A Pilot Prospective Study Evaluating the Effect of Curcuma-Based Herbal Food Supplement on the Outcome of In Vitro Fertilization in Patients Testing Positive for Four Immunological Biomarkers.

Background and Objectives: Inflammation and oxidative stress have been described to reduce the chance for pregnancy instauration and maintenance. NOFLAMOX, a recently developed herbal preparation with recognized antioxidant and anti-inflammatory properties, can represent an interesting treatment to increase the chance of pregnancy, both physiological or after in vitro fertilization (IVF). The aim of this study was to assess NOFLAMOX's effect; a population with unexplained infertility was screened for the recently described IMMUNOX panel based on four immunological biomarkers with a prospective study approach. Materials and Methods: Patients with unexplained infertility and positive for at least one of the biomarkers of the IMMUNOX panel were included in this study and treated with NOFLAMOX for three months prior to an IVF cycle. Results: Eighty-six patients (n = 86) were screened with the IMMUNOX panel and the forty-seven (54.5%) found positive were included in this study. In more detail, 11 were positive for TNFα (23.4%), 18 (38.3%) for glycodelin (GLY), 29 (61.7%) for Total Oxidative Status (TOS), and 32 (68.1%) for Complement Activity Toxic Factor (CATF). After three months of treatment, a significant reduction in the number of IMMUNOX-positive patients was observable, with 26 patients who turned IMMUNOX-negative displaying a quantitative statistically significant variation of 100% (11/11), 38.9% (7/18), 65.5% (18/29), and 75% (24/32), for TNFα, glycodelin, TOS, and CATF, respectively. Followed in the subsequent IVF cycle, this NOFLAMOX-treated population showed a pregnancy rate of 42.3% compared to the 4.7% of the IMMUNOX-positive group of patients. Conclusions: Taken together, the results of this study suggest that NOFLAMOX could represent an interesting option for those patients with unexplained infertility of inflammatory/oxidative origin. Further studies are needed to confirm these results and explore possible strategies to restore fertility in women with immune-mediated sterility.

miRNA expression profiling in a human stem cell-based model as a tool for developmental neurotoxicity testing.

The main aim of this study was to evaluate whether microRNA (miRNA) profiling could be a useful tool for in vitro developmental neurotoxicity (DNT) testing. Therefore, to identify the possible DNT biomarkers among miRNAs, we have studied the changes in miRNA expressions in a mixed neuronal/glial culture derived from carcinoma pluripotent stem cells (NT2 cell line) after exposure to methyl mercury chloride (MeHgCl) during the process of neuronal differentiation (2-36 days in vitro (DIV1)). The neuronal differentiation triggered by exposure to retinoic acid (RA) was characterized in the control culture by mRNA expression analysis of neuronal specific markers such as MAP2, NF-200, Tubulin ßIII, MAPT-tau, synaptophysin as well as excitatory (NMDA, AMPA) and inhibitory (GABA) receptors. The results obtained from the miRNA expression analysis have identified the presence of a miRNA signature which is specific for neural differentiation in the control culture and another for the response to MeHgCl-induced toxicity. In differentiated neuronal control cultures, we observed the downregulation of the stemness phenotype-linked miR-302 cluster and the overexpression of several miRNAs specific for neuronal differentiation (e.g. let-7, miR-125b and miR-132). In the cultures exposed to MeHgCl (400 nM), we observed an overexpression of a signature composed of five miRNAs (miR-302b, miR-367, miR-372, miR-196b and miR-141) that are known to be involved in the regulation of developmental processes and cellular stress response mechanisms. Using gene ontology term and pathway enrichment analysis of the validated targets of the miRNAs deregulated by the toxic treatment, the possible effect of MeHgCl exposure on signalling pathways involved in axon guidance and learning and memory processes was revealed. The obtained data suggest that miRNA profiling could provide simplified functional evaluation of the toxicity pathways involved in developmental neurotoxicity in comparison with the transcriptomics studies.

A human pluripotent carcinoma stem cell-based model for in vitro developmental neurotoxicity testing: effects of methylmercury, lead and aluminum evaluated by gene expression studies.

