Bernd Nürnberg

PI3K promotes voltage-dependent calcium channel trafficking to the plasma membrane

Phosphatidylinositol 3-kinase (PI3K) has been shown to enhance native voltage-dependent calcium channel (Cav) currents both in myocytes and in neurons; however, the mechanism(s) responsible for this regulation were not known. Here we show that PI3K promotes the translocation of GFP-tagged Cav channels to the plasma membrane in both COS-7 cells and neurons. We show that the effect of PI3K is mediated by Akt/PKB and specifically requires Cavβ2 subunits. The mutations S574A and S574E in Cavβ2a prevented and mimicked, respectively, the effect of PI3K/Akt-PKB, indicating that phosphorylation of Ser574 on Cavβ2a is necessary and sufficient to promote Cav channel trafficking.

Macrophages Induce the Inflammatory Response in the Pulmonary Arthus Reaction through Gαi2 Activation That Controls C5aR and Fc Receptor Cooperation

Complement and FcγR effector pathways are central triggers of immune inflammation; however, the exact mechanisms for their cooperation with effector cells and their nature remain elusive. In this study we show that in the lung Arthus reaction, the initial contact between immune complexes and alveolar macrophages (AM) results in plasma complement-independent C5a production that causes decreased levels of inhibitory FcγRIIB, increased levels of activating FcγRIII, and highly induced FcγR-mediated TNF-α and CXCR2 ligand production. Blockade of C5aR completely reversed such changes. Strikingly, studies of pertussis toxin inhibition show the essential role of Gi-type G protein signaling in C5aR-mediated control of the regulatory FcγR system in vitro, and analysis of the various C5aR-, FcγR-, and Gi-deficient mice verifies the importance of Gαi2-associated C5aR and the FcγRIII-FcγRIIB receptor pair in lung inflammation in vivo. Moreover, adoptive transfer experiments of C5aR- and FcγRIII-positive cells into C5aR- and FcγRIII-deficient mice establish AM as responsible effector cells. AM lacking either C5aR or FcγRIII do not possess any such inducibility of immune complex disease, whereas reconstitution with FcγRIIB-negative AM results in an enhanced pathology. These data suggest that AM function as a cellular link of C5a production and C5aR activation that uses a Gαi2-dependent signal for modulating the two opposing FcγR, FcγRIIB and FcγRIII, in the initiation of the inflammatory cascade in the lung Arthus reaction.

Tumor immune escape by the loss of homeostatic chemokine expression

The novel keratinocyte-specific chemokine CCL27 plays a critical role in the organization of skin-associated immune responses by regulating T cell homing under homeostatic and inflammatory conditions. Here we demonstrate that human keratinocyte-derived skin tumors may evade T cell-mediated antitumor immune responses by down-regulating the expression of CCL27 through the activation of epidermal growth factor receptor (EGFR)–Ras–MAPK-signaling pathways. Compared with healthy skin, CCL27 mRNA and protein expression was progressively lost in transformed keratinocytes of actinic keratoses and basal and squamous cell carcinomas. In vivo, precancerous skin lesions as well as cutaneous carcinomas showed significantly elevated levels of phosphorylated ERK compared with normal skin, suggesting the activation of EGFR–Ras signaling pathways in keratinocyte-derived malignancies. In vitro, exogenous stimulation of the EGFR–Ras signaling pathway through EGF or transfection of the dominant-active form of the Ras oncogene (H-RasV12) suppressed whereas an EGFR tyrosine kinase inhibitor increased CCL27 mRNA and protein production in keratinocytes. In mice, neutralization of CCL27 led to decreased leukocyte recruitment to cutaneous tumor sites and significantly enhanced primary tumor growth. Collectively, our data identify a mechanism of skin tumors to evade host antitumor immune responses.

The transforming acidic coiled coil 3 protein is essential for spindle-dependent chromosome alignment and mitotic survival.

