The contractile vacuole in Ca2+-regulation in Dictyostelium: its essential function for cAMP-induced Ca2+-influx

Background  

cAMP-induced Ca²⁺-influx in Dictyostelium is controlled by at least two non-mitochondrial Ca²⁺-stores: acidic stores and the endoplasmic reticulum (ER). The acidic stores may comprise the contractile vacuole network (CV), the endosomal compartment and acidocalcisomes. Here the role of CV in respect to function as a potential Ca²⁺-store was investigated.     

Rapamycin antagonizes NF-kappaB nuclear translocation activated by TNF-alpha in primary vascular smooth muscle cells and enhances apoptosis

Several lines of evidence support the view that rapamycin inhibits NF-kappaB. TNF-alpha, a potent inducer of NF-kappaB, is released after artery injury (e.g., balloon angioplasty) and plays an important role in inflammation and restenosis. We investigated the effect of rapamycin on NF-kappaB activation and apoptosis in vascular smooth muscle cells (VSMCs) stimulated with TNF-alpha. Using EMSA, we found that TNF-alpha caused NF-kappaB nuclear translocation in VSMCs after 1 h of incubation. Rapamycin inhibited IkappaBalpha degradation, thereby preventing nuclear translocation. Activation of NF-kappaB was accompanied by an increase of Bcl-xL and Bfl-1/A1 proteins, detected by Western blot assay, whereas rapamycin prevented the TNF-alpha-induced enhancement of these antiapoptotic proteins. The extent of apoptosis of VSMCs exposed to TNF-alpha was significantly enhanced by rapamycin. The effect of rapamycin appeared to be independent of the phosphatidylinositol 3-kinase/Akt-protein kinase B survival pathway, because the phosphatidylinositol 3-kinase inhibitor wortmannin neither prevented IkappaBalpha degradation nor increased apoptosis of cells incubated with TNF-alpha. Finally, we demonstrate that the large immunophilin FK-506 binding protein FKBP51 is essential for TNF-alpha-induced NF-kappaB activation in VSMCs. Our findings show that rapamycin inhibits NF-kappaB activation and acts in concert with TNF-alpha in induction of VSMC apoptosis.     

Heat shock-induced attenuation of hydroxyl radical generation and mitochondrial aconitase activity in cardiac H9c2 cells

A mild heat shock (hyperthermia) protects cells from apoptotic and necrotic deaths by inducing overexpression of various heat shock proteins (Hsps). These proteins, in combination with the activation of the nitric oxide synthase (NOS) enzyme, play important roles in the protection of the myocardium against a variety of diseases. In the present work we report that the generation of potent reactive oxygen species (ROS), namely ·OH in cardiac H9c2 cells, is attenuated by heat shock treatment (2 h at 42°C). Western blot analyses showed that heat shock treatment induced overexpression of Hsp70, Hsp60, and Hsp25. The observed ·OH was found to be derived from the superoxide (O₂^–·) generated by the mitochondria. Whereas the manganese superoxide dismutase (MnSOD) activity was increased in the heat-shocked cells, the mitochondrial aconitase activity was reduced. The mechanism of O₂^–· conversion into ·OH in mitochondria is proposed as follows. The O₂^–· leaked from the electron transport chain, oxidatively damages the mitochondrial aconitase, releasing a free Fe²⁺. The aconitase-released Fe²⁺ combines with H₂O₂ to generate ·OH via a Fenton reaction and the oxidized Fe³⁺ recombines with the inactivated enzyme after being reduced to Fe²⁺ by other cellular reductants, turning it over to be active. However, in heat-shocked cells, because of higher MnSOD activity, the excess H₂O₂ causes irreversible damage to the mitochondrial aconitase enzyme, thus inhibiting its activity. In conclusion, we propose that attenuation of ·OH generation after heat shock treatment might play an important role in reducing the myocardial ischemic injury, observed in heat shock-treated animals. proteins; free radicals; spin trapping; reactive oxygen species     

Crystal structure of the temperature-sensitive and allosteric-defective chaperonin GroELE461K

