Your search keyword '"Fenaille F"' showing total 6 results

1. Energy Resolved Mass Spectrometry for Interoperable Non-resonant Collisional Spectra in Metabolomics.

Author

Hueber A, Kulyk H, Damont A, Nicol E, Alves S, Liuu S, Green M, Bertrand-Michel J, Cenac N, Fenaille F, and Tabet JC

Subjects

Amino Acids analysis, Amino Acids chemistry, Amino Acids metabolism, Metabolomics methods, Mass Spectrometry methods

Abstract

In untargeted metabolomics, the unambiguous identification of metabolites remains a major challenge. This requires high-quality spectral libraries for reliable metabolite identification, which is essential for translating metabolomics data into meaningful biological information. Several attempts have been made to generate reproducible product ion spectra (PIS) under a low collision energy ( E Lab ) regime and nonresonant collisional conditions but have not fully succeeded. We examined the ERMS (energy-resolved mass spectrometry) breakdown curves of two lipo-amino acids and showed the possibility to highlight "singular points", called descriptors hereafter (linked to respective E Lab depending on the instrument), for each of the monomodal product ion profiles. Using several instruments based on different technologies, the PIS recorded at these specific E Lab sites shows remarkable similarities. The descriptors appeared as being independent of the fragmentation mechanisms and can be used to overcome the main instrumental effects that limit the interoperability of spectral libraries. This proof-of-concept study, performed on two particular lipo-amino acids, demonstrates the high potential of ERMS-derived information to determine the instrument-specific E Lab at which PIS recorded in nonresonant conditions become highly similar and instrument-independent, thus comparable across platforms. This innovative but straightforward approach could help remove some of the obstacles to metabolite identification in nontargeted metabolomics, putting an end to a challenging chimera.

Published

2024

2. Impact of Source Conditions on Collision Cross Section Determination by Trapped Ion Mobility Spectrometry.

Author

George AC, Schmitz I, Colsch B, Afonso C, Fenaille F, and Loutelier-Bourhis C

Abstract

Collision cross section (CCS) values determined in ion mobility-mass spectrometry (IM-MS) are increasingly employed as additional descriptors in metabolomics studies. CCS values must therefore be reproducible and the causes of deviations must be carefully known and controlled. Here, we analyzed lipid standards by trapped ion mobility spectrometry-mass spectrometry (TIMS-MS) to evaluate the effects of solvent and flow rate in flow injection analysis (FIA), as well as electrospray source parameters including nebulizer gas pressure, drying gas flow rate, and temperature, on the ion mobility and CCS values. The stability of ion mobility experiments was studied over 10 h, which established the need for a delay-time of 20 min to stabilize source parameters (mostly pressure and temperature). Modifications of electrospray source parameters induced shifts of ion mobility peaks and even the occurrence of an additional peak in the ion mobility spectra. This behavior could be essentially explained by ion-solvent cluster formation. Changes in source parameters were also found to impact CCS value measurements, resulting in deviations up to 0.8%. However, internal calibration with the Tune Mix calibrant reduced the CCS deviations to 0.1%. Thus, optimization of source parameters is essential to achieve a good desolvation of lipid ions and avoid misinterpretation of peaks in ion mobility spectra due to solvent effects. This work highlights the importance of internal calibration to ensure interoperable CCS values, usable in metabolomics annotation.

Published

2024

3. Combining Chemical Knowledge and Quantum Calculation for Interpreting Low-Energy Product Ion Spectra of Metabolite Adduct Ions: Sodiated Diterpene Diester Species as a Case Study.

Author

Tabet JC, Gimbert Y, Damont A, Touboul D, Fenaille F, and Woods AS

Subjects

Metabolomics, Diterpenes analysis, Diterpenes chemistry, Sodium chemistry, Tandem Mass Spectrometry methods

Abstract

We investigated the product ion spectra of [M + Na] + from diterpene diester species and low molecular mass metabolites analyzed by electrospray ionization (ESI). Mainly, the formation of protonated salt structures was proposed to explain the observed neutral losses of carboxylic acids. It also facilitates understanding sodium retention on product ions or on neutral losses. In addition, the occurrence of consecutive carboxylic acid losses is rather unexpected under resonant excitation conditions. Quantum calculation demonstrated that the exothermic character of such neutral losses can represent a relevant explanation. There is no doubt that the formation and role of the protonated salt structures will be helpful for a better understanding and software-assisted interpretation of tandem mass spectra from small molecules, especially in the ever-growing metabolomics field.

Published

2021

4. First Direct Evidence of Interpartner Hydride/Deuteride Exchanges for Stored Sodiated Arginine/Fructose-6-phosphate Complex Anions within Salt-Solvated Structures.

