Sandra Peherstorfer1, Hans Henning Brewitz2, Ajay Abisheck Paul George2, Amelie Wißbrock2, Jana Maria Adam2, Lutz Schmitt3, Diana Imhof4. 1. Institute of Biochemistry, University of Düsseldorf, 40255 Düsseldorf, Germany. 2. Pharmaceutical Biochemistry and Bioanalytics, Pharmaceutical Institute, University of Bonn, 53121 Bonn, Germany. 3. Institute of Biochemistry, University of Düsseldorf, 40255 Düsseldorf, Germany. Electronic address: Lutz.Schmitt@hhu.de. 4. Pharmaceutical Biochemistry and Bioanalytics, Pharmaceutical Institute, University of Bonn, 53121 Bonn, Germany. Electronic address: dimhof@uni-bonn.de.
Abstract
BACKGROUND: Tight regulation of heme homeostasis is a critical mechanism in pathogenic bacteria since heme functions as iron source and prosthetic group, but is also toxic at elevated concentrations. Hemolysin-activating lysine-acyltransferase (HlyC) from Escherichia coli is crucial for maturation of hemolysin A, which lyses several mammalian cells including erythrocytes liberating large amounts of heme for bacterial uptake. A possible impact and functional consequences of the released heme on events employing bacterial HlyC have remained unexplored. METHODS: Heme binding to HlyC was investigated using UV/vis and SPR spectroscopy. Functional impact of heme association was examined using an in vitro hemolysis assay. The interaction was further studied by homology modeling, molecular docking and dynamics simulations. RESULTS: We identified HlyC as potential heme-binding protein possessing heme-regulatory motifs. Using wild-type protein and a double alanine mutant we demonstrated that heme binds to HlyC via histidine 151 (H151). We could show further that heme inhibits the enzymatic activity of wild-type HlyC. Computational studies illustrated potential interaction sites in addition to H151 confirming the results from spectroscopy indicating more than one heme-binding site. CONCLUSIONS: Taken together, our results reveal novel insights into heme-protein interactions and regulation of a component of the heme uptake system in one of the major causative agents of urinary tract infections in humans. GENERAL SIGNIFICANCE: This study points to a possible novel mechanism of regulation as present in many uropathogenic E. coli strains at an early stage of heme iron acquisition from erythrocytes for subsequent internalization by the bacterial heme-uptake machinery.
BACKGROUND: Tight regulation of heme homeostasis is a critical mechanism in pathogenic bacteria since heme functions as iron source and prosthetic group, but is also toxic at elevated concentrations. Hemolysin-activating lysine-acyltransferase (HlyC) from Escherichia coli is crucial for maturation of hemolysin A, which lyses several mammalian cells including erythrocytes liberating large amounts of heme for bacterial uptake. A possible impact and functional consequences of the released heme on events employing bacterial HlyC have remained unexplored. METHODS:Heme binding to HlyC was investigated using UV/vis and SPR spectroscopy. Functional impact of heme association was examined using an in vitro hemolysis assay. The interaction was further studied by homology modeling, molecular docking and dynamics simulations. RESULTS: We identified HlyC as potential heme-binding protein possessing heme-regulatory motifs. Using wild-type protein and a double alanine mutant we demonstrated that heme binds to HlyC via histidine 151 (H151). We could show further that heme inhibits the enzymatic activity of wild-type HlyC. Computational studies illustrated potential interaction sites in addition to H151 confirming the results from spectroscopy indicating more than one heme-binding site. CONCLUSIONS: Taken together, our results reveal novel insights into heme-protein interactions and regulation of a component of the heme uptake system in one of the major causative agents of urinary tract infections in humans. GENERAL SIGNIFICANCE: This study points to a possible novel mechanism of regulation as present in many uropathogenic E. coli strains at an early stage of hemeiron acquisition from erythrocytes for subsequent internalization by the bacterial heme-uptake machinery.
Authors: Charlotte A Bäuml; Thomas Schmitz; Ajay Abisheck Paul George; Monica Sudarsanam; Kornelia Hardes; Torsten Steinmetzer; Lori A Holle; Alisa S Wolberg; Bernd Pötzsch; Johannes Oldenburg; Arijit Biswas; Diana Imhof Journal: J Med Chem Date: 2019-03-21 Impact factor: 7.446
Authors: Marie-Thérèse Hopp; Daniel Domingo-Fernández; Yojana Gadiya; Milena S Detzel; Regina Graf; Benjamin F Schmalohr; Alpha T Kodamullil; Diana Imhof; Martin Hofmann-Apitius Journal: Biomolecules Date: 2021-04-27
Authors: Amelie Wißbrock; Nishit B Goradia; Amit Kumar; Ajay Abisheck Paul George; Toni Kühl; Peter Bellstedt; Ramadurai Ramachandran; Patrick Hoffmann; Kerstin Galler; Jürgen Popp; Ute Neugebauer; Kornelia Hampel; Bastian Zimmermann; Susanne Adam; Maximilian Wiendl; Gerhard Krönke; Iqbal Hamza; Stefan H Heinemann; Silke Frey; Axel J Hueber; Oliver Ohlenschläger; Diana Imhof Journal: Sci Rep Date: 2019-11-15 Impact factor: 4.379
Authors: Amit Luthra; Jairo M Montezuma-Rusca; Carson J La Vake; Morgan LeDoyt; Kristina N Delgado; Timothy C Davenport; Mary Fiel-Gan; Melissa J Caimano; Justin D Radolf; Kelly L Hawley Journal: PLoS Pathog Date: 2020-09-16 Impact factor: 6.823