Zinc deficiency affects the STAT1/3 signaling pathways in part through redox-mediated mechanisms.

Zinc deficiency affects the development of the central nervous system (CNS) through mechanisms only partially understood. We previously showed that zinc deficiency causes CNS oxidative stress, damaging microtubules and impairing protein nuclear shuttling. STAT1 and STAT3 transcription factors, which require nuclear import for their functions, play major roles in CNS development. Thus, we investigated whether zinc deficiency disrupts STAT1 and STAT3 signaling pathways in the developing fetal CNS, characterizing the involvement of oxidative stress and the cytoskeleton in the adverse effects. Maternal (gestation day 0-19) marginal zinc deficiency (MZD) reduced STAT1 and STAT3 tyrosine phosphorylation and their nuclear translocation in the embryonic day 19 (E19) rat brain. Similar effects were observed in zinc depleted IMR-32 neuroblastoma cells, with an associated decrease in STAT1- and STAT3-dependent gene transactivation. Zinc deficiency caused oxidative stress (increased 4-hydroxynonenal-protein adducts) in E19 brain and IMR-32 cells, which was prevented in cells by supplementation with 0.5mM α-lipoic acid (LA). In zinc depleted IMR-32 cells, the low tyrosine phosphorylation of STAT1, but not that of STAT3, recovered upon incubation with LA. STAT1 and STAT3 nuclear transports were also restored by LA. Accordingly, chemical disruption of the cytoskeleton partially reduced STAT1 and STAT3 nuclear levels. In summary, the redox-dependent tyrosine phosphorylation, and oxidant-mediated disruption of the cytoskeleton are involved in the deleterious effects of zinc deficit on STAT1 and STAT3 activation and nuclear translocation. Therefore, disruption of the STAT1 and STAT3 signaling pathways may in part explain the deleterious effects of maternal MZD on fetal brain development.

Nitric oxide and iron overload. Limitations of ESR detection by DETC.

The ability of the ESR technique based on diethyldithiocarbamate (DETC) administration was studied as a suitable method to assess NO generation in vivo. The technique was successfully employed to measure NO generation after LPS treatment. DETC2-Fe-NO adducts were detected in liver homogenates of iron overloaded animals. When iron was administered to the animals simultaneously with LPS, NO-dependent signal increased 122%, but the content of NO2- and NO3- in sera was significantly lower (44%) as compared to LPS-treated rats. Iron dextran administration was responsible for a three-fold increase in the DETC2-Fe-NO content in non-LPS treated rats, while NOS activity and sera NO2- and NO3- levels remained unaffected. The adduct generation rate by a chemical NO-source was recorded in the presence of either control or iron overloaded homogenates supplemented with DETC in vivo. The exposure of liver homogenates to NO was performed either by the addition of 1 mM SNAP as NO donor or infusing an aqueous NO solution. In the presence of iron overloaded samples the adduct generation rate was 3.8-4.4-fold higher than in the presence of control samples. This effect restricts the applicability of the method to experimental conditions where iron levels remain constant, therefore it is not suitable for NO generation studies in experimental models where animals were subjected to iron overload.