Solution NMR characterization of apical membrane antigen 1 and small molecule interactions as a basis for designing new antimalarials

Plasmodium falciparum apical membrane antigen 1 (PfAMA1) plays an important role in the invasion by merozoites of human red blood cells during a malaria infection. A key region of PfAMA1 is a conserved hydrophobic cleft formed by 12 hydrophobic residues. As anti‐apical membrane antigen 1 antibodies...

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Published in:Journal of molecular recognition 2016-06, Vol.29 (6), p.281-291
Main Authors: Krishnarjuna, Bankala, Lim, San Sui, Devine, Shane M., Debono, Cael O., Lam, Raymond, Chandrashekaran, Indu R., Jaipuria, Garima, Yagi, Hiromasa, Atreya, Hanudatta S., Scanlon, Martin J., MacRaild, Christopher A., Scammells, Peter J., Norton, Raymond S.
Format: Article
Language:English
Subjects:
AMA1
Amino Acid Sequence
Antigens
Antigens, Protozoan - chemistry
Antigens, Protozoan - metabolism
Antimalarials - chemistry
Antimalarials - metabolism
Backbone
Benzimidazoles - chemistry
Benzimidazoles - metabolism
Binding
Binding Sites
Drug Design
fragments
Humans
isotopic labelling
Labelling
Magnetic resonance
Membrane Proteins - chemistry
Membrane Proteins - metabolism
Membranes
Models, Molecular
NMR
Nuclear magnetic resonance
Nuclear Magnetic Resonance, Biomolecular
Plasmodium falciparum
Plasmodium falciparum - metabolism
Protein Binding
Protein Conformation
Protozoan Proteins - chemistry
Protozoan Proteins - metabolism
Pyrazoles - chemistry
Pyrazoles - metabolism
resonance assignments
Small Molecule Libraries - chemistry
Small Molecule Libraries - metabolism
SPR
Thiazoles - chemistry
Thiazoles - metabolism
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container_end_page 291
container_issue 6
container_start_page 281
container_title Journal of molecular recognition
container_volume 29
creator Krishnarjuna, Bankala
Lim, San Sui
Devine, Shane M.
Debono, Cael O.
Lam, Raymond
Chandrashekaran, Indu R.
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Yagi, Hiromasa
Atreya, Hanudatta S.
Scanlon, Martin J.
MacRaild, Christopher A.
Scammells, Peter J.
Norton, Raymond S.
description Plasmodium falciparum apical membrane antigen 1 (PfAMA1) plays an important role in the invasion by merozoites of human red blood cells during a malaria infection. A key region of PfAMA1 is a conserved hydrophobic cleft formed by 12 hydrophobic residues. As anti‐apical membrane antigen 1 antibodies and other inhibitory molecules that target this hydrophobic cleft are able to block the invasion process, PfAMA1 is an attractive target for the development of strain‐transcending antimalarial agents. As solution nuclear magnetic resonance spectroscopy is a valuable technique for the rapid characterization of protein–ligand interactions, we have determined the sequence‐specific backbone assignments for PfAMA1 from two P. falciparum strains, FVO and 3D7. Both selective labelling and unlabelling strategies were used to complement triple‐resonance experiments in order to facilitate the assignment process. We have then used these assignments for mapping the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected on the basis of their affinities measured from surface plasmon resonance binding experiments. Among the compounds tested, benzimidazoles showed binding to a similar region on both FVO and 3D7 PfAMA1, suggesting that these compounds are promising scaffolds for the development of novel PfAMA1 inhibitors. Copyright © 2016 John Wiley & Sons, Ltd. Backbone resonance assignments for apical membrane antigen 1 (AMA1) (DI + DII) from FVO and 3D7 strains of Plasmodium falciparum were determined using triple‐resonance nuclear magnetic resonance experiments together with different isotope labelling methods. Two‐dimensional [1H‐15N]‐transverse relaxation optimized spectroscopy experiments were used to map the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected from surface plasmon resonance binding experiments based on their affinities for AMA1. Our results suggest that benzimidazoles bind to a similar region on both FVO and 3D7 P. falciparum AMA1 and, thus, that they are promising scaffolds for the development of new P. falciparum AMA1 inhibitors.
