Your search keyword '"Peetz O"' showing total 9 results

1. Membrane insertion mechanism and molecular assembly of the bacteriophage lysis toxin ΦX174-E.

Author

Mezhyrova J, Martin J, Peetz O, Dötsch V, Morgner N, Ma Y, and Bernhard F

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacteriophage phi X 174 metabolism, Bacteriophage phi X 174 pathogenicity, Binding Sites, Cell Wall genetics, Cell Wall metabolism, Cell Wall virology, Dimyristoylphosphatidylcholine chemistry, Dimyristoylphosphatidylcholine metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Gene Expression, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Nanoparticles chemistry, Peptidylprolyl Isomerase metabolism, Phosphatidylglycerols chemistry, Phosphatidylglycerols metabolism, Protein Binding, Protein Conformation, Protein Engineering methods, Protein Interaction Domains and Motifs, Protein Multimerization, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Solubility, Toxins, Biological genetics, Toxins, Biological metabolism, Transferases (Other Substituted Phosphate Groups) genetics, Transferases (Other Substituted Phosphate Groups) metabolism, Antibiosis genetics, Bacteriophage phi X 174 genetics, Escherichia coli virology, Escherichia coli Proteins genetics, Lysogeny genetics, Peptidylprolyl Isomerase genetics, Toxins, Biological chemistry

Abstract

The bacteriophage ΦX174 causes large pore formation in Escherichia coli and related bacteria. Lysis is mediated by the small membrane-bound toxin ΦX174-E, which is composed of a transmembrane domain and a soluble domain. The toxin requires activation by the bacterial chaperone SlyD and inhibits the cell wall precursor forming enzyme MraY. Bacterial cell wall biosynthesis is an important target for antibiotics; therefore, knowledge of molecular details in the ΦX174-E lysis pathway could help to identify new mechanisms and sites of action. In this study, cell-free expression and nanoparticle technology were combined to avoid toxic effects upon ΦX174-E synthesis, resulting in the efficient production of a functional full-length toxin and engineered derivatives. Pre-assembled nanodiscs were used to study ΦX174-E function in defined lipid environments and to analyze its membrane insertion mechanisms. The conformation of the soluble domain of ΦX174-E was identified as a central trigger for membrane insertion, as well as for the oligomeric assembly of the toxin. Stable complex formation of the soluble domain with SlyD is essential to keep nascent ΦX174-E in a conformation competent for membrane insertion. Once inserted into the membrane, ΦX174-E assembles into high-order complexes via its transmembrane domain and oligomerization depends on the presence of an essential proline residue at position 21. The data presented here support a model where an initial contact of the nascent ΦX174-E transmembrane domain with the peptidyl-prolyl isomerase domain of SlyD is essential to allow a subsequent stable interaction of SlyD with the ΦX174-E soluble domain for the generation of a membrane insertion competent toxin., (© 2020 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2021

2. LanI-Mediated Lantibiotic Immunity in Bacillus subtilis: Functional Analysis.

Author

Geiger C, Korn SM, Häsler M, Peetz O, Martin J, Kötter P, Morgner N, and Entian KD

Subjects

ATP-Binding Cassette Transporters metabolism, Anti-Bacterial Agents pharmacology, Bacillus subtilis genetics, Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Bacterial Proteins metabolism, Bacteriocins genetics, Drug Resistance, Bacterial, Gene Expression Regulation, Bacterial, Genes, Bacterial, Lactococcus lactis, Lipoproteins genetics, Lipoproteins immunology, Lipoproteins isolation & purification, Lipoproteins metabolism, Membrane Proteins genetics, Membrane Proteins isolation & purification, Membrane Proteins metabolism, Bacillus subtilis immunology, Bacillus subtilis metabolism, Bacteriocins metabolism, Immunity, Nisin metabolism

