Chronic intermittent stress-induced alterations in the spermatogenesis and antioxidant status of the testis are irreversible in albino rat.

The study was undertaken to find out whether or not chronic stress-induced alterations in spermatogenesis are accompanied by oxidative damage in the testis and reversibility of these effects. Adult male rats (n = 10) were subjected to restraint for 1 h and later after a gap of 4 h to forced swimming exercise for 15 min daily for 60 days and controls (n = 5) were maintained without disturbance. After treatment period, controls and 5 rats in stress group were killed and remaining rats in stress group were maintained without any treatment for 4 months and then autopsied to find out whether effects are reversible or not. The body and testicular weight, total sperm count, and mean number of type A spermatogonia, mid-pachytene spermatocytes, stage 7 spermatids, and elongated spermatids (cellular association in stage VII of spermatogenesis) showed a significant decrease whereas the abnormal sperm count and germ cell apoptosis were increased in stressed and recovery group rats compared to controls. Activities of testicular SOD, CAT, GPx, and GST were significantly decreased whereas MDA levels were significantly increased in stressed rats compared to controls. The SOD, GST, and CAT activities of recovery groups were significantly lower than controls, whereas MDA levels and GPx activity of these rats did not differ from controls. The results, for the first time, reveal that stress-induced loss of germ cells leading to decrease in sperm count may be due to oxidative damage caused by chronic stress and majority of these changes are not reversible.

Chronic stress-induced oxidative damage and hyperlipidemia are accompanied by atherosclerotic development in rats.

Although stress-induced hyperlipidemia and increased oxidative stress have been reported and implicated in etiology of atherosclerosis, experimental evidence for stress-induced atherosclerotic development concomitant with these alterations is lacking. In this study, exposure of adult male albino Wistar rats (Rattus norvegicus) to restraint for 1 h and after a gap of 4 h to forced swimming for 15 min every day for 2, 4, or 24 weeks resulted in a duration of exposure-dependent hyperlipidemia as shown by significant increases in concentrations of blood cholesterol, low-density lipoproteins, and triglycerides and decrease in high-density lipoprotein concomitant with increased oxidative stress as indicated by decrease in hepatic antioxidant enzyme activities and increase in lipid peroxidation in the liver, kidney, and heart. These alterations were accompanied by development of fibrous layer, formation of foam cells, reduction in elastic fibers, and accumulation of Oil-Red-O-positive lipid droplets in the intima of thoracic aorta following 24 weeks of stress exposure, but not after 4 weeks. The study demonstrates for the first time that (i) chronic stress-induced hyperlipidemia and oxidative damage are coupled with atherosclerotic development in rats fed with normal diet and (ii) chronic stress effects prevail even after the cessation of stress exposure as indicated by high concentration of blood cholesterol and reduced hepatic superoxide dismutase activity 20 weeks after 2 or 4 weeks of stress. This study exemplifies long-term allostatic regulation leading to a pathological state, with long-term hyperlipidemia and oxidative damage from chronic stress resulting in atherosclerosis.

Chronic stress and carbohydrate metabolism: persistent changes and slow return to normalcy in male albino rats.

The present study tested the hypothesis that long-term repeated exposure to stressors results in irreversible changes in carbohydrate metabolism. Groups of adult male rats (five per group) were restrained for 1 h and 4 h later were forced to swim for 15 min everyday for 2, 4, or 24 weeks; five rats were autopsied after each interval. Groups of five rats exposed to stress for 2 or 4 weeks were maintained without further treatment (recovery groups) for up to 24 weeks. The fasting blood glucose concentration, measured at weekly intervals, was significantly higher in the stressed rats than in controls throughout the experiment, except in the 24th week, whereas that of the recovery groups was significantly higher than controls only up to the 8th week after the end of stress exposure and then reached normalcy. The blood concentrations of glucose, lactate, and pyruvate were significantly higher in the 2 and 4 weeks stress groups than in controls, whereas, except for lactate, in rats stressed for 24 weeks these values did not significantly differ from those in controls. These changes were accompanied by increased gluconeogenesis and glycogenolysis as shown by alterations in activities of hepatic carbohydrate metabolizing enzymes and unaltered blood insulin concentrations in rats stressed for 2, 4, and 24 weeks. Furthermore, the blood insulin levels did not significantly vary among controls and the 2, 4, and 24 weeks stress groups. The results reveal that though hyperglycemia induced by long-term stress exposure is reversible, it persists for a prolonged period, even after the termination of stress exposure, before reaching normalcy. Prevalence of hyperglycemia for a prolonged period through increased activities of hepatic enzymes in stressed rats exemplifies allostasis.