THE ROLE OF ADRENAL AND THYROID HORMONES IN GASTRIC DEVELOPMENT (THYROXINE, PARIETAL CELL, CORTICOSTERONE)

The role of adrenal and thyroid hormones on the development of chief and parietal cells was studied in the rat. Administration of corticosterone or thyroxine in the first and second postnatal weeks resulted in the precocious appearance of pepsinogen in the oxyntic gland mucosa and an increase in basal acid output. When pups were adrenalectomized or made hypothyroid, both pepsinogen and basal acid secretion were lowed. Corticosterone injection increased pepsinogen content and acid secretion to levels higher than those of control in hypothyroid and adrenalectomized rats while thyroxine had no such effect in adrenalectomized rats. Morphologically, chief cells responded to corticosterone or thyroxine with increases in both zymogen granules and RER. Chief cells, however, contained less zymogen granules and RER in adrenalectomized and hypothyroid rats. Corticosterone was effective in restoring the normal morphological appearance of chief cells in the hypothyroid rats while thyroxine had no effect in the adrenalectomized rats. In response to corticosterone or thyroxine, parietal cells in normal animals appeared to contain more mitochondria, tubulovesicles and intracellular canaliculi than those of control. Unlike chief cells, parietal cells retained normal ultrastructure in the absence of adrenal and thyroid hormones. These data indicate that (1) corticosterone is necessary for the functional and morphological development of chief cells; (2) the morphological development of parietal cells does not appear to depend upon corticosterone, (3) the effect of thyroxine on the development of chief and parietal cells is due to corticosterone. ^

Function of cardiolipin in mitochondria of Saccharomyces cerevisiae

Cardiolipin and its precursor phosphatidylglycerol, phospholipids found uniquely in membranes engaged in oxidative phosphorylation, play important roles in multimeric complexes of the energy transducing system (ETS) associated with the inner mitochondrial membrane. A combined molecular genetic and biochemical approach was used to more precisely define the role of cardiolipin in cell processes. ^ Strains of yeast Saccharomyces cerevisiae unable to synthesize cardiolipin because of the crd1Δ allele (encodes cardiolipin synthase) with different phenotypes were analyzed to determine which phenotypes are due to lack of cardiolipin. We concluded that many of the severe phenotypes ascribed to cells lacking cardiolipin, particularly when grown at 37°C, are because of the synergistic interaction of the crd1Δ mutation with the reduced expression of the PET56 gene which encodes a component essential for the formation of functional mitochondrial ribosomes. We also demonstrate that much of the reduced mitochondrial function in crd1Δ is because of reduced expression of ETS components at elevated temperature. ^ A crd1Δ mutant of S. cerevisiae has less severe physiological changes than strains lacking both phosphatidylglycerol and cardiolipin due to an increased level of phosphatidylglycerol, which might partially substitute for the cardiolipin-requiring functions. By varying the level of cardiolipin, we were able to correlate phenotypes in a dose-dependent manner with the level of cardiolipin to support more strongly an involvement of cardiolipin in a particular cellular process. There is almost complete lack of a supercomplex composed of cytochrome bc1 complex (complex III) and cytochrome c oxidase (complex IV) in extracts of cardiolipin-lacking mitochondria when compared to wild type cells and the level of supercomplex varies in proportion to the cardiolipin levels. Reduced cardiolipin levels also compromise the growth properties of yeast in a dose-dependent manner suggesting that the loss in growth efficiency is related to a role of cardiolipin that cannot be replaced by phosphatidylglycerol. An independent kinetic approach was performed to compare organization of the respiratory chain in wild-type and cardiolipin-lacking mitochondria. Cardiolipin-lacking mitochondria display kinetic properties for electron transfer between complexes III and IV via cytochrome c consistent with cytochrome c being a freely diffusible carrier, confirming complexes III and IV exist as individual complexes and not associated into a supercomplex in cardiolipin-lacking mitochondria. ^

Calcium mobilization from the endoplasmic reticulum to the mitochondria during apoptosis in prostate cancer