Abstract

Lantibiotics subtilin and nisin are produced by Bacillus subtilis and Lactococcus lactis , respectively. To prevent toxicity of their own lantibiotic, both bacteria express specific immunity proteins, called SpaI and NisI. In addition, ABC transporters SpaFEG and NisFEG prevent lantibiotic toxicity by transporting the respective peptides to the extracellular space. Although the three-dimensional structures of SpaI and NisI have been solved, very little is known about the molecular function of either lipoprotein. Using laser-induced liquid bead ion desorption (LILBID)-mass spectrometry, we show here that subtilin interacts with SpaI monomers. The expression of either SpaI or NisI in a subtilin-nonproducing B. subtilis strain resulted in the respective strain being more resistant against either subtilin or nisin. Furthermore, pore formation provided by subtilin and nisin was prevented specifically upon the expression of either SpaI or NisI. As shown with a nisin-subtilin hybrid molecule, the C-terminal part of subtilin but not any particular lanthionine ring was needed for SpaI-mediated immunity. With respect to growth, SpaI provided less immunity against subtilin than is provided by the ABC transporter SpaFEG. However, SpaI prevented pore formation much more efficiently than SpaFEG. Taken together, our data show the physiological function of SpaI as a fast immune response to protect the cellular membrane. IMPORTANCE The two lantibiotics nisin and subtilin are produced by Lactococcus lactis and Bacillus subtilis , respectively. Both peptides have strong antimicrobial activity against Gram-positive bacteria, and therefore, appropriate protection mechanisms are required for the producing strains. To prevent toxicity of their own lantibiotic, both bacteria express immunity proteins, called SpaI and NisI, and in addition, ABC transporters SpaFEG and NisFEG. Whereas it has been shown that the ABC transporters protect the producing strains by transporting the toxic peptides to the extracellular space, the exact mode of action and the physiological function of the lipoproteins during immunity are still unknown. Understanding the exact role of lantibiotic immunity proteins is of major importance for improving production rates and for the design of newly engineered peptide antibiotics. Here, we show (i) the specificity of each lipoprotein for its own lantibiotic, (ii) the specific physical interaction of subtilin with its lipoprotein SpaI, (iii) the physiological function of SpaI in protecting the cellular membrane, and (iv) the importance of the C-terminal part of subtilin for its interaction with SpaI., (Copyright © 2019 American Society for Microbiology.)

Published

2019

3. LILBID and nESI: Different Native Mass Spectrometry Techniques as Tools in Structural Biology.

Author

Peetz O, Hellwig N, Henrich E, Mezhyrova J, Dötsch V, Bernhard F, and Morgner N

Subjects

Antiporters analysis, Antiporters chemistry, Avidin analysis, Avidin chemistry, Bacterial Proteins analysis, Bacterial Proteins chemistry, Buffers, Detergents chemistry, Escherichia coli Proteins analysis, Escherichia coli Proteins chemistry, Glycerol chemistry, Lasers, Membrane Proteins analysis, Potassium Channels analysis, Potassium Channels chemistry, Spectrometry, Mass, Electrospray Ionization instrumentation, Mass Spectrometry instrumentation, Mass Spectrometry methods, Membrane Proteins chemistry

Abstract

Native mass spectrometry is applied for the investigation of proteins and protein complexes worldwide. The challenge in native mass spectrometry is maintaining the features of the proteins of interest, such as oligomeric state, bound ligands, or the conformation of the protein complex, during transfer from solution to gas phase. This is an essential prerequisite to allow conclusions about the solution state protein complex, based on the gas phase measurements. Therefore, soft ionization techniques are required. Widely used for the analysis of protein complexes are nanoelectro spray ionization (nESI) mass spectrometers. A newer ionization method is laser induced liquid bead ion desorption (LILBID), which is based on the release of protein complexes from solution phase via infrared (IR) laser desorption. We use both methods in our lab, depending on the requirements of the biological system we are interested in. Here we benchmark the performance of our LILBID mass spectrometer in comparison to a nESI instrument, regarding sample conditions, buffer and additive tolerances, dissociation mechanism and applicability towards soluble and membrane protein complexes. Graphical Abstract ᅟ.

Published

2019

4. Native mass spectrometry goes more native: investigation of membrane protein complexes directly from SMALPs.

Author

Hellwig N, Peetz O, Ahdash Z, Tascón I, Booth PJ, Mikusevic V, Diskowski M, Politis A, Hellmich Y, Hänelt I, Reading E, and Morgner N

Subjects

Lipid Bilayers chemistry, Mass Spectrometry, Models, Molecular, Particle Size, Lipids chemistry, Maleates chemistry, Membrane Proteins analysis, Styrene chemistry

Abstract

Other than more widely used methods, the use of styrene maleic acid allows the direct extraction of membrane proteins from the lipid bilayer into SMALPs keeping it in its native lipid surrounding. Here we present the combined use of SMALPs and LILBID-MS, allowing determination of oligomeric states of membrane proteins of different functionality directly from the native nanodiscs.

Published

2018

5. Lipid Conversion by Cell-Free Synthesized Phospholipid Methyltransferase Opi3 in Defined Nanodisc Membranes Supports an in Trans Mechanism.

