Kartenstapel

chloroplast: Photosynthetic metabolism

Chloroplast: Non-photosynthetic metabolism:

Nuclear genome:

How much proteine Plastome codes?

The chloroplast proteome comprises about 2500 proteins

Photosynthetic protein complexes involved in linear electron transfer at the thylakoid membrane

Nuclear and plastid encoded subunits of photosynthetic complexes

Posttranslational transport mechanisms of nuclear encoded thylakoid proteins/ Cotranslational transport mechanisms of plastid encoded thylakoid proteins

Targeting pathways for nuclear encoded proteins to the thylakoid

cpSRP

LHCPs:

Insertion of LHCP into the thylakoid membrane

Central questions:

Plastome encodes:

About 50 % of the plastid-encoded TM proteins are cotranslationally inserted

Targeting of inner membrane proteins in E. coli: cotranslational / SRP-dependent

Mechanisms of cotranslational transport and insertion?Central questions:

WHY DO WE NEED NEW ANTIBIOTICS?

MULTI-RESISTANT BACTERIA

COVID-19 - RELATED DEATHS

CHALLENGE MARKET FAILURE

CHALLENGE INNOVATION GAP

CLASSICAL ANTIBIOTIC TARGETS

APPROACHES TO IDENTIFYING NOVEL ANTIBIOTICS

RESEARCH INTERESTS OF THE BANDOW LAB

SEARCH FOR NOVEL ANTIBIOTICS FOR CLINICAL USE

RESEARCH AT THE CENTER FOR SYSTEM-BASED ANTIBIOTIC RESEARCH

ACTIVITY AND MASS-GUIDED NATURAL PRODUCT DISCOVERY

CONCLUSION AND NEXT STEP

WHY DO RIBOSOMES NEED TO BE RESCUED

trans-TRANSLATION

ALTERNATIVE RESCUE PATHWAYS IN B. subtilis

SUMMARY OMICS APPROACHES IN ANTIBIOTIC DISCOVERY

What are algae?

What are microalgae?

Commonly, ‘microalgae‘ means unicellular eukaryotes and cyanobacteria

Chloroplasts derive from cyanobacteria

Oxygenic phototrophs are the basis of life

Example: O2 as substrate and reactant in tetrapyrrole biosynthesis

The marine food chain starts with microalgae

Photosynthesis can be stressful

Vitamins and ‚biofuels‘: acclimation strategies

Microalgae are already used commercially

Photosynthesis-dependent H2 production by several species → Prof. Happe

Biotechnology book written & edited by faculty members

Microalgae could help combat climate change

The case of Chlamydomonas reinhardtii

What does it take to become a model organism?

Chlamydomonas as a model

Major research fields emplyoing Chlamydomonas

Two of our research projects as examples for the values of Chlamydomonas

Old Yellow Enzymes: FMN-containing ene-reductases of biotechnological interest

Old Yellow Enzymes: promiscuous FMN-containing ene-reductases of biotechnological interest

Old Yellow Enzymes: not much is known about their biological role

Whole-cell biotransformation in photosynthetic (NADPH-supplying) organisms

Oxygenic photosynthesis

Photosynthetic H2 production

Bacterial cell biology: How do bacteria organize their life?

Major tools: Life Cell Fluorescence Microscopy & Genetics

Fluorescence Microscopy

Genetics

The complexity of bacterial popula)ons

The Myxobacteria

How to make a fruiting body?

Regulatory network of M. xanthus development

Coordination of cell motility

Myxobacteria use two motility system

Changing direction: Cell polarity and cell reversals

Setting the cell reversal frequency: The Frz two-component chemosensory system

"Typical" two-component chemosensory system

Setting cell reversal frequency: The Frz two-component chemosensory system

Predation

Predatory bacteria

Endobiotic predation by Bdellovibrio

Epibiotic predation by Myxococcus xanthus

What are plant-pathogen interactions?

Why do we care about plant-pathogen interactions?

Why do we STILL care about plant-pathogen interactions?

Plant-pathogen interactions are like the invasion of a fortress

How do pathogens counteract the plant defenses?

Pathogens deploy several virulence factors

How do plants defend themselves?

How do plants recognize pathogens?

PAMPs trigger basal plant defenses

Effectors from the pathogen block the plant defenses

How do plants recognize pathogens?

TAL effectors

microtubule cytoskeleton

Effectors mess up with everything in the cell!

A bacterial effector

Current research projects in The Üstün Lab

Protein homeostasis: The Life and death of proteins

Protein Degradation Pathways in Eukaryotes

Ubiquitin is the “king”

Proteasome-development: Auxin

Research topics of our group grefen

PROTEIN-PROTEIN INTERACTION ASSAYS

BIMOLECULAR FLUORESCENCE COMPLEMENTATION (BIFC)

The Secretory Pathway in Plants

ER Insertion Pathways

TEXTBOOK EXAMPLE FOR TA PROTEIN INSERTION?

SRP INDEPENDENT (SND) IS PARTIALLY CONSERVED IN ARABIDOPSIS

Balancing water

Stomata: Development vs. Function

Summary

Fungal fruiting bodies: function:

What are fungi ?

Fungal phylogeny

What are the defining characteristics of fungi?

Fungal morphology: yeasts versus filamentous fungi

Filamentous fungi: multinucleate mycelial compartments

Multicellular development in eukaryotes

Evolution of multicellular development in fungi

Asexual and sexual development in fungi

Major features of Basidiomycota

Chromosome content of fungal cells and nuclei: example of a dikaryotic life cycle in a basidiomycete

Major features of Ascomycota

Chromosome content of fungal cells and nuclei: example of a haplo-dikaryotic life cycle in an ascomycete

Sexual development in filamentous ascomycetes: fruiting body formation

Genomics and transcriptomics to study multicellular development

Sordaria macrospora, Pyronema confluens and Ascodesmis nigricans

Asco- & Basidiomycota = Dikarya

Multicellular growth modes in eukaryotes

Fungal growth by simple (multicellular) structures

Fruiting bodies as complex multicellular structures

Global mushroom production in culture

Megadiversity of fruiting body shapes in Agaricomycetes

Megadiversity of basidiospore architectures

Multicellular structure formation in eukaryotes

Triggers of complex multicellular development

Actinobacteria

The bacterial cell wall

Actinobacteria: cell envelopes

Actinobacteria and biotechnology

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