Previous studies have implicated Ca2+ fluxes in the control of apoptosis but their exact roles in regulating the process remain obscure. Because Ca2+ can serve as a signal for cytochrome c release from isolated mitochondria, we hypothesized that alterations in intracellular Ca2+ compartmentalization might serve as a release signal in whole cells undergoing apoptosis. Exposure of human PC-3 prostate adenocarcinoma cells to staurosporine or DNA damaging agent (doxorubicin) but not to anti-Fas antibody led to early release of Ca2+ from the endoplasmic reticulum and subsequent accumulation of Ca2+ within mitochondria. Both events were blocked in cells stably transfected with Bcl-2 but were not affected by treatment with the pancaspase inhibitor, zVADfmk. The effects of staurosporine were associated with re-localization of Bax from the cytosol to both endoplasmic reticular and mitochondrial membranes. Neither ER Ca 2+ pool depletion nor mitochondrial Ca2+ uptake were observed in DU-145 cells that possess a frameshift mutation in the Bax gene unless wild-type Bax was restored via adenoviral gene transfer. Cytochrome c release and downstream features of apoptosis were attenuated by treatment with an inhibitor of mitochondria) Ca2+ uptake (RU-360). Although, direct pharmacological ER Ca2+ pool emptying in cells treated with thapsigargin did not lead to early cytochrome c release, pretreatment of cells with staurosporine dramatically sensitized mitochondria to thapsigargin-induced cytochrome c release. Together, our data demonstrate that ER-to-mitochondrial Ca2+ fluxes promote cytochrome c release and apoptosis in cells exposed to some (but not all) pro-apoptosic stimuli. ^

p21 activated kinase 5 links multiple GTPase signaling pathways at mitochondria

The p21-activated kinase 5 (PAK5) is a serine/threonine protein kinase associated with the group 2 subfamily of PAKs. Although our understanding about PAK5 is very limited, it is receiving increasing interest due to its tissue specific expression pattern and important signaling properties. PAK5 is highly expressed in brain. Its overexpression induces neurite outgrowth in neuroblastoma cells and promotes survival in fibroblasts. ^ The serine/threonine protein kinase Raf-1 is an essential mediator of Ras-dependent signaling that controls the ERK/MAPK pathway. In contrast to PAK5, Raf-1 has been the subject of intensive investigation. However due to the complexity of its activation mechanism, the biological inputs controlling Raf-1 activation are not fully understood. ^ PAKs 1-3 are the known kinases responsible for phosphorylation of Raf-1 on serine 338, which is a crucial phosphorylation site for Raf-1 activation. However, dominant negative versions of these kinases do not block EGF-induced Raf-1 activation, indicating that other kinases may regulate the phosphorylation of Raf-1 on serine 338. ^ This thesis work was initiated to test whether the group 2 PAKs 4, 5 and 6 are responsible for EGF-induced Raf-1 activation. We found that PAK5, and to a lesser extent PAK4, can activate Raf-1 in cells. Our studies thereafter focused on PAK5. With the progress of our study we found that PAK5 does not significantly stimulate serine 338 phosphorylation of Triton X-100 soluble Raf-1. PAK5, however, constitutively and specifically associates with Raf-1 and targets it to a Triton X-100 insoluble, mitochondrial compartment, where PAK5 phosphorylates serine 338 of Raf-1. We further demonstrated that endogenous PAK5 and Raf-1 colocalize in Hela cells at the mitochondrial outer membrane. In addition, we found that the mitochondria-targeting of PAK5 is determined by its C-terminal kinase domain plus the upstream proximal region, and facilitated by the N-terminal p21 binding domain. We also demonstrated that Rho GTPases Cdc42 and RhoD associate with and regulate the subcellular localization of PAK5. Taken together, this work suggests that the mitochondria-targeting of PAK5 may link Ras and Rho GTPase-mediated signaling pathways, and sheds light on aspects of PAK5 signaling that may be important for regulating neuronal homeostasis. ^

A novel mechanism of 3-bromopyruvate-induced cell death through targeting hexokinase and ubiquitination

Increased dependence on aerobic glycolysis for energy (ATP) supply has been observed in various human cancer cells. It is plausible to exploit this metabolic alteration for therapeutic benefits by inhibiting glycolysis to preferentially abolish cancer energy metabolism and kill the malignant cells. 3-Bromopyruvate has been shown to be a potent inhibitor of glycolysis capable of inducing severe ATP reduction and cell death in various cancer cell lines, especially cancer cells with mitochondrial defects or under hypoxic conditions. However, the detailed mechanisms of this novel anticancer agent still remain unclear. My study demonstrated that 3-Bromopyruvate caused a covalent modification of hexokinase II, a key glycolytic enzyme, and disrupted its association with mitochondria. This led to mitochondrial permeability transition and a substantial release of apoptosis-inducing faction (AIF) prior to cytochrome c release. Dissociation of HK II from mitochondria using a cell permeable specific peptide also induced the release of AIF and cytochrome c, and caused substantial cell death. HK II-targeted peptide did not cause significant change in mitochondria respiration and glycolysis activity, suggesting that dissociation of this molecule from mitochondria alone can also cause cell death, and that this may be a novel mechanism by which 3-Bromopyruvate exerts its potent cytotoxic action, in addition to its inhibition of the enzyme activity. Another significant new discovery was that 3-Bromopyruvate induced rapid reduction of protein ubiquitination in vivo, which occurred within several hours of drug incubation and before ATP reduction and cell death. Further mechanistic studies showed that this was due to the inhibition the ubiquitin activating enzyme E1 and the conjugating enzyme E2. Knocking down ubiquitin protein expression by siRNA did not suppress mitochondria respiration and glycolysis, but caused significant cell death. Taken together, this study demonstrated that induction of HK II dissociation from mitochondria and inhibition of glycolysis are two newly discovered mechanisms that contribute to the potent anticancer activity of 3-Bromopyruvate, and identified this compound as a valuable chemical tool for research in protein ubiquitination. ^

