Analysis of noncovalent and covalent protein-ligand complexes by electrospray ionisation mass spectrometry

Sundqvist, Gustav

January 2008

In this thesis, the application of electrospray ionisation mass spectrometry (ESI-MS) to the analysis of intact proteins is demonstrated. In papers I and II, the use of ESI-MS for the analysis of noncovalent protein-ligand complexes were discussed. In addition, the interfacing of liquid chromatography (LC) with ESI-MS and the development of an LC-ESI-MS method were demonstrated in paper III for the quality control of recombinant proteins. Furthermore, this method was applied in paper IV for the analysis of covalent glycosyl-enzyme intermediates. The monitoring of noncovalent complexes by ESI-MS is well established. However, the varying characteristic of ESI-MS data, especially in the analysis of noncovalent complexes can make the quantification of such complexes troublesome. In paper I, it was demonstrated how the variation in the position of the ESI-emitter and the initial droplet size of the electrosprayed droplets, together with different partitioning of a protein and its ligand in these droplets, can be the cause of such varying characteristics. Furthermore, it was shown that the partitioning can be of electrostatic and/or hydrophobic/hydrophilic origin. Thus it was demonstrated that if the ligand is more hydrophobic and thereby more surface active relative to the protein, decreasing the droplet size or increasing the distance between the electrospray emitter and the sampling orifice will lead to more efficient sampling of the droplet bulk where the ligand concentration is low. This results in a favoured sampling of free protein relative to the protein ligand complex. The opposite was shown to occur if the ligand is more hydrophilic than the protein. In paper II, Ribonuclease A (RNAse) was used as a model for enzymes acting on polymeric substrates with different chain lengths. Nano-ESI-MS was applied to monitor the noncovalent interactions between RNAse and different target ligands. Among the single building blocks of RNA, including ribose, the bases adenine, guanine, cytosine and uracil, and phosphate, only phosphate was observed to interact at multiple RNAse sites at a higher cone voltage. Furthermore, monobasic singlestranded deoxycytidylic acid oligomers (dCx) of different lengths (X=6, 9 and 12), and RNAse were analysed with nano-ESI-MS. The deoxycytidylic acid with 12 nucleotides was observed with the highest complex to free protein ratio, hence indicating the strongest interaction. Finally, collision induced dissociation of the noncovalent RNAseA-dC6 complex resulted in dissociation of covalently bound cytosine from the nucleotide backbone rather than break up of the noncovalent complex, illustrating the cooperative effect of multiple noncovalent interactions. In paper III an LC-ESI-MS method was presented capable of analysing proteins 10-100 kDa in size, from salt-containing liquid samples. The proteins included human protein fragments for the largescale production of antibodies and human protein targets for structural determination, expressed in E. coli. Also, glycosylated proteins expressed in Pichia pastoris were analysed. The method provides fast chromatography, is robust and makes use of cheap desalting/trap columns. In addition it was used with optimised reduction and alkylation protocols in order to minimize protein aggregation of denatured and incorrectly folded proteins containing cysteins, which otherwise form adducts by disulfide bond formation. Furthermore, the method was used in paper IV for the quantification of covalent proteinligand intermediates formed enzymatically between PttXET16-34, a xyloglucan endo-transglycosylase (XET) from hybrid aspen, and the synthetic substrates GalGXXXGGG and GalXXXGXXXG designed in order to function as donor substrates only. Thus covalent GalG-enzyme and GalGXXXG-enzyme complexes were detected. Moreover, establishing of a pseudo equilibrium for the formation of the covalent GalGXXXG-enzyme complex enabled quantification of the saccharide and enzyme constituents of this equilibrium and determination of the free energy of formation (∆G0). The high mass resolution of the TOF-MS allowed unambiguous assessment of the covalent nature of the glycosyl-enzyme complexes. Morover, the formation of noncovalent complexes between excess substrate and protein, which can deteriorate MS-signal and increase spectrum complexity, was efficiently avoided by the chromatographic step, which separated the saccharide content from the protein content. / QC 20100913

noncovalent complex

droplet fission

nano-electrospray ionisation

mass spectrometry

Analytical chemistry

Analytisk kemi

Implementation and applications of density-fitted symmetry-adapted perturbation theory

Hohenstein, Edward G.

