Atomistic Insights into the Formation of Nonspecific Protein Complexes during Electrospray Ionization

Aliyari, Elnaz; Konermann, Lars

doi:10.1021/acs.analchem.1c02836

Cited by 6 publications

(8 citation statements)

References 100 publications

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“…Results from some molecular dynamics simulations indicate that peptides and proteins can be desorbed from charged droplets either as an extended chain or as intact, folded complexes. − Our results indicate that under conditions where ion desorption from the liquid–air interface occurs for Cs + , Rb + , K + , Na + , Li + , and Cu + , desorption of peptides and proteins does not occur consistent with a large negative solvation energy for these ions. Future work with emitters with even smaller tip diameters may shed additional light into ion formation mechanisms in electrospray ionization.…”

Section: Discussionmentioning

confidence: 80%

Lighting Up at High Potential: Effects of Voltage and Emitter Size in Nanoelectrospray Ionization

Jordan

Miller

Harper

et al. 2023

J. Am. Soc. Mass Spectrom.

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Effects of electrospray voltage on cluster size and abundance formed from aqueous CsI were investigated with emitter tip diameters between 260 ± 7 nm and 2.45 ± 0.30 μm. Cluster size increases with increasing voltage, increasing solution concentration and increasing emitter diameter consistent with formation of larger initial droplet sizes. For emitters with tip diameters above ∼1 μm, varying the voltage either up or down leads to reproducible voltage-dependent extents of cluster formation. In contrast, higher voltages with submicron diameter emitters can lead to only Cs+ and Cs(H2O)+ and no clusters. This change in ion formation reproducibly occurs at spray potentials >1.3 kV for 260 nm emitters and appears to be induced by a corona discharge and material build-up at the emitter tip. Under conditions where abundant Cs+ is observed and no clusters are formed, ions such as K+ and Cu1+ are also observed but ions with more negative solvation energies, such as Ba2+, are not. Similarly, ions from bradykinin and ubiquitin are observed predischarge but not post discharge. Ions with more positive solvation energies can desorb directly from the air–water interface that is created at the tip of these emitters, whereas ions with more negative solvation energies as well as peptide and protein ions do not. These results indicate that ion desorption directly from solution can occur, and similar experiments with even smaller emitters may lead to new insights into ion formation in electrospray ionization.

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Section: Discussionmentioning

confidence: 80%

Lighting Up at High Potential: Effects of Voltage and Emitter Size in Nanoelectrospray Ionization

Jordan

Miller

Harper

et al. 2023

J. Am. Soc. Mass Spectrom.

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“…However, on one hand, the release of nanodisc from the nano-droplet obtained from the MD simulation at high temperature is consistent with that at room temperature (300 K). On the other hand, in reported studies, MD simulations at high temperature produced the same m/z ratios as the mass spectrometry experiments 21 , 28 , 29 , and the force field for the liquid phase is suitable for modeling gaseous ions 56 . Therefore, the limitations of the methods used in this work may affect the accuracy of the predicted m/z ratio, but likely have little influence on the observed ESI process.…”

Section: Discussionmentioning

confidence: 92%

“…Therefore, theoretical approaches have been used to extract the relation between charge state and the mass/shape of the gaseous ions from the available mass spectrometry results 10 – 13 . Computational methods, especially molecular dynamics (MD) simulations 14 , 15 , have also been performed to investigate the charge-induced conformational transitions of proteins 16 – 18 and polymers 19 in vacuum, the relation of charge states versus nano-droplet morphologies 20 , and release of analyte ions, such as small ions 21 – 23 , peptides 24 , polymers 25 – 27 , global proteins 28 , and protein complexes 29 , from charged nano-droplets 30 . Here, we explored the spatio-temporal evolution of charged nano-droplets with empty (without protein) lipid nanodiscs at atomistic resolution using MD simulations.…”

