Seminare Biotechnologie
Das Seminar findet Mittwochs um 12:00 Uhr im WS und um 10:30 Uhr im SS statt.
Suchen Sie sich ein Thema aus (Eigenrecherche oder aktuelle Seminarthemen) und kontaktieren Sie den entsprechenden Betreuer, um die Betreuung und einen potentiellen Seminartermin abzustimmen (siehe Seminarkalender; max. drei Vorträge pro Termin).
Danach bitte die Themenwahl und den freien Wunschtermin direkt unter demian.dietrich(at)uni-saarland.de mitteilen.
Planen Sie bitte rechtzeitig. Das Seminar findet nur im laufenden Semester statt.
Jedes Thema kann nur 1 mal vergeben werden.
Das dritte Seminar der Biotechnologen kann/soll der Vorbereitung der Masterarbeit dienen. Es geht dabei klar um eine intensive Vorbereitung durch Literaturstudium und soll keine erarbeiteten Ergebnisse enthalten.
Jeder Vortrag soll 20 min dauern. Danach folgen 10 min Diskussion und Kritik durch Studenten, Kollegen und Betreuer.
Für den Erhalt der entsprechenden Credit Points ist die Anwesenheit verpflichtend.
1. und 2. Seminarvortrag: Der Vortrag inklusive einer detaillierten Liste der verwendeten Literatur, sowie eine zusammenfassende Ausarbeitung (max. 3 Seiten) müssen dem Betreuer und Herrn Dietrich als pdf-Datei am Tag des Vortrags zugesendet werden. Die Ausarbeitung und der Vortrag werden anschließend im Seminarkalender hochgeladen.
Masterseminar: Die Anwesenheit des Betreuers der Masterarbeit ist verpflichtend. Im Fall des Masterseminars muss keine zusammenfassende Ausarbeitung abgegeben werden.
Liste der aktuellen Seminarthemen
| Betreuer |
Referent |
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| A1. Biofuel in higher plants |
M.Sc. Wassilina Bugaeva | Eren Aktas |
| A2. Biofuel in green micro algae | M.Sc. Janick Peter | |
| A3. Fishoilproduction in plant seeds | M.Sc. Anne Könnel |
| Themen AK Kohring (Betreuer Gert-Wieland Kohring) |
Referent |
| B1. The role of laboratory-scale bioreactors at the semi-continuous and continuous microbiological and biotechnological processes. Applied Microbiology and Biotechnology (2018) 102:7293–7308 | Gregor Ullrich |
| B2. Biosynthesis of pneumocandin lipopeptides and perspectives for its production and related echinocandins | |
| B3. PHA synthase (PhaC): interpreting the functions of bioplastic-producing enzyme from a structural perspective | |
| B4. Bioprocesses for 2-phenylethanol and 2-phenylethyl acetate production: current state and perspectives | |
| B5.Biocatalytic concepts for synthesizing amine bulk chemicals: recent approaches towards linear and cyclic aliphatic primary amines and ω-substituted derivatives thereof | |
| B6. Endo-xylanases as tools for production of substituted xylooligosaccharides with prebiotic properties | |
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B7. Sustainable production of glutathione from lignocellulose-derived sugars using engineered Saccharomyces cerevisiae |
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| B8. Landomycin biosynthesis and its regulation in Streptomyces |
Patrick Oberhäuser |
| B9. Managing microbial communities in membrane biofilm reactors | Tobias Sukmann |
| B10. Architectural adaptations of microbial fuel cells | |
| B11. Recent developments in non-biodegradable biopolymers: Precursors, production processes, and future perspectives | Anna Betz |
| B12. Opportunities, challenges, and future perspectives of succinic acid production by Actinobacillus succinogenes | Fabienne Wittling |
| B13. Engineering of lactic acid bacteria for delivery of therapeutic proteins and peptides | Ez Eddin Kheuri |
| B14. Deciphering bacterial xylose metabolism and metabolic engineering of industrial microorganisms for use as efficient microbial cell factories | |
| B15. Microbial conversion of xylose into useful bioproducts |
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Betreuer |
Referent |
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Betreuer |
Referent |
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D1. Degradation and assimilation of aromatic compounds by Corynebacterium glutamicum: another potential for applications for this bacterium? Shen et al. (2012). Appl Microbiol Biotechnol, 95, 77-89. |
Dr.-Ing. Michael Kohlstedt |
