Your search keyword '"Franz-Wachtel, Mirita"' showing total 6 results

1. The T4bSS of Legionella features a two-step secretion pathway with an inner membrane intermediate for secretion of transmembrane effectors.

Author

Malmsheimer, Silke, Grin, Iwan, Bohn, Erwin, Franz-Wachtel, Mirita, Macek, Boris, Sahr, Tobias, Smollich, Fabian, Chetrit, David, Meir, Amit, Roy, Craig, Buchrieser, Carmen, and Wagner, Samuel

Subjects

MEMBRANE proteins, BACTERIAL cell walls, ALVEOLAR macrophages, BIOLOGICAL membranes, EUKARYOTIC cells

Abstract

To promote intracellular survival and infection, Legionella spp. translocate hundreds of effector proteins into eukaryotic host cells using a type IV b protein secretion system (T4bSS). T4bSS are well known to translocate soluble as well as transmembrane domain-containing effector proteins (TMD-effectors) but the mechanisms of secretion are still poorly understood. Herein we investigated the secretion of hydrophobic TMD-effectors, of which about 80 were previously reported to be encoded by L. pneumophila. A proteomic analysis of fractionated membranes revealed that TMD-effectors are targeted to and inserted into the bacterial inner membranes of L. pneumophila independent of the presence of a functional T4bSS. While the T4bSS chaperones IcmS and IcmW were critical for secretion of all tested TMD-effectors, they did not influence inner membrane targeting of these proteins. As for soluble effector proteins, translocation of all investigated TMD-effectors depended on a C-terminal secretion signal. A deeper analysis of the TMD-effector SidF showed that this signal needed to be presented towards the cytoplasmic side of the inner membrane and that a small periplasmic loop was required for efficient translocation. We propose that strongly hydrophobic TMD-effectors are secreted in a two-step secretion process: Initially, an inner membrane intermediate is formed, that is extracted towards the cytoplasmic side, possibly by the help of the type IV coupling protein complex and subsequently secreted into eukaryotic host cells by the T4bSS core complex. Overall, our study highlights the amazing versatility of T4bSS to secrete soluble and TMD-effectors from different subcellular locations of the bacterial cell. Author summary: Legionella is a water-borne bacterial pathogen that can cause severe and often fatal pneumonia. It employs a so-called type VI b secretion system to inject hundreds of different effector proteins in order to establish an intracellular niche inside its natural host amoeba or inside alveolar macrophages of the lung. Many of these effector proteins are hydrophobic transmembrane proteins that find their final destination in one of the host cell's biological membranes. Here we present evidence that some of these transmembrane-effectors are secreted in a two-step secretion process with an intermediate in the inner membrane of Legionella. Extraction from this membrane and subsequent secretion likely occur at the cytoplasmic side of the membrane as these transmembrane effectors require C-terminal secretion signals facing inside. Our study highlights the amazing capability of type VI b secretion systems to secrete soluble and transmembrane-effectors from different subcellular locations of the bacterial cell. [ABSTRACT FROM AUTHOR]

Published

2024

2. A single class of ARF GTPase activated by several pathway-specific ARF-GEFs regulates essential membrane traffic in Arabidopsis.

Author

Singh, Manoj K., Richter, Sandra, Beckmann, Hauke, Kientz, Marika, Stierhof, York-Dieter, Anders, Nadine, Fäßler, Florian, Nielsen, Michael, Knöll, Christian, Thomann, Alexis, Franz-Wachtel, Mirita, Macek, Boris, Skriver, Karen, Pimpl, Peter, and Jürgens, Gerd

Subjects

GUANOSINE triphosphatase, GTPASE-activating protein, ARABIDOPSIS, GUANINE nucleotide exchange factors, INTRACELLULAR membranes