The major advantage of the neuronal cell culture models derived from human stem cells is their ability to replicate the crucial stages of neurodevelopment such as the commitment of human stem cells to the neuronal lineage and their subsequent stages of differentiation into neuronal and glial-like cell. In these studies we used mixed neuronal/glial culture derived from the NTERA-2 (NT-2) cell line, which has been established from human pluripotent testicular embryonal carcinoma cells. After characterization of the different stages of cell differentiation into neuronal- and glial-like phenotype toxicity studies were performed to evaluate whether this model would be suitable for developmental neurotoxicity studies. The cells were exposed during the differentiation process to non-cytotoxic concentrations of methylmercury chloride, lead chloride and aluminum nitrate for two weeks. The toxicity was then evaluated by measuring the mRNA levels of cell specific markers (neuronal and glial). The results obtained suggest that lead chloride and aluminum nitrate at low concentrations were toxic primarily to astrocytes and at the higher concentrations it also induced neurotoxicity. In contrast, MetHgCl was toxic for both cell types, neuronal and glial, as mRNA specific for astrocytes and neuronal markers were affected. The results obtained suggest that a neuronal mixed culture derived from human NT2 precursor cells is a suitable model for developmental neurotoxicity studies and gene expression could be used as a sensitive endpoint for initial screening of potential neurotoxic compounds.

Modulation of palmitic acid-induced cell death by ergothioneine: evidence of an anti-inflammatory action.

Inflammation and reactive oxygen species have been implicated in pathogenesis of vascular diabetic complications. However, treatment with classic free-radical scavengers and antioxidants has not been yet proved to reduce the risk of developing such complications. In search of more effective treatment we have tested the protective role of Ergothioneine (EGT), in vitro, on C2C12 cells model on FFA-induced lipotoxicity. Cells were incubated for 24 h in the presence of palmitic acid (PA) (250, 500, 750, 1000 microM), added as pro-oxidant compound, with or without 24-h pre-treatment with EGT. Cells were assessed for cell viability and MAPKs expression by Western Blot. Pre-treatment with EGT resulted in greater cell viability at each PA concentration (EGT 500 microM: 5, 16, 17, 23% and EGT 1000 microM: 9, 18, 21 and 25%). In response to PA exposure, p38 and JNK activity increased significantly while EGT prevented such activation. Moreover the analysis of the IL-6 production reveal that EGT is also able to exert anti-inflammatory action inhibiting the PA IL-6 modulation (P < 0.001). In conclusion, these results indicate that 1. EGT has a protective role on PA-induced cell death, possibly via 2. reduced activity of MAPKs cascade having also 3. an anti-inflammatory action exerted on the IL-6 modulation.

High insulin levels impair intracellular receptor trafficking in human cultured myoblasts.

Chronic hyperinsulinemia is both a marker and a cause for insulin resistance. This study analyzes the effect of long-term exposure to high insulin levels on insulin-insulin receptor metabolism in human myoblasts. Cells were grown in the presence of low (107 pM, SkMC-L) or high (1430 pM, SkMC-H) insulin concentrations. Insulin receptor (IR) phosphorylation, IR internalization, dissociation and recycling, as well as insulin degradation have been investigated. Basal IR phosphorylation was higher in SkMC-H than in SkMC-L (P<0.01) but after acute insulin stimulation (10nM insulin for 10 min), IR phosphorylation increased (P<0.01) in SkMC-L, but not in SkMC-H. Chronic hyperinsulinism significantly decreased insulin-IR complex internalization (P<0.01). Nevertheless the t(1/2) value of receptor internalization was similar in both cells. Intracellular dissociation of insulin-IR complex was slightly but significantly lower in SkMC-H than in SkMC-L. Finally, SkMC-H showed a complete, but significantly delayed recycling of IR to plasma membrane (t(1/2)=20 min versus SkMC-L t(1/2)=7 min). The time course of intracellular degradation measured by HPLC, showed whenever studied, significantly (P<0.01) higher levels of intracellular intact insulin in cells exposed to high insulin concentrations. Nevertheless, the patterns of insulin degradation were over-imposable between SkMC-H and SkMC-L. In summary, continuous exposure of cultured myoblasts to high insulin levels induces subtle derangements of intracellular receptor trafficking and insulin degradation. These alterations may contribute to the insulin resistance of hyperinsulinemic states such as obesity and Type 2 Diabetes.

Molecular effects of fermented papaya preparation on oxidative damage, MAP Kinase activation and modulation of the benzo[a]pyrene mediated genotoxicity.