Author

Henrich E, Löhr F, Pawlik G, Peetz O, Dötsch V, Morgner N, de Kroon AI, and Bernhard F

Subjects

Cell-Free System enzymology, Cell Membrane chemistry, Membrane Lipids chemistry, Nanostructures chemistry, Phosphatidyl-N-Methylethanolamine N-Methyltransferase chemistry, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins chemistry

Abstract

Biomembranes composed of lipids and proteins play central roles in physiological processes, and the precise balance between different lipid species is crucial for maintaining membrane function. One pathway for the biosynthesis of the abundant lipid phosphatidylcholine in eukaryotes involves a membrane-integrated phospholipid methyltransferase named Opi3 in yeast. A still unanswered question is whether Opi3 can catalyze phosphatidylcholine synthesis in trans, at membrane contact sites. While evidence for this activity was obtained from studies with complex in vitro-reconstituted systems based on endoplasmic reticulum membranes, isolated and purified Opi3 could not be analyzed. We present new insights into Opi3 activity by characterizing the in vitro-synthesized enzyme in defined hydrophobic environments. Saccharomyces cerevisiae Opi3 was cell-free synthesized and either solubilized in detergent micelles or co-translationally inserted into preformed nanodisc membranes of different lipid compositions. While detergent-solubilized Opi3 was inactive, the enzyme inserted into nanodisc membranes showed activity and stayed monomeric as revealed by native mass spectrometry. The methylation of its lipid substrate dioleoylphosphatidylmonomethylethanolamine to phosphatidylcholine was monitored by one-dimensional 31 P nuclear magnetic resonance. Phosphatidylcholine formation was observed not only in nanodiscs containing inserted Opi3 but also in nanodiscs devoid of the enzyme containing the lipid substrate. This result gives a clear indication for in trans catalysis by Opi3; i.e., it acts on the substrate in juxtaposed membranes, while in cis lipid conversion may also contribute. Our established system for the characterization of pure Opi3 in defined lipid environments may be applicable to other lipid biosynthetic enzymes and help in understanding the subcellular organization of lipid synthesis.

Published

2018

6. Insights into Cotranslational Membrane Protein Insertion by Combined LILBID-Mass Spectrometry and NMR Spectroscopy.

Author

Peetz O, Henrich E, Laguerre A, Löhr F, Hein C, Dötsch V, Bernhard F, and Morgner N

Subjects

Spectrometry, Mass, Electrospray Ionization, Lasers, Membrane Proteins analysis, Nuclear Magnetic Resonance, Biomolecular

Abstract

Cotranslational insertion of membrane proteins into defined nanoparticle membranes has been developed as an efficient process to produce highly soluble samples in native-like environments and to study lipid-dependent effects on protein structure and function. Numerous examples of the structural and functional characterization of transporters, ion channels, or G-protein-coupled receptors in cotranslationally formed nanodisc complexes demonstrate the versatility of this approach, although the basic underlying mechanisms of membrane insertion are mainly unknown. We have revealed the first aspects of the insertion of proteins into nanodiscs by combining cell-free expression, noncovalent mass spectrometry, and NMR spectroscopy. We provide evidence of cooperative insertion of homo-oligomeric complexes and demonstrate the possibility to modulate their stoichiometry by modifying reaction conditions. Additionally, we show that significant amounts of lipid are released from the nanodiscs upon insertion of larger protein complexes.

Published

2017

7. From Gene to Function: Cell-Free Electrophysiological and Optical Analysis of Ion Pumps in Nanodiscs.

Author

Henrich E, Sörmann J, Eberhardt P, Peetz O, Mezhyrova J, Morgner N, Fendler K, Dötsch V, Wachtveitl J, Bernhard F, and Bamann C

Subjects

Chromatography, Gel, Escherichia coli, Feasibility Studies, Flavobacteriaceae, Ion Transport, Mass Spectrometry, Membrane Potentials, Nanostructures, Optogenetics, Photolysis, Rhodopsins, Microbial isolation & purification, Membranes, Artificial, Optical Imaging, Rhodopsins, Microbial chemistry

