and sensitivity. In total, 21 GM3, 28 SulfoHexCer, 26 SulfoHex2Cer, 10 PG, 19 PI, 4 LPI, and 7 PS are determined in the aqueous phase of lipidomic extracts from kidney tumor tissue samples and surrounding normal tissue samples of 20 RCC patients. S-plots allow the identification of most upregulated (PI 40:5, PI 40:4, GM3 34:1, and GM3 42:2) and most downregulated (PI 32:0, PI 34:0, PS 36:4, and LPI 16:0) lipids, which are primarily responsible for the differentiation of tumor and normal groups. Another confirmation of most dysregulated lipids is performed by the calculation of fold changes together with T and p values to highlight their statistical significance. The comparison of HILIC/ESI-MS data and matrix-assisted laser desorption/ionization mass spectrometric imaging (MALDI-MSI) data confirms that lipid dysregulation patterns are similar for both methods. Graphical abstract ᅟ.
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