GMZ27 is a new organic arsenic derivative with anti-leukemic activity, via the induction of reactive oxygen species through NADPH oxidase and mitochondrial pathway that lead to leukemia cell apoptosis

Arsenic trioxide (ATO) is an inorganic arsenic derivative that is very effective against relapsed acute promyelocytic leukemia. It is being investigated as therapy for other cancers, but the risk/benefit ratio is questionable due to significant side effects. In contrast, organic arsenic derivatives (OAD) are known to be much less toxic than ATO. Based on high activity, we selected GMZ27 (dipropil-s-glycerol arsenic) for further study and have confirmed its potent activity against human acute leukemia cell lines. This anti-leukemic activity is significantly higher than that of ATO. Both in vivo and in vitro tests have shown that GMZ27 is significantly less toxic to normal bone marrow mononuclear cells and normal mice. Therefore, further study of the biological activity of GMZ27 was undertaken. ^ GMZ27, in contrast to ATO, can only marginally induce maturation of leukemic cells. GMZ27 has no effect on cell cycle. The anti-leukemic activity of GMZ27 against acute myeolocytic leukemia cells is not dependent upon degradation of PML-RARα fusion protein. GMZ27 causes dissipation of mitochondrial transmembrane potential, cleavage of caspase 9, caspase 3 activation. Further studies indicated that GMZ27 induces intracellular reactive oxygen species (ROS) production, and modification of intracellular ROS levels had profound effect on its potential to inhibit proliferation of leukemic cells. Therefore ROS production plays a major role in the anti-leukemic activity of GMZ27. ^ To identify how GMZ27 induces ROS, our studies focused on mitochondria and NADPH oxidase. The results indicated that the source of ROS generation induced by GMZ27 is dose dependent. At the low dose (0.3 uM) GMZ27 induces NADPH oxidase activity that leads to late ROS production, while at the high dose (2.0 uM) mitochondria function is disrupted and early ROS production is induced leading to dramatic cell apoptosis. Therefore, late, ROS production can be detected in mitochondria are depleted Rho-0 cells. Our work not only delineates a major biologic pathway for the anti-leukemic activity of GMZ27, but also discusses possible ways of enhancing the effect by the co-application of NADPH oxidase activator. Further study of this interaction may lead to achieving better therapeutic index.^

BIOLOGICAL MECHANISMS AND CLINICAL IMPLICATIONS OF BCR-ABL-INDUCED MITOCHONDRIAL OXIDATIVE STRESS AND CELL SURVIVAL IN CHRONIC MYELOID LEUKEMIA

Chronic myeloid leukemia (CML), a myeloproliferative disorder, represents approximately 15-20% of all adult leukemia. The development of CML is clearly linked to the constitutively active protein-tyrosine kinase BCR-ABL, which is encoded by BCR-ABL fusion gene as the result of chromosome 9/22 translocation (Philadelphia chromosome). Previous studies have demonstrated that oxidative stress-associated genetic, metabolic and biological alterations contribute to CML cell survival and drug refractory. Mitochondria and NAD(P)H oxidase (NOX) are the major sources of BCR-ABL-induced cellular reactive oxygen species (ROS) production. However, it is still unknown how CML cells maintain the altered redox status, while escaping from the persistent oxidative stress-induced cell death. Therefore, elucidation of the mechanisms by which CML cells cope with oxidative stress will provide new insights into CML leukemogenesis. The major goal of this study is to identify the survival factors protecting CML cells against oxidative stress and develop novel therapeutic strategies to overcome drug resistance. Several experimental models were used to test CML cell redox status and cellular sensitivity to oxidative stress, including BCR-ABL inducible cell lines, BCR-ABL stably transformed cell lines and BCR-ABL-expressing CML blast crisis cells with differential BCL-XL/BCL-2 expressions. Additionally, an artificial CML cell model with heterogenic BCL-XL/BCL-2 expression was established to assess the correlation between differential survival factor expression patterns and cell sensitivity to Imatinib and oxidative stress. In this study, BCL-XL and GSH have been identified as the major survival factors responsive to BCR-ABL-promoted cellular oxidative stress and play a dominant role in regulating the threshold of oxidative stress-induced apoptosis. Cell survival factors BCL-XL and BCL-2 differentially protect mitochondria under oxidative stress. BCL-XL is an essential survival factor in preventing excessive ROS-induced cell death while BCL-2 seems to play a relatively minor role. Furthermore, the redox modulating reagent β-phenethyl isothiocyanate (PEITC) has been found to efficiently deplete GSH and induce potent cell killing effects in drug-resistant CML cells. Combination of PEITC with BCL-XL/BCL2 inhibitor ABT737 or suppression of BCL-XL by BCR-ABL inhibitor Gleevec dramatically sensitizes CML cells to apoptosis. These results have suggested that elevation of BCL-XL and cellular GSH are important for the development of CML, and that redox-directed therapy is worthy of further clinical investigations in CML.

