The PIDDosome activates p53 in response to supernumerary centrosomes.

Centrosomes, the main microtubule-organizing centers in animal cells, are replicated exactly once during the cell division cycle to form the poles of the mitotic spindle. Supernumerary centrosomes can lead to aberrant cell division and have been causally linked to chromosomal instability and cancer. Here, we report that an increase in the number of mature centrosomes, generated by disrupting cytokinesis or forcing centrosome overduplication, triggers the activation of the PIDDosome multiprotein complex, leading to Caspase-2-mediated MDM2 cleavage, p53 stabilization, and p21-dependent cell cycle arrest. This pathway also restrains the extent of developmentally scheduled polyploidization by regulating p53 levels in hepatocytes during liver organogenesis. Taken together, the PIDDosome acts as a first barrier, engaging p53 to halt the proliferation of cells carrying more than one mature centrosome to maintain genome integrity.

Targeting antiapoptotic A1/Bfl-1 by in vivo RNAi reveals multiple roles in leukocyte development in mice.

Gene-targeting studies in mice have identified the essential roles of most prosurvival Bcl-2 family members in normal physiology and under conditions of stress. The function of one member, Bcl2a1/Bfl-1/A1, is only poorly understood because of quadruplication of its gene locus in mice, hindering conventional knockout studies. To overcome this problem, we generated mouse models allowing traceable constitutive or reversible ablation of A1 in the hematopoietic system by RNA interference. Knockdown of A1 impaired early stages of T-cell differentiation, B-cell homeostasis, and sensitized transitional as well as follicular B cells to apoptosis induced by ligation of the B-cell receptor. As a consequence, B-cell proliferation in response to mitogens was severely impaired, whereas that of T cells appeared unaffected. Furthermore, depending on the extent of A1 knockdown, granulocytes showed increased spontaneous death in culture or failed to accumulate in significant numbers in vivo. These models highlight the critical role of A1 in leukocyte development and homeostasis, constituting valuable tools for investigating presumed roles of this Bcl-2 family member in immunity, tumorigenesis, and drug resistance.

Necrosis-like death can engage multiple pro-apoptotic Bcl-2 protein family members.

Necroptosis is a physiologically relevant mode of cell death with some well-described initiating events, but largely unknown executioners. Here we investigated necrostatin-1 (Nec-1) sensitive death elicited by different necroptosis stimuli in L929 mouse fibrosarcoma cells, mouse embryonic fibroblasts (MEF) and bone marrow-derived macrophages. We found that TNFα- or zVAD-induced necroptosis occurs independently of the recently implicated executioners Bmf or PARP-2, but can involve the Bcl-2 family proteins Bid and Bak. Furthermore, this type of necroptosis is associated with mitochondrial cytochrome c release and partly sensitive to cyclosporine A inhibition, suggesting a cross talk with the mitochondrial permeability transition pore. Necroptosis triggered by cadmium (Cd) exposure caused fully Nec-1-sensitive and caspase-independent death in L929 cells that was associated with autocrine TNFα-mediated feed-forward signalling. In MEF Cd-exposure elicited a mixed mode of cell death that was to some extent Nec-1-sensitive but also displayed features of apoptosis. It was partly dependent on Bmf and Bax/Bak, proteins typically considered to act pro-apoptotic, but ultimately insensitive to caspase inhibition. Overall, our study indicates that inducers of "extrinsic" and "intrinsic" necroptosis can both trigger TNF-receptor signalling. Further, necroptosis may depend on mitochondrial changes engaging proteins considered critical for MOMP during apoptosis that ultimately contribute to caspase-independent necrotic cell death.

The BH3-only protein NOXA serves as an independent predictor of breast cancer patient survival and defines susceptibility to microtubule targeting agents.

