Dendrimeric template of Plasmodium falciparum histidine rich protein II repeat motifs bearing Asp→Asn mutation exhibits heme binding and β-hematin formation

Plasmodium falciparum (Pf) employs a crucial PfHRPII catalyzed reaction that converts toxic heme into hemozoin. Understanding heme polymerization mechanism is the first step for rational design of new drugs, targeting this pathway. Heme binding and hemozoin formation have been ascribed to PfHRPII as...

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Veröffentlicht in:	PloS one 2014-11, Vol.9 (11), p.e112087
Hauptverfasser:	Kumari, Pinky, Sahal, Dinkar, Chauhan, Virander S
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Sprache:	eng
Schlagworte:	Amino Acid Motifs Amino Acid Sequence Amino acids Antigens, Protozoan - chemistry Asparagine - genetics Aspartic Acid - genetics Bicarbonates - metabolism Binding Binding Sites Biochemistry Biology and Life Sciences Biotechnology Chromatography, High Pressure Liquid Chromatography, Reverse-Phase Dendrimers - chemistry Drug delivery Drug development Drugs Forming Genetic engineering Heme Heme - metabolism Hemeproteins - metabolism Hemozoin Histidine Hydrogen Ionic interactions Kinetics Laboratories Malaria Mass Spectrometry Medicine and Health Sciences Metals Molecular Sequence Data Mutation Mutation - genetics Parasites Peptides pH effects Physical Sciences Plasmodium falciparum Polymerization Protein Binding Protein Stability Proteins Protozoan Proteins - chemistry Repetitive Sequences, Amino Acid Residues Spectrum Analysis Structure-Activity Relationship Titrimetry
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creator	Kumari, Pinky Sahal, Dinkar Chauhan, Virander S
description	Plasmodium falciparum (Pf) employs a crucial PfHRPII catalyzed reaction that converts toxic heme into hemozoin. Understanding heme polymerization mechanism is the first step for rational design of new drugs, targeting this pathway. Heme binding and hemozoin formation have been ascribed to PfHRPII aspartate carboxylate-heme metal ionic interactions. To investigate, if this ionic interaction is indeed pivotal, we examined the comparative heme binding and β-hematin forming abilities of a wild type dendrimeric peptide BNT1 {harboring the native sequence motif of PfHRPII (AHHAHHAADA)} versus a mutant dendrimeric peptide BNTM {in which ionic Aspartate residues have been replaced by the neutral Asparaginyl residues (AHHAHHAANA)}. UV and IR data reported here reveal that at pH 5, both BNT1 and BNTM exhibit comparable heme binding as well as β-hematin forming abilities, thus questioning the role of PfHRPII aspartate carboxylate-heme metal ionic interactions in heme binding and β-hematin formation. Based on our data and information in the literature we suggest the possible role of weak dispersive interactions like N-H···π and lone-pair···π in heme binding and hemozoin formation.
doi_str_mv	10.1371/journal.pone.0112087
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Understanding heme polymerization mechanism is the first step for rational design of new drugs, targeting this pathway. Heme binding and hemozoin formation have been ascribed to PfHRPII aspartate carboxylate-heme metal ionic interactions. To investigate, if this ionic interaction is indeed pivotal, we examined the comparative heme binding and β-hematin forming abilities of a wild type dendrimeric peptide BNT1 {harboring the native sequence motif of PfHRPII (AHHAHHAADA)} versus a mutant dendrimeric peptide BNTM {in which ionic Aspartate residues have been replaced by the neutral Asparaginyl residues (AHHAHHAANA)}. UV and IR data reported here reveal that at pH 5, both BNT1 and BNTM exhibit comparable heme binding as well as β-hematin forming abilities, thus questioning the role of PfHRPII aspartate carboxylate-heme metal ionic interactions in heme binding and β-hematin formation. 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Understanding heme polymerization mechanism is the first step for rational design of new drugs, targeting this pathway. Heme binding and hemozoin formation have been ascribed to PfHRPII aspartate carboxylate-heme metal ionic interactions. To investigate, if this ionic interaction is indeed pivotal, we examined the comparative heme binding and β-hematin forming abilities of a wild type dendrimeric peptide BNT1 {harboring the native sequence motif of PfHRPII (AHHAHHAADA)} versus a mutant dendrimeric peptide BNTM {in which ionic Aspartate residues have been replaced by the neutral Asparaginyl residues (AHHAHHAANA)}. UV and IR data reported here reveal that at pH 5, both BNT1 and BNTM exhibit comparable heme binding as well as β-hematin forming abilities, thus questioning the role of PfHRPII aspartate carboxylate-heme metal ionic interactions in heme binding and β-hematin formation. Based on our data and information in the literature we suggest the possible role of weak dispersive interactions like N-H···π and lone-pair···π in heme binding and hemozoin formation.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>25398028</pmid><doi>10.1371/journal.pone.0112087</doi><oa>free_for_read</oa></addata></record>
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subjects	Amino Acid Motifs Amino Acid Sequence Amino acids Antigens, Protozoan - chemistry Asparagine - genetics Aspartic Acid - genetics Bicarbonates - metabolism Binding Binding Sites Biochemistry Biology and Life Sciences Biotechnology Chromatography, High Pressure Liquid Chromatography, Reverse-Phase Dendrimers - chemistry Drug delivery Drug development Drugs Forming Genetic engineering Heme Heme - metabolism Hemeproteins - metabolism Hemozoin Histidine Hydrogen Ionic interactions Kinetics Laboratories Malaria Mass Spectrometry Medicine and Health Sciences Metals Molecular Sequence Data Mutation Mutation - genetics Parasites Peptides pH effects Physical Sciences Plasmodium falciparum Polymerization Protein Binding Protein Stability Proteins Protozoan Proteins - chemistry Repetitive Sequences, Amino Acid Residues Spectrum Analysis Structure-Activity Relationship Titrimetry
title	Dendrimeric template of Plasmodium falciparum histidine rich protein II repeat motifs bearing Asp→Asn mutation exhibits heme binding and β-hematin formation
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