Short-term oral exposure to aluminium decreases glutathione intestinal levels and changes enzyme activities involved in its metabolism

To study the effects of aluminium (Al) on glutathione (GSH) metabolism in the small intestine, adult male Wistar rats were orally treated with AlCl3.6H2O at doses of 30, 60, 120 and 200 mg/kg body weight (b.w.) per day, during seven days. Controls received deionized water. At doses above 120 mg/kg b.w., Al produced both a significant reduction of GSH content and an increase of oxidized/reduced glutathione ratio (P < 0.05). The index of oxidative stress of the intestine mucosa in terms of lipid peroxidation evaluated by thiobarbituric acid reactive substances was significantly increased (52%) at higher Al dose used. The duodenal expression of the multidrug resistance-associated protein 2 in brush border membranes, determined by Western blot technique, was increased 2.7-fold in rats treated with 200mg AlCl3/kg b.w (P < 0.01). Intestine activities of both GSH-synthase (from 60 mg/kg b.w.) and GSSG-reductase (from 120 mg/kg b.w.) were significantly reduced (26% and 31%, respectively) while glutathione-S-transferase showed to be slightly modified in the Al-treated groups. Conversely, gamma-glutamyltranspeptidase activity was significantly increased (P < 0.05) due to the Al treatment. Al reduced in vitro mucosa-to-lumen GSH efflux (P < 0.05). A positive linear correlation between the intestine GSH depletion and reduction of in situ 45Ca intestinal absorption, both produced by Al, was found (r = 0.923, P = 0.038). Taking as a whole, these results show that Al would alter GSH metabolism in small intestine by decreasing its turnover, leading to an unbalance of redox state in the epithelial cells, thus contributing to deteriorate GSH-dependent absorptive functions.     

Interaction between the human hippocampus and the caudate nucleus during route recognition

Navigation through familiar environments can rely upon distinct neural representations that are related to different memory systems with either the hippocampus or the caudate nucleus at their core. However, it is a fundamental question whether and how these systems interact during route recognition. To address this issue, we combined a functional neuroimaging approach with a naturally occurring, well-controlled human model of caudate nucleus dysfunction (i.e., preclinical and early-stage Huntington's disease). Our results reveal a noncompetitive interaction so that the hippocampus compensates for gradual caudate nucleus dysfunction with a gradual activity increase, maintaining normal behavior. Furthermore, we revealed an interaction between medial temporal and caudate activity in healthy subjects, which was adaptively modified in Huntington patients to allow compensatory hippocampal processing. Thus, the two memory systems contribute in a noncompetitive, cooperative manner to route recognition, which enables the hippocampus to compensate seamlessly for the functional degradation of the caudate nucleus.     

A novel site of AKT-mediated phosphorylation in the human MDM2 onco-protein

MDM2 is an E3 ubiquitin ligase which mediates ubiquitylation and proteasome-dependent degradation of the p53 tumor suppressor protein. Phosphorylation of MDM2 by the protein kinase AKT is thought to regulate MDM2 function in response to survival signals, but there has been uncertainty concerning the identity of the sites phosphorylated by AKT. In the present study, we identify Ser-166, a site previously reported as an AKT target, and Ser-188, a novel site which is the major site of phosphorylation of MDM2 by AKT in vitro. Analysis of MDM2 in cultured cells confirms that Ser-166 and Ser-188 are phosphorylated by AKT in a physiological context.     

A telemetry-based device to determine the force-displacement behaviour of materials in high impact loading situations

Meaningful testing of stab resistant body armour requires the use of realistic body tissue simulants. A device for the determination of the force-displacement behaviour of materials in high impact loading situations has been developed for the testing of such simulants. Force measurement is achieved with the use of electrical foil strain gauges applied to a cylindrical load cell. A piezo-resistive accelerometer (+/- 500 g) is used to calculate the displacement of the device through double integration of its signal, with the impact velocity used as a boundary condition. The signals from the strain gauge circuit and the accelerometer are sampled at 2500 Hz. The data are transmitted to a receiver via telemetry using a 418 MHz FM transmitter and from the receiver to a laptop PC via the serial port. Calibration of the device is described and sample results showing forces up to 2500 N and displacements up to 0.04 m are presented.     

