Investigation of protein-ion interactions by mass spectrometry and ion mobility mass spectrometry

Berezovskaya, Yana

January 2012

Protein‐ion interactions play an important role in biological systems. A considerable number of elements (estimated 25 – 30) are essential in higher life forms such as animals and humans, where they are integral part of enzymes involved in plethora of cellular processes. It is difficult to overestimate the importance of thorough understanding of how protein‐ion interplay affects living cell in order to be able to address therapeutic challenges facing humanity. Presented to the reader’s attention is a gas‐phase biophysical analysis of peptides’ and proteins’ interactions with biologically relevant ions (Zn2+ and I–). This investigation provides an insight into conformational changes of peptides and proteins triggered by ions. Mass spectrometry and ion mobility mass spectrometry are used in this work to probe peptide and protein affinities for a range of ions, along with conformational changes that take place as a result of binding. Observation of peptide and protein behaviour in the gas phase can inform the investigator about their behaviour in solution prior to ionisation and transfer from the former into the latter phase. Wherever relevant, the gas‐phase studies are complemented by molecular dynamics simulations and the results are compared to solution phase findings (spectroscopy). Two case studies of protein‐ion interactions are presented in this thesis. Firstly, sequence‐to‐structure relationships in proteins are considered via protein design approach using two synthetic peptide‐based systems. The first system is a synthetic consensus zinc finger sequence (vCP1) that is responsive to zinc: it adopts a zinc finger fold in the presence of Zn2+ by coordinating the metal ion by two cysteines and two histidines. This peptide has been selected as a reference for the zinc‐bound state and a simple model to refine the characterisation method in preparation for analysis of a more sophisticated second system – dual conformational switch. This second system (ZiCop) is designed to adopt either of the two conformations in response to a stimulus: zinc finger or coiled coil. The reversible switch between the two conformational states is controlled by the binding of zinc ion to the peptide. Interactions of both peptide systems with a number of other divalent metal cations (Co2+, Ca2+ and Cu2+) are considered also, and the differences in binding and switching behaviour are discussed. Secondly, protein‐salt interactions are investigated using three proteins (lysozyme, cytochrome c and BPTI) using variable temperature ion mobility mass spectrometry. Ion mobility measurements were carried out on these proteins with helium as the buffer gas at three different drift cell temperatures – ‘ambient’ (300 K), ‘cold’ (260 K) and ‘hot’ (360 K), and their conformational preferences in response to HI binding and temperature are discussed.

572

Comparative study of materials-binding peptide interactions with gold and silver surfaces and nanostructures: A thermodynamic basis for biological selectivity of inorganic materials

Palafox-Hernandez, J.P., Tang, Z., Hughes, Zak E., Li, Y., Swihart, M.T., Prasad, P.N., Walsh, T.R., Knecht, M.R.

13 March 2019

No / Controllable 3D assembly of multicomponent inorganic nanomaterials by precisely positioning two or more types of nanoparticles to modulate their interactions and achieve multifunctionality remains a major challenge. The diverse chemical and structural features of biomolecules can generate the compositionally specific organic/inorganic interactions needed to create such assemblies. Toward this aim, we studied the materials-specific binding of peptides selected based upon affinity for Ag (AgBP1 and AgBP2) and Au (AuBP1 and AuBP2) surfaces, combining experimental binding measurements, advanced molecular simulation, and nanomaterial synthesis. This reveals, for the first time, different modes of binding on the chemically similar Au and Ag surfaces. Molecular simulations showed flatter configurations on Au and a greater variety of 3D adsorbed conformations on Ag, reflecting primarily enthalpically driven binding on Au and entropically driven binding on Ag. This may arise from differences in the interfacial solvent structure. On Au, direct interaction of peptide residues with the metal surface is dominant, while on Ag, solvent-mediated interactions are more important. Experimentally, AgBP1 is found to be selective for Ag over Au, while the other sequences have strong and comparable affinities for both surfaces, despite differences in binding modes. Finally, we show for the first time the impact of these differences on peptide mediated synthesis of nanoparticles, leading to significant variation in particle morphology, size, and aggregation state. Because the degree of contact with the metal surface affects the peptide’s ability to cap the nanoparticles and thereby control growth and aggregation, the peptides with the least direct contact (AgBP1 and AgBP2 on Ag) produced relatively polydispersed and aggregated nanoparticles. Overall, we show that thermodynamically different binding modes at metallic interfaces can enable selective binding on very similar inorganic surfaces and can provide control over nanoparticle nucleation and growth. This supports the promise of bionanocombinatoric approaches that rely upon materials recognition. / Air Office of Scientific Research grant number FA9550-12-1-0226

