scholarly journals Surface-Induced Dissociation of Anionic vs Cationic Native-like Protein Complexes

2021 ◽  
Author(s):  
Sophie Harvey ◽  
Zachary VanAernum ◽  
Vicki Wysocki
Keyword(s):  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Charge Reduction ◽  
Surface Induced Dissociation ◽  
Negative Mode ◽  
Peak Broadening ◽  
Lower Charge ◽  
Positive Mode ◽  
Charge States

<p>Characterizing protein-protein interactions, stoichiometries, and subunit connectivity is key to understanding how subunits assemble in biologically relevant multi-subunit protein complexes. Native mass spectrometry (nMS) has emerged as a powerful tool to study protein complexes due to its low sample requirements and tolerance for heterogeneity. For such nMS studies, positive mode ionization is routinely used and charge reduction, through the addition of solution additives, is often used, as the resulting lower charge states are often more compact and considered more native like. When studied with surface-induced dissociation, charge reduced complexes often give increased structural information over their “normal-charged” counter parts. A disadvantage of charge-reduction is that increased adduction, and hence peak broadening, is often observed when charge-reducing solution additives are present. Recent studies have shown that protein complexes ionized using negative mode generally form in lower charge states relative to positive mode. Here we demonstrate that the lower charged protein complex anions, activated by SID in an ultrahigh mass range Orbitrap mass spectrometer, fragment in a manner consistent with their solved structure, hence providing substructural information. Negative mode ionization in ammonium acetate offers the advantage of charge reduction without the peak broadening associated with solution phase charge reduction additives and provides direct structural information, when coupled with SID. </p>

scholarly journals Surface-Induced Dissociation of Anionic vs Cationic Native-like Protein Complexes

2021 ◽  
Author(s):  
Sophie Harvey ◽  
Zachary VanAernum ◽  
Vicki Wysocki
Keyword(s):  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Charge Reduction ◽  
Surface Induced Dissociation ◽  
Negative Mode ◽  
Peak Broadening ◽  
Lower Charge ◽  
Positive Mode ◽  
Charge States

<p>Characterizing protein-protein interactions, stoichiometries, and subunit connectivity is key to understanding how subunits assemble in biologically relevant multi-subunit protein complexes. Native mass spectrometry (nMS) has emerged as a powerful tool to study protein complexes due to its low sample requirements and tolerance for heterogeneity. For such nMS studies, positive mode ionization is routinely used and charge reduction, through the addition of solution additives, is often used, as the resulting lower charge states are often more compact and considered more native like. When studied with surface-induced dissociation, charge reduced complexes often give increased structural information over their “normal-charged” counter parts. A disadvantage of charge-reduction is that increased adduction, and hence peak broadening, is often observed when charge-reducing solution additives are present. Recent studies have shown that protein complexes ionized using negative mode generally form in lower charge states relative to positive mode. Here we demonstrate that the lower charged protein complex anions, activated by SID in an ultrahigh mass range Orbitrap mass spectrometer, fragment in a manner consistent with their solved structure, hence providing substructural information. Negative mode ionization in ammonium acetate offers the advantage of charge reduction without the peak broadening associated with solution phase charge reduction additives and provides direct structural information, when coupled with SID. </p>

scholarly journals Surface-Induced Dissociation of Anionic vs Cationic Native-like Protein Complexes

2021 ◽  
Author(s):  
Sophie Harvey ◽  
Zachary VanAernum ◽  
Vicki Wysocki
Keyword(s):  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Charge Reduction ◽  
Surface Induced Dissociation ◽  
Negative Mode ◽  
Peak Broadening ◽  
Lower Charge ◽  
Positive Mode ◽  
Charge States

