High Doses of Ascorbate Kill Y79 Retinoblastoma Cells In vitro

Objectives: To tests the sensitivity of Y79 retinoblastoma cell lines to high doses of ascorbate, in vitro, and compare its effects with those of some chemotherapeutic agents routinely employed in the treatment of retinoblastoma. Methods: Y79 retinoblastoma cells have been exposed to increasing doses of either sodium ascorbate (SA) or Melphalan (MEL), to define a dose-response curve around the peak plasma concentrations reached by both chemicals when administered according to the existing therapeutic procedures and protocols. The assessment of cell number and viability was performed, before and after exposure, with both the manual (Trypan Blue Exclusion Test) and automated (flow cytometry) methods. Fluorescence microscopy and direct observation of cells in culture, with inverted microscope, were also performed. Results: Y79 cells are highly sensitive to the cytotoxic effect of SA, with cell viability reduced of over 90% in some experiments. As reported in the literature, this effect is directly cytotoxic and most probably mediated by acute oxidative stress on different cellular components. The same does not apply to Melphalan which, at the doses commonly used for therapeutic purposes, did not show any significant effect on cell viability, in vitro. Conclusion: To our knowledge, this is the first report showing that high doses of SA can actively kill retinoblastoma cells in vitro. While it is not surprising for SA, to show direct cytotoxic effect on tumor cells, the data reported herein represent the first evidence in favor of the possible clinical use of high doses of intravenous SA, to treat children affected by retinoblastoma. Given the many advantages of SA over the chemotherapeutic agents commonly employed to treat cancer (including its almost total absence of toxic or side effects, and its exclusive specificity for cancer cells), it is reasonable to assume, from the data reported herein, that the high doses of intravenous ascorbate, have the potential to represent a real revolution in the treatment of retinoblastoma

Clozapine Impairs Insulin Action by Up-Regulating Akt Phosphorylation and Ped/Pea-15 Protein Abundance

Clinical and experimental evidence indicates that atypical antipsychotics impair glucose metabolism. We investigated whether clozapine may directly affect insulin action by analyzing insulin signaling in vitro and in vivo. Clozapine reduced insulin-stimulated glucose uptake in PC12 and in L6 cells, representative models of neuron and skeletal muscle, respectively. Consistently, clozapine reduced insulin effect on insulin receptor (IR) by 40% and on IR substrate-1 (IRS1) tyrosine phosphorylation by 60%. Insulin-stimulated Akt phosphorylation was also reduced by about 40%. Moreover, insulin-dependent phosphorylation of protein kinase C-ζ (PKC-ζ) was completely blunted in clozapine-treated cells. Interestingly, clozapine treatment was accompanied by an insulin-independent increase of Akt phosphorylation, with no change of IR, IRS1, and PKC-ζ basal phosphorylation. The cellular abundance of Ped/Pea-15, an Akt substrate and inducer of insulin resistance, was also increased following clozapine exposure, both in the absence and in the presence of cyclohexymide, a protein synthesis inhibitor. Similar as in cellular models, in the caudate–putamen and in the tibialis muscle of clozapine-treated C57/BL/KsJ mice, Akt phosphorylation and Ped/Pea-15 protein levels were increased and PKC-ζ phosphorylation was decreased. Thus, in these experimental models, clozapine deranged Akt function and up-regulated Ped/Pea-15, thereby inhibiting insulin stimulation of PKC-ζ and of glucose uptake. J. Cell. Physiol. 227: 1485–1492, 2012. © 2011 Wiley Periodicals, Inc

Muscle pathology patterns in possibly adjuvant related autoimmune/inflammatory syndrome (ASIA)

Growing evidence shows a link for biologically inert molecules, such as vaccine adjuvants and silicone implants, with the occurrence of autoimmunity-related disorders, defined as autoimmune/inflammatory syndrome induced by adjuvant-ASIA (1). Clinical conditions encompass siliconosis, the Gulf war syndrome, the macrophagic myofasciitis syndrome (MMF), post-vaccination phenomena and the spectrum of related syndromes is expanding (2). Involvement of skeletal muscle in ASIA is acknowledged in MMF, defined by long-term persistence of vaccine alum adjuvants within macrophages at sites of previous immunization. A few reports describe vaccine and silicone implants related autoimmune inflammatory myopathies (3). We carried out an immunopathological analysis of skeletal muscle biopsy in a case of MMF and two cases of possible ASIA myositis, chronologically subsequent to breast silicone implant. MMF showed the typical fascial/ perimysial macrophagic invasion, with no endomysial mononuclear infiltrates and fibral neolocalization of MHC-I complex restricted to the adjacency of macrophage deposits. The first myositis case presented with a subacute onset twenty years after an uneventful additive breast silicone implant. Endomysial inflammation, microangiopathy and multifocal fibral localization of MHC-II complex were observed. In the second patient, the onset of proximal weakness, myalgiae and a tenfold increase of creatinkinase levels occurred seven years after an unsuccessful additive mastoplasty, with rupture of prostheses and re-implantation three years later. Muscle biopsy, besides inflammation changes, showed peculiar myofibrillar disruption, with MHC-I reactive sarcoplasmic inclusions expressing several structural muscle proteins. Molecular pathogenesis of ASIA is yet undefined: genetical susceptibility is currently investigated (1,2). Due to the role of vaccines in medicine and the wide use of silicon medical devices, identification of their cause/effect link with autoimmunity is of great interest

Differential expression of follistatin and FLRG in human breast proliferative disorders

<p>Abstract</p> <p>Background</p> <p>Activins are growth factors acting on cell growth and differentiation. Activins are expressed in high grade breast tumors and they display an antiproliferative effect inducing G0/G1 cell cycle arrest in breast cancer cell lines. Follistatin and follistatin- related gene (FLRG) bind and neutralize activins. In order to establish if these activin binding proteins are involved in breast tumor progression, the present study evaluated follistatin and FLRG pattern of mRNA and protein expression in normal human breast tissue and in different breast proliferative diseases.</p> <p>Methods</p> <p>Paraffin embedded specimens of normal breast (NB - n = 8); florid hyperplasia without atypia (FH - n = 17); fibroadenoma (FIB - n = 17); ductal carcinoma <it>in situ </it>(DCIS - n = 10) and infiltrating ductal carcinoma (IDC - n = 15) were processed for follistatin and FLRG immunohistochemistry and <it>in situ </it>hybridization. The area and intensity of chromogen epithelial and stromal staining were analyzed semi-quantitatively.</p> <p>Results</p> <p>Follistatin and FLRG were expressed both in normal tissue and in all the breast diseases investigated. Follistatin staining was detected in the epithelial cytoplasm and nucleus in normal, benign and malignant breast tissue, with a stronger staining intensity in the peri-alveolar stromal cells of FIB at both mRNA and protein levels. Conversely, FLRG area and intensity of mRNA and protein staining were higher both in the cytoplasm and in the nucleus of IDC epithelial cells when compared to NB, while no significant changes in the stromal intensity were observed in all the proliferative diseases analyzed.</p> <p>Conclusion</p> <p>The present findings suggest a role for follistatin in breast benign disease, particularly in FIB, where its expression was increased in stromal cells. The up regulation of FLRG in IDC suggests a role for this protein in the progression of breast malignancy. As activin displays an anti-proliferative effect in human mammary cells, the present findings indicate that an increased FST and FLRG expression in breast proliferative diseases might counteract the anti-proliferative effects of activin in human breast cancer.</p