Heat stroke induces autophagy as a protection mechanism against neurodegeneration in the brain.

Heat stroke (HS) is defined clinically as a condition when core body temperature rises above 40°C and is accompanied by central nervous system abnormalities. In this study, we established a rat model of HS by exposing anesthetized rats to elevated ambient temperature (40°C) until core temperature reaching 40.5°C (HS onset). The rat was immediately removed from heating chamber, allowed recovery for various time periods, and killed for histological and biochemical studies. Our results indicated neuronal shrinkage and pyknosis of the nucleus and sustained up to 12 h recovery time in cerebral cortex. Elevated expression of autophagy-related proteins, including microtubule associated protein light chain 3 and beclin 1 in cortical tissue at various times (3, 6, 12 h) of recovery was observed. In addition, the number of autophagosomes stained by monodansylcadaverine, a specific autophagosome marker, increased after heat exposure but was reduced by pretreatment with 3-methyladenine, an autophagy inhibitor. Furthermore, heat exposure increased neuronal degeneration in cortical tissue, as evidenced by staining with the fluorescent dye Fluoro-Jade B for degenerating neuron. Pretreatment with 3-methyladenine in HS rats aggravated neurodegeneration. Taken together, these results suggest that HS induces autophagy as a protection mechanism against neurodegeneration. Modulation of autophagy may provide a potential therapeutic approach for HS and await further research.

Oxidative stress and erythropoietin response in altitude exposure.

PURPOSE: Oxidative stress and erythropoietin (EPO) levels are increased following high altitude exposure. We hypothesized that the altitude-oxidative stress and EPO response would be associated with the presence or absence of acute mountain sickness (AMS) in subjects exposed at high altitude. METHODS: The study enrolled 29 healthy volunteers exposed at altitudes without strenuous physical exercise. Oxidative stress was determined by the spectrophotometric measurement of the colour occurring during the reaction of malondialdehyde (MDA) with thiobarbituric acid (TBA) on blood samples. Ferritin and EPO were also measured simultaneously. RESULTS: During a rise in altitude at 2000 and 3000 m, there were no changes in plasma ferritin level in either of the 2 groups with or without AMS. In contrast, EPO increased at an altitude of 3000 m and after returning to sea level (28.2+/-2.7, 26.9+/-3.3 vs 12.2+/-1.4 and 17.1+/-1.6, P < 0.05, in group without AMS; 29.3+/-4.5, 22.8+/-2.7 vs 10.6+/-1.0 and 16.1+/-1.5, # P < 0.05, in group with AMS; compared with the baseline level and at the height of 2000 meters). At a height of 3000 m, plasma MDA level was elevated compared with that at the altitude of baseline and 2000 m in both groups of subjects with and without AMS (3.77+/-0.29 vs 1.14+/-0.17, and 1.64+/-0.22, P < 0.001, in subjects with AMS; 3.65+/-0.39 vs 1.71+/-0.21, and 1.73+/-0.21, P < 0.001, in subjects without AMS) . After returning to sea level, subjects without AMS had lower MDA oxidative stress compared with those with AMS (2.58+/-0.26 vs 3.51+/-0.24, P = 0.0223). Along with a rise in altitude, the oxidative stress in these both groups was not correlated with the changes in EPO (r2 = 0.0728, P = 0.1096). CONCLUSION: High altitude-induced oxidative stress, detected by MDA assay, is not different between the two groups of subjects with and without AMS. Upon return to sea level, subjects without AMS had lower MDA oxidative stress burden and higher EPO level than those with AMS. Whether the subjects with altitude illness had delayed recovery from oxidative stress merits further investigation.

Characterization of an iron-responsive promoter in the protozoan pathogen Trichomonas vaginalis.

Iron has been shown to regulate transcription in the protozoan pathogen Trichomonas vaginalis. In this study, a DNA transfection system was developed to monitor ap65-1 promoter activity in response to changing iron supply. In conjunction with electrophoretic mobility shift assay, iron-induced transcription of the ap65-1 gene was shown to be regulated by multiple closely spaced DNA elements spanning an iron-responsive region (-110/-54), including an iron-responsive DNA element ((-98)AGATAACGA(-90)), which overlaps with a 3'-MYB-like protein binding sequence ((-95)TAACGATAT(-87)), and three nearby T-rich sequences ((-110)ATTTTT(-105), (-78)ATTATT(-73), and (-59)ATTTTT(-54)). 5'- and 3'-flanking sequences of the iron-responsive region were shown to regulate basal transcription. A distal DNA regulatory region was shown to enhance both basal and iron-induced transcription. These findings delineate the DNA regulatory elements and nuclear proteins involving in iron-induced transcription of the ap65-1 gene, which provide useful tools for the future study of transcriptional regulation in T. vaginalis.