Major biological effects of estrogen in the uterus are thought to be primarily mediated by nuclear estrogen receptors, ERalpha and ERbeta. We show here that estrogen in an ER-independent manner rapidly up-regulates the expression of Wnt4 and Wnt5a of the Wnt family and frizzled-2 of the Wnt receptor family in the mouse uterus. One of the mechanisms by which Wnts mediate canonical signaling involves stabilization of intracellular beta-catenin. We observed that estrogen treatment prompts nuclear localization of active beta-catenin in the uterine epithelium. We also found that adenovirus mediated in vivo delivery of SFRP-2, a Wnt antagonist, down-regulates estrogen-dependent beta-catenin activity without affecting some of the early effects (water imbibition and angiogenic markers) and inhibits uterine epithelial cell growth, suggesting that canonical Wnt signaling is critical to estrogen-induced uterine growth. Our present results provide evidence for a novel role of estrogen that targets early Wnt/beta-catenin signaling in an ER-independent manner to regulate the late uterine growth response that is ER dependent.
Long-term storage of information is a hallmark feature of the brain, yet routine turnover of synaptic receptors appears to be intrinsically paradoxical to this capability. To investigate how the brain preserves its delicate synaptic efficacies, we generated inducible and reversible knockout mice in which the NMDA receptor can be temporarily switched off in the forebrain specifically during the storage stage. Retention of 9-month contextual and cued fear memories is severely disrupted by prolonged, but not transient, loss of the NMDA receptor that occurs 6 months after initial training and at least 2 months prior to memory retrieval. Normal learning and memory function in subsequent tasks following the 9-month retention tests suggest that the observed retention deficits did not result from recall or performance impairment. Thus, our study reveals a hitherto unrecognized role of the NMDA receptor in dynamically maintaining the long-term synaptic stability of memory storage circuits in the brain.
Stromal cell polyploidy is a unique phenomenon that occurs during uterine decidualization following embryo implantation, although the developmental mechanism still remains elusive. The general consensus is that the aberrant expression and altered functional activity of cell cycle regulatory molecules at two particular checkpoints G1 to S and G2 to M in the cell cycle play an important role in the development of cellular polyploidy. Despite the compelling evidence of intrinsic cell cycle alteration, it has been implicated that the development of cellular polyploidy may be controlled by specific actions of extracellular growth regulators. Here we show a novel role for heparin-binding EGF-like growth factor (HB-EGF) in the developmental process of stromal cell polyploidy in mice. HB-EGF, which is one of the earliest known molecular mediators of implantation in mice and humans, promotes stromal cell polyploidy via upregulation of cyclin D3. Adenoviral delivery of antisense cyclin D3 attenuates cyclin D3 expression and abrogates HB-EGF-induced stromal cell polyploidy in vitro and in vivo. Collectively, the results demonstrate that the regulation of stromal cell polyploidy and decidualization induced by HB-EGF depend on cyclin D3 induction.
Our previous studies have demonstrated that ortho-substituted PCBs cause a rapid cell death in both thymocytes and cerebellar granule cell neurons, whereas coplanar congeners are without effect at comparable concentrations and exposure times. We have demonstrated that multiple membrane components are altered by these exposures, including the plasma membrane, mitochondria, and endoplasmic reticulum. The present experiments were designed to test the hypothesis that because of their stereochemistry, ortho-substituted congeners cause a greater disruption of membrane integrity than do coplanar congeners, and that this membrane disruption results in altered cellular function and to cell death. To test this hypothesis we have measured fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH) in thymocytes, cerebellar granule cells, and lipid bilayer vesicles upon exposure to an ortho-substituted PCB congener (PCB 52) and a coplanar congener (PCB 77), and compared results obtained in these studies to those from flow cytometric studies of plasma membrane permeability to large molecules and elevations of intracellular calcium in living cells. The fluorescence polarization of the DPH probe, which inserts into the lipid bilayer, reflects changes in membrane fluidity. In all three preparations we found that whereas fluorescence polarization was unchanged upon exposure to PCB 77, it was reduced significantly by PCB 52, reflecting an increase in membrane fluidity. These observations are consistent with the hypothesis that ortho-substituted PCBs disrupt membrane structure, which alters the function of membrane proteins. In the two cell types we have studied, the disruption is sufficient to cause death of the cell within a brief time.
The effects of exposure of acutely dissociated rat thymocytes to various polychlorinated biphenyl (PCB) congeners were examined using flow cytometry. Non-planar, ortho-substituted congeners caused a rapid cell death at low micromolar concentrations, while coplanar, dioxin-like congeners at the same concentration were without significant effect. The most potent of the congeners studied was PCB 52 (2,2',5,5'-tetrachlorobiphenyl), which had an IC50 of 3.96 microM at 20 min. Prior to loss of viability there was a decrease in mitochondrial membrane potential Delta Psi m, an accumulation of intracellular calcium, and a progressive leakiness of the plasma membrane. Application of PCB 52 in calcium-free medium reduced the calcium accumulation, but did not reduce cell death. Agents that depolarized mitochondria also did not induce the same degree of cell death caused by PCB 52. Cyclosporin A, which prevents opening of the mitochondria permeability transition channel, protected against cell death but did not protect against mitochondrial depolarization or calcium accumulation. Rapamycin and FK 506 at high concentration provided partial protection against cell death. These observations indicate that the ortho-substituted PCB 52 disrupts plasma, mitochondrial and endoplasmic reticulum membranes. We hypothesize that PCB 52 incorporates into lipid bilayers and with its bulky, three-dimensional ortho-substituted congener structure disrupts membrane function to a greater degree than coplanar congeners.