Noble metals

Peptide interactions

Nanostructures

Molecular simulation

Secondary Structural and Functional Studies of Rotavirus NSP4 and Caveolin-1 Peptide-Peptide Interactions

Schroeder, Megan Elizabeth

2009 December 1900

The rotavirus NSP4 protein is the first described viral enterotoxin. Abundant data from our laboratory reveals that NSP4 binds both the N- and C-termini of caveolin- 1 (aa2-31 and 161-178, respectively). Yeast two-hybrid and peptide binding analysis mapped the caveolin-1 binding site to three hydrophobic residues within the amphipathic a-helix, enterotoxic peptide domain (aa114-135). The research studies herein utilized peptides to investigate the interaction between NSP4 and caveolin-1. Peptides were synthesized corresponding to the amphipathic a-helix and caveolin-1 binding domain of NSP4 (aa112-140) and to the N- (aa2-20 and 19-40) and C- (161-178) termini of caveolin-1, and were utilized in structural and functional studies. Fluorescence binding assays revealed that NSP4 (aa112-140) binds to the N-terminus (aa19-40) of caveolin-1 with a stronger affinity than the C-terminus (aa161-178). In addition, this assay further delineated the NSP4 binding domain on caveolin-1 to aa19-40. Secondary structural changes following NSP4-caveolin-1 peptide-peptide interactions were investigated by circular dichroism analysis. Changes in a-helix formation were observed only upon interaction of the NSP4112-140 peptide with the C-terminal caveolin-1 peptide (C-Cav161- 178). The NSP4112-140 peptide contains a potential cholesterol recognition amino acid consensus (CRAC) sequence. Therefore this peptide was examined for cholesterol binding. Results of the binding assay revealed NSP4 binds cholesterol with a Kd of 7.67 +/- 1.49nM and this interaction occurs via aa112-140. Mutation of amino acid residues within the CRAC motif resulted in weaker binding affinities between each of the corresponding mutant peptides and cholesterol. NSP4 peptides containing mutations within the hydrophobic and charged faces of the amphipathic a-helix, enterotoxic peptide and caveolin-1 binding domain of NSP4 were examined for changes in secondary structure as well as diarrhea induction in mouse pups. Circular dichroism analysis revealed that mutation of hydrophobic residues resulted in a decrease in a-helix formation, whereas mutation of acidic and basic charged residues caused little to no change in a-helical content. When tested for diarrhea induction in mouse pups, the peptides containing mutations of either the hydrophobic or basic charged residues did not cause diarrhea. Taken together, the results of this research suggest a complex interplay between NSP4 secondary structure, caveolin-1 and cholesterol binding and diarrheagenic function.