Interphalangeal joint and tendon forces: normal model and biomechanical consequences of surgical reconstruction

Soft tissue reconstructive surgery for rheumatoid-related proximal interphalangeal joint deformities frequently fails to produce the long-term predicted results. Detailed information on the biomechanics of this joint, under both normal and pathological conditions, is required to assess the efficacy of such surgical intervention. A biomechanical model of the proximal interphalangeal joint has been developed to investigate tendon and joint loading during real life three-dimensional activities. Based on a rigid body mechanics approach, the model uses high resolution MRI scans to obtain anatomical tendon and bone geometries in conjunction with three-dimensional kinematic and loading data. The model incorporates an optimisation routine which minimises overall maximum tendon stress in the eight individual elements considered. Radial and ulnar joint force components are included at the proximal interphalangeal joint level. Two simulated pathological versions of the mathematical model are developed to accommodate the altered anatomic relationships after tendon reconstructive surgery. Joint forces of up to 450N and common usage of the extensor mechanism during normal pinching and grasping activities are predicted. The ulnar lateral bands of the extensor tendon are generally loaded to a greater extent than the radial bands. Extensor tendon and joint forces in the simulated pathological models are significantly higher than those in the normal model. Combined with the poor tendon quality of rheumatoid arthritis patients generally, these amplified internal forces may lead to further joint deformation.     

Transition to androgen-independence in prostate cancer

Prostate carcinoma is the most frequently diagnosed malignancy and the second leading cause of death as a result of cancer in men in the western countries. Withdrawal of androgens or the peripheral blockage of androgen action remain the critical therapeutic options for the treatment of advanced prostate cancer. However, after initial regression, most of the prostate cancers become androgen-independent and progress further, with eventual fatal outcome. Understanding the mechanisms of transition to androgen independence and tumor progression in prostate cancer is critical to finding new ways to treat aged patients that are ineligible for conventional chemotherapy. A large number of different molecular mechanisms might be responsible for the transition to androgen-independence. Many of these involve the androgen receptor (AR) and its signalling pathways, but they might also include genetic changes that affect several genes, which results in the activation of oncogenes or the inactivation of tumor suppressor genes. Here, we discuss the most recent and relevant findings on androgen resistance in prostate cancer in order provide a comprehensive interpretation of the clinical behaviour of tumors at molecular levels.     

Estrogenic effect of a series of bisphenol analogues on gene and protein expression in MCF-7 breast cancer cells

Bisphenols constitute a family of compounds, which includes many substances that have as a common chemical structure two phenolic rings joined together through a bridging carbon. In the present study, we aimed to determine whether several events triggered by 17 beta-estradiol (E(2)) in MCF-7 breast cancer cells were also observed in response to various bisphenol-A (BPA) analogues. We studied the expression of estrogen controlled genes by measuring the induction of pS2 (mRNA and protein) and progesterone receptor (PgR) as well as the expression of a luciferase reporter gene transfected into MVLN cells. These data were compared to the cell proliferation potency and effectiveness as the latest expression of estrogen controlled functions. Bisphenols showed an agonistic effect in all our assays, suggesting that these compounds may act through all the response pathways triggered by the natural hormone. We found differences between the assays in the potency of bisphenols, defined as the minimum concentration required to produce a maximal effect. In the cell proliferation assay, all tested compounds needed a lower concentration than in the other assays to give maximal response. Our results suggest that the polarity and nature of the substituent in the central carbon determines the estrogenic potency. Presence of two propyl chains at the central carbon appears to confer the greatest potency in both gene and protein expression assays.     

Comprehensive Analysis of a cis-Regulatory Region Reveals Pleiotropy in Enhancer Function

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Diphenhydramine inhibits voltage-gated proton channels (Hv1) and induces acidification in leukemic Jurkat T cells- New insights into the pro-apoptotic effects of antihistaminic drugs

An established characteristic of neoplastic cells is their metabolic reprogramming, known as the Warburg effect, with greater reliance on energetically less efficient pathways (such as glycolysis and pentose phosphate shunt) compared with oxidative phosphorylation. This results in an overproduction of acidic species that must be extruded to maintain intracellular homeostasis. We recently described that blocking the proton currents in leukemic cells mediated by Hv1 ion channels triggers a marked intracellular acidification and apoptosis induction. Moreover, histamine H1-receptor antagonists were found to induce apoptosis in tumoral cells but the mechanism is still unclear. By using Jurkat T cells, we now show how diphenhydramine inhibits Hv1 mediated currents, inducing a drop in intracellular pH and cellular viability. This provides evidence of a new target structure responsible of the known pro-apoptotic action of antihistaminic drugs.