Author

Darii E, Gimbert Y, Alves S, Damont A, Perret A, Woods AS, Fenaille F, and Tabet JC

Abstract

Mass spectrometric investigations of noncovalent binding between low molecular weight compounds revealed the existence of gas-phase (GP) noncovalent complex (NCC) ions involving zwitterionic structures. ESI MS is used to prove the formation of stable sodiated NCC anions between fructose (F6P) and arginine (R) moieties. Theoretical calculations indicate a folded solvated salt (i.e., sodiated carboxylate interacting with phosphate) rather than a charge-solvated form. Under standard CID conditions, [(F6P+R-H+Na)-H] - competitively forms two major product ions (PIs) through partner splitting [(R-H+Na) loss] and charge-induced cross-ring cleavage while preserving the noncovalent interactions (noncovalent product ions (NCPIs)). MS/MS experiments combined with in-solution proton/deuteron exchanges (HDXs) demonstrated an unexpected labeling of PIs, i.e., a correlated D-enrichment/D-depletion. An increase in activation time up to 3000 ms favors such processes when limited to two H/D exchanges. These results are rationalized by interpartner hydride/deuteride exchanges (⟨HDX⟩) through stepwise isomerization/dissociation of sodiated NCC-d11 anions. In addition, the D-enrichment/D-depletion discrepancy is further explained by back HDX with residual water in LTQ (selective for the isotopologue NCPIs as shown by PI relaxation experiments). Each isotopologue leads to only one back HDX unlike multiple HDXs generally observed in GP. This behavior shows that NCPIs are zwitterions with charges solvated by a single water molecule, thus generating a back HDX through a relay mechanism, which quenches the charges and prevents further back HDX. By estimating back HDX impact on D-depletion, the interpartner ⟨HDX⟩ complementarity was thus illustrated. This is the first description of interpartner ⟨HDX⟩ and selective back HDX validating salt-solvated structures.

Published

2021

5. Development of a Mass Spectrometry Imaging Method for Detecting and Mapping Graphene Oxide Nanoparticles in Rodent Tissues.

Author

Cazier H, Malgorn C, Fresneau N, Georgin D, Sallustrau A, Chollet C, Tabet JC, Campidelli S, Pinault M, Mayne M, Taran F, Dive V, Junot C, Fenaille F, and Colsch B

Subjects

Animals, Female, Graphite administration & dosage, Mice, Mice, Inbred BALB C, Graphite analysis, Liver chemistry, Lung chemistry, Nanoparticles analysis, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods

Abstract

Graphene-based nanoparticles are continuously being developed for biomedical applications, and their use raises concerns about their environmental and biological impact. In the literature, some imaging techniques based on fluorescence and radioimaging have been used to explore their fate in vivo . Here, we report on the use of label-free mass spectrometry and mass spectrometry imaging (MSI) for graphene oxide (GO) and reduced graphene oxide (rGO) analyses in rodent tissues. Thereby, we extend previous work by focusing on practical questions to obtain reliable and meaningful images. Specific radical anionic carbon clusters ranging from C 2 -• to C 9 -• were observed for both GO and rGO species, with a base peak at m / z 72 under negative laser desorption ionization mass spectrometry (LDI-MS) conditions. Extension to an LDI-MSI method was then performed, thus enabling the efficient detection of GO nanoparticles in lung tissue sections of previously exposed mice. The possibility of quantifying those nanoparticles on tissue sections has also been investigated. Two different ways of building calibration curves (i.e., GO suspensions spotted on tissue sections, or added to lung tissue homogenates) were evaluated and returned similar results, with linear dynamic concentration ranges over at least 2 orders of magnitude. Moreover, intra- and inter-day precision studies have been assessed, with relative standard deviation below 25% for each concentration point of a calibration curve. In conclusion, our study confirms that LDI-MSI is a relevant approach for biodistribution studies of carbon-based nanoparticles, as quantification can be achieved, provided that nanoparticle suspension and manufacturing are carefully controlled.

Published

2020

6. Study of protein modification by 4-hydroxy-2-nonenal and other short chain aldehydes analyzed by electrospray ionization tandem mass spectrometry.

Author

Fenaille F, Guy PA, and Tabet JC

Subjects

Amino Acid Sequence, Insulin chemistry, Insulin metabolism, Lipid Peroxidation, Models, Chemical, Molecular Sequence Data, Molecular Structure, Oxidation-Reduction, Protein Processing, Post-Translational, Spectrometry, Mass, Electrospray Ionization, Aldehydes chemistry, Proteins chemistry, Proteins metabolism

Abstract

A convenient way to study lipid oxidation products-modified proteins by means of suitable model systems has been investigated. As a model peptide, the oxidized B chain of insulin has been chemically modified by either 4-hydroxy-2-nonenal (HNE) or hexanal and the extent, sites, and structure of modifications were assessed by electrospray mass spectrometry. A reduction step, using either NaCNBH(3) or NaBH(4), was also studied to stabilize the alkylated compounds. From the data gathered, it appeared that NaCNBH(3), when added at the beginning of incubation, dramatically influenced the HNE-induced modifications in terms of the addition mechanism (Schiff base formation instead of Michael addition) but also of the amino acid residues modified (N-terminal amino acid instead of histidine residues). However, by reducing the HNE-adducted species at the end of the reaction with NaBH(4), the fragment ions obtained in the product ion scan experiments become more stable and thus, easier to interpret in terms of origin and mechanism involved. With regard to hexanal induced modifications, we have observed that hexanal addition under reductive conditions led to an extensive modification of the peptide backbone. Moreover, as confirmed by "in-source" collision followed by collision induced dissociation (CID) experiments on selected precursor ions (pseudo-MS(3) experiments), N,N-di-alkylations were first observed on the N-terminal residue and further on Lys(29) residue. On the other hand, compared to the native peptide, no significant changes in MS/MS fragmentation patterns (b and y ions series) were observed whatever the basic site modified by the aldehyde-addition.

Published

2003