Breast cancer (BC) treatment frequently involves microtubule-targeting agents (MTAs), such as paclitaxel, that arrest cells in mitosis. Sensitivity to MTAs is defined by a subset of pro- and anti-apoptotic BCL2 family proteins controlling mitochondrial apoptosis. Here, we aimed to determine their prognostic value in primary tumour samples from 92 BC patients. Our analysis identified high NOXA/PMAIP mRNA expression levels as an independent prognostic marker for improved relapse-free survival (RFS) and overall survival (OS) in multivariate analysis in BC patients, independent of their molecular subtype. Analysis of available TCGA datasets of 1060 BC patients confirmed our results and added a clear predictive value of NOXA mRNA levels for patients who received MTA-based therapy. In this TCGA cohort, 122 patients received MTA-treatment and high NOXA mRNA levels correlated with their progression-free interval (PFI) and OS. Our follow-up analyses in a panel of BC cell lines of different molecular subtypes identified NOXA protein expression as a key determinant of paclitaxel sensitivity in triple-negative breast cancer (TNBC) cells. Moreover, we noted highest additive effects between paclitaxel and chemical inhibition of BCLX, but not BCL2 or MCL1, documenting dependence of TNBC cells on BCLX for survival and paclitaxel sensitivity defined by NOXA expression levels.

MARCH5-dependent degradation of MCL1/NOXA complexes defines susceptibility to antimitotic drug treatment.

Cells experiencing delays in mitotic progression are prone to undergo apoptosis unless they can exit mitosis before proapoptotic factors reach a critical threshold. Microtubule targeting agents (MTAs) arrest cells in mitosis and induce apoptotic cell death engaging the BCL2 network. Degradation of the antiapoptotic BCL2 family member MCL-1 is considered to set the time until onset of apoptosis upon MTA treatment. MCL1 degradation involves its interaction with one of its key binding partners, the proapoptotic BH3-only protein NOXA. Here, we report that the mitochondria-associated E3-ligase MARCH5, best known for its role in mitochondrial quality control and regulation of components of the mitochondrial fission machinery, controls the levels of MCL1/NOXA protein complexes in steady state as well as during mitotic arrest. Inhibition of MARCH5 function sensitizes cancer cells to the proapoptotic effects of MTAs by the accumulation of NOXA and primes cancer cells that may undergo slippage to escape death in mitosis to cell death in the next G1 phase. We propose that inhibition of MARCH5 may be a suitable strategy to sensitize cancer cells to antimitotic drug treatment.

E2F-Family Members Engage the PIDDosome to Limit Hepatocyte Ploidy in Liver Development and Regeneration.

E2F transcription factors control the cytokinesis machinery and thereby ploidy in hepatocytes. If or how these proteins limit proliferation of polyploid cells with extra centrosomes remains unknown. Here, we show that the PIDDosome, a signaling platform essential for caspase-2-activation, limits hepatocyte ploidy and is instructed by the E2F network to control p53 in the developing as well as regenerating liver. Casp2 and Pidd1 act as direct transcriptional targets of E2F1 and its antagonists, E2F7 and E2F8, that together co-regulate PIDDosome expression during juvenile liver growth and regeneration. Of note, whereas hepatocyte aneuploidy correlates with the basal ploidy state, the degree of aneuploidy itself is not limited by PIDDosome-dependent p53 activation. Finally, we provide evidence that the same signaling network is engaged to control ploidy in the human liver after resection. Our study defines the PIDDosome as a primary target to manipulate hepatocyte ploidy and proliferation rates in the regenerating liver.

CHK1 dosage in germinal center B cells controls humoral immunity.

Germinal center (GC) B cells are among the fastest replicating cells in our body, dividing every 4-8 h. DNA replication errors are intrinsically toxic to cells. How GC B cells exert control over the DNA damage response while introducing mutations in their antibody genes is poorly understood. Here, we show that the DNA damage response regulator Checkpoint kinase 1 (CHK1) is essential for GC B cell survival. Remarkably, effective antibody-mediated immunity relies on optimal CHK1 dosage. Chemical CHK1 inhibition or loss of one Chk1 allele impairs the survival of class-switched cells and curbs the amplitude of antibody production. Mechanistically, active B cell receptor signaling wires the outcome of CHK1-inhibition towards BIM-dependent apoptosis, whereas T cell help favors temporary cell cycle arrest. Our results predict that therapeutic CHK1 inhibition in cancer patients may prove potent in killing B cell lymphoma and leukemia cells addicted to B cell receptor signaling, but will most likely dampen humoral immunity.