<p>Characterizing protein-protein interactions, stoichiometries, and subunit connectivity is key to understanding how subunits assemble in biologically relevant multi-subunit protein complexes. Native mass spectrometry (nMS) has emerged as a powerful tool to study protein complexes due to its low sample requirements and tolerance for heterogeneity. For such nMS studies, positive mode ionization is routinely used and charge reduction, through the addition of solution additives, is often used, as the resulting lower charge states are often more compact and considered more native like. When studied with surface-induced dissociation, charge reduced complexes often give increased structural information over their “normal-charged” counter parts. A disadvantage of charge-reduction is that increased adduction, and hence peak broadening, is often observed when charge-reducing solution additives are present. Recent studies have shown that protein complexes ionized using negative mode generally form in lower charge states relative to positive mode. Here we demonstrate that the lower charged protein complex anions, activated by SID in an ultrahigh mass range Orbitrap mass spectrometer, fragment in a manner consistent with their solved structure, hence providing substructural information. Negative mode ionization in ammonium acetate offers the advantage of charge reduction without the peak broadening associated with solution phase charge reduction additives and provides direct structural information, when coupled with SID. </p>

Protein Interaction Domains and Post-Translational Modifications: Structural Features and Drug Discovery Applications

2020 ◽  
Vol 27 (37) ◽  
pp. 6306-6355 ◽  
Author(s):  
Marian Vincenzi ◽  
Flavia Anna Mercurio ◽  
Marilisa Leone
Keyword(s):  
Drug Discovery ◽  
Protein Interaction ◽  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Structural Features ◽  
Protein Protein Interactions ◽  
Modular Architecture ◽  
Post Translational Modifications ◽  
Interaction Domains

Background:: Many pathways regarding healthy cells and/or linked to diseases onset and progression depend on large assemblies including multi-protein complexes. Protein-protein interactions may occur through a vast array of modules known as protein interaction domains (PIDs). Objective:: This review concerns with PIDs recognizing post-translationally modified peptide sequences and intends to provide the scientific community with state of art knowledge on their 3D structures, binding topologies and potential applications in the drug discovery field. Method:: Several databases, such as the Pfam (Protein family), the SMART (Simple Modular Architecture Research Tool) and the PDB (Protein Data Bank), were searched to look for different domain families and gain structural information on protein complexes in which particular PIDs are involved. Recent literature on PIDs and related drug discovery campaigns was retrieved through Pubmed and analyzed. Results and Conclusion:: PIDs are rather versatile as concerning their binding preferences. Many of them recognize specifically only determined amino acid stretches with post-translational modifications, a few others are able to interact with several post-translationally modified sequences or with unmodified ones. Many PIDs can be linked to different diseases including cancer. The tremendous amount of available structural data led to the structure-based design of several molecules targeting protein-protein interactions mediated by PIDs, including peptides, peptidomimetics and small compounds. More studies are needed to fully role out, among different families, PIDs that can be considered reliable therapeutic targets, however, attacking PIDs rather than catalytic domains of a particular protein may represent a route to obtain selective inhibitors.

Oxidation products of alpha-pinene and their electrical mobilities

2020 ◽  
Author(s):  
Aurora Skyttä ◽  
Lauri Ahonen ◽  
Runlong Cai ◽  
Juha Kangasluoma
Keyword(s):  
Gas Flow ◽  
Structural Information ◽  
Uv Light ◽  
Protein Complexes ◽  
Measurement Techniques ◽  
Oxidation Products ◽  
Electrical Mobility ◽  
Mobility Spectrum ◽  
Negative Mode ◽  
Alpha Pinene