The chaperonin GroEL adopts a double-ring structure with various modes of allosteric communication. The simultaneous positive intra-ring and negative inter-ring co-operativities alternate the functionality of the folding cavities in both protein rings. Negative inter-ring co-operativity is maintained through different inter-ring interactions, including a salt bridge involving Glu 461. Replacement of this residue by Lys modifies the temperature sensitivity of the substrate-folding activity of this protein, most likely as a result of the loss of inter-ring co-operativity. The crystal structure of the mutant chaperonin GroELE461K has been determined at 3.3A and compared with other structures: the wild-type GroEL, an allosteric defective GroEL double mutant and the GroEL-GroES-(ADP)7 complex. The inter-ring region of the mutant exhibits the following characteristics: (i) no salt-bridge stabilizes the inter-ring interface; (ii) the mutated residue plays a central role in defining the relative ring rotation (of about 22 degrees) around the 7-fold axis; (iii) an increase in the inter-ring distance and solvent accessibility of the inter-ring interface; and (iv) a 2-fold reduction in the stabilization energy of the inter-ring interface, due to the modification of inter-ring interactions. These characteristics explain how the thermal sensitivity of the protein's fundamental properties permits GroEL to distinguish physiological (37 degrees C) from stress (42 degrees C) temperatures.     

Contractile ring-independent localization of DdINCENP, a protein important for spindle stability and cytokinesis

Dictyostelium DdINCENP is a chromosomal passenger protein associated with centromeres, the spindle midzone, and poles during mitosis and the cleavage furrow during cytokinesis. Disruption of the single DdINCENP gene revealed important roles for this protein in mitosis and cytokinesis. DdINCENP null cells lack a robust spindle midzone and are hypersensitive to microtubule-depolymerizing drugs, suggesting that their spindles may not be stable. Furthermore DdCP224, a protein homologous to the microtubule-stabilizing protein TOGp/XMAP215, was absent from the spindle midzone of DdINCENP null cells. Overexpression of DdCP224 rescued the weak spindle midzone defect of DdINCENP null cells. Although not required for the localization of the myosin II contractile ring and subsequent formation of a cleavage furrow, DdINCENP is important for the abscission of daughter cells at the end of cytokinesis. Finally, we show that the localization of DdINCENP at the cleavage furrow is modulated by myosin II but it occurs by a mechanism different from that controlling the formation of the contractile ring.     

Nucleoplasmin Binds Histone H2A-H2B Dimers through Its Distal Face

Nucleoplasmin (NP) is a pentameric chaperone that regulates the condensation state of chromatin extracting specific basic proteins from sperm chromatin and depositing H2A-H2B histone dimers. It has been proposed that histones could bind to either the lateral or distal face of the pentameric structure. Here, we combine different biochemical and biophysical techniques to show that natural, hyperphosphorylated NP can bind five H2A-H2B dimers and that the amount of bound ligand depends on the overall charge (phosphorylation level) of the chaperone. Three-dimensional reconstruction of NP/H2A-H2B complex carried out by electron microscopy reveals that histones interact with the chaperone distal face. Limited proteolysis and mass spectrometry indicate that the interaction results in protection of the histone fold and most of the H2A and H2B C-terminal tails. This structural information can help to understand the function of NP as a histone chaperone.     

Role of DnaJ G/F-rich Domain in Conformational Recognition and Binding of Protein Substrates

DnaJ from Escherichia coli is a Type I Hsp40 that functions as a cochaperone of DnaK (Hsp70), stimulating its ATPase activity and delivering protein substrates. How DnaJ binds protein substrates is still poorly understood. Here we have studied the role of DnaJ G/F-rich domain in binding of several substrates with different conformational properties (folded, partially (un)folded and unfolded). Using partial proteolysis we find that RepE, a folded substrate, contacts a wide DnaJ area that involves part of the G/F-rich region and Zn-binding domain. Deletion of G/F-rich region hampers binding of native RepE and reduced the affinity for partially (un)folded substrates. However, binding of completely unfolded substrates is independent on the G/F-rich region. These data indicate that DnaJ distinguishes the substrate conformation and is able to adapt the use of the G/F-rich region to form stable substrate complexes.     

