The precise co-localization and stoichiometric expression of two different light-gated membrane proteins can vastly improve the physiological usefulness of optogenetics for the modulation of cell excitability with light. Here we present a gene-fusion strategy for the stable 1:1 expression of any two microbial rhodopsins in a single polypeptide chain. By joining the excitatory channelrhodopsin-2 with the inhibitory ion pumps halorhodopsin or bacteriorhodopsin, we demonstrate light-regulated quantitative bi-directional control of the membrane potential in HEK293 cells and neurons in vitro. We also present synergistic rhodopsin combinations of channelrhodopsin-2 with Volvox carteri channelrhodopsin-1 or slow channelrhodopsin-2 mutants, to achieve enhanced spectral or kinetic properties, respectively. Finally, we demonstrate the utility of our fusion strategy to determine ion-turnovers of as yet uncharacterized rhodopsins, exemplified for archaerhodopsin and CatCh, or to correct pump cycles, exemplified for halorhodopsin.
Rhodopsins are membrane-embedded photoreceptors found in all major taxonomic kingdoms using retinal as their chromophore. They play well-known functions in different biological systems, but their roles in fungi remain unknown. The filamentous fungus Fusarium fujikuroi contains two putative rhodopsins, CarO and OpsA. The gene carO is light-regulated, and the predicted polypeptide contains all conserved residues required for proton pumping. We aimed to elucidate the expression and cellular location of the fungal rhodopsin CarO, its presumed proton-pumping activity and the possible effect of such function on F. fujikuroi growth. In electrophysiology experiments we confirmed that CarO is a green-light driven proton pump. Visualization of fluorescent CarO-YFP expressed in F. fujikuroi under control of its native promoter revealed higher accumulation in spores (conidia) produced by light-exposed mycelia. Germination analyses of conidia from carO− mutant and carO+ control strains showed a faster development of light-exposed carO− germlings. In conclusion, CarO is an active proton pump, abundant in light-formed conidia, whose activity slows down early hyphal development under light. Interestingly, CarO-related rhodopsins are typically found in plant-associated fungi, where green light dominates the phyllosphere. Our data provide the first reliable clue on a possible biological role of a fungal rhodopsin.
Aspergillus (A.) fumigatus is an opportunistic fungal mold inducing invasive aspergillosis (IA) in immunocompromised patients. Although antifungal activity of human natural killer (NK) cells was shown in previous studies, the underlying cellular mechanisms and pathogen recognition receptors (PRRs) are still unknown. Using flow cytometry we were able to show that the fluorescence positivity of the surface receptor CD56 significantly decreased upon fungal contact. To visualize the interaction site of NK cells and A. fumigatus we used SEM, CLSM and dSTORM techniques, which clearly demonstrated that NK cells directly interact with A. fumigatus via CD56 and that CD56 is re-organized and accumulated at this interaction site time-dependently. The inhibition of the cytoskeleton showed that the receptor re-organization was an active process dependent on actin re-arrangements. Furthermore, we could show that CD56 plays a role in the fungus mediated NK cell activation, since blocking of CD56 surface receptor reduced fungal mediated NK cell activation and reduced cytokine secretion. These results confirmed the direct interaction of NK cells and A. fumigatus, leading to the conclusion that CD56 is a pathogen recognition receptor. These findings give new insights into the functional role of CD56 in the pathogen recognition during the innate immune response.Invasive aspergillosis (IA), primarily caused by the mold Aspergillus fumigatus, is a devastating disease in immunocompromised patients suffering from hematological malignancies or undergoing allogeneic hematopoietic stem cell transplantation (HSCT) 1 . The mortality rate of HSCT patients diagnosed with IA ranges from 60-90% 2 and the prognosis for long-term survival is extremely poor 3 . Recently, it was shown that HSCT patients with probable/proven IA had a delayed reconstitution of natural killer (NK) cells for more than a year post HSCT 4 . In addition, patients with severe IA were found to have a lower NK cell count compared to patients with well-controlled IA, suggesting that NK cells play a critical role in immunity to IA.NK cells comprise 5-15% of the peripheral blood mononuclear cells (PBMCs) in healthy individuals and belong to the innate immune system 5 . Upon activation, NK cells release immune regulatory cytokines to stimulate other immune cells and display cytotoxicity directed against tumor or virus-infected cells by granule release 5 . NK cells are defined as CD56 positive and CD3 negative cells and can be distinguished into CD3 − CD56 dim CD16 + and CD3 − CD56 bright CD16 − cells. While CD56 dim cells are more cytotoxic, CD56 bright cells produce high levels of cytokines such as IFNγ and TNFα 6 . The function of NK cells is induced by the interplay of inhibitory and activating receptors 7 , leading to cytotoxicity directed against tumors and virus-infected cells. Besides the recognition of these cells, NK cells also recognize other infectious pathogens, become activated, and as a response induce either lysis of these pathogens or trigger activation of other...
