The interaction of human carbonic anhydrase II to solid surfaces and its applications

Udd, Annika

January 2009

<p><p>The adsorption of proteins to solid surfaces has been extensively investigated during the past 20-30 years. The knowledge can be applied in biotechnological applications in for example immunoassays and biosensors. Human carbonic anhydrase II is a widely studied protein and the CO₂-activity makes it an interesting candidate for biotechnological purposes. To make this possible, the factors affecting the adsorption of proteins have to be mapped. The stability of the protein is under great influence of the adsorption and the protein tends to undergo conformational changes leading to a molten globule like state upon adsorption. The stability of a protein also affects the extent of conformational changes and the nature of the adsorption. A more stable protein, adsorbs with less structural changes as a consequence of adsorption, and desorbs from the surface more rapidly than a less stable one. Also the hydrophobicity, charge and area of the surface are affecting the interaction with the protein. Still, the same adsorption pattern is noticed for the same protein at different surfaces, leading to the conclusion that the properties of the protein affect the interaction, rather than the properties of the surface. Biosensors containing carbonic anhydrase have been developed. These make measurement and detection of zinc ions possible. To be able to use carbonic anhydrase as a potential agent in biotechnology, attached to solid surfaces, the protein has to be biotechnologically engineered to get a more stable structure, or else the denaturation will destroy this possibility.</p></p>

Human carbonic anhydrase II

solid surfaces

adsorption

applications

Biochemistry

Biokemi

The interaction of human carbonic anhydrase II to solid surfaces and its applications

Udd, Annika

January 2009

The adsorption of proteins to solid surfaces has been extensively investigated during the past 20-30 years. The knowledge can be applied in biotechnological applications in for example immunoassays and biosensors. Human carbonic anhydrase II is a widely studied protein and the CO2-activity makes it an interesting candidate for biotechnological purposes. To make this possible, the factors affecting the adsorption of proteins have to be mapped. The stability of the protein is under great influence of the adsorption and the protein tends to undergo conformational changes leading to a molten globule like state upon adsorption. The stability of a protein also affects the extent of conformational changes and the nature of the adsorption. A more stable protein, adsorbs with less structural changes as a consequence of adsorption, and desorbs from the surface more rapidly than a less stable one. Also the hydrophobicity, charge and area of the surface are affecting the interaction with the protein. Still, the same adsorption pattern is noticed for the same protein at different surfaces, leading to the conclusion that the properties of the protein affect the interaction, rather than the properties of the surface. Biosensors containing carbonic anhydrase have been developed. These make measurement and detection of zinc ions possible. To be able to use carbonic anhydrase as a potential agent in biotechnology, attached to solid surfaces, the protein has to be biotechnologically engineered to get a more stable structure, or else the denaturation will destroy this possibility.

Human carbonic anhydrase II

solid surfaces

adsorption

applications

Biochemistry

Biokemi

Human Carbonic Anhydrase Ii; Preparation, Metal-Substitution, Activity, and Inhibition

Wilson, David L

14 August 2015

This report details the activities and inhibition of metal-substituted human carbonic anhydrase II (M-HCA-II). The traditional activities (hydrolysis of CO2 and para-nitrophenol acetate) in addition to new activities (oxidation of 2-aminophenol, disproportionation of H2O2, and disproportionation of superoxide) were investigated. Values reported for the relative hydrolytic activities of M-HCA-IIs are reported here for the first time, ranging from 47.5 % (plus or minus 0.6) to 86 % (plus or minus 4) for the hydrolysis of CO2 and from 0.299 % (plus or minus 0.012) to 4.72 % (plus or minus 0.015) for the hydrolysis of para-nitrophenol acetate. With respect to new activities, only the oxidation of 2-aminophenol was observed. Turnover was observed for Fe-HCA-II (kcat/KM = 3.6 plus or minus 1.3 mM-1 s-1) and Cu-HCA-II (kcat/KM = 8 plus or minus 2 mM-1 s-1). Inhibition of Zn-, (di-substituted) Cu2-, and Cu/Zn-HCA-II hydrolysis of CO2 and para-nitrophenol acetate by sulfanilamide, coumarin, and ortho-coumaric acid were investigated. Sulfanilamide was shown to inhibit: Zn-HCA-II, Cu2-HCA-II, and Cu/Zn-HCA-II - (with CO2) KM = 8.9 plus or minus 1.1 microM, 11 plus or minus 2 microM, 8.8 plus or minus 1.4 microM and (with p-nitrophenyl acetate) KM = 8.4 plus or minus 1.0 microM, (none), 8.4 plus or minus 1.4 microM, respectively. No inhibition was observed for coumarin or ortho-coumaric acid or its derivatives for any CAs studied.

human carbonic anhydrase II

HCA-II

metal-substitution

copper

cobalt

manganese

iron

nickel

sulfanilamide

coumarin

kinetics

2-aminophenol

catalase

superoxide dismutase

peroxidase

Reconnaissance de surfaces protéiques par des foldamères d'oligoamides aromatiques / Recognition of protein surfaces by aromatic oligoamide foldamers

