In addition to their bridging function between innate and adaptive immunity, dendritic cells (DCs) may also contribute to primary resistance against infection. Here we analyzed the role of DCs during infection with Listeria monocytogenes by performing systemic in vivo depletion of these cells. We showed that CD8alpha(+) DCs were crucial for L. monocytogenes spreading and proliferation in the spleen. Efficient and rapid uptake of L. monocytogenes by CD8alpha(+) DCs required the small GTPase Rac1 and is a general characteristic of this DC subpopulation in filtering particles out of the blood. Thus, CD8alpha(+) DCs appear to play an important role for efficient bacterial entry into the spleen, which is of relevance for subsequent immune responses.
Ppt1 is the yeast member of a novel family of protein phosphatases, which is characterized by the presence of a tetratricopeptide repeat (TPR) domain. Ppt1 is known to bind to Hsp90, a molecular chaperone that performs essential functions in the folding and activation of a large number of client proteins. The function of Ppt1 in the Hsp90 chaperone cycle remained unknown. Here, we analyzed the function of Ppt1 in vivo and in vitro. We show that purified Ppt1 specifically dephosphorylates Hsp90. This activity requires Hsp90 to be directly attached to Ppt1 via its TPR domain. Deletion of the ppt1 gene leads to hyperphosphorylation of Hsp90 in vivo and an apparent decrease in the efficiency of the Hsp90 chaperone system. Interestingly, several Hsp90 client proteins were affected in a distinct manner. Our findings indicate that the Hsp90 multichaperone cycle is more complex than was previously thought. Besides its regulation via the Hsp90 ATPase activity and the sequential binding and release of cochaperones, with Ppt1, a specific phosphatase exists, which positively modulates the maturation of Hsp90 client proteins.
Prions are infectious, self-propagating amyloid-like protein aggregates of mammals and fungi. We have studied aggregation propensities of a yeast prion domain in cell culture to gain insights into general mechanisms of prion replication in mammalian cells. Here, we report the artificial transmission of a yeast prion across a phylogenetic kingdom. HA epitope-tagged yeast Sup35p prion domain NM was stably expressed in murine neuroblastoma cells. Although cytosolically expressed NM-HA remained soluble, addition of fibrils of bacterially produced Sup35NM to the medium efficiently induced appearance of phenotypically and biochemically distinct NM-HA aggregates that were inherited by daughter cells. Importantly, NM-HA aggregates also were infectious to recipient mammalian cells expressing soluble NM-HA and, to a lesser extent, to yeast. The fact that the yeast Sup35NM domain can propagate as a prion in neuroblastoma cells strongly argues that cellular mechanisms support prion-like inheritance in the mammalian cytosol.PrP ͉ Sup35 P rions are infectious particles composed exclusively or predominantly of proteins. In mammals, prions are the causative agent of transmissible spongiform encephalopathies or prion diseases that are associated with the conversion of the normal host encoded prion protein, PrP C , to its infectious, aggregated prion isoform, PrP Sc (1). Mammalian prion diseases belong to the group of protein misfolding diseases that are associated with the abnormal aggregation of diverse host proteins into highly ordered, -sheet-rich fibrillar aggregates, the so-called amyloids. A hallmark of prions is the existence of different strains that are associated with characteristic disease phenotypes (2). Remarkably, prions have also been identified in fungi, where they represent epigenetic elements of inheritance that replicate via a similar mechanism of selfpropagating protein conformation. Prions of eukaryotic microorganisms have been invaluable in elucidating basic concepts of prion biology. In fact, discoveries in yeast prion biology allowed formal demonstration of the protein-only hypothesis originally proposed for mammalian prions. Unlike mammalian prions, however, yeast prions are generally not lethal. The Saccharomyces cerevisiae epigenetic element [PSI ϩ ] is a prion of the translation termination factor subunit Sup35p (3, 4) that arises from conversion of soluble active monomers to an inactive amyloid (5-9), leading to a change in the yeast metabolic phenotype. Translation termination activity is conferred by the carboxyl-terminal domain C, whereas the amino-terminal Sup35NM domain is necessary and sufficient for prion-based inheritance (10). The N region comprises a prionforming domain (amino acids 1-97), which is defined as the minimal region essential for induction and propagation of the prion state (10). Acting as a linker between the N and C regions, the highly charged M region increases the solubility of the protein (8) and imparts stability of the prion during mitosis and meiosis (11). Yeast prion b...
Prions are self-templating protein conformers that replicate by recruitment and conversion of homotypic proteins into growing protein aggregates. Originally identified as causative agents of transmissible spongiform encephalopathies, increasing evidence now suggests that prion-like phenomena are more common in nature than previously anticipated. In contrast to fungal prions that replicate in the cytoplasm, propagation of mammalian prions derived from the precursor protein PrP is confined to the cell membrane or endocytic vesicles. Here we demonstrate that cytosolic protein aggregates can also behave as infectious entities in mammalian cells. When expressed in the mammalian cytosol, protein aggregates derived from the prion domain NM of yeast translation termination factor Sup35 persistently propagate and invade neighboring cells, thereby inducing a self-perpetuating aggregation state of NM. Cell contact is required for efficient infection. Aggregates can also be induced in primary astrocytes, neurons, and organotypic cultures, demonstrating that this phenomenon is not specific to immortalized cells. Our data have important implications for understanding prion-like phenomena of protein aggregates associated with human diseases and for the growing number of amyloidogenic proteins discovered in mammals.
Cationic triphenylphosphinegold(I) complexes are excellent catalysts for a cascade reaction of propargyl-Claisen rearrangement and heterocyclization to synthesize tri- and tetrasubstituted furans. Starting from easily accessed propargyl vinyl ethers, the furans are obtained in 72-99% yield. [reaction: see text]
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