Carolina D Pederzolli’s research while affiliated with Federal University of Rio Grande do Sul and other places

Introduction: Phenylketonuria (PKU) is characterized by deficiency of the enzyme phenylalanine hydroxylase, leading to accumulation of phenylalanine. Early diagnosis and subordination to low--phenylalanine diet are important to prevent the harmful effects of hyperphenylalaninemia. In case the diet is not strictly followed, some possible effects are imbalance in the neutral amino acids that use the same carrier of phenylalanine to cross the blood-brain barrier, causing hence reduction in tryptophan entry, the precursor of serotonin in the brain. This neurotransmitter has been implicated in the regulation of mood states, and its high production is linked to central fatigue in individuals subjected to prolonged exercise. Physical exercise increases free tryptophan levels in the blood, which facilitates its influx in the brain, and therefore, may be useful in hyperphenylalaninemia states. Objective: To assess whether aerobic exercise is able to normalize the concentrations of tryptophan in the brain of rats with hyperphenylalaninemia. Methods: 32 rats were randomly assigned to sedentary (Sed) and exercise (Exe) groups, and then divided into control (SAL) and hyperphenylalaninemia (PKU). Hyperphenylalaninemia was induced by administration of alpha-metylphenylalanine and phenylalanine for three days, while the SAL groups received saline. Exe groups held a session of aerobic exercise lasting 60 minutes and speed of 12 m.min-1. Results: The concentration of tryptophan in the brain of PKU groups was significantly lower than SAL groups (both in Sed and Exe groups), compatible with the condition of hyperphenylalaninemia. The exercise increased brain tryptophan levels comparing to sedentary animals. The most interesting finding was that the brain tryptophan levels of ExePKU group were not different from SedSAL group. Conclusion: The results indicate an important role of aerobic exercise to restore the concentration of tryptophan in the brain in hyperphenylalaninemic rats.

The acidic Seminal Fluid Protein (aSFP), a 12.9 kDa protein is a maker for bovine semen freezability possibly due to its antioxidant activity and effect on sperm mitochondrial function. However, its precise function on sperm preservation during freezing-thaw is poorly understood. The use of recombinant DNA technology allows new approaches on the study of function and structure of proteins, and its production in procaryote systems offers several advantages. The present work describes the recombinant expression of the bovine aSFP and its binding properties. A cDNA library from the bovine seminal vesicle was used as template for amplification of the aSFP coding region. The amplicon was cloned into a pET23a(+) vector and transformed into E.coli BL21 pLysS strain. The recombinant expression was obtained in E coli. One step ion immobilized affinity chromatography was performed, resulting in high yield of purified protein. To determine the bioactivity of the raSFP, the protein was incubated in different concentrations with 10 7 spermtozoa at 37°C for 5 h. Western blotting and fluorescence microscopy analyses showed the ability of the recombinant aSFP to attach to the spermatozoa. Based on our results, the described method can be used to obtain mg levels of recombinant aSFP.

The present study investigated the effects of chronic hyperprolinemia on oxidative and metabolic status in liver and serum of rats. Wistar rats received daily subcutaneous injections of proline from their 6th to 28th day of life. Twelve hours after the last injection the rats were sacrificed and liver and serum were collected. Results showed that hyperprolinemia induced a significant reduction in total antioxidant potential and thiobarbituric acid-reactive substances. The activities of the antioxidant enzymes catalase and superoxide dismutase were significantly increased after chronic proline administration, while glutathione (GSH) peroxidase activity, dichlorofluorescin oxidation, GSH, sulfhydryl, and carbonyl content remained unaltered. Histological analyses of the liver revealed that proline treatment induced changes of the hepatic microarchitecture and increased the number of inflammatory cells and the glycogen content. Biochemical determination also demonstrated an increase in glycogen concentration, as well as a higher synthesis of glycogen in liver of hyperprolinemic rats. Regarding to hepatic metabolism, it was observed an increase on glucose oxidation and a decrease on lipid synthesis from glucose. However, hepatic lipid content and serum glucose levels were not changed. Proline administration did not alter the aminotransferases activities and serum markers of hepatic injury. Our findings suggest that hyperprolinemia alters the liver homeostasis possibly by induction of a mild degree of oxidative stress and metabolic changes. The hepatic alterations caused by proline probably do not implicate in substantial hepatic tissue damage, but rather demonstrate a process of adaptation of this tissue to oxidative stress. However, the biological significance of these findings requires additional investigation.

Testis and epididymis are the sites of formation and maturation of spermatozoa and must be well balanced with reactive oxygen species (ROS) and antioxidant agents. The excess of ROS lead to severe cell damage such as membrane lipid peroxidation and DNA fragmentation. On the other hand, an excess of ROS scavengers could inhibit key cell signaling pathways, some triggered by free radicals, impairing formation of fertile spermatozoa [1]. The aim of this work was to quantify the activities of three scavenger enzymes in equine testis and epididymis. MATERIAL AND METHODS RESULTS AND DISCUSSION We observed an equal distribution on catalase and SOD activities between testis and the three regions of the epididymis (Figure 1). Figure 1-Catalase, SOD and GPX activities in stallion testis and epididymis. Results expressed in means±SE. These results agree to other findings that compared catalase and SOD in testis and epididymis tissue homogenates [5,6]. GPX activity was higher in the caput then the corpus, but similar to testis and cauda tissue homogenates. This finding could result from the localized expression pattern of the GPX protein family along the epididymis. Specifically in the mouse, GPX5 is expressed exclusively in segments I and II [7], and is more active in the caput [8]. The higher amount of this this isotype could be responsible for the higher activity of GPX in this region. Rat epididymal spermatozoa also presents higher GPX activity in the caput than cauda [9]. Since caput epididymis lumen has a high sperm concentration in an elevated metabolic state, GPX could play a major role on protecting cells against increasing peroxidative conditions. CONCLUSION Stallion's testis and epididymis have catalase and SOD activities equally distributed and GPX is more active in caput than corpus, suggesting a major protective role in spermatozoa in caput epididymis.