Abstract

In eukaryotes, GTP-bound ARF GTPases promote intracellular membrane traffic by mediating the recruitment of coat proteins, which in turn sort cargo proteins into the forming membrane vesicles. Mammals employ several classes of ARF GTPases which are activated by different ARF guanine-nucleotide exchange factors (ARF-GEFs). In contrast, flowering plants only encode evolutionarily conserved ARF1 GTPases (class I) but not the other classes II and III known from mammals, as suggested by phylogenetic analysis of ARF family members across the five major clades of eukaryotes. Instead, flowering plants express plant-specific putative ARF GTPases such as ARFA and ARFB, in addition to evolutionarily conserved ARF-LIKE (ARL) proteins. Here we show that all eight ARF-GEFs of Arabidopsis interact with the same ARF1 GTPase, whereas only a subset of post-Golgi ARF-GEFs also interacts with ARFA, as assayed by immunoprecipitation. Both ARF1 and ARFA were detected at the Golgi stacks and the trans-Golgi network (TGN) by both live-imaging with the confocal microscope and nano-gold labeling followed by EM analysis. ARFB representing another plant-specific putative ARF GTPase was detected at both the plasma membrane and the TGN. The activation-impaired form (T31N) of ARF1, but neither ARFA nor ARFB, interfered with development, although ARFA-T31N interfered, like ARF1-T31N, with the GDP-GTP exchange. Mutant plants lacking both ARFA and ARFB transcripts were viable, suggesting that ARF1 is sufficient for all essential trafficking pathways under laboratory conditions. Detailed imaging of molecular markers revealed that ARF1 mediated all known trafficking pathways whereas ARFA was not essential to any major pathway. In contrast, the hydrolysis-impaired form (Q71L) of both ARF1 and ARFA, but not ARFB, had deleterious effects on development and various trafficking pathways. However, the deleterious effects of ARFA-Q71L were abolished by ARFA-T31N inhibiting cognate ARF-GEFs, both in cis (ARFA-T31N,Q71L) and in trans (ARFA-T31N + ARFA-Q71L), suggesting indirect effects of ARFA-Q71L on ARF1-mediated trafficking. The deleterious effects of ARFA-Q71L were also suppressed by strong over-expression of ARF1, which was consistent with a subset of BIG1-4 ARF-GEFs interacting with both ARF1 and ARFA. Indeed, the SEC7 domain of BIG5 activated both ARF1 and ARFA whereas the SEC7 domain of BIG3 only activated ARF1. Furthermore, ARFA-T31N impaired root growth if ARF1-specific BIG3 was knocked out and only ARF1- and ARFA-activating BIG4 was functional. Activated ARF1 recruits different coat proteins to different endomembrane compartments, depending on its activation by different ARF-GEFs. Unlike ARF GTPases, ARF-GEFs not only localize at distinct compartments but also regulate specific trafficking pathways, suggesting that ARF-GEFs might play specific roles in traffic regulation beyond the activation of ARF1 by GDP-GTP exchange. [ABSTRACT FROM AUTHOR]

Published

2018

3. A flagellum-specific chaperone facilitates assembly of the core type III export apparatus of the bacterial flagellum.

Author

Fabiani, Florian D., Renault, Thibaud T., Peters, Britta, Dietsche, Tobias, Gálvez, Eric J. C., Guse, Alina, Freier, Karen, Charpentier, Emmanuelle, Strowig, Till, Franz-Wachtel, Mirita, Macek, Boris, Wagner, Samuel, Hensel, Michael, and Erhardt, Marc

Subjects

MOLECULAR chaperones, BIOSYNTHESIS, MEMBRANE proteins, PROTEOLYTIC enzymes, PROTONS

Abstract

Many bacteria move using a complex, self-assembling nanomachine, the bacterial flagellum. Biosynthesis of the flagellum depends on a flagellar-specific type III secretion system (T3SS), a protein export machine homologous to the export machinery of the virulence-associated injectisome. Six cytoplasmic (FliH/I/J/G/M/N) and seven integral-membrane proteins (FlhA/B FliF/O/P/Q/R) form the flagellar basal body and are involved in the transport of flagellar building blocks across the inner membrane in a proton motive force-dependent manner. However, how the large, multi-component transmembrane export gate complex assembles in a coordinated manner remains enigmatic. Specific for most flagellar T3SSs is the presence of FliO, a small bitopic membrane protein with a large cytoplasmic domain. The function of FliO is unknown, but homologs of FliO are found in >80% of all flagellated bacteria. Here, we demonstrate that FliO protects FliP from proteolytic degradation and promotes the formation of a stable FliP–FliR complex required for the assembly of a functional core export apparatus. We further reveal the subcellular localization of FliO by super-resolution microscopy and show that FliO is not part of the assembled flagellar basal body. In summary, our results suggest that FliO functions as a novel, flagellar T3SS-specific chaperone, which facilitates quality control and productive assembly of the core T3SS export machinery. [ABSTRACT FROM AUTHOR]

Published

2017

4. Ste12/Fab1 phosphatidylinositol-3-phosphate 5-kinase is required for nitrogen-regulated mitotic commitment and cell size control.

Author

Cobley, David, Hálová, Lenka, Schauries, Marie, Kaczmarek, Adrian, Franz-Wachtel, Mirita, Du, Wei, Krug, Karsten, Maček, Boris, and Petersen, Janni

Subjects

PHOSPHATIDYLINOSITOL 3-kinases, CELL cycle, CELL size, CELL growth, TOR proteins, CELL proliferation

