Daniela Münch scite author profile

dMersacidin, gallidermin, and nisin are lantibiotics, antimicrobial peptides containing lanthionine. They show potent antibacterial activity. All three interfere with cell wall biosynthesis by binding lipid II, but they display different levels of interaction with the cytoplasmic membrane. On one end of the spectrum, mersacidin interferes with cell wall biosynthesis by binding lipid II without integrating into bacterial membranes. On the other end of the spectrum, nisin readily integrates into membranes, where it forms large pores. It destroys the membrane potential and causes leakage of nutrients and ions. Gallidermin, in an intermediate position, also readily integrates into membranes. However, pore formation occurs only in some bacteria and depends on membrane composition. In this study, we investigated the impact of nisin, gallidermin, and mersacidin on cell wall integrity, membrane pore formation, and membrane depolarization in Bacillus subtilis. The impact of the lantibiotics on the cell envelope was correlated to the proteomic response they elicit in B. subtilis. By drawing on a proteomic response library, including other envelope-targeting antibiotics such as bacitracin, vancomycin, gramicidin S, or valinomycin, YtrE could be identified as the most reliable marker protein for interfering with membrane-bound steps of cell wall biosynthesis. NadE and PspA were identified as markers for antibiotics interacting with the cytoplasmic membrane.

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Copsin, a Novel Peptide-based Fungal Antibiotic Interfering with the Peptidoglycan Synthesis

Essig

Hofmann

Münch

et al. 2014

Journal of Biological Chemistry

139

124

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Background: Secreted antibacterial substances of fungi provide a rich source for new antibiotics. Results: Copsin is a novel fungal antimicrobial peptide that binds in a unique manner to the cell wall precursor lipid II. Conclusion: As part of the defense strategy of a mushroom, copsin kills bacteria by inhibiting the cell wall synthesis. Significance: Copsin provides a novel highly stabilized scaffold for antibiotics.

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Identification and in vitro Analysis of the GatD/MurT Enzyme-Complex Catalyzing Lipid II Amidation in Staphylococcus aureus

et al. 2012

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The peptidoglycan of Staphylococcus aureus is characterized by a high degree of crosslinking and almost completely lacks free carboxyl groups, due to amidation of the D-glutamic acid in the stem peptide. Amidation of peptidoglycan has been proposed to play a decisive role in polymerization of cell wall building blocks, correlating with the crosslinking of neighboring peptidoglycan stem peptides. Mutants with a reduced degree of amidation are less viable and show increased susceptibility to methicillin. We identified the enzymes catalyzing the formation of D-glutamine in position 2 of the stem peptide. We provide biochemical evidence that the reaction is catalyzed by a glutamine amidotransferase-like protein and a Mur ligase homologue, encoded by SA1707 and SA1708, respectively. Both proteins, for which we propose the designation GatD and MurT, are required for amidation and appear to form a physically stable bi-enzyme complex. To investigate the reaction in vitro we purified recombinant GatD and MurT His-tag fusion proteins and their potential substrates, i.e. UDP-MurNAc-pentapeptide, as well as the membrane-bound cell wall precursors lipid I, lipid II and lipid II-Gly5. In vitro amidation occurred with all bactoprenol-bound intermediates, suggesting that in vivo lipid II and/or lipid II-Gly5 may be substrates for GatD/MurT. Inactivation of the GatD active site abolished lipid II amidation. Both, murT and gatD are organized in an operon and are essential genes of S. aureus. BLAST analysis revealed the presence of homologous transcriptional units in a number of gram-positive pathogens, e.g. Mycobacterium tuberculosis, Streptococcus pneumonia and Clostridium perfringens, all known to have a D-iso-glutamine containing PG. A less negatively charged PG reduces susceptibility towards defensins and may play a general role in innate immune signaling.

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Characterization of co-translationally formed nanodisc complexes with small multidrug transporters, proteorhodopsin and with the E. coli MraY translocase

Roos

Zocher

Müller

et al. 2012

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Nanodiscs (NDs) enable the analysis of membrane proteins (MP) in natural lipid bilayer environments. In combination with cell-free (CF) expression, they could be used for the co-translational insertion of MPs into defined membranes. This new approach allows the characterization of MPs without detergent contact and it could help to identify effects of particular lipids on catalytic activities. Association of MPs with different ND types, quality of the resulting MP/ND complexes as well as optimization parameters are still poorly analyzed. This study describes procedures to systematically improve CF expression protocols for the production of high quality MP/ND complexes. In order to reveal target dependent variations, the co-translational ND complex formation with the bacterial proton pump proteorhodopsin (PR), with the small multidrug resistance transporters SugE and EmrE, as well as with the Escherichia coli MraY translocase was studied. Parameters which modulate the efficiency of MP/ND complex formation have been identified and in particular effects of different lipid compositions of the ND membranes have been analyzed. Recorded force distance pattern as well as characteristic photocycle dynamics indicated the integration of functionally folded PR into NDs. Efficient complex formation of the E. coli MraY translocase was dependent on the ND size and on the lipid composition of the ND membranes. Active MraY protein could only be obtained with ND containing anionic lipids, thus providing new details for the in vitro analysis of this pharmaceutically important protein.

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Structural variations of the cell wall precursor lipid II in Gram-positive bacteria — Impact on binding and efficacy of antimicrobial peptides

Münch

Sahl

2015

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Antimicrobial peptides (AMPs) are natural antibiotics produced by virtually all living organisms. Typically, AMPs are cationic and amphiphilic and first contacts with target microbes involve interactions with negatively charged components of the cell envelope such as lipopolysaccharide (LPS), and wall- or lipoteichoic acids (WTA, LTA). The importance of charge-mediated interactions of AMPs with the cell envelope is reflected by effective microbial resistance mechanisms which are based on reduction of the overall charge of these polymers. The anionic polymers are linked in various ways to the stress-bearing polymer of the cell envelope, the peptidoglycan, which is made of a highly conserved building block, a disaccharide-pentapeptide moiety that also contains charged residues. This structural element, in spite of its conservation throughout the bacterial world, can undergo genus- and species-specific modifications that also impact significantly on the overall charge of the cell envelope and on the binding affinity of AMPs. The modification reactions involved largely occur on the membrane-bound peptidoglycan building block, the so-called lipid II, which is a most prominent target for AMPs. In this review, we focus on modifications of lipid II and peptidoglycan and discuss their consequences for the interactions with various classes of AMPs, such as defensins, lantibiotics and glyco-(lipo)-peptide antibiotics. This article is part of a Special Issue entitled: Bacterial Resistance to Antimicrobial Peptides.

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Daniela Münch

Proteomic Response of Bacillus subtilis to Lantibiotics Reflects Differences in Interaction with the Cytoplasmic Membrane

Copsin, a Novel Peptide-based Fungal Antibiotic Interfering with the Peptidoglycan Synthesis

Identification and in vitro Analysis of the GatD/MurT Enzyme-Complex Catalyzing Lipid II Amidation in Staphylococcus aureus

Characterization of co-translationally formed nanodisc complexes with small multidrug transporters, proteorhodopsin and with the E. coli MraY translocase

Structural variations of the cell wall precursor lipid II in Gram-positive bacteria — Impact on binding and efficacy of antimicrobial peptides

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