Rotavirus NSP4

caveolin-1

circular dichroism

cholesterol

peptide-peptide interactions

Caractérisation structurale et biologique de nouveaux agents antibactériens naturels actifs dans les infections intestinales : des peptides de la chromogranine A et des principes actifs de Chromolaena odorata / Structural and biological characterization of new natural antibacterial agents active in intestinal infections : chromogranin A-derived peptides and active molecules of Chromolaena odorata

Atindehou, Ménonvè

15 June 2012

Les premières souches bactériennes résistantes aux antibiotiques sont connues depuis 70 ans et se sont multipliées ces dernières années posant un grave problème de santé publique. Parmi les nombreux types d’infections induites par ces bactéries, nous nous sommes intéressés aux infections intestinales qui peuvent dégénérer en maladies inflammatoires de l’intestin et cancers. Notre travail de thèse a consisté à proposer des outils thérapeutiques dans le traitement des pathologies intestinales infectieuses : des peptides antimicrobiens dérivés de la chromogranine A et des extraits de plantes de la médecine traditionnelle béninoise. La chromogranine A est une protéine libérée par les cellules nerveuses, neuroendocrines et immunitaires au cours d’un stress et maturée en peptides. Des peptides actifs contre quatre souches bactériennes pathogènes (Klebsiella oxytoca, Salmonella enterica, Shigella sonnei et Vibrio cholera non O1) ont été identifiés et l’interaction bactérie-peptide analysée. L’étude de la combinaison peptide-antibiotique montre que la cateslytine permet de réduire les doses d’antibiotiques nécessaires. Ensuite, nous avons étudié l’implication de deux peptides sur un modèle de cellules neuroendocrines, les cellules BON. La chromofungine provoque la stimulation des cellules BON en induisant un influx de calcium extracellulaire, tandis que la catestatine est capable de bloquer l’activité de la chromofungine.Après un screening des extraits de 14 plantes du Bénin, nous avons isolé deux molécules, la sinensétine et l’O-tétraméthyléther scutellaréine, responsables de l’activité antibactérienne de Chromolaena odorata contre les pathogènes étudiés. / The first bacterial strains resistant to antibiotics appeared 70 years ago and have proliferated in recent years causing a serious public health problem. Such bacteria are responsible of several types of infections including intestinal infections with chronic inflammatory bowel diseases and cancers. This work consisted of proposing new therapeutic tools in the treatment of intestinal pathologies. In this context, we have studied antimicrobial peptides derived from chromogranin A and plant extracts used in Beninese traditional medicine for the treatment of such diseases. Chromogranin A is a protein produced by nervous, endocrine and immune cells during a stress and processed to generate biologically active peptides. We identified antimicrobial peptides, active against four pathogenic bacterial strains (Klebsiella oxytoca, Salmonella enterica, Shigella sonnei and Vibrio cholera non O1) and analyzed the bacteria-peptide interactions. Moreover, the study of the peptide-antibiotic combination shows that cateslytin is useful for reducing doses of antibiotic drugs. In addition of this work, we have studied the effects of two peptides derived from chromogranin A on neuroendocrine cells with model of BON cells. Chromofungin stimules BON cells by inducing an influx of extracellular calcium, whereas catestatin is able to block chromofungin’s activity.With plant extracts, after a screening on 14 plants from Benin, our works enabled us to isolate two active molecules, sinensetin and O-tetramethylether scutellarein, responsible of the antimicrobial activity of Chromolaena odorata against the studied pathogenic strains.

Peptides antimicrobiens

Chromogranine A

Immunité innée

Infections intestinales

Bactéries gram-pathogènes

Neuroimmunité

Analyse protéomique

Chromogranin A

Intestinal infections

Bacteria-peptide interactions

Chromolaena odorata

571.9

616.3

Étude des mécanismes d’extraction lipidique par le peptide mélittine et la protéine BSP1

