Your search keyword '"Jung, Sascha"' showing total 4 results

1. Confirmation of the Disulfide Connectivity and Strategies for Chemical Synthesis of the Four-Disulfide-Bond-Stabilized Aspergillus giganteus Antifungal Protein, AFP.

Author

Váradi G, Batta G, Galgóczy L, Hajdu D, Fizil Á, Czajlik A, Virágh M, Kele Z, Meyer V, Jung S, Marx F, and Tóth GK

Subjects

alpha-Fetoproteins, Disulfides, Antifungal Agents chemistry, Fungal Proteins metabolism

Abstract

Emerging fungal infections require new, more efficient antifungal agents and therapies. AFP, a protein from Aspergillus giganteus with four disulfide bonds, is a promising candidate because it selectively inhibits the growth of filamentous fungi. In this work, the reduced form of AFP was prepared using native chemical ligation. The native protein was synthesized via oxidative folding with uniform protection for cysteine thiols. AFP's biological activity depends heavily on the pattern of natural disulfide bonds. Enzymatic digestion and MS analysis provide proof for interlocking disulfide topology ( abcdabcd ) that was previously assumed. With this knowledge, a semi-orthogonal thiol protection method was designed. By following this strategy, out of a possible 105, only 6 disulfide isomers formed and 1 of them proved to be identical with the native protein. This approach allows the synthesis of analogs for examining structure-activity relationships and, thus, preparing AFP variants with higher antifungal activity.

Published

2023

2. Species-Specific Differences in the Susceptibility of Fungi to the Antifungal Protein AFP Depend on C-3 Saturation of Glycosylceramides.

Author

Paege N, Warnecke D, Zäuner S, Hagen S, Rodrigues A, Baumann B, Thiess M, Jung S, and Meyer V

Subjects

Chitin analysis, Fungi growth & development, Mass Spectrometry, Microbial Sensitivity Tests, Antifungal Agents pharmacology, Cell Membrane chemistry, Cell Membrane drug effects, Ceramides analysis, Fungal Proteins pharmacology, Fungi chemistry, Fungi drug effects

Abstract

AFP is an antimicrobial peptide (AMP) produced by the filamentous fungus Aspergillus giganteus and is a very potent inhibitor of fungal growth that does not affect the viability of bacteria, plant, or mammalian cells. It targets chitin synthesis and causes plasma membrane permeabilization in many human- and plant-pathogenic fungi, but its exact mode of action is not known. After adoption of the "damage-response framework of microbial pathogenesis" regarding the analysis of interactions between AMPs and microorganisms, we have recently proposed that the cytotoxic capacity of a given AMP depends not only on the presence/absence of its target(s) in the host and the AMP concentration applied but also on other variables, such as microbial survival strategies. We show here using the examples of three filamentous fungi ( Aspergillus niger , Aspergillus fumigatus , and Fusarium graminearum ) and two yeasts ( Saccharomyces cerevisiae and Pichia pastoris ) that the important parameters defining the AFP susceptibilities of these fungi are (i) the presence/absence of glycosylceramides, (ii) the presence/absence of Δ3( E ) desaturation of the fatty acid chain therein, and (iii) the (dis)ability of these fungi to respond to AFP inhibitory effects with the fortification of their cell walls via increased chitin and β-(1,3)-glucan synthesis. These observations support the idea of the adoption of the damage-response framework to holistically understand the outcome of AFP inhibitory effects. IMPORTANCE Our data suggest a fundamental role of glycosylceramides in the susceptibility of fungi to AFP. We discovered that only a minor structural difference in these molecules-namely, the saturation level of their fatty acid chain, controlled by a 2-hydroxy fatty N-acyl-Δ3( E )-desaturase-represents a key to understanding the inhibitory activity of AFP. As glycosylceramides are important components of fungal plasma membranes, we propose a model which links AFP-mediated inhibition of chitin synthesis in fungi with its potential to disturb plasma membrane integrity., (Copyright © 2019 Paege et al.)

Published

2019

3. A Computational Modeling Approach Predicts Interaction of the Antifungal Protein AFP from Aspergillus giganteus with Fungal Membranes via Its γ-Core Motif.