&lt;p&gt;OXIDATION PRODUCTS OF ALPHA-PINENE AND THEIR ELECTRICAL MOBILITIES&lt;br&gt;A. SKYTT&amp;#196; 1 , L. AHONEN 1 , R. CAI 1 and J. KANGASLUOMA 1&lt;br&gt;1 Institute for Atmospheric and Earth System Research/Physics, Faculty of Science, University of&lt;br&gt;Helsinki, Helsinki, 00140, Finland&lt;/p&gt;&lt;p&gt;&amp;#945;-pinene C10H16 is a monoterpene emitted by vegetation and its low volatile oxidation products are important source for secondary organic aerosols (SOA) in the atmosphere (Ehn et al., 2014). Because of the significant amount of &amp;#945;-pinene in the atmosphere, we investigated the oxidation&lt;br&gt;products of &amp;#945;-pinene.&lt;/p&gt;&lt;p&gt;In our setup we used parallel plate DMA (SEADM; (de la Mora et al., 2006)) at mobility resolution of about 80 coupled with APITOF-MS (Tofwerk AG; (Junninen et al., 2010)) and a flow tube system. A DMA can be used to measure the electrical mobility of the molecule or cluster and mass&lt;br&gt;spectrometer to measure the mass of those clusters. Based on the mass the chemical composition of the cluster can be determined.&lt;/p&gt;&lt;p&gt;&lt;br&gt;The electrospray solution is sprayed through a thin capillary into the chamber through which neutral&lt;br&gt;sample is passed through. As a solute we used NaNO3 , NaI, LiCl and CH3CO2K dissolved in&lt;br&gt;methanol all charged in positive and negative mode. Particles that are charged by reagent ions are&lt;br&gt;led into the DMA via narrow inlet slit.&lt;/p&gt;&lt;p&gt;&lt;br&gt;&amp;#945;-pinene was evaporated into a carrier gas flow and then oxidized using ozone produced from synthetic air with UV-light. The oxidation products are detected by charging them with ions sprayed from the electrospray solution and then directed into the DMA chamber. &amp;#945;-pinene oxidation products of oxidation state C10H16O2&amp;#8722;7 were detected with almost all charger ions. Also, other products with different amounts of carbon and hydrogen were detected. Measurements made in negative mode were much more clear and because of this concentrated to examine them.&lt;/p&gt;&lt;p&gt;&lt;br&gt;Mobility provides information on the structure of the compound. One cluster can have multiple peaks in the mobility spectrum if it has multiple different structures. In the mobility spectrum of C10H16O3 charged with NO3&amp;#8722; we observe two peaks clearly separate mobility peaks that likely&lt;br&gt;correspond to two different structural isomers of the compound. We will present analysis of the mobility-mass measurements of &amp;#945;-pinene oxidation products, from where structural information will be obtained when combined to chemical reaction pathways and modeling of the electrical mobilities from the calculated structures.&lt;/p&gt;&lt;p&gt;&lt;br&gt;REFERENCES&lt;br&gt;Ehn, M. et al, (2014). A large source of low-volatility secondary organic aerosol. (Nature, 506(7489), 476-+.&lt;br&gt;doi:10.1038/nature13032).&lt;/p&gt;&lt;p&gt;&lt;br&gt;Fern&amp;#225;ndez de la Mora et al, (2006). The potential of differen-&lt;br&gt;tial mobility analysis coupled to MS for the study of very large singly and multiply chargedproteins and protein complexes in the gas phase.&lt;br&gt;doi:10.1002/biot.200600070). (Biotechnology Journal, 1(9), 988-997.&lt;/p&gt;&lt;p&gt;&lt;br&gt;Junninen, H. et al,&amp;#160;(2010). A high-resolution mass spectrometer&lt;br&gt;to measure atmospheric ion composition. (Atmospheric Measurement Techniques, 3(4), 1039-&lt;br&gt;1053. doi:10.5194/amt-3-1039-2010).&lt;/p&gt;

scholarly journals Synthesis of two new enrichable and MS-cleavable cross-linkers to define protein–protein interactions by mass spectrometry

2015 ◽  
Vol 13 (17) ◽  
pp. 5030-5037 ◽  
Author(s):  
Anthony M. Burke ◽  
Wynne Kandur ◽  
Eric J. Novitsky ◽  
Robyn M. Kaake ◽  
Clinton Yu ◽  
...  
Keyword(s):  
Mass Spectrometry ◽  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Cross Linking ◽  
Protein Protein Interactions ◽  
The Cross

The cross-linking Mass Spectrometry (XL-MS) technique extracts structural information from protein complexes without requiring highly purified samples, crystallinity, or large amounts of material.

