Involvement of the mitochondrial permeability transition pore in chronic ethanol-mediated liver injury in mice.

Chronic ethanol consumption increases sensitivity of the mitochondrial permeability transition (MPT) pore induction in liver. Ca(2+) promotes MPT pore opening, and genetic ablation of cyclophilin D (CypD) increases the Ca(2+) threshold for the MPT. We used wild-type (WT) and CypD-null (CypD(-/-)) mice fed a control or an ethanol-containing diet to investigate the role of the MPT in ethanol-mediated liver injury. Ca(2+)-mediated induction of the MPT and mitochondrial respiration were measured in isolated liver mitochondria. Steatosis was present in WT and CypD(-/-) mice fed ethanol and accompanied by increased terminal deoxynucleotidyl transferase dUTP-mediated nick-end label-positive nuclei. Autophagy was increased in ethanol-fed WT mice compared with ethanol-fed CypD(-/-) mice, as reflected by an increase in the ratio of microtubule protein 1 light chain 3B II to microtubule protein 1 light chain 3B I. Higher levels of p62 were measured in CypD(-/-) than WT mice. Ethanol decreased mitochondrial respiratory control ratios and select complex activities in WT and CypD(-/-) mice. Ethanol also increased CypD protein in liver of WT mice. Mitochondria from control- and ethanol-fed WT mice were more sensitive to Ca(2+)-mediated MPT pore induction than mitochondria from their CypD(-/-) counterparts. Mitochondria from ethanol-fed CypD(-/-) mice were also more sensitive to Ca(2+)-induced swelling than mitochondria from control-fed CypD(-/-) mice but were less sensitive than mitochondria from ethanol-fed WT mice. In summary, CypD deficiency was associated with impaired autophagy and did not prevent ethanol-mediated steatosis. Furthermore, increased MPT sensitivity was observed in mitochondria from ethanol-fed WT and CypD(-/-) mice. We conclude that chronic ethanol consumption likely lowers the threshold for CypD-regulated and -independent characteristics of the ethanol-mediated MPT pore in liver mitochondria.

Metabolic and cardiac signaling effects of inhaled hydrogen sulfide and low oxygen in male rats.

Low concentrations of inhaled hydrogen sulfide (H(2)S) induce hypometabolism in mice. Biological effects of H(2)S in in vitro systems are augmented by lowering O(2) tension. Based on this, we hypothesized that reduced O(2) tension would increase H(2)S-mediated hypometabolism in vivo. To test this, male Sprague-Dawley rats were exposed to 80 ppm H(2)S at 21% O(2) or 10.5% O(2) for 6 h followed by 1 h recovery at room air. Rats exposed to H(2)S in 10.5% O(2) had significantly decreased body temperature and respiration compared with preexposure levels. Heart rate was decreased by H(2)S administered under both O(2) levels and did not return to preexposure levels after 1 h recovery. Inhaled H(2)S caused epithelial exfoliation in the lungs and increased plasma creatine kinase-MB activity. The effect of inhaled H(2)S on prosurvival signaling was also measured in heart and liver. H(2)S in 21% O(2) increased Akt-P(Ser473) and GSK-3ß-P(Ser9) in the heart whereas phosphorylation was decreased by H(2)S in 10.5% O(2), indicating O(2) dependence in regulating cardiac signaling pathways. Inhaled H(2)S and low O(2) had no effect on liver Akt. In summary, we found that lower O(2) was needed for H(2)S-dependent hypometabolism in rats compared with previous findings in mice. This highlights the possibility of species differences in physiological responses to H(2)S. Inhaled H(2)S exposure also caused tissue injury to the lung and heart, which raises concerns about the therapeutic safety of inhaled H(2)S. In conclusion, these findings demonstrate the importance of O(2) in influencing physiological and signaling effects of H(2)S in mammalian systems.

Cystamine and cysteamine prevent 3-NP-induced mitochondrial depolarization of Huntington's disease knock-in striatal cells.

Abstract Cystamine significantly improved motor deficits and extended survival in mouse models of Huntington's disease (HD); however, the precise mechanism(s) by which cystamine and the related compound cysteamine are beneficial remain to be elucidated. Using clonal striatal cell lines from wild-type (STHdhQ7/HdhQ7) and mutant huntingtin knock-in (STHdhQ111/HdhQ111) mice, we have tested the hypothesis that cystamine and cysteamine could be beneficial by preventing the depolarization of mitochondria in cell cultures. Treatment with 3-nitroproprionic acid (3-NP), a mitochondrial complex II inhibitor, induces mitochondrial depolarization and cell death of mutant HD striatal cells but not of wild-type cells. The 3-NP-mediated decrease in the mitochondrial membrane potential was attenuated by 50 microm cystamine and completely inhibited by 250 microm cystamine. Similar results were obtained using cysteamine (50-500 microm). In addition, both cystamine and cysteamine significantly attenuated the 3-NP-induced cell death. Treatment of mutant HD striatal cells with 3-NP resulted in a robust decrease in the cellular and mitochondrial levels of glutathione (GSH) compared with cells exposed to the vehicle alone. Pre-treatment of the cells with cystamine and cysteamine completely prevented the 3-NP-mediated decrease in cellular and mitochondrial GSH levels. Incubation with L-buthionine (S,R) sulfoximine (BSO) 250 microm in combination with cystamine (250 microm) or cysteamine (250 microm) prior to being treated with 3-NP completely prevented the beneficial effects of cystamine and cysteamine on the 3-NP-mediated mitochondrial depolarization. These results demonstrate that cystamine and cysteamine prevent the 3-NP-induced mitochondrial depolarization of HD striatal cell cultures.

