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The fungus Candida albicans is a typical member of the human microbiota, where it usually behaves as a commensal. It can also become pathogenic; often causing minor superficial infections in healthy people, but also potentially fatal invasive systemic infections in immunocompromised people. Unfortunately, there is only a fairly limited set of antifungal drugs, and evolution of drug resistance threatens their efficacy. Greater understanding of the mechanisms that C. albicans uses to survive in and infect the host can uncover candidate targets for novel antifungals. Protein kinases are central to a vast array of signalling pathways which govern practically all aspects of life, and furthermore are relatively straightforward to design drugs against. As such, investigation and characterization of protein kinases in C. albicans as well as their target proteins and the pathways they govern are important targets for research. AMP-activated kinases are well conserved proteins which respond to energy stress; they are represented in yeasts by the heterotrimeric SNF1 complex, which responds primarily to the absence of glucose. In this work, the SNF1 pathway was investigated with two primary goals: identify novel targets of this protein kinase and elucidate why SNF1 is essential. Two approaches were used to identify novel targets of SNF1. In one, suppressor mutants were evolved from a strain in which SNF1 activity is reduced, which exhibits defects in carbon source utilization and cell wall integrity. This revealed a suppressor mutation within SNF1 itself, coding for the catalytic subunit of the complex – SNF1Δ311-316. The second approach screened a library of artificially activated zinc cluster transcription factors, identifying Czf1 as one such transcription factor which, upon artificial activation, restored resistance to cell wall stress in a mutant of the SNF1 pathway. Finally, a, inducible gene deletion system revealed that SNF1 is not an essential gene.
The fungal cell wall is essential for the maintenance of cellular integrity and mediates interactions of the cells with the environment. It is a highly flexible organelle whose composition and organization is modulated in response to changing growth conditions. In the pathogenic yeast Candida albicans, a network of signaling pathways regulates the structure of the cell wall, and mutants with defects in these pathways are hypersensitive to cell wall stress. By harnessing a library of genetically activated forms of all C. albicans zinc cluster transcription factors, we found that a hyperactive Czf1 rescued the hypersensitivity to cell wall stress of different protein kinase deletion mutants. The hyperactive Czf1 induced the expression of many genes with cell wall-related functions and caused visible changes in the cell wall structure. C. albicans czf1Δ mutants were hypersensitive to the antifungal drug caspofungin, which inhibits cell wall biosynthesis. The changes in cell wall architecture caused by hyperactivity or absence of Czf1 resulted in an increased recognition of C. albicans by human neutrophils. Our results show that Czf1, which is known as a regulator of filamentous growth and white-opaque switching, controls the expression of cell wall genes and modulates the architecture of the cell wall.
Cellular membranes form a boundary to shield the inside of a cell from the outside. This is of special importance for bacteria, unicellular organisms whose membranes are in direct contact with the environment. The membrane needs to allow the reception of information about beneficial and harmful environmental conditions for the cell to evoke an appropriate response. Information gathering is mediated by proteins that need to be correctly organized in the membrane to be able to transmit information. Several principles of membrane organization are known that show a heterogeneous distribution of membrane lipids and proteins. One of them is functional membrane microdomains (FMM) which are platforms with a distinct lipid and protein composition. FMM move within the membrane and their integrity is important for several cellular processes like signal transduction, membrane trafficking and cellular differentiation. FMM harbor the marker proteins flotillins which are scaffolding proteins that act as chaperones in tethering protein cargo to FMM. This enhances the efficiency of cargo protein oligomerization or complex formation which in turn is important for their functionality. The bacterium Bacillus subtilis contains two flotillin proteins, FloA and FloT. They form different FMM assemblies which are structurally similar, but differ in the protein cargo and thus in the specific function.
In this work, the mobility of FloA and FloT assemblies in the membrane was dissected using live-cell fluorescence microscopy techniques coupled to genetic, biochemical and molecular biological methods. A characteristic mobility pattern was observed which revealed that the mobility of both flotillins was spatially restricted. Restrictions were bigger for FloT resulting in a decreased diffusion coefficient compared to FloA. Flotillin mobility depends on the interplay of several factors. Firstly, the intrinsic properties of flotillins determine the binding of different protein interaction partners. These proteins directly affect the mobility of flotillins. Additionally, binding of interaction partners determines the assembly size of FloA and FloT. This indirectly affects the mobility, as the endo-cytoskeleton spatially restricts flotillin mobility in a size-dependent manner. Furthermore, the extracellular cell wall plays a dual role in flotillin mobility: its synthesis stimulates flotillin mobility, while at the same time its presence restricts flotillin mobility. As the intracellular flotillins do not have spatial access to the exo-cytoskeleton, this connection is likely mediated indirectly by their cell wall-associated protein interaction partners. Together the exo- and the endo-cytoskeleton restrict the mobility of FloA and FloT.
Similar structural restrictions of flotillin mobility have been reported for plant cells as well, where the actin cytoskeleton and the cell wall restrict flotillin mobility. These similarities between eukaryotic and prokaryotic cells indicate that the restriction of flotillin mobility might be a conserved mechanism.