A HIDDEN MARKOV MODEL FOR PREDICTING PROTEIN INTERFACES

2007 ◽  
Vol 05 (03) ◽  
pp. 739-753 ◽  
Author(s):  
CAO NGUYEN ◽  
KATHELEEN J. GARDINER ◽  
KRZYSZTOF J. CIOS
Keyword(s):  
Markov Model ◽  
Hidden Markov Model ◽  
Protein Interactions ◽  
Protein Function ◽  
Structural Information ◽  
Protein Complexes ◽  
Hidden Markov ◽  
Transition Probability ◽  
Accessible Surface Area ◽  
Protein Chain

Protein–protein interactions play a defining role in protein function. Identifying the sites of interaction in a protein is a critical problem for understanding its functional mechanisms, as well as for drug design. To predict sites within a protein chain that participate in protein complexes, we have developed a novel method based on the Hidden Markov Model, which combines several biological characteristics of the sequences neighboring a target residue: structural information, accessible surface area, and transition probability among amino acids. We have evaluated the method using 5-fold cross-validation on 139 unique proteins and demonstrated precision of 66% and recall of 61% in identifying interfaces. These results are better than those achieved by other methods used for identification of interfaces.

scholarly journals Investigation of protein–protein interactions by isotope‒edited Fourier transformed infrared spectroscopy

2004 ◽  
Vol 18 (3) ◽  
pp. 397-406 ◽  
Author(s):  
Tiansheng Li
Keyword(s):  
Ftir Spectroscopy ◽  
Conformational Changes ◽  
Protein Interactions ◽  
Isotope Labeling ◽  
Structural Information ◽  
Protein Complexes ◽  
Secondary Structures ◽  
Receptor Complex ◽  
Protein Protein Interactions

Recent advance in FTIR spectroscopy has shown the usefulness of13C uniform isotope labeling in proteins to study protein–protein interactions.13C uniform isotope labeling can significantly resolve the spectral overlap in the amide I/I′ region in the spectra of protein–protein complexes, and therefore allows more accurate determination of secondary structures of individual protein component in the complex than does the conventional FTIR spectroscopy. Only a limited number of biophysical techniques can be used effectively to obtain structural information of large protein–protein complex in solution. Though X‒ray crystallography and NMR have been used to provide structural information of proteins at atomic resolution, they are limited either by the ability of protein to crystallize or the large molecular weight of protein. Vibrational spectroscopy, including FTIR and Raman spectroscopies, has been extensively employed to investigate secondary structures and conformational dynamics of protein–protein complexes. However, significant spectral overlap in the amide I/Iʹ region in the spectra of protein–protein complexes often hinders the utilization of vibrational spectroscopy in the study of protein–protein complex. In this review, we shall discuss our recent work involving the application of isotope labeled FTIR to the investigation of protein–protein complexes such as cytokine–receptor complexes. One of the examples involves G‒CSF/receptor complex. To determine unambiguously the conformations of G‒CSF and the receptor in the complex, we have prepared uniformly13C/15N isotope labeled G‒CSF to resolve its amide Iʹ band from that of its receptor in the IR spectrum of the complex. Conformational changes and structural stability of individual protein subunit in G‒CSF/receptor complex have then been investigated by using FTIR spectroscopy (Li et al.,Biochemistry29 (1997), 8849–8859). Another example involves BDNF/trkB complex in which13C/15N uniformly labeled BDNF is complexed with its receptor trkB (Li et al.,Biopolymers67(1) (2002), 10–19). Interactions of13C/15N uniformly labeled brain‒derived neurotrophic factor (BDNF) with the extracellular domain of its receptor, trkB, have been investigated by employing FTIR spectroscopy. Conformational changes and structural stability and dynamics of BDNF/trkB complex have been determined unambiguously by FTIR spectroscopy, since amide I/Iʹ bands of13C/15N labeled BDNF are resolved from those of the receptor. Together, those studies have shown that isotope edited FTIR spectroscopy can be successfully applied to the determination of protein secondary structures of protein complexes containing either the same or different types of secondary structures. It was observed that13C/15N uniform labeling also affects significantly the frequency of amide IIʹ band, which may permit the determination of hydrogen–deuterium exchange in individual subunit of protein–protein complexes.