20 July 2011

Noncovalent interactions play a vital role throughout much of chemistry. The understanding and characterization of these interactions is an area where theoretical chemistry can provide unique insight. While many methods have been developed to study noncovalent interactions, symmetry-adapted perturbation theory (SAPT) stands out as one of the most robust. In addition to providing energetic information about an interaction, it provides insight into the underlying physics of the interaction by decomposing the energy into electrostatics, exchange, induction and dispersion. Therefore, SAPT is capable of not only answering questions about how strongly a complex is bound, but also why it is bound. This proves to be an invaluable tool for the understanding of noncovalent interactions in complex systems. The wavefunction-based formulation of SAPT can provide qualitative results for large systems as well as quantitative results for smaller systems. In order to extend the applicability of this method, approximations to the two-electron integrals must be introduced. At low-order, the introduction of density fitting approximations allows SAPT computations to be performed on systems with up to 220 atoms and 2850 basis functions. Higher-orders of SAPT, which boasts accuracy rivaling the best theoretical methods, can be applied to systems with over 40 atoms. Higher-order SAPT also benefits from approximations that attempt to truncate unneccesary unoccupied orbitals.

Molecular interactions

Noncovalent interactions

Molecular recognition

SAPT

Perturbation (Mathematics)

Quantum chemistry

Chemistry, Physical and theoretical

Development And Benchmarking Of A Semilocal Density-Functional Approximation Including Dispersion

Kannemann, Felix Oliver

22 February 2013

Density-functional theory has become an indispensible tool for studying matter on the atomic level, being routinely applied across diverse disciplines from solid-state physics to chemistry and molecular biology. Its failure to account for dispersion interactions has spurred intensive research over the past decade. In this thesis, a semilocal density-functional approximation including dispersion is developed by combining standard functionals for exchange and correlation with the nonempirical “exchange-hole dipole moment“ (XDM) dispersion model of Becke and Johnson. With a minimum of empiricism, the method accurately describes all types of noncovalent interactions, from the extremely weak dispersion forces in rare-gas systems to the hydrogen bonding and stacking interactions responsible for the structure and function of biological macromolecules such as DNA and proteins. The method is compatible with a wide variety of standard Gaussian basis sets, and is easily applied to any system that can be modeled with density-functional theory.

Nové nanočástice v ultrastrukturální diagnostice / The new nanoparticles in the ultastructural diagnostics

MARTYKÁNOVÁ, Denisa

January 2014

The aim of this master thesis is to focus on a various methods of the conjugation of palladium nanoparticles of different shapes on the protein. The main point was to use both covalent and non-covalent conjugation of palladium nanoparticles on the protein and to use the functional conjugates to find out their stability in time.

Measuring the Interaction and Cooperativity Between Ionic, Aromatic, and Nonpolar Amino Acids in Protein Structure

Smith, Mason Scott

01 July 2018

Protein folding studies have provided important insights about the key role of non-covalent interactions in protein structure and conformational stability. Some of these interactions include salt bridges, cation-π, and anion-Ï€ interactions. Understanding these interactions is crucial to developing methods for predicting protein secondary, tertiary, quaternary structure from primary sequence and understanding protein-protein interactions and protein-ligand interactions. Several studies have described how the interaction between two amino acid side chains have a substantial effect on protein structure and conformational stability. This is under the assumption that the interaction between the two amino acids is independent of surrounding interactions. We are interested in understanding how salt bridges, cation-π, and anion-π interactions affect each other when they are in close proximity. Chapter 1 is a brief introduction on noncovalent interactions and noncovalent interaction cooperativity. Chapter 2 describes the progress we have made measuring the cooperativity between noncovalent interactions involving cations, anions and aromatic amino acids in a coiled-coil alpha helix model protein. Chapter 3 describes cooperativity between cation, anion, and nonaromatic hydrophobic amino acids in the context of a coiled-coil alpha helix. In chapter 4 we describe a strong anion-π interaction in a reverse turn that stabilizes a beta sheet model protein. In chapter 5 we measure the interaction between a cysteine linked maleimide and two lysines in a helix and show that it is a general strategy to stabilize helical structure.

cation

anion

noncovalent interaction

coiled coil

protein structure

Conformational stability.

Physical Sciences and Mathematics

PEGylation Stabilizes the Conformation of Proteins and the Noncovalent Interactions Within Them

Draper, Steven R. E.