Several PCB congeners were assessed for their cytotoxicity on cerebellar granule cells in an attempt to compare their structure-activity relationship as potential neurotoxicants and to assess the mechanisms associated with their toxicity. Flow cytometry was used to monitor the changes of a number of biochemical endpoints: membrane integrity, intracellular free calcium concentration ([Ca(2+)](i)), reactive oxygen species (ROS) production, mitochondrial membrane potential (Delta psi(m)), and cell size. The non-coplanar, ortho-substituted congeners, PCB 8 (2,4'-dichlorobiphenyl), PCB 28 (2,4,4'-trichlorobiphenyl), PCB 47 (2,4,2',4'-tetrachlorobiphenyl), and PCB 52 (2,5,2',5'-tetrachlorobiphenyl) (10 microM) killed neurons to different degrees within 30 min. Loss of viability was accompanied by increased [Ca(2+)](i) and decreased Delta psi(m). No significant changes of ROS level were observed during exposure. The coplanar congeners, PCB 77 (3,4,3',4'-tetrachlorobiphenyl), PCB 80 (3,5,3',5'-tetrachlorobiphenyl), and PCB 81 (3,4,5,4'-tetrachlorobiphenyl) (10 microM), had no effects on membrane integrity, [Ca(2+)](i) or Delta psi(m) in this time period of exposure. In Ca(2+)-free Tyrode's medium, there was no [Ca(2+)](i) increase after exposure to the ortho-substituted congeners, but also no reduction in loss of membrane integrity, suggesting Ca(2+) influx was not the cause of viability loss. The mitochondrial uncoupler, carbonyl cyanide m-chlorophenyl hydrazone (CCCP) (1-2 microM), caused a large decrease of Delta psi(m), but only a slight loss of viability, which suggested that Delta psi(m) is not the primary cause of PCB 52-induced cell death. These studies show that ortho-substituted PCBs are toxic to cerebellar granule cells; however, their toxic action is not secondary to elevation of intracellular calcium, a change in mitochondrial membrane potential, or free radical generation.
Cisplatin-resistance is a major obstacle for the successful therapy to ovarian cancer, and exploring novel approach to deactivate cisplatin-resistant ovarian cells will improve the clinical outcomes. Our present study showed that there was no dark cytotoxicity of MPPa in the COC1/DDP cells at the dose of 0.25 -4 μM, and LED-activated MPPa resulted in drug doseand light-dependent cytotoxicity. Apoptotic rate 6 h after LEDactivated MPPa (2 μM) increased to 16.71% under the light energy of 1 J/cm 2 . Confocal laser scanning microscopy showed that MPPa mainly localized in the intracellular membrane system, namely the endoplasmic reticulum, Golgi apparatus, lysosomes and mitochondria in the COC1/DDP cells. Mitochondrial membrane potential (ΔΨm) was collapsed when COC1/DDP cells were exposed to 2 μM MPPa for 20 h and then 1 J/cm 2 irradiation of LED source. These data demonstrated that LEDactivated MPPa significantly deactivated cisplatin-resistant ovarian cell line COC1/DDP cells and enhanced apoptosis and decreased ΔΨ m , which suggests LED is an efficient light source for PDT and LED-activated MPPa can be developed as new modality for treating cisplatin-resistant ovarian.The setup of light source from a light emitting diode (LED) at the wavelength of 630 nm and the power density from 1 to 130 mW/cm 2 distributing uniformly over an area of 78.5 cm 2
Cerebral ischemia/reperfusion injury (IRI) is a serious complication during the treatment of stroke patients with very few effective clinical treatment. Hydrogen (H2) can protect mitochondria function and have favorable therapeutic effects on cerebral IRI. Mitophagy plays an important role in eliminating damaged or dysfunctional mitochondria and maintaining mitochondria homeostasis. However, whether the protection of H2 on cerebral IRI is via regulating mitophagy is still unknown. In this study, OGD/R damaged hippocampal neurons were used to mimic cerebral IRI in vivo and we detected the effect of H2, Rap (autophagy activator) and 3-MA (autophagy inhibitor) on OGD/R neurons. The results of MTT indicated that H2 and RAP could increase cell viability after OGD/R treatment, while 3-MA further aggravated injury and inhibited the protection of H2 and RAP. Furthermore, the intracellular ROS and apoptosis ratio were determined, the results showed that ROS and apoptosis level significantly increased after OGD/R, H2 and RAP effectively restrained the increment of ROS level and apoptosis ratio but their protective effect can be weakened by 3-MA. Mitochondrial membrane potential (MMP) and mitophagy level were also determined, the data showed that H2 and RAP protected against the loss of MPP and increased the co-localization of mitochondria with GFP-LC3 while 3-MA exerted antagonistic effect. At last, the mitophagy-related factors LC3, PINK1 and Parkin expression were detected and analyzed. We found that the expression of LC3 was increased after OGD/R which can be further enhanced by H2 and RAP treatment, but treatment with 3-MA was opposite. The result revealed H2 and RAP could activate mitophagy while 3-MA inhibit mitophagy. In addition, the study found H2 and RAP could significantly induce the expression of PINK1 and Parkin in OGD/R neurons which was inhibited by 3-MA. Taken together, our findings demonstrated H2 had a neuroprotective effect on OGD/R damaged neurons by protecting mitochondrial function and the potential protection mechanism may closely related to enhancement of mitophagy mediated by PINK1/Parkin signaling pathway.
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