Phagocytosis of Cryptococcus neoformans by,and Nonlytic Exocytosis from,Acanthamoeba castellanii

Cryptococcus neoformans, an encapsulated, pathogenic yeast, is endowed with a variety of virulence factors, including a polysaccharide capsule. During mammalian infection, the outcome of the interaction between C. neoformans and macrophages is central to determining the fate of the host. Previous studies have shown similarities between the interaction of C. neoformans with macrophages and with amoebae, resulting in the proposal that fungal virulence for mammals originated from selection by amoeboid predators. In this study, we investigated the interaction of C. neoformans with the soil amoeba Acanthamoeba castellanii. Comparison of phagocytic efficiency of the wild type, nonencapsulated mutants, and complemented strains showed that the capsule was antiphagocytic for amoebae. Capsular enlargement was associated with a significant reduction in phagocytosis, suggesting that this phenomenon protects against ingestion by phagocytic predators. C. neoformans var. neoformans cells were observed to exit amoebae several hours after ingestion, in a process similar to the recently described nonlytic exocytosis from macrophages. Cryptococcal exocytosis from amoebae was dependent on the strain and on actin and required fungal viability. Additionally, the presence of a capsule was inversely correlated with the likelihood of extrusion in certain strains. In summary, nonlytic exocytosis from amoebae provide another parallel to observations in fungus-macrophage interactions. These results provide additional support for the notion that some mechanisms of virulence observed during mammalian infection originated, and were selected for, by environmental interactions.The encapsulated yeast Cryptococcus neoformans is an environmental organism that is capable of causing human disease. This fungus is a facultative intracellular pathogen with a unique pathogenic strategy, despite no obvious need for replication in an animal host as part of its life cycle (10). C. neoformans is known to interact with protozoa, some of which have been shown to be effective predators for this fungus (6, 26), and amoebae appear to be important for the control of C. neoformans in the environment (28). Previously, we reported that the interaction of C. neoformans with Acanthamoeba castellanii directly paralleled the interaction with human macrophages (33). Similarities between C. neoformans interactions with amoebae and macrophages included intracellular replication in a phagosome and the release of polysaccharide-containing vesicles into the cytoplasm (33). Furthermore, passage of avirulent C. neoformans and Histoplasma capsulatum through slime mold and amoebae was shown to increase virulence in mice (31, 32). On the basis of these observations, it was proposed that the capacity for mammalian virulence emerged from interactions with phagocytic predators, such as amoebae and slime mold, in the environment (7, 17, 30). Consequently, single-cell protists have emerged as important systems for the study of C. neoformans virulence, and subsequent studies have investigated the interaction of this fungus with slime mold and paramecia (9, 31). Additional evidence for this concept comes from studies of insect fungal pathogens, which suggest that the capacity for insect pathogenicity may follow preadaptation from interactions with amoebae in the environment (4). Understanding the mechanisms by which virulence emerges in environmental microbes is important considering that global warming has been hypothesized to bring about new fungal diseases in the coming century (13).Recent work in our laboratory and in that of Robin May simultaneously uncovered a novel strategy of avoiding macrophage killing whereby yeast cells were expulsed without lysis of the host cell (2, 19). The process is remarkable in that extrusion of the C. neoformans-filled phagosome is accompanied by the survival of both the host cells and the yeast cells. Phagosome extrusion or fungal exocytosis appears to be a C. neoformans-dictated event that is dependent on both the presence of the polysaccharide capsule and on the depolymerization of actin. A corollary of the hypothesis that C. neoformans virulence emerged from interactions with environmental predators is that phenomena observed with mammalian cells are likely to have a counterpart in free-living phagocytic cells. Consequently, the observation of an apparently unique event such as phagosomal extrusion from mammalian macrophages suggested a need to search for similar events in C. neoformans interactions with environmental phagocytic predators.In this study, we investigated parallels between the intracellular pathogenic strategy of C. neoformans in both macrophages and A. castellanii, focusing on characterizing the impact of the capsule on protozoan phagocytosis and on ascertaining whether fungal cells could also exit amoebae, including the role of the capsule in that possible mechanism. Using time-lapse microscopy, we observed the exocytosis of C. neoformans from A. castellanii. While there are significant differences in the nonlytic exocytosis process when comparing amoebae and macrophages, the observation of this phenomenon in amoebae provides additional support for the idea that the virulence of C. neoformans was selected for, and is maintained, by interactions in the environment with other soil organisms.(This research was conducted by Cara Chrisman in partial fulfillment of the requirements for a Ph.D. from the Sue Golding Graduate Division of Medical Science, Albert Einstein College of Medicine, Yeshiva University, Bronx, NY [awarded in 2010].)