08 June 2021

PEGylation has been used for decades to enhance the pharmacokinetic properties of protein therapeutics. This method has been effective at increasing the serum half-life of these drugs, but the mechanism of how it does this is unclear. Chapter 1 is an introduction to the methods of PEGylation. In chapter 2 we show that the effect of PEGylation on the conformational stability of the WW domain differs based on amino acid linker and conjugation site. We show that all positions in the WW domain that were tested can be stabilized by at least one amino acid linker. The rate of proteolysis is proportional to the degree of conformational stability. Chapter 3 shows that PEG-based desolvation can increase the strength of the interaction between two salt bridge residues, though the effect of structural context is unclear. A crystal structure shows that PEG occupies the space between the PEGylation site and the salt bridge, displacing water. In Chapter 4 we discuss the effect that PEGylation has on the interaction strength of a solvent exposed hydrophobic patch. When the c Log P of the hydrophobic patch increases, PEG increases the conformational stability of the WW domain more dramatically. Chapter 5 is about the effect of PEG based desolvation on the strength of an NH-π hydrogen bond in the WW domain between Trp11 and Asn26. When Trp11 is mutated to Phe, Tyr and naphthylalanine (Nal), the melting temperatures correlate with the calculated interaction energies between the sidechain arene of the hydrogen bond acceptor and formamide. When Asn26 is PEGylated in the presence of each of these amino acids, the effect that PEG has on the conformational stability of the WW domain correlates with the melting temperature of the nonPEGylated variants, the calculated interaction energies, the arene molecular polarizability, and the arene molar volume.

PEG

PEGylation

conformational stability

protein therapeutics

desolvation

noncovalent interactions

Physical Sciences and Mathematics

Studies on Asymmetric Hetero-Michael Addition Utilizing Various Modes of Organocatalytic Activation / 有機分子触媒による様々な活性化を利用した不斉ヘテロマイケル付加反応に関する研究

Fukata, Yukihiro

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19725号 / 工博第4180号 / 新制||工||1645(附属図書館) / 32761 / 京都大学大学院工学研究科材料化学専攻 / (主査)教授 松原 誠二郎, 教授 中尾 佳亮, 教授 杉野目 道紀 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

hetero-Michael addition

organocatalyst

noncovalent bond-activation

covalent bond-activation

Asmmetric synthesis

500

Bio-inspired Design and Self-Assembly of Nucleobase- and Ion-Containing Polymers

Zhang, Keren

24 June 2016

Bio-inspired monomers functionalized with nucleobase or ionic group allowed synthesis of supramolecular polymers using free radical polymerization and controlled radical polymerization techniques. Comprehensive investigations for the structure-property-morphology relationships of these supramolecular polymers elucidated the effect of noncovalent interactions on polymer physical properties and self-assembly behaviors. Reverse addition-fragmentation chain transfer (RAFT) polymerization afforded acrylic ABC and ABA triblock copolymers with nucleobase-functionalized external blocks and a low-Tg central block. The hard-soft-hard triblock polymer architecture drove microphase-separation into a physically crosslinked hard phase in a low Tg matrix. Hydrogen bonding in the hard phase enhanced the mechanical strength and maintained processability of microphase-separated copolymers for thermoplastics and elastomers. A thermodynamically favored one-to-one stoichiometry of adenine and thymine yielded the optimal thermomechanical performance. Intermolecular hydrogen bonding of two thymine units and one adenine unit allowed the formation of base triplets and directed self-assembly of ABC triblock copolymers into remarkably well-defined lamellae with long-range ordering. Acetyl protected cytosine and guanine-containing random copolymers exhibited tunable cohesive strength and peel strength as pressure sensitive adhesives. Post-functionalization converted unprotected cytosine pendent groups in acrylic random copolymers to ureido-cytosine units that formed quadruple self-hydrogen bonding. Ureido-cytosine containing random copolymers self-assembled into nano-fibrillar hard domains in a soft acrylic matrix, and exhibited enhanced cohesive strength, wide service temperature window, and low moisture uptake as soft adhesives. A library of styrenic DABCO salt-containing monomers allowed the synthesis of random ionomers with two quaternized nitrogen cations on each ionic pendant group. Thermomechanical, morphological, and rheological analyses revealed that doubly-charged DABCO salts formed stronger ionic association and promoted more well-defined microphase-separation compared to singly-charged analogs with the same charge density. Bulkier counterions led to enhanced thermal stability, increased phase-mixing, and reduced water uptake for DABCO salt-containing copolymers, while alkyl substituent lengths only significantly affected water uptake of DABCO salt-containing copolymers. Step growth polymerization of plant oil-based AB monomer and diamines enabled the synthesis of unprecedented isocyanate-free poly(amide hydroxyurethane)s, the first examples of film-forming, linear isocyanate-free polyurethanes with mechanical integrity and processability. Successful electrospinning of segmented PAHUs afforded randomly orientated, semicrystalline fibers that formed stretchable, free-standing fiber mats with superior cell adhesion and biocompatibility. / Ph. D.

noncovalent interaction

hydrogen bonding

ionic interaction

nucleobase

DABCO salt

self-assembly

microphase-separation

non-isocyanate polyurethane

Self-association of [PtII(1,10-Phenanthroline)(N-pyrrolidyl-N-(2,2-dimethyl-propanoyl)thiourea)]+ and non-covalent outer-sphere complex formation with fluoranthene through cation-π interactions : a high resolution 1H and DOSY NMR study

Kotze, Izak Aldert

12 1900

Thesis (MSc (Chemistry and Polymer Science))--University of Stellenbosch, 2009. / Please refer to full text for abstract. Abstract contains special characters.

