Die Regulation des Zelltods ist ein kritischer Schritt in der Embryonalentwicklung, der Gewebehomöostase und bei der Abwehr eindringender Krankheitserreger. Hierbei spielt Caspase-8 (Casp8) eine entscheidende Rolle, indem das Enzym extrinsische Apoptose induziert. Außerdem hemmt Casp8 Nekroptose und sichert so die embryonale Entwicklung. Wir zeigen hier, dass eine weitere wichtige Funktion der enzymatische Aktivität von Casp8 die Hemmung der Pyroptose ist. Um die spezifische Rolle der enzymatischen Aktivität von Casp8 zu untersuchen, haben wir eine Mauslinie etabliert, welche eine Punktmutation in der Substratbindetasche von Casp8 (Mutation des katalytischen Cysteins 362 zu Serin) aufweist. Diese Mutation führt zum Verlust der enzymatischer Aktivität von Casp8 C362S. Die Expression von katalytisch inaktiver Casp8 C362S resultiert in eine embryonale Letalität bei E10,5 aufgrund von kardiovaskulären Defekten, ähnlich zu Casp8-/-Mäusen. Die Blockade von Nekroptose durch zusätzliche Deletion von MLKL verhinderte den kardiovaskulären Phänotyp, verursachte jedoch unerwartet die perinatale Letalität von Casp8 C362S/C362S Mäusen. Dies deutet darauf hin, dass der Verlust der enzymatischen Aktivität von Casp8 die perinatale Entwicklung durch zusätzliche, Nekroptose-unabhängigen Funktionen beeinträchtigt. Der spezifische Verlust der katalytischen Aktivität von Casp8 in Darmepithelzellen (IECs) führte zu einer Darmentzündung ähnlich zu Casp8 IEC-KO Mäusen. Eine zusätzliche Deletion von MLKL verschlimmerte die Entzündung des Darms und verursachte ein vorzeitiges Versterben von Casp8 C362S/IEC-/Mlkl-/-Mäusen durch die Induktion des pyroptischen Zelltods. In diesem Zusammenhang konnten Prozesse, welche charakteristisch für Pyroptose sind, wie die Bildung von ASC-Specks, die Aktivierung von Casp1 sowie die Produktion von IL-1β beobachtet werden. Unsere Zellkulturanalysen zeigen, dass katalytisch inaktive Casp8 mit ASC kolokalisiert, sowie ASC-Nukleation und Casp1-Aktivierung induziert. Dementsprechend verhinderte die Deletion von ASC oder Casp1 die Entzündung des Darms und den vorzeitigen Tod von Casp8 C362S/C362S /Mlkl-/-Mäusen. Diese Ergebnisse zeigen eine noch unbekannte und unerwartete Rolle für Casp8 als Proteingerüst eines Signalkomplexes, welcher unter Gegebenheiten bei denen Apoptose und Nekroptose blockiert sind, gebildet wird.
Clinical resistance to epidermal growth factor receptor (EGFR) inhibition in lung cancer has been linked to the emergence of the EGFR T790M resistance mutation or amplification of MET. Additional mechanisms contributing to EGFR inhibitor resistance remain elusive. By applying combined analyses of gene expression, copy number, and biochemical analyses of EGFR inhibitor responsiveness, we identified homozygous loss of PTEN to segregate EGFRdependent and EGFR-independent cells. We show that in EGFR-dependent cells, PTEN loss partially uncouples mutant EGFR from downstream signaling and activates EGFR, thereby contributing to erlotinib resistance. The clinical relevance of our findings is supported by the observation of PTEN loss in 1 out of 24 primary EGFR-mutant non-small cell lung cancer (NSCLC) tumors. These results suggest a novel resistance mechanism in EGFR-mutant NSCLC involving PTEN loss.