Increased glutathione levels in cortical and striatal mitochondria of the R6/2 Huntington's disease mouse model.

Huntington's disease (HD) is a progressive neurodegenerative disease characterized by a severe neuronal loss that occurs primarily in the neostriatum. It has been postulated that mitochondria dysfunction and oxidative stress may play significant roles in the etiology of the disease. Indeed, markers of oxidative stress damage have been detected in the brains of HD patients and in mouse models of HD. In this study, we evaluate the changes in the levels of the potent, endogenous antioxidant glutathione and enzymes involved in its metabolism or recycling in the cortex and striatum of an extensively studied HD mouse model (R6/2). In both cortex and striatum, the levels of cellular glutathione were not significantly different in the R6/2 mice when compared with littermate wild type controls. Remarkably, the levels of glutathione were significantly increased in mitochondria isolated from the cortex and striatum of R6/2 mice when compared with wild type control mice. This specific increase in the levels of glutathione in mitochondria suggests that a compensatory mechanism is induced in the R6/2 mice to protect against an increase in oxidative stress in mitochondria.

Molecules mimicking Smad1 interacting with Hox stimulate bone formation.

Bone morphogenetic proteins (BMPs) induce osteoblast differentiation and bone formation. Smads, a group of functionally and structurally related intracellular effectors, mediate signaling initiated by BMPs and regulate cell definite commitment. Previously, we showed that Smad1 activates osteopontin and osteoprotegerin gene expression by dislodging Hoxc-8 from its DNA binding sites. A domain of Smad1, termed Smad1C, was characterized as interacting with Hoxc-8 and then crippling its DNA-binding ability. Ectopic expression of Smad1C is able to bypass BMP signaling in the induction of osteoblast differentiation and bone formation in vitro. To test the function of Smad1C on osteogenesis in vivo, we generated transgenic mice in which Smad1C expression was induced with doxycycline and localized in bone by using a tetracycline-inducible expression system (Tet-on) modified with a bone-specific gene promoter, type I collagen alpha1. The mice expressing Smad1C showed increased skeletal bone mineral density compared with their littermates. Bone histomorphometric analysis of mouse tibiae showed that Smad1C significantly increases trabecular bone area and length of trabecular surface covered with osteoid and up-regulates bone marker gene (OPN, Cbfa1, Col I alpha1, BSP, ALP) expression in vivo. Moreover, stromal cells isolated from mice expressing Smad1C displayed a higher potential for differentiating into osteoblasts than the other mice. These results indicate that Smad1C mimics BMPs in the induction of osteogenesis in vivo. Most important, using a high throughput screening assay based on mimicking Smad1C's displacement of Hoxc-8 binding to DNA, we identified chemical entities that exhibit bone anabolic activity in cell and bone organ cultures, suggesting the possibility that the compounds may be used as bone anabolic agents to treat bone pathologies.

Smad4 as a transcription corepressor for estrogen receptor alpha.

Antiestrogen compounds exhibit a variety of different effects in different tissues and are widely used for the treatment of osteoporosis, breast cancer, and other diseases. Upon examining the molecular mechanisms, we found that Smad4, a common signal transducer in the bone morphogenetic protein (BMP)/transforming growth factor-beta (TGF-beta) signaling pathway, functions as a transcription corepressor for human estrogen receptor alpha (ERalpha). Endogenous ERalpha was co-immunoprecipitated with Smad4, and the interaction was induced by antiestrogen ligands such as tamoxifen, raloxifene, and droloxifen, which was confirmed in chromatin immunoprecipitation assays. Smad4 and ERalpha form a complex when ERalpha binds to the estrogen-responsive element within the estrogen target gene promoter. Importantly, the expression of Smad4 inhibits both antiestrogen-induced luciferase activity and estrogen downstream target gene transcription in breast cancer cells. Mapping of the interaction domains indicates that the activation function 1 (AF1) domain of ERalpha is essential for its interaction with Smad4, while the MH1 domain and linker region of Smad4 are essential for the interaction. Our findings represent a novel mechanism that TGF-beta may regulate cell fate through Smad4-mediated cross-talk with estrogen.