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D2. Robust, small-scale cultivation platform for |
M.Sc. Lars Gläser |
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D3. Metabolic engineering of natural product biosynthesis in actinobacteria http://dx.doi.org/10.1016/j.copbio.2016.03.008 |
M.Sc. Martin Kuhl |
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D4. Crispr/Cas9 coupled recombineering for metabolic engineering of corynebacterium glutamicum. 10.1016/j.ymben.2017.06.010 |
M.Sc. Christina Rohles |
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D5. Development of an Improved System for the Generation of Knockout Mutants of Amycolatopsis sp. Strain ATCC 39116. 10.1128/AEM.02660-16 |
M.Sc. Nadja Barton |
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D6. Recovery of microalgal biomass and metabolites: process options and economics https://doi.org/10.1016/S0734-9750(02)00050-2 |
M.Sc. Dennis Schulze | |
| D7. Improved fermentative production of the compatible solute ectoine by Corynebacterium glutamicum from glucose and alternative carbon sources | M.Sc. Lukas Jungmann | |
| D8. Saccharomyces cerevisiae goes through distinct metabolic phases during its replicative lifespan | Dr.-Ing. Michael Kohlstedt | |
| D9. Yeast 2.0—connecting the dots in the construction of the world's first functional synthetic eukaryotic genome | Dr.-Ing. Michael Kohlstedt | |
| D10. Metabolic engineering of microbial cell factories for production of nutraceuticals | Dr.-Ing. Michael Kohlstedt | |
| D11. Quantitative RNA-seq Analysis Unveils Osmotic and Thermal Adaptation Mechanisms Relevant for Ectoine Production in Chromohalobacter salexigens | M.Sc. Lukas Jungmann | |
| D12. Corynebacterium glutamicum mechanosensitive channels: towards unpuzzling “glutamate efflux” for amino acid production | M.Sc. Lukas Jungmann | |
| D13. Function of L-Pipecolic Acid as Compatible Solute in Corynebacterium glutamicum as Basis for Its Production Under Hyperosmolar Conditions | M.Sc. Sarah Pauli | |
| D14. Functional expression of L-lysine α-oxidase from Scomber japonicus in Escherichia coli for one-pot synthesis of L-pipecolic acid from DL-lysine | M.Sc. Sarah Pauli | |
| D15. Rational engineering of Streptomyces albus J1074 for the overexpression of secondary metabolite gene clusters | M.Sc. Julian Stegmüller | |
| D16. The Key to Acetate: Metabolic Fluxes of Acetic Acid Bacteria under Cocoa Pulp Fermentation-Simulating Conditions | M.Sc. Muzi Tangyu | |
| D17. Substrates and oxygen dependent citric acid production by Yarrowia lipolytica: insights through transcriptome and fluxome analyses | M.Sc. Sofija Jovanovic | |
| D18. Synthetic biology tools for engineering Yarrowia lipolytica | M.Sc. Sofija Jovanovic | |
| D19. Development of a novel, robust and cost-efficient process for valorizing dairy waste exemplified by ethanol production | M.Sc. Christina Rohles | |
| D20. Regulating malonyl-CoA metabolism via synthetic antisense RNAs for enhanced biosynthesis of natural products. | M.Sc. Selma Beganovic | |
| D21. Butanol fermentation of the brown seaweed Laminaria digitata by Clostridium beijerinckii DSM-6422 | M.Sc. Sarah-Lisa Hoffmann | |
| D22. Multi-omics analysis unravels a segregated metabolic flux network that tunes co-utilization of sugar and aromatic carbons in Pseudomonas putida | Dr. Judith Becker | |
| D23. Identification of the two-component guaiacol demethylase system from Rhodococcus rhodochrous and expression in Pseudomonas putida EM42 for guaiacol assimilation | Dr. Judith Becker | |
| D24. Simultaneous Improvements of Pseudomonas Cell Growth and Polyhydroxyalkanoate Production from a Lignin Derivative for Lignin-Consolidated Bioprocessing | Dr. Judith Becker | |
| D25. A preliminary study on L-lysine fermentation from lignocellulose feedstock and techno-economic evaluation | Dr. Judith Becker | |
| D26. Biotechnological applications of extremophiles, extremozymes and extremolytes | Dr. Judith Becker | |
| D27. Complete biosynthesis of cannabinoids and their unnatural analogues in yeast | Dr.-Ing. Michael Kohlstedt | |
| D28. Metabolite concentrations, fluxes and free energies imply efficient enzyme usage | Dr.-Ing. Michael Kohlstedt |