Cancer-associated centrosomal transforming acidic coiled coil (TACC) proteins are involved in mitotic spindle function. By employing gene targeting, we have recently described a nonredundant and essential role of TACC3 in regulating cell proliferation. In this study, we used an inducible RNA interference approach to characterize the molecular function of TACC3 and its role in mitotic progression and cell survival. Our data demonstrate that a TACC3 knockdown arrests G1 checkpoint-compromised HeLa cells prior to anaphase with aberrant spindle morphology and severely misaligned chromosomes. Interestingly, TACC3-depleted cells fail to accumulate the mitotic kinase Aurora B and the checkpoint protein BubR1 to normal levels at kinetochores. Moreover, localization of the structural protein Ndc80 at outer kinetochores is reduced, indicating a defective kinetochore-microtubule attachment in TACC3-deficient cells. As a consequence of prolonged TACC3 depletion, cells undergo caspase-dependent cell death that relies on a spindle checkpoint-dependent mitotic arrest. TACC3 knockdown cells that escape from this arrest by mitotic slippage become highly polyploid and accumulate supernumerary centrosomes. Similarly, deficiency of the post-mitotic cell cycle inhibitor p21WAF exacerbates the effects of TACC3 depletion. Our findings therefore point to an essential role of TACC3 in spindle assembly and cellular survival and identify TACC3 as a potential therapeutic target in cancer cells.

Rho GTPases and phosphoinositide 3-kinase organize formation of branched dendrites

Neurons receive information from other neurons via their dendritic tree. Dendrites and their branches result from alternating outgrowth and retraction. The Rho GTPases Rac and Cdc42 (cell division cycle 42) facilitate the outgrowth of branches, whereas Rho attenuates it. The mechanism of neurite retraction is unknown. Because the adenylyl cyclase activator forskolin causes numerous branched extensions in NG108-15 cells, we have investigated the underlying mechanism in this cell line. In additional studies, we used cultured hippocampal neurons in which forskolin induces branched dendrites. In both cell types, forskolin enhanced the activity of Cdc42, but not that of Rac, although both GTPases were necessary for the formation of branched extensions. Time lapse microscopy showed that forskolin did not increase the rate of addition of new extensions or branches, but it reduced the rate of the retraction so that more branched extensions persisted. Inhibition of phosphoinositide 3-kinase activity by wortmannin or LY294002 also reduced the rate of retraction and thus facilitated dendritic arborization. Forskolin diminished the activity of phosphoinositide 3-kinases. Inhibitors of phosphoinositide 3-kinases not only reduced the retraction but also the addition of new dendrites and branches. This reduction was no longer present when Rho kinase was simultaneously inactivated, suggesting an interaction of phosphoinositide 3-kinases and Rho kinase. The present results show a central role of phosphoinositide 3-kinases in dendrite formation. In neuronal cells, increased levels of cAMP can support dendritic arborization by modulating the activity of the lipid kinase.

TACC3 depletion sensitizes to paclitaxel-induced cell death and overrides p21WAF-mediated cell cycle arrest

Regulators of the mitotic spindle apparatus are attractive cellular targets for antitumor therapy. The centrosomal protein transforming acidic coiled coil (TACC) 3 is required for spindle assembly and proper chromosome segregation. In this study, we employed an inducible RNA interference approach to downregulate TACC3 expression. We show that TACC3 knock-down in NIH3T3 fibroblasts caused aneuploidy, but failed to overtly impair mitotic progression. TACC3 depletion rather triggered a postmitotic p53–p21WAF pathway and led to a reversible cell cycle arrest. Similar effects were induced by low concentrations of paclitaxel, a spindle poison used in antitumor therapy. Interestingly, however, and unlike in TACC3-proficient cells, paclitaxel was able to induce strong polyploidy and subsequent apoptosis in TACC3-depleted cells. Even though paclitaxel treatment was associated with the activation of the survival kinase Akt and an antiapoptotic expression of cytoplasmic p21WAF and cyclin D1, this inhibition of cell death was abrogated by depletion of TACC3. Thus, our data identify TACC3 as a potential target to overcome p21WAF-associated protection of transformed cells against paclitaxel-induced cell death.

The centrosome and mitotic spindle apparatus in cancer and senescence

Altered cell division is associated with overproliferation and tumorigenesis, however, mitotic aberrations can also trigger antiproliferative responses leading to postmitotic cell cycle exit. Here, we focus on the role of the centrosome and in particular of centrosomal TACC (transforming acidic coiled coil) proteins in tumorigenesis and cellular senescence. We have compiled recent evidence that inhibition or depletion of various mitotic proteins which take over key roles in centrosome and kinetochore integrity and mitotic checkpoint function is sufficient to activate a p53-p21WAF driven premature senescence phenotype. These findings have direct implications for proliferative tissue homeostasis as well as for cellular and organismal aging.