Buratto, Jeremie

07 January 2014

Les interactions protéine - protéine sont au centre de nombreux processus biologiques, et représentent des cibles thérapeutiques pertinentes pour le traitement de certaines maladies. La conception de molécules antagonistes visant à inhiber ces interactions requiert la reconnaissance spécifique d’une des surfaces protéiques impliquées. Les foldamères de type oligoamides de quinoline constituent de bons candidats. Leur production et leur fonctionnalisation sont relativement aisées. Ils adoptent des structures hélicoïdales semblables à celles rencontrées dans les protéines. Grâce à différentes techniques biophysiques (CD, SPR, diffraction des rayons X), nous montrons que ces molécules sont aptes à reconnaître une surface protéique. Deux protéines cibles ont été choisies : l’interleukine 4 et l’anhydrase carbonique humaine II.La stratégie retenue dans ce travail (ancrage du foldamère à la protéine via un bras espaceur) nous a permis d’obtenir des informations structurales sur les interactions foldamère – protéine avant toute optimisation de ces interactions. La première structure 3D d’un complexe foldamère de quinoline complexée à une protéine est décrite. / Protein-protein interactions are a central issue in biological processes and represent relevant therapeutic targets for the treatment of diseases. The design of antagonistic molecules directed towards the disruption of these interactions requires the specific recognition of protein surfaces. Quinoline oligoamide foldamers present all the properties to reach that point. They are easily synthesized and fold into helices (similar to α helices) which can be decorated. Thanks to biophysical studies (CD, SPR, RX diffraction), we demonstrate that these molecules are able to recognize protein surfaces. Two proteins have been studied: the human interleukin 4 and the human carbonic anhydrase II.The applied strategy (keeping the foldamer close to the protein surface via a linker) allowed us to gather structural information about foldamer protein interactions before any strong binding is established. The first crystal structure between a protein and an aromatic amide foldamer is reported.

Reconnaissance de surface protéique

Foldamères d’oligoamides de quinoline

Interactions foldamère - protéine

Interleukine 4 humaine

Anhydrase carbonique humaine II

Proteic surface recognition

Quinoline oligoamide foldamer

Oldamer - protein interactions

Human interleukin 4

Human carbonic anhydrase II

Reconnaissance de surfaces de protéines par les foldamères d'oligoamides aromatiques / Protein surface recognition using aromatic oligoamide foldamers

Vallade, Maëlle

29 September 2016

Les protéines étant au coeur d’un grand nombre de processus biologiques, elles sont des cibles thérapeutiques largement convoitées. Les foldamères, notamment les oligoamides aromatiques, présentent une structure bien définie, prévisible, stable en solution et à l’état solide. Ajouté à cela, leur taille moyenne en fait de bons candidats pour la reconnaissance de surfaces de protéines, grâce à leurs chaînes latérales protéinogènes. Cette thèse présente les différentes étapes de leur conception, de la synthèse de la brique constitutive à l’obtention d’un foldamère fonctionnalisé grâce à la synthèse en phase supportée. La stratégie d’investigation des interactions entre un foldamère et une protéine est détaillée. L’originalité réside dans le fait que le foldamère est ancré directement à la protéine et le dichroïsme circulaire sert de méthode de screening. L’analyse structurale des hits permet de générer de nouveaux foldamères dans le but d’améliorer les interactions avec la protéine : c’est une stratégie itérative. Cette approche est appliquée premièrement à l’anhydrase carbonique humaine II, protéine modèle qui sert de preuve de principe pour cette approche ; puis à des protéines d’intérêt thérapeutique plus important : l’interleukine 4 et la cyclophiline A. Enfin, une étude concernant l’introduction de flexibilité au sein de foldamères de quinolines est présentée. / Since proteins are at the basis of many biological processes, they are widely studied as therapeutic targets. Aromatic oligoamide foldamers have a very well defined structure, predictable and stable both in solution and solid state. Because of their medium size, they appear as potent candidates for protein surface recognition thanks to their proteinogenic side chains. This manuscript presents the different steps of their design, from the scaffold’s synthesis to obtaining a functionalized foldamer, thanks to solid phase synthesis. The strategy to investigate protein/foldamer interactions will be detailed. Its originality lies in the fact that the foldamer is anchored to the protein. Circular dichroism has been used as a screening method to detect foldamer/protein interactions. Structural analysis of the hits will allow the design of new foldamers with the objective of enhancing foldamer/protein interactions: it is an iterative strategy. This approach has been applied firstly to human carbonic anhydrase II (HCA). This protein is used as a model system and proof of concept before moving to more therapeutically relevant proteins; interleukin 4 and cyclophilin A. Finally, a study on introducing flexibility in quinoline foldamers is presented.

Foldamère d’oligoamides aromatiques

Reconnaissance de surface de protéine

Quinoline

Anhydrase carbonique humaine II (HCA),

Interleukine 4 (IL-4)

Cyclophiline A (CypA)

Analyse structurale

Cinétique d’inversion d’hélicité

Aromatic oligoamide foldamers

Protein surface recognition

Quinoline

Human carbonic anhydrase II (HCA)

Interleukin 4 (IL-4)

Cyclophilin A (CypA)

Structural analysis

Kinetic of handedness inversion