Abstract

Nanodiscs that hold a lipid bilayer surrounded by a boundary of scaffold proteins have emerged as a powerful tool for membrane protein solubilization and analysis. By combining nanodiscs and cell-free expression technologies, even completely detergent-free membrane protein characterization protocols can be designed. Nanodiscs are compatible with various techniques, and due to their bilayer environment and increased stability, they are often superior to detergent micelles or liposomes for membrane protein solubilization. However, transport assays in nanodiscs have not been conducted so far, due to limitations of the two-dimensional nature of nanodisc membranes that offers no compartmentalization. Here, we study Krokinobacter eikastus rhodopsin-2 (KR2), a microbial light-driven sodium or proton pump, with noncovalent mass-spectrometric, electrophysiological, and flash photolysis measurements after its cotranslational insertion into nanodiscs. We demonstrate the feasibility of adsorbing nanodiscs containing KR2 to an artificial bilayer. This allows us to record light-induced capacitive currents that reflect KR2's ion transport activity. The solid-supported membrane assay with nanodisc samples provides reliable control over the ionic condition and information of the relative ion activity of this promiscuous pump. Our strategy is complemented with flash photolysis data, where the lifetimes of different photointermediates were determined at different ionic conditions. The advantage of using identical samples to three complementary approaches allows for a comprehensive comparability. The cell-free synthesis in combination with nanodiscs provides a defined hydrophobic lipid environment minimizing the detergent dependence often seen in assays with membrane proteins. KR2 is a promising tool for optogenetics, thus directed engineering to modify ion selectivity can be highly beneficial. Our approach, using the fast generation of functional ion pumps incorporated into nanodiscs and their subsequent analysis by several biophysical techniques, can serve as a versatile screening and engineering platform. This may open new avenues for the study of ion pumps and similar electrogenic targets., (Copyright © 2017 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2017

8. Analyzing native membrane protein assembly in nanodiscs by combined non-covalent mass spectrometry and synthetic biology.

Author

Henrich E, Peetz O, Hein C, Laguerre A, Hoffmann B, Hoffmann J, Dötsch V, Bernhard F, and Morgner N

Subjects

Mass Spectrometry, Protein Binding, Protein Folding, Synthetic Biology, Membrane Proteins metabolism, Protein Multimerization

Abstract

Membrane proteins frequently assemble into higher order homo- or hetero-oligomers within their natural lipid environment. This complex formation can modulate their folding, activity as well as substrate selectivity. Non-disruptive methods avoiding critical steps, such as membrane disintegration, transfer into artificial environments or chemical modifications are therefore essential to analyze molecular mechanisms of native membrane protein assemblies. The combination of cell-free synthetic biology, nanodisc-technology and non-covalent mass spectrometry provides excellent synergies for the analysis of membrane protein oligomerization within defined membranes. We exemplify our strategy by oligomeric state characterization of various membrane proteins including ion channels, transporters and membrane-integrated enzymes assembling up to hexameric complexes. We further indicate a lipid-dependent dimer formation of MraY translocase correlating with the enzymatic activity. The detergent-free synthesis of membrane protein/nanodisc samples and the analysis by LILBID mass spectrometry provide a versatile platform for the analysis of membrane proteins in a native environment., Competing Interests: VD: Reviewing editor, eLife. The other authors declare that no competing interests exist.

Published

2017

9. The synaptic vesicle protein SV31 assembles into a dimer and transports Zn 2 .

Author

Waberer L, Henrich E, Peetz O, Morgner N, Dötsch V, Bernhard F, and Volknandt W

Subjects

Animals, Biological Transport, Cations, Divalent metabolism, Membrane Transport Proteins metabolism, Mutagenesis, Site-Directed methods, Protein Multimerization, Rats, Membrane Proteins metabolism, Nerve Tissue Proteins metabolism, Synaptic Vesicles metabolism, Zinc metabolism

Abstract

The integral synaptic vesicle protein SV31 has been shown to bind divalent cations. Here, we demonstrate that SV31 protein synthesized within a cell-free system binds Zn 2+ and to a lower extent Ni 2+ and Cu 2+ ions. Expression with Zn 2+ stabilized the protein and increased solubility. SV31 was preferentially monomeric in detergent and revealed specific binding of Zn 2+ . When co-translationally inserted into defined nanodisc bilayers, SV31 assembled into dimeric complexes, resulting in increased binding of Zn 2+ . Putative Zn 2+ -binding motifs within SV31 comprise aspartic acid and histidine residues. Site-directed mutagenesis of two conserved aspartic acid residues leads to a potent decrease in Zn 2+ binding but did not affect dimerization. Chemical modification of histidine residues abolished some of the Zn 2+ -binding capacity. We demonstrate proton-dependent transport of Zn 2+ as by accumulation of fluorescent FluoZin-1 inside of SV31-containing proteoliposomes. Transport activity has a K m value of 44.3 μM and required external Zn 2+ and internal acidic pH. Our results demonstrate that the synaptic vesicle-integral protein SV31 functions as a proton-dependent Zn 2+ transporter. SV31 may attribute specific and yet undiscovered functions to subsets of synapses., (© 2016 International Society for Neurochemistry.)

Published

2017