Super-resolution microscopy has evolved as a powerful method for subdiffractionresolution fluorescence imaging of cells and cellular organelles, but requires sophisticated and expensive installations. Expansion microscopy (ExM), which is based on the physical expansion of the cellular structure of interest, provides a cheap alternative to bypass the diffraction limit and enable super-resolution imaging on a conventional fluorescence microscope. While ExM has shown impressive results for the magnified visualization of proteins and RNAs in cells and tissues, it has not yet been applied in fungi, mainly due to their complex cell wall. Here we developed a method that enables reliable isotropic expansion of ascomycetes and basidiomycetes upon treatment with cell wall degrading enzymes. Confocal laser scanning microscopy (CLSM) and structured illumination microscopy (SIM) images of 4.5-fold expanded sporidia of Ustilago maydis expressing fluorescent fungal rhodopsins and hyphae of Fusarium oxysporum or Aspergillus fumigatus expressing either histone H1-mCherry together with Lifeact-sGFP or mRFP targeted to mitochondria, revealed details of subcellular structures with an estimated spatial resolution of around 30 nm. ExM is thus well suited for cell biology studies in fungi on conventional fluorescence microscopes.
Super-resolution microscopyrequires small fluorescent labels.Wereport the application of genetic code expansion in combination with bioorthogonal click chemistry to label the NR1 domain of the NMDAr eceptor.W eg enerated NR1 mutants incorporating an unnatural amino acid at various positions in order to attach small organic fluorophores such as Cy5-tetrazine site-specifically to the extracellular domain of the receptor.M utants were optimizedw ith regardt op rotein expression, labeling efficiency and receptor functionality as tested by fluorescence microscopyand whole-cell patchclamp. The results showt hat bioorthogonal clickc hemistry in combination with small organic dyes is superior to available immunocytochemistry protocols for receptor labeling in live and fixedc ells and enables single-molecule sensitive superresolution microscopyexperiments. Super-resolutionmicroscopyprovidesspatialresolutionwellbeyond the diffraction limit on the order of af ew tens of nanometers.A st he ability to resolve structures in fluorescence microscopy not only depends on the optical resolution but also on labeling size and density,there is astrong need for efficient fluorescence labeling methods. [1] Ideally,t he fluorescent label should be small (relative to the optical resolution), specific (targeted against aw ell determined antigen), effective (with ah igh labeling efficiency), show appropriate photophysical behavior (depending on the applied imaging technique), and should not impair target function. Small organic fluorophores have the smallest footprint if incorporated by site-specific chemistry on as mall carrier. [2] Va rious approaches exist to reduce the carrier size, such as using genetically encoded tags [3] nanobodies, [4] affimers, [5] aptamers, [6] super-binding peptides, [7] or rare amino acid side chains.
Fungi possess diverse photosensory proteins that allow them to perceive different light wavelengths and to adapt to changing light conditions in their environment. The biological and physiological roles of the green light-sensing rhodopsins in fungi are not yet resolved. The rice plant pathogen Fusarium fujikuroi exhibits two different rhodopsins, CarO and OpsA. CarO was previously characterized as a light-driven proton pump. We further analyzed the pumping behavior of CarO by patch-clamp experiments. Our data show that CarO pumping activity is strongly augmented in the presence of the plant hormone indole-3-acetic acid and in sodium acetate, in a dose-dependent manner under slightly acidic conditions. By contrast, under these and other tested conditions, the Neurospora rhodopsin (NR)-like rhodopsin OpsA did not exhibit any pump activity. Basic local alignment search tool (BLAST) searches in the genomes of ascomycetes revealed the occurrence of rhodopsin-encoding genes mainly in phyto-associated or phytopathogenic fungi, suggesting a possible correlation of the presence of rhodopsins with fungal ecology. In accordance, rice plants infected with a CarO-deficient F. fujikuroi strain showed more severe bakanae symptoms than the reference strain, indicating a potential role of the CarO rhodopsin in the regulation of plant infection by this fungus.
In fungi, green light is absorbed by rhodopsins, opsin proteins carrying a retinal molecule as chromophore. The basidiomycete Ustilago maydis , a fungal pathogen that infects corn plants, encodes three putative photoactive opsins, called ops1 (UMAG_02629), ops2 (UMAG_00371), and ops3 (UMAG_04125). UmOps1 and UmOps2 are expressed during the whole life cycle, in axenic cultures as well as in planta , whereas UmOps3 was recently shown to be absent in axenic cultures but highly expressed during plant infection. Here we show that expression of UmOps1 and UmOps2 is induced by blue light under control of white collar 1 (Wco1). UmOps1 is mainly localized in the plasma membrane, both when expressed in HEK cells and U. maydis sporidia. In contrast, UmOps2 was mostly found intracellularly in the membranes of vacuoles. Patch-clamp studies demonstrated that both rhodopsins are green light-driven outward rectifying proton pumps. UmOps1 revealed an extraordinary pH dependency with increased activity in more acidic environment. Also, UmOps1 showed a pronounced, concentration-dependent enhancement of pump current caused by weak organic acids (WOAs), especially by acetic acid and indole-3-acetic acid (IAA). In contrast, UmOps2 showed the typical behavior of light-driven, outwardly directed proton pumps, whereas UmOps3 did not exhibit any electrogenity. With this work, insights were gained into the localization and molecular function of two U. maydis rhodopsins, paving the way for further studies on the biological role of these rhodopsins in the life cycle of U. maydis .
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