doi_str_mv 10.1002/jmr.2529
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A key region of PfAMA1 is a conserved hydrophobic cleft formed by 12 hydrophobic residues. As anti‐apical membrane antigen 1 antibodies and other inhibitory molecules that target this hydrophobic cleft are able to block the invasion process, PfAMA1 is an attractive target for the development of strain‐transcending antimalarial agents. As solution nuclear magnetic resonance spectroscopy is a valuable technique for the rapid characterization of protein–ligand interactions, we have determined the sequence‐specific backbone assignments for PfAMA1 from two P. falciparum strains, FVO and 3D7. Both selective labelling and unlabelling strategies were used to complement triple‐resonance experiments in order to facilitate the assignment process. We have then used these assignments for mapping the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected on the basis of their affinities measured from surface plasmon resonance binding experiments. Among the compounds tested, benzimidazoles showed binding to a similar region on both FVO and 3D7 PfAMA1, suggesting that these compounds are promising scaffolds for the development of novel PfAMA1 inhibitors. Copyright © 2016 John Wiley &amp; Sons, Ltd. Backbone resonance assignments for apical membrane antigen 1 (AMA1) (DI + DII) from FVO and 3D7 strains of Plasmodium falciparum were determined using triple‐resonance nuclear magnetic resonance experiments together with different isotope labelling methods. Two‐dimensional [1H‐15N]‐transverse relaxation optimized spectroscopy experiments were used to map the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected from surface plasmon resonance binding experiments based on their affinities for AMA1. 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Two‐dimensional [1H‐15N]‐transverse relaxation optimized spectroscopy experiments were used to map the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected from surface plasmon resonance binding experiments based on their affinities for AMA1. 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Two‐dimensional [1H‐15N]‐transverse relaxation optimized spectroscopy experiments were used to map the binding sites for small molecules, including benzimidazoles, pyrazoles and 2‐aminothiazoles, which were selected from surface plasmon resonance binding experiments based on their affinities for AMA1. Our results suggest that benzimidazoles bind to a similar region on both FVO and 3D7 P. falciparum AMA1 and, thus, that they are promising scaffolds for the development of new P. falciparum AMA1 inhibitors.</abstract><cop>England</cop><pub>Blackwell Publishing Ltd</pub><pmid>26804042</pmid><doi>10.1002/jmr.2529</doi><tpages>11</tpages></addata></record>
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ispartof Journal of molecular recognition, 2016-06, Vol.29 (6), p.281-291
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subjects AMA1
Amino Acid Sequence
Antigens
Antigens, Protozoan - chemistry
Antigens, Protozoan - metabolism
Antimalarials - chemistry
Antimalarials - metabolism
Backbone
Benzimidazoles - chemistry
Benzimidazoles - metabolism
Binding
Binding Sites
Drug Design
fragments
Humans
isotopic labelling
Labelling
Magnetic resonance
Membrane Proteins - chemistry
Membrane Proteins - metabolism
Membranes
Models, Molecular
NMR
Nuclear magnetic resonance
Nuclear Magnetic Resonance, Biomolecular
Plasmodium falciparum
Plasmodium falciparum - metabolism
Protein Binding
Protein Conformation
Protozoan Proteins - chemistry
Protozoan Proteins - metabolism
Pyrazoles - chemistry
Pyrazoles - metabolism
resonance assignments
Small Molecule Libraries - chemistry
Small Molecule Libraries - metabolism
SPR
Thiazoles - chemistry
Thiazoles - metabolism
title Solution NMR characterization of apical membrane antigen 1 and small molecule interactions as a basis for designing new antimalarials
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