Abstract

Tight coupling of cell growth and cell cycle progression enable cells to adjust their rate of division, and therefore size, to the demands of proliferation in varying nutritional environments. Nutrient stress promotes inhibition of Target Of Rapamycin Complex 1 (TORC1) activity. In fission yeast, reduced TORC1 activity advances mitotic onset and switches growth to a sustained proliferation at reduced cell size. A screen for mutants, that failed to advance mitosis upon nitrogen stress, identified a mutant in the PIKFYVE 1-phosphatidylinositol-3-phosphate 5-kinase fission yeast homolog Ste12. Ste12PIKFYVE deficient mutants were unable to advance the cell cycle to reduce cell size after a nitrogen downshift to poor nitrogen (proline) growth conditions. While it is well established that PI(3,5)P2 signalling is required for autophagy and that Ste12PIKFYVE mutants have enlarged vacuoles (yeast lysosomes), neither a block to autophagy or mutants that independently have enlarged vacuoles had any impact upon nitrogen control of mitotic commitment. The addition of rapamycin to Ste12PIKFYVE deficient mutants reduced cell size at division to suggest that Ste12PIKFYVE possibly functions upstream of TORC1. ste12 mutants display increased Torin1 (TOR inhibitor) sensitivity. However, no major impact on TORC1 or TORC2 activity was observed in the ste12 deficient mutants. In summary, Ste12PIKFYVE is required for nitrogen-stress mediated advancement of mitosis to reduce cell size at division. [ABSTRACT FROM AUTHOR]

Published

2017

5. Structural and Functional Characterization of the Bacterial Type III Secretion Export Apparatus.

Author

Dietsche, Tobias, Tesfazgi Mebrhatu, Mehari, Zilkenat, Susann, Grin, Iwan, Wagner, Samuel, Brunner, Matthias J., Marlovits, Thomas C., Abrusci, Patrizia, Lea, Susan, Yan, Jun, Robinson, Carol V., Franz-Wachtel, Mirita, Macek, Boris, Schärfe, Charlotta, Kohlbacher, Oliver, and Galán, Jorge E.

Subjects

MICROBIOLOGY, CYTOGENETICS, GATING system (Founding), GRAM-negative bacteria, STOICHIOMETRY

Abstract

Bacterial type III protein secretion systems inject effector proteins into eukaryotic host cells in order to promote survival and colonization of Gram-negative pathogens and symbionts. Secretion across the bacterial cell envelope and injection into host cells is facilitated by a so-called injectisome. Its small hydrophobic export apparatus components SpaP and SpaR were shown to nucleate assembly of the needle complex and to form the central “cup” substructure of a Salmonella Typhimurium secretion system. However, the in vivo placement of these components in the needle complex and their function during the secretion process remained poorly defined. Here we present evidence that a SpaP pentamer forms a 15 Å wide pore and provide a detailed map of SpaP interactions with the export apparatus components SpaQ, SpaR, and SpaS. We further refine the current view of export apparatus assembly, consolidate transmembrane topology models for SpaP and SpaR, and present intimate interactions of the periplasmic domains of SpaP and SpaR with the inner rod protein PrgJ, indicating how export apparatus and needle filament are connected to create a continuous conduit for substrate translocation. [ABSTRACT FROM AUTHOR]

Published

2016

6. Control of Morphological Differentiation of Streptomyces coelicolor A3(2) by Phosphorylation of MreC and PBP2.

Author

Ladwig, Nils, Franz-Wachtel, Mirita, Hezel, Felix, Soufi, Boumediene, Macek, Boris, Wohlleben, Wolfgang, and Muth, Günther

Subjects

*STREPTOMYCES coelicolor, *BACTERIA morphology, *PHOSPHORYLATION, *SERINE/THREONINE kinases, *BACTERIAL genomes, *EUKARYOTES

Abstract

During morphological differentiation of Streptomyces coelicolor A3(2), the sporogenic aerial hyphae are transformed into a chain of more than fifty spores in a highly coordinated manner. Synthesis of the thickened spore envelope is directed by the Streptomyces spore wall synthesizing complex SSSC which resembles the elongasome of rod-shaped bacteria. The SSSC includes the eukaryotic type serine/threonine protein kinase (eSTPK) PkaI, encoded within a cluster of five independently transcribed eSTPK genes (SCO4775-4779). To understand the role of PkaI in spore wall synthesis, we screened a S. coelicolor genomic library for PkaI interaction partners by bacterial two-hybrid analyses and identified several proteins with a documented role in sporulation. We inactivated pkaI and deleted the complete SCO4775-4779 cluster. Deletion of pkaI alone delayed sporulation and produced some aberrant spores. The five-fold mutant NLΔ4775-4779 had a more severe defect and produced 18% aberrant spores affected in the integrity of the spore envelope. Moreover, overbalancing phosphorylation activity by expressing a second copy of any of these kinases caused a similar defect. Following co-expression of pkaI with either mreC or pbp2 in E. coli, phosphorylation of MreC and PBP2 was demonstrated and multiple phosphosites were identified by LC-MS/MS. Our data suggest that elaborate protein phosphorylation controls activity of the SSSC to ensure proper sporulation by suppressing premature cross-wall synthesis. [ABSTRACT FROM AUTHOR]

Published

2015