Section: Introductionmentioning

confidence: 99%

Release of nanodiscs from charged nano-droplets in the electrospray ionization revealed by molecular dynamics simulations

Wang

Tieleman

2023

Commun Chem

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Electrospray ionization (ESI) is essential for application of mass spectrometry in biological systems, as it prevents the analyte being split into fragments. However, due to lack of a clear understanding of the mechanism of ESI, the interpretation of mass spectra is often ambiguous. This is a particular challenge for complex biological systems. Here, we focus on systems that include nanodiscs as membrane environment, which are essential for membrane proteins. We performed microsecond atomistic molecular dynamics simulations to study the release of nanodiscs from highly charged nano-droplets into the gas phase, the late stage of ESI. We observed two distinct major scenarios, highlighting the diversity of morphologies of gaseous product ions. Our simulations are in reasonable agreement with experimental results. Our work provides a detailed atomistic view of the ESI process of a heterogeneous system (lipid nanodisc), which may give insights into the interpretation of mass spectra of all lipid-protein systems.

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“…Therefore, theoretical approaches have been used to extract the relation between charge state and the mass/shape of the gaseous ions from the available mass spectrometry results [9][10][11][12] . Computational methods, especially molecular dynamics (MD) simulations [13][14] , have also been performed to investigate the charge-induced conformational transitions of proteins [15][16][17] and polymers 18 in vacuum, the relation of charge states versus nano-droplet morphologies 19 , and release of analyte ions, such as small ions [20][21][22] , peptides 23 , polymers [24][25][26] , global proteins 27 , and protein complexes 28 , from charged nanodroplets 29 . Here, we explored the spatio-temporal evolution of charged nano-droplets with empty (without protein) lipid nanodiscs at atomistic resolution using MD simulations.…”

Section: Introductionmentioning

confidence: 99%

Release of lipid nanodiscs from charged nano-droplets in the electrospray ionization process revealed by microsecond atomistic molecular dynamics simulations

Wang

Tieleman

2022

Preprint

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Electrospray ionization (ESI) prevents the analyte being split into fragments and is widely used to analyze biomolecules. Nanodiscs provide a native-like environment for membrane proteins, while making them accessible in aqueous solution for analysis. We performed microsecond molecular dynamics simulations at different temperatures, to provide atomistic insight in the release of intact nanodiscs from charged nano-droplets, the late stage of the ESI process. Two distinct main scenarios, at-center and off-center, were observed. The at-center scenario follows the charged residue model, and in the process the nanodisc stays well in the droplet interior, with the membrane scaffold protein (MSP) keeping its annular geometry. As solvent evaporates, lipids turn over to protect the hydrophilic surface. The off-center scenario conforms to a hybrid model of the charged residue model and chain ejection model. The nanodisc migrates to the water/air interface, leading to lipids escaping from the dissociated dimer and the partial ejection of one monomer of MSP. A diversity of morphologies of product gaseous ions was observed, as evidenced by their structural details, collision cross sections and moments of inertia. Our results are in reasonable agreement with results of mass spectrometry in mass-to-charge ratio, charge state and collision cross section. Our work displays the first atomistic view of a heterogeneous system, a lipid nanodisc, releasing from highly charged nano-droplets into the gas phase, which may provide structural supports for the interpretation of mass spectra of complicated systems. What we observe in our simulations could also be generalized to other protein-lipid systems.

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Atomistic Insights into the Formation of Nonspecific Protein Complexes during Electrospray Ionization

Cited by 6 publications

References 100 publications

Lighting Up at High Potential: Effects of Voltage and Emitter Size in Nanoelectrospray Ionization

Lighting Up at High Potential: Effects of Voltage and Emitter Size in Nanoelectrospray Ionization

Release of nanodiscs from charged nano-droplets in the electrospray ionization revealed by molecular dynamics simulations

Release of lipid nanodiscs from charged nano-droplets in the electrospray ionization process revealed by microsecond atomistic molecular dynamics simulations

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