The involvement of oxidative and nitrosative stress mechanisms in several biological and pathological processes including aging, cancer, cardiovascular and neurodegenerative diseases has continued to fuel suggestions that processes can potentially be modulated by treatment with free-radical scavengers and antioxidant. The fermented papaya preparation (FPP) derived from Carica papaya Linn was investigated for its ability to modulate oxidative DNA damage due to H2O2 in rat pheochromocytoma (PC12) cells and protection of brain oxidative damage in hypertensive rats. Cells pre-treated with FPP (50 microg/ml) prior to incubation with H2O2 had significantly increased viability and sustenance of morphology and shape. The human hepatoma (HepG2) cells exposed to H2O2 (50 microM) showed an olive tail moment of 10.56 +/- 1.44 compared to 1.37 +/- 0.29 of the solvent control. A significant reduction (P < or = 0.05) of DNA damage was observed at concentrations > or = 10 microg/ml FPP, with 50 microg/ml FPP reducing the genotoxic effect of H2O2 by about 1.5-fold compared to only H2O2 exposed cells.

Modulation of hydrogen peroxide-induced DNA damage, MAPKs activation and cell death in PC12 by ergothioneine.

BACKGROUND & AIMS: Ergothioneine (EGT) is a natural occurring compound, synthesized by soil bacteria in fungal substrates, exhibiting antioxidant functions in many cell models. The aim of this study was to assess the effect of EGT in the prevention of H2O2-dependent cell death and oxidative damage on a model of neural cell derived from rat pheocromocytoma, the PC12. METHODS: The ability of EGT was tested by the 3 (4,5-dimethylthiazol-2-yl) 2, 5-diphenyltetrazolium bromide (MTT) assay and Comet assay. H2O2 insult was challenged with increasing concentration of antioxidant using two different incubation periods: 1 and 23 h of EGT pre-treatment followed by 23 and 1 h of H2O2, respectively, for both the MTT and the Comet assay data. CONCLUSION: The pre-treatment for 23 h with EGT, 250 microM and 1mM, followed by 1h of H2O2 incubation at the concentration of 250 and 500 microM, resulted in increased cell viability (P < 0.001) compared to the H2O2 cell batch. This correlated with a decrease in DNA damage as visualized by the Comet assay. Moreover, protein analysis reveals that in the presence of 250 microM of H2O2, EGT acted as a p38-MAPK and Akt specific inhibitor. EGT may play a protective role in rescuing cells from stress-induced apoptosis, likely by activating an intracellular antioxidant pathway involving p38 MAPK genes cascade.

Continually high insulin levels impair Akt phosphorylation and glucose transport in human myoblasts.

Chronic hyperinsulinemia is both a marker and a cause for insulin resistance. This study analyzes the effect of long-term exposure to high insulin levels on the insulin-signaling pathway and glucose transport in cultured human myoblasts. Human myoblasts were grown in the presence of low (107 pmol/L, SkMC-L) or high (1430 pmol/L, SkMC-H) insulin concentrations for 3 weeks. Glucose transport, insulin receptor (IR), and IR substrate 1 (IRS1) phosphorylation, phosphatidylinositol 3'-kinase (PI3K) activity, as well as Akt-Ser473 phosphorylation have been investigated at the end of the incubation period and after a further short-term insulin stimulation. At the end of the incubation period, IR, IRS1, p85/PI3K, Akt, and GLUT4 protein expression levels were similar in both culture conditions. Basal glucose transport was similar in SkMC-L and SkMC-H, but after short-term insulin stimulation significantly increased (P < .01) only in SkMC-L. IR binding was down-regulated in SkMC-H (P < .01), but IR and IRS1 tyrosine phosphorylation and PI3K activity were significantly higher (P < .01) in SkMC-H than SkMC-L. Despite increased PI3K activation, Akt-Ser473 phosphorylation was similar in SkMC-L and SkMC-H. After a short-term insulin stimulation (10 nmol/L insulin for 10 minutes), IR and IRS1 tyrosine phosphorylation, PI3K activation, and Akt-Ser473 phosphorylation significantly increased (P < .01 and P < .05 for Akt) in SkMC-L but not in SkMC-H. Serine phosphorylation of IRS1 was similar in SkMC-L and SkMC-H. Moreover, in the SkMC-H, insulin stimulation was associated with the inhibition of IRS1 tyrosine dephosphorylation (P < .05). In summary, continuous exposure of cultured myoblasts to high insulin levels induces a persistent up-regulation of IR, IRS1, and PI3K activity associated with the demodulation of insulin signaling. Moreover, the impairment of the insulin-signaling steps between PI3K and Akt is concomitant with the desensitization of glucose transport. These alterations may contribute to the derangement insulin-signaling pathway states of hyperinsulinemia such as obesity and type 2 diabetes.