Therrien, Alexandre

12 1900

Les peptides et protéines extracteurs de lipides (PEL) se lient aux membranes lipidiques puis en extraient des lipides en formant de plus petits auto-assemblages, un phénomène qui peut aller jusqu'à la fragmentation des membranes. Dans la nature, cette extraction se produit sur une gamme de cellules et entraîne des conséquences variées, comme la modification de la composition de la membrane et la mort de la cellule. Cette thèse se penche sur l’extraction lipidique, ou fragmentation, induite par le peptide mélittine et la protéine Binder-of-SPerm 1 (BSP1) sur des membranes lipidiques modèles. Pour ce faire, des liposomes de différentes compositions sont préparés et incubés avec la mélittine ou la BSP1. L'association aux membranes est déterminée par la fluorescence intrinsèque des PEL, tandis que l'extraction est caractérisée par une plateforme analytique combinant des tests colorimétriques et des analyses en chromatographie en phase liquide et spectrométrie de masse (LCMS). La mélittine fait partie des peptides antimicrobiens cationiques, un groupe de PEL très répandu chez les organismes vivants. Ces peptides sont intéressants du point du vue médical étant donné leur mode d’action qui vise directement les lipides des membranes. Plusieurs de ceux-ci agissent sur les membranes des bactéries selon le mécanisme dit « en tapis », par lequel ils s’adsorbent à leur surface, forment des pores et ultimement causent leur fragmentation. Dans cette thèse, la mélittine est utilisée comme peptide modèle afin d’étudier le mécanisme par lequel les peptides antimicrobiens cationiques fragmentent les membranes. Les résultats montrent que la fragmentation des membranes de phosphatidylcholines (PC) est réduite par une déméthylation graduelle de leur groupement ammonium. L'analyse du matériel fragmenté révèle que les PC sont préférentiellement extraites des membranes, dû à un enrichissement local en PC autour de la mélittine à l'intérieur de la membrane. De plus, un analogue de la mélittine, dont la majorité des résidus cationiques sont neutralisés, est utilisé pour évaluer le rôle du caractère cationique de la mélittine native. La neutralisation augmente l'affinité du peptide pour les membranes neutres et anioniques, réduit la fragmentation des membranes neutres et augmente la fragmentation des membranes anioniques. Malgré les interactions électrostatiques entre le peptide cationique et les lipides anioniques, aucune spécificité lipidique n'est observée dans l'extraction. La BSP1 est la protéine la plus abondante du liquide séminal bovin et constitue un autre exemple de PEL naturel important. Elle se mélange aux spermatozoïdes lors de l’éjaculation et extrait des lipides de leur membrane, notamment le cholestérol et les phosphatidylcholines. Cette étape cruciale modifie la composition lipidique de la membrane du spermatozoïde, ce qui faciliterait par la suite la fécondation de l’ovule. Cependant, le contact prolongé de la protéine avec les spermatozoïdes endommagerait la semence. Cette thèse cherche donc à approfondir notre compréhension de ce délicat phénomène en étudiant le mécanisme moléculaire par lequel la protéine fragmente les membranes lipidiques. Les résultats des présents travaux permettent de proposer un mécanisme d’extraction lipidique en 3 étapes : 1) L'association à l’interface des membranes; 2) La relocalisation de l’interface vers le cœur lipidique; 3) La fragmentation des membranes. La BSP1 se lie directement à deux PC à l'interface; une quantité suffisante de PC dans les membranes est nécessaire pour permettre l'association et la fragmentation. Cette liaison spécifique ne mène généralement pas à une extraction lipidique sélective. L'impact des insaturations des chaînes lipidiques, de la présence de lysophosphatidylcholines, de phosphatidyléthanolamine, de cholestérol et de lipides anioniques est également évalué. Les présentes observations soulignent la complexe relation entre l'affinité d'un PEL pour une membrane et le niveau de fragmentation qu'il induit. L'importance de la relocalisation des PEL de l'interface vers le cœur hydrophobe des membranes pour permettre leur fragmentation est réitérée. Cette fragmentation semble s'accompagner d'une extraction lipidique préférentielle seulement lorsqu'une séparation de phase est induite au niveau de la membrane, nonobstant les interactions spécifiques PEL-lipide. Les prévalences des structures amphiphiles chez certains PEL, ainsi que de la fragmentation en auto-assemblages discoïdaux sont discutées. Finalement, le rôle des interactions électrostatiques entre les peptides antimicrobiens cationiques et les membranes bactériennes