Staphylococcus aureus is a common bacterial etiology of serious infectious diseases. S. aureus can invade various types of non-professional phagocytes to produce host cell death. We show here that shortly after invasion of HeLa cells S. aureus transit to autophagosomes was characterized by double membranes and co-localization with LC3. S. aureus were not able to replicate and produce cell death in autophagy-deficient atg5 ؊/؊ mouse embryonic fibroblasts. S. aureus-containing autophagosomes do not acidify nor do they acquire lysosome-associated membrane protein-2, indicating that S. aureus inhibits autophagosome maturation and fusion with lysosomes. Eventually, S. aureus escape from autophagosomes into the cytoplasm, which results in caspase-independent host cell death. S. aureus strains deficient for agr, a global regulator of S. aureus virulence, were not targeted by autophagy and did not produce host-cell death. Autophagy induction by rapamycin restored both replication and cytotoxicity of agr-deficient S. aureus strains, indicating that an agr-regulated factor(s) is required for autophagy-mediated cytotoxicity. The results of this study suggest that rapid induction of autophagy is essential for S. aureus replication, escape into the cytoplasm, and host cell killing.Staphylococcus aureus is the major cause of community-acquired and nosocomial infections such as pneumonia, endocarditis, osteomyelitis, and wound infections (1, 2). An important feature of S. aureus is the ability to invade the vascular system from local infection sites (3). Such dissemination includes passing across cellular barriers like the endothelial barrier, which leads to bacteremia and sepsis. Recent studies revealed the consistent ability of S. aureus to infect various types of non-professional phagocytic host cells such as keratinocytes, fibroblasts, endothelial cells, and epithelial cells (4 -6). Adherence to and invasion of non-professional phagocytic cells by S. aureus has been implicated in the pathogenesis of invasive and metastatic infections i.e. during hematogenous dissemination (7).We have recently shown that some but not all S. aureus strains are able to induce host cell death after invasion, which correlates with the virulence of a particular S. aureus strain (8). However, the exact molecular mechanisms leading to intracellular survival of S. aureus and death of host cells remained unclear. Although some investigators reported induction of caspase-dependent programmed cell death (apoptosis) involving tumor necrosis factor or CD95 signaling pathways, others observed necrosis of S. aureus-infected host cells induced by ␣-toxin (9 -11).In many cases microorganisms internalized by host cells are efficiently eliminated by host defense mechanisms. The microbial phagosome matures by sequential transient fusion events with early and late endosomal compartments, which are controlled by Rab GTPases (12). However, some pathogens like Mycobacteria tuberculosis, Legionella pneumophila, and Brucella abortus have evolved species-specific mec...
In cancer, genetically activated proto-oncogenes often induce ''upstream'' dependency on the activity of the mutant oncoprotein. Therapeutic inhibition of these activated oncoproteins can induce massive apoptosis of tumor cells, leading to sometimes dramatic tumor regressions in patients. The PI3K and MAPK signaling pathways are central regulators of oncogenic transformation and tumor maintenance. We hypothesized that upstream dependency engages either one of these pathways preferentially to induce ''downstream'' dependency. Therefore, we analyzed whether downstream pathway dependency segregates by genetic aberrations upstream in lung cancer cell lines. Here, we show by systematically linking drug response to genomic aberrations in non-small-cell lung cancer, as well as in cell lines of other tumor types and in a series of in vivo cancer models, that tumors with genetically activated receptor tyrosine kinases depend on PI3K signaling, whereas tumors with mutations in the RAS/RAF axis depend on MAPK signaling. However, efficacy of downstream pathway inhibition was limited by release of negative feedback loops on the reciprocal pathway. By contrast, combined blockade of both pathways was able to overcome the reciprocal pathway activation induced by inhibitor-mediated release of negative feedback loops and resulted in a significant increase in apoptosis and tumor shrinkage. Thus, by using a systematic chemo-genomics approach, we identify genetic lesions connected to PI3K and MAPK pathway activation and provide a rationale for combined inhibition of both pathways. Our findings may have implications for patient stratification in clinical trials.cancer genomics ͉ combination therapy ͉ high-throughput cell line screening ͉ oncogene dependency
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