Noncovalent interactions

Nuclear magnetic resonance spectroscopy

Diffusion coefficients

Complex compounds

Ligands

Dissertations -- Chemistry

Theses -- Chemistry

Chemistry and Polymer Science

Study Of Covalent And Non-Covalent Interactions In Ternary Systems Involving: Metal/DNA-RNA/Protein, Where Metal = Platinum(II), Palladium(II)

Atilio, Anzellotti I.

01 January 2007

Ternary systems comprising DNA/RNA, proteins and one (or more) metal ion are generating increased interest due to its biological relevance. The knowledge gained from the study of these systems could provide important clues regarding the precise mechanism for transcription factors, repair proteins and metal complexes with anti-tumoral/anti-viral activities.The interactions occurring among the components of these ternary systems can be broadly grouped into covalent and non-covalent. The first kind of interactions can lead to the irreversible transformation of the components in the system, while the second is thought to be reversible leading to transient states and fluxionality. Both kinds of interaction are generally present in living systems, complementing the function of each other.Monofunetional Platinum-nucleobase complexes (MPNs) are synthesized via substitution of a chloride ligand by a nucleobase in platinum complexes with trans geometry. MPNs are particularly interesting for the study of ternary systems since they mimic the first step in the formation of a platinum-DNA adduct and their interaction with aminoacids/proteins provide a good first approach for more complex systems.The presence of the nucleobase as a ligand, significantly modifies the biological activity of these complexes by reducing its cytotoxicity and generating a promising anti-viral activity, especially against HIV-1 virus. The specific role of the nucleobase ligand on these complexes as a non-covalent motif, important for protein recognition, was explored in models involving tryptophan/N-acetyl tryptophan and a small protein domain called zinc finger, containing also a tryptophan residue.The coordination of the nucleobase to a metal ion such as Pt(II) or Pd(II) was found to increase its π-stacking interaction towards aromatic residues in proteins, specifically tryptophan. The enhancing effect was found to depend on the nature of the metal ion, nature of nucleobase and size/complexity of the protein model. Furthermore, DFT studies revealed an important change in the energy for the lowest unoccupied molecular orbital (LUMO) in the coordinated nucleobases, which could place this orbital in an favored position to interact with the highest occupied molecular orbital (HOMO) in the tryptophan residue. Results from calculations showed a good correlation with experimental evidence and could indicate an important role for the frontier molecular orbitals (HOMO/LUMO) of the species involved in the π-stacking interaction.This study was extended to a zinc finger domain from an essential protein in HIV-1 virus, i.e. nucleocapsid protein NCp7. Findings showed that the nucleobase ligand in addition to modulate hydrolysis and reaction rates for MPNs can also be responsible for an initial non-covalent recognition towards a specific protein. This initial recognition has been proposed as the first stage in a two-step mechanism of action for these platinum complexes that ultimately can lead to zinc ejection from the zinc finger domain in the viral NCp7. The significance of the data presented show that is possible to modulate the ligand coordination sphere in metal complexes to can result in great differences in terms of biological effects.The novel chemistry derived from DNA adducts with platinum complexes with a trans geometry was also explored in silico. The molecular dynamics of two free DNA 20-mer is compared with the corresponding metallated-adducts, namely monofunctional, 1,2-bifunctional interstrand and 1,3-bifunctional intrastrand. The differences in terms of structure and energy are compared for these systems, in general the monofunctional adduct exhibited the most interesting feature in terms of structural change in the DNA double strand causing the destacking of the metallated nucleobase. Bifunctional adducts exhibited loss of Watson-crick bonds and localized change in sugar puckering. These results showed that important differences can be found for platinated DNA even at short simulation times < 1 ns.

Metal/DNA-RNA/protein

Platinum

Ternary systems

Noncovalent

Stacking

Zinc finger

Tryptophan

Palladium

Chemistry

Physical Sciences and Mathematics