Gαi2 Is the Essential Gαi Protein in Immune Complex–Induced Lung Disease

Heterotrimeric G proteins of the Gαi family have been implicated in signaling pathways regulating cell migration in immune diseases. The Gαi-protein–coupled C5a receptor is a critical regulator of IgG FcR function in experimental models of immune complex (IC)–induced inflammation. By using mice deficient for Gαi2 or Gαi3, we show that Gαi2 is necessary for neutrophil influx in skin and lung Arthus reactions and agonist-induced neutrophilia in the peritoneum, whereas Gαi3 plays a less critical but variable role. Detailed analyses of the pulmonary IC-induced inflammatory response revealed several shared functions of Gαi2 and Gαi3, including mediating C5a anaphylatoxin receptor–induced activation of macrophages, involvement in alveolar production of chemokines, transition of neutrophils from bone marrow into blood, and modulation of CD11b and CD62L expression that account for neutrophil adhesion to endothelial cells. Interestingly, C5a-stimulated endothelial polymorphonuclear neutrophil transmigration, but not chemotaxis, is enhanced versus reduced in the absence of neutrophil Gαi3 or Gαi2, respectively, and knockdown of endothelial Gαi2 caused decreased transmigration of wild-type neutrophils. These data demonstrate that Gαi2 and Gαi3 contribute to inflammation by redundant, overlapping, and Gαi-isoform–specific mechanisms, with Gαi2 exhibiting unique functions in both neutrophils and endothelial cells that appear essential for polymorphonuclear neutrophil recruitment in IC disease.

The heterotrimeric G protein G(i3) regulates hepatic autophagy downstream of the insulin receptor.

Compelling evidence suggests that the heterotrimeric G protein Gi3 specifically transmits the antiautophagic effects of insulin and amino acids in the liver. This points to a previously unrecognized cross talk between the insulin receptor tyrosine kinase and Gi3. Interestingly, Gi3 is localized not only to plasma membranes but also to membranes of the autophagosomal compartment. Furthermore, as part of insulin’s or phenylalanine’s actions to inhibit autophagy, Gi3 is redistributed away from autophagosomes. Therefore, endomembrane-associated rather than plasma membrane-localized Gi3 may serve as the target of insulin’s endocrine and metabolic actions. We therefore propose that the function and regulation of organelle-associated heterotrimeric G proteins may be different from their roles at the plasma membrane where they act as signal transducers of seven-transmembrane receptors. Here, we discuss recent findings and propose a function for Gi3 in mTOR-dependent signaling pathways. We hypothesize that Gi family members may have tissue-specific roles in the regulation of autophagy under different physiological and pathological conditions. Addendum to: An Obligatory Requirement for the Heterotrimeric G Protein Gi3 in the Antiautophagic Action of Insulin in the Liver A. Gohla, K. Klement, R.P. Piekorz, K. Pexa, S. vom Dahl, K. Spicher, V. Dreval, D. Häussinger, L. Birnbaumer and B. Nürnberg Proc Natl Acad Sci USA 2007; 104:3003-8

Subunit composition and functional properties of G-protein heterotrimers on rat chromaffin granules

Heterotrimeric G-proteins at the plasma membrane serve as switches between heptahelical receptors and intracellular signal cascades. Likewise endomembrane associated G-proteins may transduce signals from intracellular compartments provided they consist of a functional trimer. Using quantitative immunoelectron microscopy we found heterotrimeric G-protein subunits Galpha2, Galpha(q/11), Gbeta2 and Gbeta5 to reside on secretory granules in chromaffin cells of rat adrenal glands. Thus rat chromaffin granules are equipped with functional G-proteins that consist of a specific alpha-, beta- and probably gamma-subunit combination. Serotonin uptake into a crude rat chromaffin granule preparation was inhibited by activated Galphao2 (10 nM) to nearly the same extent as by GMppNp (50 microM) whereas GDPbetaS was ineffective. The data support the idea that vesicular G-proteins directly regulate the transmitter content of secretory vesicles. In this respect Galphao2 appears to be the main regulator of vesicular momoamine transporter activity.