Effects of Chow and Liquid Diet on Liver Integrity and Antioxidant Defense in Sleep-Deprived Male Rats

The influence of diet composition and availability on liver and antioxidant system function under sleep deprivation (SD) in rats is not completely known. We have previously demonstrated that chow-fed sleep-deprived rats lose weight and present a starvation-like metabolic and hormonal profile, accompanied by hyperphagia. On the other hand, liquid diet attenuates weight loss and the endocrine-metabolic effects associated to SD. It is widely known that energy metabolism is strongly correlated with the production of free radicals and that oxidative cell damage may occur. Our objective was to verify whether the two different diets offered during SD would also affect antioxidant defense system and liver integrity. Male rats were distributed into the following groups: control, sleep-deprived for 96 h by the platform technique (SD-96h) or SD-96h recovered for 24 h (Rebound). Rats were fed with chow pellets (CP) or a liquid diet (LD). Our results show that the CP rats showed changes in antioxidant defense parameters and liver damage markers after SD. However, such changes were attenuated in rats fed the liquid diet. We conclude that the attenuated effect of LD on some studied liver damage and antioxidant defense markers lead us to suggest that these changes are at least partially linked to energy deficits induced by SD.


Introduction
It is widely known that energy metabolism is strongly correlated with the production of free radicals and that oxidative cell damage may occur by the increased production of oxidative species as well as by the impairment of antioxidant defenses [1,2].
Sleep deprivation (SD) is thought to be a risk factor for several diseases. However, the physical and biochemical changes produced by SD and its health consequences are not completely known. Using an animal model, Rechtschaffen's group characterized the response to long-term SD and found that it includes a progressive increase in both food intake and energy expenditure [3,4]. Likewise, SD induced by the flowerpot or platform technique also increases food intake [5] as well as resting oxygen consumption and the expression of the uncoupling protein-1 gene in brown adipose tissue [6].
The higher energy expenditure characteristic of SD has been related to mitochondrial thermogenesis, which in turn attributed to high expression of the uncoupling protein-2 gene in the liver and muscle tissue of rats deprived of sleep using the disc-over-water technique [7].
Although some evidence exists that hyperphagia could be overestimated by the gnawing behavior that increases during SD [8], recently we demonstrated that the liquid diet (LD) could favor hyperphagia and attenuate negative energy balance [9].
We have previously observed that SD induces energy deficits that were related to changes in feeding behavior and affected by the type of diet consumed. Regardless of the diet consumed, SD consistently increased animals' glucagon levels and decreased their leptin and triacylglycerol levels and liver glycogen stores [8]. However, such changes were mostly avoided in the rats on the LD. SD induces a wide range of metabolic and hormonal changes that are strongly linked to the severity of weight loss. The LD, but not the chow pellets (CP), favored energy intake, consequently lessening the energy deficit induced by SD [8]. This difference is likely due to the easier access to food and inhibition of the gnawing behavior [7].
Although enhanced cellular metabolism may result in the production of larger amounts of reactive oxygen species (ROS) and cell damage, no studies verifying whether different diets affect oxidative stress and liver damage markers after SD have been reported. Hence, the present study was conducted to determine whether different diets could modify liver damage and antioxidant defense markers in sleepdeprived rats.

Animals, housing conditions and ethical care
Male Wistar rats from a colony maintained by the Department of Psychobiology -UNIFESP were used. These animals were derived from the Charles River Laboratories Inc. (Wilmington, MA, USA) foundation colony. Throughout the experiment, all animals were maintained on a 12:12-h light-dark cycle (lights on at 0700 h) under controlled temperature (21ºC-24ºC) conditions and with free access to food and water. Animal care and use procedures were carried out by trained personnel (FELASA Category C) and conducted in accordance with the Guide for the Care and Use of Laboratory Animals. The

Sleep deprivation procedure
The SD procedure was an adaptation of the classical model for use with rodents. This method consists of placing an animal on top of a narrow platform (6.5 cm in diameter) surrounded by water in a 23×23×35 cm container [for details, see Martins et al. [10]. All animals were allowed to adapt to the platform for 30 to 40 min for three consecutive days, and SD was initiated at 0800 h after a day of washout. Members of the control group were individually placed in the same container as the sleep-deprived animals, but water was substituted for wood shavings. This substitution was also performed during the recovery period in the rebound group. Previous data from our laboratory indicate that this methods results in a complete elimination of paradoxical sleep and a 37% decrease in slow-wave sleep. Moreover, sleep recovery after the 96h SD protocol is characterized by an increased paradoxical sleep time (+184.7%) accompanied by a reduction in slowwave sleep (-12.2%) [11].