Regulation and function of the cytokine-inducible SH-2 domain proteins, CIS and SOCS3, in mammary epithelial cells.

The cytokine-inducible src homology 2 (SH-2) proteins, CIS (cytokine inducible SH-2 domain protein) and SOCS3 (suppressor of cytokine signaling 3), are implicated in the negative regulation of prolactin (PRL) receptor-mediated activation of signal transducer and activator of transcription 5 (STAT5). We have studied the expression and function of CIS and SOCS3 proteins in the mouse mammary gland and in HC11 mammary epithelial cells. CIS and SOCS3 were differentially regulated: high expression levels of CIS mRNA were measured during the second half of pregnancy, whereas SOCS3 expression was high during the first 12 d post conceptum. SOCS3 levels increased, whereas CIS levels decreased, in the initial phase of involution. At the beginning of the lactation period both CIS and SOCS3 were high. PRL and epidermal growth factor (EGF) were able to induce CIS and SOCS3, whereas glucocorticoids inhibited their expression in mammary epithelial cells. The effect of EGF was much stronger on SOCS3 than on CIS. Ectopic expression of both SOCS3 and CIS inhibited STAT5 activation. Our data indicate that in the mammary gland CIS and SOCS3 are involved in regulating STAT5 signaling at three different instances: 1) SOCS3 serves as a mediator of the inhibitory EGF effect on PRL-induced STAT5 activation; 2) CIS and SOCS3 play a role as negative feedback inhibitors of PRL action; 3) Inhibition of CIS and SOCS3 expression by glucocorticoids contributes to the positive effect of glucocorticoids on PRL-induced STAT5 activation.

Embryonic stem cell differentiation requires full length Chd1.

The modulation of chromatin dynamics by ATP-dependent chromatin remodeling factors has been recognized as an important mechanism to regulate the balancing of self-renewal and pluripotency in embryonic stem cells (ESCs). Here we have studied the effects of a partial deletion of the gene encoding the chromatin remodeling factor Chd1 that generates an N-terminally truncated version of Chd1 in mouse ESCs in vitro as well as in vivo. We found that a previously uncharacterized serine-rich region (SRR) at the N-terminus is not required for chromatin assembly activity of Chd1 but that it is subject to phosphorylation. Expression of Chd1 lacking this region in ESCs resulted in aberrant differentiation properties of these cells. The self-renewal capacity and ESC chromatin structure, however, were not affected. Notably, we found that newly established ESCs derived from Chd1(Δ2/Δ2) mutant mice exhibited similar differentiation defects as in vitro generated mutant ESCs, even though the N-terminal truncation of Chd1 was fully compatible with embryogenesis and post-natal life in the mouse. These results underscore the importance of Chd1 for the regulation of pluripotency in ESCs and provide evidence for a hitherto unrecognized critical role of the phosphorylated N-terminal SRR for full functionality of Chd1.

The NOXA-MCL1-BIM axis defines lifespan on extended mitotic arrest.

Cell death on extended mitotic arrest is considered arguably most critical for the efficacy of microtubule-targeting agents (MTAs) in anticancer therapy. While the molecular machinery controlling mitotic arrest on MTA treatment, the spindle assembly checkpoint (SAC), appears well defined, the molecular components executing cell death, as well as factors connecting both networks remain poorly understood. Here we conduct a mini screen exploring systematically the contribution of individual BCL2 family proteins at single cell resolution to death on extended mitotic arrest, and demonstrate that the mitotic phosphorylation of BCL2 and BCLX represent a priming event for apoptosis that is ultimately triggered by NOXA-dependent MCL1 degradation, enabling BIM-dependent cell death. Our findings provide a comprehensive model for the initiation of apoptosis in cells stalled in mitosis and provide a molecular basis for the increased efficacy of combinatorial treatment of cancer cells using MTAs and BH3 mimetics.