Tissue accumulation of homocysteine occurs in classical homocystinuria, a metabolic disease characterized biochemically by cystathionine β-synthase deficiency. Vascular manifestations such as myocardial infarction, cerebral thrombosis, hepatic steatosis, and pulmonary embolism are common in this disease and poorly understood. In this study, we investigated the effect of chronic hyperhomocysteinemia on some parameters of oxidative stress (thiobarbituric acid-reactive substances, protein carbonyl content, 2',7'-dichlorofluorescein fluorescence assay, and total radical-trapping antioxidant potent) and activities of antioxidant enzymes (superoxide dismutase, catalase, and glutathione peroxidase) in the rat lung. Reduced glutathione content and glucose 6-phosphate dehydrogenase activity, as well as nitrite levels, were also evaluated. Wistar rats received daily subcutaneous injections of Hcy (0.3-0.6 μmol/g body weight) from the 6th to the 28th days-of-age and the control group received saline. One and 12 h after the last injection, rats were killed and the lungs collected. Hyperhomocysteinemia increased lipid peroxidation and oxidative damage to protein, and disrupted antioxidant defenses (enzymatic and non-enzymatic) in the lung of rats, characterizing a reliable oxidative stress. In contrast, this amino acid did not alter nitrite levels. Our findings showed a consistent profile of oxidative stress in the lung of rats, elicited by homocysteine, which could explain, at least in part, the mechanisms involved in the lung damage that is present in some homocystinuric patients.

N-Acetylaspartic acid (NAA) accumulates in Canavan disease, a severe inherited neurometabolic disorder clinically characterized by mental retardation, hypotonia, macrocephaly, and seizures. The mechanisms of brain damage in this disease remain poorly understood. Recent studies developed by our research group showed that NAA induces oxidative stress in vitro and in vivo in cerebral cortex of rats. Lipoic acid is considered as an efficient antioxidant which can easily cross the blood-brain barrier. Considering the absence of specific treatment to Canavan disease, this study evaluates the possible prevention of the oxidative stress promoted by NAA in vivo by the antioxidant lipoic acid to preliminarily evaluate lipoic acid efficacy against pro-oxidative effects of NAA. Fourteen-day-old Wistar rats received an acute administration of 0.6 mmol NAA/g body weight with or without lipoic acid (40 mg/kg body weight). Catalase (CAT), glutathione peroxidase (GPx), and glucose 6-phosphate dehydrogenase activities, hydrogen peroxide content, thiobarbituric acid-reactive substances (TBA-RS), spontaneous chemiluminescence, protein carbonyl content, total antioxidant potential, and DNA-protein cross-links were assayed in the cerebral cortex of rats. CAT, GPx activities, and total antioxidant potential were significantly reduced, while hydrogen peroxide content, TBA-RS, spontaneous chemiluminescence, and protein carbonyl content were significantly enhanced by acute administration of NAA. Those effects were all prevented by lipoic acid pretreatment. Our results clearly show that lipoic acid may protect against the oxidative stress promoted by NAA. This could represent a new therapeutic approach to the patients affected by Canavan disease.

5-Oxoproline accumulates in glutathione synthetase deficiency, an autossomic recessive inherited disorder clinically characterized by hemolytic anemia, metabolic acidosis, and severe neurological symptoms whose mechanisms are poorly known. In the present study we investigated the effects of acute subcutaneous administration of 5-oxoproline to verify whether oxidative stress is elicited by this metabolite in vivo in cerebral cortex and cerebellum of 14-day-old rats. Our results showed that the acute administration of 5-oxoproline is able to promote both lipid and protein oxidation, to impair brain antioxidant defenses, to alter SH/SS ratio and to enhance hydrogen peroxide content, thus promoting oxidative stress in vivo, a mechanism that may be involved in the neuropathology of gluthatione synthetase deficiency.

N-Acetylaspartic acid accumulates in Canavan Disease, a severe inherited neurometabolic disease clinically characterized by severe mental retardation, hypotonia, macrocephaly and generalized tonic and clonic type seizures. Considering that the mechanisms of brain damage in this disease remain poorly understood, in the present study we investigated the in vitro and in vivo effects of N-acetylaspartic acid on the activities of catalase, superoxide dismutase and glutathione peroxidase, as well as on hydrogen peroxide concentration in cerebral cortex of 14-day-old rats. Catalase and glutathione peroxidase activities were significantly inhibited, while hydrogen peroxide concentration was significantly enhanced by N-acetylaspartic acid both in vitro and in vivo. In contrast, superoxide dismutase activity was not altered by N-acetylaspartic acid. Our results clearly show that N-acetylaspartic acid impairs the enzymatic antioxidant defenses in rat brain. This could be involved in the pathophysiological mechanisms responsible for the brain damage observed in patients affected by Canavan Disease.