Experimental procedures
The SD procedure was an adaptation of the classical model for rodents [7,10,11]. Thirty rats were housed individually for 3 days and adapted to sleep deprivation procedures during this period, followed by a washout day. Thereafter, the animals were weighed (362.5 ± 39.8 g) and weight-matched cohorts were distributed into the control, sleepdeprived for 96 h (SD-96 h), and SD-96 h recovered for 24 h (Rebound) groups. The sleep-deprived and Rebound groups were submitted to 96 h of sleep deprivation while the control rats were maintained in isolated home-cages. After 96 h of sleep deprivation, the Rebound group was permitted to sleep for 24 h before sample collection. Chow pellets (25.3% calories as protein, 11.6% as fat, and 63.1% as carbohydrate; 3.485 Kcal/g; Nuvilab-CR1, Colombo, Brazil) were accessible during all experiments.
After SD and rebound periods, all animals were euthanized by decapitation between 0700 h and 0930 h for blood and liver sample collection.

Analytical procedures
Blood was collected in tubes containing pre-chilled heparin or no anti-coagulant (Becton Dickinson, New England, UK); the tubes were centrifuged at 4°C for 10 min at 3,000 rpm to extract plasma and serum aliquots, respectively. Liver and blood antioxidant defense markers were assessed as described elsewhere [12,13]. Aspartate-aminotransferase (AST) and alanine-aminotransferases (ALT) were measured using colorimetric automated procedures (ADVIA 1650, BAYER Diagnostics Corporation) routinely performed in clinical laboratories. Fibrinogen was determined using an automated blood coagulation system (Dade Behring, New York) that assessed plasma collected in sodium-citrate tubes. Interleukin-6 was determined using a rat-specific ELISA kit (R&D systems Inc., Minneapolis, USA).

Statistical analysis
The results are presented as mean ± SD unless specifically noted as mean ± SE. Because there was no protocol difference between the sleep-deprived and Rebound groups except for a day of recovery in the Rebound group after 96 h of sleep deprivation, we considered both groups together as one sleep-deprived group to compare the body weight and food intake. Analysis of variance (ANOVA) was followed by the Tukey post-hoc test with the alpha value set at 0.05.

Chow pellet experiment
Sleep deprivation affected serum markers of liver damage, including the enzymes aspartate-and alanine-aminotransferase. Although the difference in AST level did not reach statistical significance [F (2,27) Mean ± SD of 10 rats per group. *Different from control group. Tukey test, p<0.05.  defense markers were related to an energy deficit because significant correlations were found between the change in body weight and each parameter in the liver [i.e., total glutathione (r=0.57; p<0.05) and catalase activity (r=0.76; p<0.05)] and erythrocytes (total glutathione; r=0.57; p<0.05).

Liquid diet experiment
Sleep deprivation in rats fed with a liquid diet did not affect the liver damage markers; the serum AST [F(2,27)=0. 19 Table 4).

Induced cell injury markers after 96 h of sleep deprivation
Serum aminotransferase levels are markers of liver damage, and a previous study showed that total SD is associated with increases in rat AST and ALT serum levels [1]; this increase has also been shown in humans deprived of sleep for 72 h [14]. Damaged hepatocytes release their contents, including ALT and AST, into the extracellular space; these contents ultimately enter the circulation and thereby increase the serum enzyme levels. These enzymes are therefore considered highly sensitive and specific pre-clinical and clinical biomarkers of hepatotoxicity [15]. Such enzymes are expressed in several tissues and primarily convert amino acids into gluconeogenic intermediates. ALT and AST catalyze the reductive transfer of an amino group from alanine or aspartate to alpha-ketoglutarate to yield glutamate and pyruvate or oxaloacetate, respectively [16].
Increased serum levels of ALT have been described under conditions associated with increased gluconeogenesis, such as fasting, drug-induced diabetes, a high protein diet or treatment with large amounts of glucocorticoids [17]. Furthermore, increased ALT activity indicates new enzyme synthesis rather than the release of inhibitors or activators in the liver [18]. Thus, increases in the catabolism of branched-chain and other amino acids during negative energy balance induces the formation and release of alanine from muscle tissue [19], which is a condition that may stimulate gluconeogenesis by increasing the metabolic pool of amino acids and result in substrate-induced ALT synthesis [20]. Accordingly, we found that rats deprived of sleep for 96 h had increased levels of serum ALT (Table 1), but there was no such increase when a balanced liquid diet was offered (Table 4). Thus, increased ALT serum levels in the chow-fed rats may be related to increased amino acid catabolism, as reflected by the large decrease in body weight and reinforced by a previous description of reduced muscle mass [21]. Considering that AST is localized in the heart, brain, skeletal muscle and liver tissue and that ALT is primarily localized in the liver [16], we suggest that the demand for movement in the disk-over-water apparatus may further increase energy expenditure as compared to the platform method, leading to an additional increase in the AST levels [1] from extra-hepatic sources.

