Showing papers by "Lutz Schmitt published in 2017"

Substrate Specificity of the Secreted Nisin Leader Peptidase NisP.

Abstract: Nisin (NisA) is an antimicrobial peptide produced by Lactococcus lactis and belongs to the class of lanthipeptides, more specifically to the class of lantibiotics. They are ribosomally synthesized as a precursor peptide and are comprised of an N-terminal leader peptide and a C-terminal core peptide. The core peptide is post-translationally modified and contains dehydrated amino acids in addition to five (methyl)-lanthionine rings, which are crucial for its activity. The leader peptide serves as a signal sequence and ensures that NisA remains inactive but secretion-competent within the cell. After translocation into the extracellular space, the leader peptide is cleaved by the leader peptidase NisP, resulting in active nisin. NisP is an extracellular subtilisin-like serine protease, which recognizes the cleavage site GASPR|IT located at the C-terminal end of the leader peptide. Here, we present the biochemical characterization of secreted and purified NisP (NisPs) with its natural substrate, the fully modi...

Stoichiometry and structure of a lantibiotic maturation complex

Abstract: Lantibiotics are ribosomally synthesized antimicrobial peptides secreted by mainly Gram-positive bacteria. Class 1 lantibiotics mature via two modification steps introduced by a modification LanBC complex. For the lantibiotic nisin, the dehydratase NisB catalyzes the dehydration of serine and threonine residues in the so-called core peptide. Second, five (methyl)-lanthionine rings are introduced in a regio- and stereospecific manner by the cyclase NisC. Here, we characterized the assembly of the NisBC complex in vitro, which is only formed in the presence of the substrate. The complex is composed of a NisB dimer, a monomer of NisC and one prenisin molecule. Interestingly, the presence of the last lanthionine ring prevented complex formation. This stoichiometry was verified by small-angle X-ray scattering measurements, which revealed the first structural glimpse of a LanBC complex in solution.

From substrate specificity to promiscuity: hybrid ABC transporters for osmoprotectants

Abstract: Summary The ABC-transporters OpuB and OpuC from Bacillus subtilis function as osmoprotectant import systems. Their structural genes have most likely evolved through a duplication event but the two transporters are remarkably different in their substrate profile. OpuB possesses narrow substrate specificity, while OpuC is promiscuous. We assessed the functionality of hybrids between these two ABC-transporters by reciprocally exchanging the coding regions for the OpuBC and OpuCC substrate-binding proteins between the corresponding opuB and opuC operons. Substantiating the critical role of the binding protein in setting the substrate specificity of ABC transporters, OpuB::OpuCC turned into a promiscuous system, while OpuC::OpuBC now exhibited narrow substrate specificity. Both hybrid transporters possessed a high affinity for their substrates but the transport capacity of the OpuB::OpuCC system was moderate due to the synthesis of only low amounts of the xenogenetic OpuCC protein. Suppressor mutations causing single amino acid substitutions in the GbsR repressor controlling the choline to glycine betaine biosynthesis pathway greatly improved OpuB::OpuCC-mediated compatible solute import through transcriptional up-regulation of the hybrid opuB::opuCC operon. Collectively, we demonstrate for the first time that one can synthetically switch the substrate specificity of a given ABC transporter by combining its core components with a xenogenetic ligand-binding protein. This article is protected by copyright. All rights reserved.

Partial external biliary diversion in bile salt export pump deficiency: Association between outcome and mutation.

Abstract: Partial external biliary diversion in bile salt export pump deficiency: Association between outcome and mutation

Transmitting the energy: interdomain cross-talk in Pdr5.

Abstract: ABC (ATP-binding cassette) transporters are ubiquitous integral membrane proteins catalyzing the active export or import of structurally and functionally unrelated compounds. In humans, these proteins are clinically and economically important, as their dysfunction is responsible for a number of diseases. In the case of multidrug resistance (MDR) ABC exporters, they particularly confer resistance to a broad spectrum of toxic compounds, placing them in the focus of clinical research. However, ABC-mediated drug resistance is not only restricted to humans. In yeast for example, MDR is called pleiotropic drug resistance (PDR). Important and well-studied members of the PDR subfamily of ABC transporters are Pdr5 from Saccharomyces cerevisiae and its homolog Cdr1 from Candida albicans. Mutational studies of these two transporters provided many insights into the complexity and conceivable mechanism of the interdomain cross-talk that transmits the energy gained from ATP hydrolysis to the substrate translocation process across the membrane. In this review, we summarize and discuss our current knowledge of the interdomain cross-talk as well as new results obtained for asymmetric ABC transporters and derive possible structural and functional implications for Pdr5.