anioniques est nuancé : les résidus chargés diminueraient l'association des peptides aux membranes neutres suite à l'augmentation de leur énergie de solvatation. / Lipid-extracting peptides and proteins (LEPs) bind to lipid membranes, extract lipids in the form of smaller auto-assemblies, and ultimately fragment membranes. In nature, this lipid extraction occurs in many different cell systems and causes various consequences, such as a modification of the membrane lipid composition or the cell death. This thesis focuses on the lipid extraction, or fragmentation, induced by the peptide melittin and the protein Binder-of-SPerm 1 (BSP1) on model lipid membranes. To this end, liposomes of different composition are prepared and incubated with melittin or BSP1. The association to membranes is determined by the LEPs intrinsic fluorescence, while the extraction is characterized by a combination of colorimetric phosphorus assays and liquid chromatography-mass spectrometry analyses (LCMS). Melittin is a cationic antimicrobial peptide, a very common category of LEP found in living organisms. Cationic antimicrobial peptides are interesting to medicine because they directly target membrane lipids. The action of many of these peptides is described by the carpet-like mechanism, by which they adsorb to membrane surface, induce the formation of pores and then cause the fragmentation of the membranes. In this thesis, melittin is used as a model peptide in order to study the mechanism by which cationic antimicrobial peptides fragment lipid membranes. Results show that the phosphocholine (PC) membrane fragmentation is reduced by a gradual demethylation of the ammonium group. Analysis of the fragmented material reveals that PC are preferentially extracted from membranes, due to a local enrichment in PC near melittin in the membrane. Furthermore, a melittin analogue, for which a majority of its cationic residues were neutralized, is used to investigate the role of the cationic character of native melittin. The neutralization increases the peptide affinity for neutral and anionic membranes, reduces fragmentation of neutral membranes and increases fragmentation of anionic membranes. Despite electrostatic interactions between the cationic peptide and the anionic lipids, no lipid specificity is observed in the extraction. BSP1 is the most abundant protein of the bovine seminal plasma and constitutes another example of important LEP found in nature. Upon ejaculation, it mixes with spermatozoa and extracts membrane lipids, such as cholesterol and phosphatidylcholines. This crucial process modulates the lipid composition of sperm membranes, which would then facilitate egg fertilization. However, a prolonged contact between the protein and spermatozoa could damage the semen. This thesis is looking to deepen our understanding of this delicate phenomenon by studying the molecular mechanism by which this protein fragments lipid membranes. Results of the present work suggest a 3-step mechanism for the extraction: 1) Association to membrane interface; 2) Relocation towards the lipid core; 3) Fragmentation of membranes. BSP1 binds directly to two interfacial PC; a sufficient quantity of PC in membranes is necessary for protein association and fragmentation. This specific binding generally does not lead to specificity in the lipid extraction. The impact of unsaturation of the lipid chains, of the presence of lysophosphatidylcholines, of phosphatidylethanolamines, of cholesterol and of anionic lipids is also studied. The present observations underline the complex relationship between a LEP affinity for membranes and the level of fragmentation it induces. The importance of LEP relocation, from the interface to the hydrophobic core of the membranes, for fragmentation is reiterated. This fragmentation seems to be lipid specific only when a phase separation of the lipids occurs in the membrane, notwithstanding specific LEP-lipid interactions. The prevalence of amphipathic structures in certain LEPs, as well as of the auto-assembled discoidal structures resulting from fragmentation is discussed. Finally, the role of electrostatic interactions between cationic antimicrobial peptides and anionic bacterial membranes is detailed: charged residues lower peptide association to neutral membrane due to an increase of their free energy of solvation.

Extraction lipidique

Fragmentation

Spécificité lipidique

Mélittine

BSP1

PDC-109

Analogue de mélittine

Interactions lipide-protéine

Interaction lipide-peptide

Liposomes

Lipid extraction

Lipid specificity

Melittin

Melittin analogue

Lipid-protein interactions

Lipid-peptide interactions

Liposomes