Inflammation produced by 96 h of sleep deprivation
Because of its location in the circulatory system, the liver functions as a center of metabolism and a center of defense. Therefore, it is not surprising that both functions were disturbed in association with the energy deficit induced by SD. The liver is a major source of acute phase proteins whose secretion is driven by inflammatory cytokines released in response to tissue damage, infection and stress. Some studies in humans have found increased levels of interleukin-6 after sleep restriction or deprivation [22,23]. However, it was observed that levels of interleukin-6 were decreased after 40 h of SD [24]. In our experiments, we found that chow-fed rats presented increased levels of fibrinogen after 96 h of SD (Table 1). Moreover, the increased levels of fibrinogen and the decreased levels of interleukin-6, which is the most potent and broadly effective stimulant of acute-phase proteins [25], suggest that another metabolic factor may account for higher acute protein levels during SD. Previous reports suggest that the metabolic, endocrine and nutritional statuses can influence the blood levels of acute phase response and inflammatory markers.
Obesity is associated with an increased inflammatory response and high levels of pro-inflammatory cytokines and acute phase proteins, and weight loss programs reduce the levels of interleukin-6, among others [26]. It has already been shown that fat tissues are an important source and contribute approximately one-third of the total circulating amount of interleukin-6 [27]. Accordingly, animal models have also shown that weight loss associated with moderate stress reduces the peripheral expression of interleukin-6 in mice [28]. Similar to our chow-fed sleepdeprived rats, a previous study found decreased circulating levels of tumor necrosis factor-α, which is another pro-inflammatory cytokine, after 96 h of SD using the platform technique [21]. Nevertheless, the stimulation of acute-phase protein synthesis requires other mediators because the infusion of catabolic hormones increases hepatic protein synthesis in vivo, but not in perfused livers [29]. Raj and colleagues [30] showed that amino acid infusion during hemodialysis increased the fractional synthesis rate of fibrinogen significantly more than without amino acid infusion. Therefore, because such changes to the fibrinogen and interleukin-6 levels were avoided in the liquid-fed sleep-deprived rats (Table 4), the increased production of acute phase proteins in the SD chow-fed rats might be the consequence of increased liver amino acid availability. This may be the result of increased proteolysis, as shown by the large weight loss and carcass protein content [21].

Repercussions in the antioxidant system after 96 h of sleep deprivation
There was a decrease in erythrocyte total glutathione after 96 h of SD, and this level remained low after recovery (Table 2). Furthermore, although liver total glutathione was decreased in the SD-96h and Rebound groups, we found no changes in the cytosolic glutathione peroxidase and superoxide dismutase activities in the chow-fed rats (Table 3).
Our group was the first to show that SD decreases total glutathione concentrations in the rat hypothalamus and thalamus without changes in antioxidant enzymes [31,32]. Thereafter, other researchers showed Liver Total Glutathione (umol/mg prot.) 6.04 ± 1.07 5.08 ± 0.95* 5.40 ± 1.10 Mean ± SD of 10 rats per group. *Different from control group. Tukey test, p<0.05. decreased activity of the antioxidant enzyme superoxide dismutase in the hippocampus and brainstem [33] as well as reduced liver total glutathione and catalase activity in the livers of sleep-deprived rats [1].
These data suggest that rather than inducing oxidative damage, SD suppresses the antioxidant defense system, which is strongly linked to weight loss. Reduced intakes of vitamins and amino acids from food can affect both enzymatic and non-enzymatic components of the antioxidant system [34]. This hypothesis is also partially supported by our observations that liquid diet-fed rats showed no changes in antioxidant defense markers (Table 4).

Conclusion
This study is the first to demonstrate that LD attenuates alterations in liver integrity and some antioxidant defense markers leading us to suggest that LD favored food intake, probably by inhibiting the gnawing behavior, consequently lessening the energy deficit induced by SD.