Induction of synthetic lethality in mutant KRAS cells for non-small cell lung cancers chemoprevention and therapy

Lung cancer is the leading cause of cancer death in both men and women in the United States and worldwide. Despite improvement in treatment strategies, the 5-year survival rate of lung cancer patients remains low. Thus, effective chemoprevention and treatment approaches are sorely needed. Mutations and activation of KRAS occur frequently in tobacco users and the early stage of development of non-small cell lung cancers (NSCLC). So they are thought to be the primary driver for lung carcinogenesis. My work showed that KRAS mutations and activations modulated the expression of TNF-related apoptosis-inducing ligand (TRAIL) receptors by up-regulating death receptors and down-regulating decoy receptors. In addition, we showed that KRAS suppresses cellular FADD-like IL-1β-converting enzyme (FLICE)-like inhibitory protein (c-FLIP) expression through activation of ERK/MAPK-mediated activation of c-MYC which means the mutant KRAS cells could be specifically targeted via TRAIL induced apoptosis. The expression level of Inhibitors of Apoptosis Proteins (IAPs) in mutant KRAS cells is usually high which could be overcome by the second mitochondria-derived activator of caspases (Smac) mimetic. So the combination of TRAIL and Smac mimetic induced the synthetic lethal reaction specifically in the mutant-KRAS cells but not in normal lung cells and wild-type KRAS lung cancer cells. Therefore, a synthetic lethal interaction among TRAIL, Smac mimetic and KRAS mutations could be used as an approach for chemoprevention and treatment of NSCLC with KRAS mutations. Further data in animal experiments showed that short-term, intermittent treatment with TRAIL and Smac mimetic induced apoptosis in mutant KRAS cells and reduced tumor burden in a KRAS-induced pre-malignancy model and mutant KRAS NSCLC xenograft models. These results show the great potential benefit of a selective therapeutic approach for the chemoprevention and treatment of NSCLC with KRAS mutations.

PML tumor suppressor potentiates cell death through inhibition of the NF -kappa B survival pathway

The promyelocytic leukemia protein PML is a growth suppressor essential for induction of apoptosis by diverse apoptotic stimuli. The mechanism by which PML regulates cell death remains unclear. In this study we found that ectopic expression of PML potentiates cell death in the TNFα-resistant tumor line U2OS and significantly sensitized these cells to apoptosis induced by TNFα in a p53-independent manner. Our study demonstrated that both PML and PML/TNFα-induced cell death are associated with DNA fragmentation, activation of caspase-3, -7, -8, and degradation of DFF/ICAD. Furthermore, we found that PML-induced and PML/TNFα-induced cell death could be blocked by the caspase-8 inhibitors crmA and c-FLIP, but not by Bcl-2, the inhibitor of mitochondria-mediated apoptotic pathway. These findings indicate that this cell death event is initiated through the death receptor-dependent apoptosis pathway. Our study further showed that PML recruits NF-kappa B (NF-κB) to the PML nuclear body, blocks NF-κB binding to its cognate enhancer, and represses its transactivation function with the C-terminal region. Therefore PML inhibits the NF-κB survival pathway. Overexpression of NF-κB rescued cell death induced by PML and PML/TNFκ. These results imply that PML is a functional repressor of NF-κB. This notion was further supported by the finding that the PML−/− mouse embryo fibroblasts (MEFs) are more resistant than the wild-type MEFs to TNFκ-induced apoptosis. In conclusion, our studies convincingly demonstrated that PML potentiates cell death through inhibition of the NF-κB survival pathway. Activation of NF-κB frequently occurs during oncogenesis. Our study here suggests that a loss of PML function enhances the NF-κB survival pathway and this event may contribute to tumorigenesis. ^