Author

Utesch T, de Miguel Catalina A, Schattenberg C, Paege N, Schmieder P, Krause E, Miao Y, McCammon JA, Meyer V, Jung S, and Mroginski MA

Subjects

Antifungal Agents pharmacology, Aspergillus classification, Cell Membrane Permeability drug effects, Computer Simulation, Magnetic Resonance Spectroscopy, Microbial Sensitivity Tests, Molecular Dynamics Simulation, Aspergillus metabolism, Aspergillus niger drug effects, Fungal Proteins isolation & purification, Fungal Proteins pharmacology

Abstract

Fungal pathogens kill more people per year globally than malaria or tuberculosis and threaten international food security through crop destruction. New sophisticated strategies to inhibit fungal growth are thus urgently needed. Among the potential candidate molecules that strongly inhibit fungal spore germination are small cationic, cysteine-stabilized proteins of the AFP family secreted by a group of filamentous Ascomycetes. Its founding member, AFP from Aspergillus giganteus , is of particular interest since it selectively inhibits the growth of filamentous fungi without affecting the viability of mammalian, plant, or bacterial cells. AFPs are also characterized by their high efficacy and stability. Thus, AFP can serve as a lead compound for the development of novel antifungals. Notably, all members of the AFP family comprise a γ-core motif which is conserved in all antimicrobial proteins from pro- and eukaryotes and known to interfere with the integrity of cytoplasmic plasma membranes. In this study, we used classical molecular dynamics simulations combined with wet laboratory experiments and nuclear magnetic resonance (NMR) spectroscopy to characterize the structure and dynamical behavior of AFP isomers in solution and their interaction with fungal model membranes. We demonstrate that the γ-core motif of structurally conserved AFP is the key for its membrane interaction, thus verifying for the first time that the conserved γ-core motif of antimicrobial proteins is directly involved in protein-membrane interactions. Furthermore, molecular dynamic simulations suggested that AFP does not destroy the fungal membrane by pore formation but covers its surface in a well-defined manner, using a multistep mechanism to destroy the membranes integrity. IMPORTANCE Fungal pathogens pose a serious danger to human welfare since they kill more people per year than malaria or tuberculosis and are responsible for crop losses worldwide. The treatment of fungal infections is becoming more complicated as fungi develop resistances against commonly used fungicides. Therefore, discovery and development of novel antifungal agents are of utmost importance., (Copyright © 2018 Utesch et al.)

Published

2018

4. A Transcriptome Meta-Analysis Proposes Novel Biological Roles for the Antifungal Protein AnAFP in Aspergillus niger.

Author

Paege N, Jung S, Schäpe P, Müller-Hagen D, Ouedraogo JP, Heiderich C, Jedamzick J, Nitsche BM, van den Hondel CA, Ram AF, and Meyer V

Subjects

Amino Acid Sequence, Aspergillus niger metabolism, Autophagy genetics, Fungal Proteins metabolism, Gene Expression Profiling, Heat-Shock Proteins genetics, Heat-Shock Proteins metabolism, Hyphae metabolism, Osmotic Pressure, Oxidative Stress, Promoter Regions, Genetic, Repressor Proteins genetics, Repressor Proteins metabolism, Secondary Metabolism genetics, Sequence Alignment, Sequence Homology, Amino Acid, Aspergillus niger genetics, Fungal Proteins genetics, Gene Expression Regulation, Fungal, Hyphae genetics, Transcriptome

Abstract

Understanding the genetic, molecular and evolutionary basis of cysteine-stabilized antifungal proteins (AFPs) from fungi is important for understanding whether their function is mainly defensive or associated with fungal growth and development. In the current study, a transcriptome meta-analysis of the Aspergillus niger γ-core protein AnAFP was performed to explore co-expressed genes and pathways, based on independent expression profiling microarrays covering 155 distinct cultivation conditions. This analysis uncovered that anafp displays a highly coordinated temporal and spatial transcriptional profile which is concomitant with key nutritional and developmental processes. Its expression profile coincides with early starvation response and parallels with genes involved in nutrient mobilization and autophagy. Using fluorescence- and luciferase reporter strains we demonstrated that the anafp promoter is active in highly vacuolated compartments and foraging hyphal cells during carbon starvation with CreA and FlbA, but not BrlA, as most likely regulators of anafp. A co-expression network analysis supported by luciferase-based reporter assays uncovered that anafp expression is embedded in several cellular processes including allorecognition, osmotic and oxidative stress survival, development, secondary metabolism and autophagy, and predicted StuA and VelC as additional regulators. The transcriptomic resources available for A. niger provide unparalleled resources to investigate the function of proteins. Our work illustrates how transcriptomic meta-analyses can lead to hypotheses regarding protein function and predict a role for AnAFP during slow growth, allorecognition, asexual development and nutrient recycling of A. niger and propose that it interacts with the autophagic machinery to enable these processes., Competing Interests: The authors have declared that no competing interests exist.

Published

2016