ProAffiMuSeq: sequence-based method to predict the binding free energy change of protein–protein complexes upon mutation using functional classification

2019 ◽  
Author(s):  
Sherlyn Jemimah ◽  
Masakazu Sekijima ◽  
M Michael Gromiha
Keyword(s):  
Free Energy ◽  
Protein Interactions ◽  
Large Scale ◽  
Structural Information ◽  
Protein Complexes ◽  
Binding Free Energy ◽  
Complex Structure ◽  
External Validation ◽  
Functional Class ◽  
Supplementary Information

Abstract Motivation Protein–protein interactions are essential for the cell and mediate various functions. However, mutations can disrupt these interactions and may cause diseases. Currently available computational methods require a complex structure as input for predicting the change in binding affinity. Further, they have not included the functional class information for the protein–protein complex. To address this, we have developed a method, ProAffiMuSeq, which predicts the change in binding free energy using sequence-based features and functional class. Results Our method shows an average correlation between predicted and experimentally determined ΔΔG of 0.73 and mean absolute error (MAE) of 0.86 kcal/mol in 10-fold cross-validation and correlation of 0.75 with MAE of 0.94 kcal/mol in the test dataset. ProAffiMuSeq was also tested on an external validation set and showed results comparable to structure-based methods. Our method can be used for large-scale analysis of disease-causing mutations in protein–protein complexes without structural information. Availability and implementation Users can access the method at https://web.iitm.ac.in/bioinfo2/proaffimuseq/. Supplementary information Supplementary data are available at Bioinformatics online.

Cross-saturation and transferred cross-saturation experiments

2014 ◽  
Vol 47 (2) ◽  
pp. 143-187 ◽  
Author(s):  
Takumi Ueda ◽  
Koh Takeuchi ◽  
Noritaka Nishida ◽  
Pavlos Stampoulis ◽  
Yutaka Kofuku ◽  
...  
Keyword(s):  
Lipid Bilayers ◽  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Protein Protein Interactions ◽  
Molecular Weights ◽  
Protein Ligands ◽  
Close Proximity ◽  
Complex Models ◽  
Functional Mechanisms

AbstractStructural analyses of protein–protein interactions are required to reveal their functional mechanisms, and accurate protein–protein complex models, based on experimental results, are the starting points for drug development. In addition, structural information about proteins under physiologically relevant conditions is crucially important for understanding biological events. However, for proteins such as those embedded in lipid bilayers and transiently complexed with their effectors under physiological conditions, structural analyses by conventional methods are generally difficult, due to their large molecular weights and inhomogeneity. We have developed the cross-saturation (CS) method, which is an nuclear magnetic resonance measurement technique for the precise identification of the interfaces of protein–protein complexes. In addition, we have developed an extended version of the CS method, termed transferred cross-saturation (TCS), which enables the identification of the residues of protein ligands in close proximity to huge (>150 kDa) and heterogeneous complexes under fast exchange conditions (>0.1 s−1). Here, we discuss the outline, basic theory, and practical considerations of the CS and TCS methods. In addition, we will review the recent progress in the construction of models of protein–protein complexes, based on CS and TCS experiments, and applications of TCS to in situ analyses of biologically and medically important proteins in physiologically relevant states.

Lithium-Protein Interactions: Analysis of Lithium-Containing Protein Crystal Structures Deposited in the Protein Data Bank

2020 ◽  
Vol 27 (8) ◽  
pp. 763-769
Author(s):  
Oliviero Carugo
Keyword(s):  
Small Molecules ◽  
Crystal Structures ◽  
Protein Data Bank ◽  
Protein Interactions ◽  
Structural Information ◽  
Protein Complexes ◽  
Aerospace Industry ◽  
Data Bank ◽  
Protein Crystal ◽  
Side Chain

Background: Despite the fact that lithium is not a biologically essential metallic element, its pharmacological properties are well known and human exposure to lithium is increasingly possible because of its used in aerospace industry and in batteries. Objective: Lithium-protein interactions are therefore interesting and the surveys of the structures of lithium-protein complexes is described in this paper. Methods: A high quality non-redundant set of lithium containing protein crystal structures was extracted from the Protein Data Bank and the stereochemistry of the lithium first coordination sphere was examined in detail. Results: Four main observations were reported: (i) lithium interacts preferably with oxygen atoms; (ii) preferably with side-chain atoms; (iii) preferably with Asp or Glu carboxylates; (iv) the coordination number tends to be four with stereochemical parameters similar to those observed in small molecules containing lithium. Conclusion: Although structural information on lithium-protein, available from the Protein Data Bank, is relatively scarce, these trends appears to be so clear that one may suppose that they will be confirmed by further data that will join the Protein Data Bank in the future.

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