Examination of potential mechanism(s) of metallothionein induction by diethyl maleate.

Diethyl maleate (DEM) is a glutathione-depleting agent that can increase the levels of the sulfhydryl-rich protein metallothionein (MT) in liver. The purpose of the present study was to examine the mechanism(s) by which DEM increases mouse hepatic MT levels. DEM appears to be an indirect MT inducer as suggested by the lack of increase in MT levels when cultured mouse hepatocytes were exposed to DEM. Four possible mechanisms by which indirect MT inducers may cause an elevation in MT concentrations in liver were examined. Zn levels did not increase prior to the increase in hepatic MT, thus, a Zn redistribution to the liver is not the cause of the liver MT induction by DEM. The adrenal gland products were not required for MT induction in liver, as adrenalectomy did not abolish the increase in hepatic MT caused by DEM. The elevation in liver MT does not appear to be due solely to the decrease in liver glutathione (60%) in the initial hour after DEM, because phorone, which decreases liver glutathione (80%), produced only a fourfold increase in hepatic MT. Activation of macrophages does not seem to account for the rise in liver MT levels, as there was no increase in abundance of cytokine mRNAs for TNF-alpha, IL-1 beta, or IL-6 in the liver. These data suggest that the induction of hepatic MT by DEM does not occur in response to (1) an increase in liver Zn that precedes the increase in liver MT, (2) release of adrenal gland products, (3) decrease in liver glutathione, or (4) increased cytokine gene expression.     

Hepatic isometallothioneins in mice: induction in adults and postnatal ontogeny

The purpose of this study was to quantitate hepatic metallothionein-I (MT-I) and metallothionein-II (MT-II) in adult mice pretreated with various dosages of selected inorganic and organic compounds and in nonchemically treated neonatal mice. Male CF-1 mice received Zn (0.38-6.0 mmol/kg, sc), Cd (5-80 mumol/kg, sc), dexamethasone (10-1000 mumol/kg, sc), or ethanol (60-180 mmol/kg, po). Liver cytosol was prepared 24 hr after the administration of each compound. In another experiment, liver cytosols were prepared from male and female neonates 1 to 35 days after parturition. MT-I and MT-II in liver cytosols were isolated by high-performance anion-exchange chromatography and quantitated by atomic absorption spectrometry. Hepatic MT-I and MT-II concentrations in adult controls were 5.1 +/- 1.3 and 3.7 +/- 1.0 micrograms/g liver, respectively. All compounds increased hepatic MT levels in a dose-dependent manner over a narrow range of dosages. The lowest dosages of Zn, Cd, dexamethasone, and ethanol that produced a significant increase in total MT content (MT-I plus MT-II) were 0.38, 0.005, 0.3, and 90 mmol/kg, respectively. Maximal induction of total MT following the highest dosages of Zn, Cd, ethanol, and dexamethasone was 58, 34, 24, and 13 times the control value (8.8 +/- 2.4 micrograms total MT/g liver), respectively. The relationship between dose and hepatic MT content was linear following ethanol administration and log-linear following Zn, Cd, and dexamethasone administration. The ratio of MT-I/MT-II was approximately 2.4 following all dosages of metals. Following low and high dosages of organic compounds, the ratio of MT-I/MT-II was approximately 1.0 and 1.5, respectively. Total MT concentration in livers of 1- to 14-day-old mice was approximately 40 times that observed in adult liver (5.5 +/- 1.6 micrograms total MT/g liver) and returned toward adult levels 21 days after parturition. The ratio of MT-I/MT-II was approximately 1.8 during Postpartum Days 1 through 14 and thereafter decreased to approximately 1.0. These results indicate that MT-I is more abundant than MT-II in mouse liver following chemical exposure and during neonatal development.     

Induction of metallothionein by diethyl maleate.

Metallothionein (MT) is a sulfhydryl-rich protein whose levels are increased by administration of a variety of agents including metals, cytokines, and oxidative stress agents. Recent studies have suggested that MT is involved in protecting against various forms of oxidative stress, but little is known about the induction of MT by oxidative stress agents. Diethyl maleate (DEM) causes oxidative stress by depleting glutathione levels and is quite effective at increasing hepatic concentrations of MT. The purpose of the current study was to learn more about the relationship between induction of MT and oxidative stress by characterizing this increase in hepatic MT levels produced by DEM. Administration of DEM (3 to 9 mmol/kg, sc) increased hepatic MT concentration in mice as much as 37-fold to 213 micrograms MT/g liver, which is similar to the hepatic MT level seen after administration of other effective MT inducers, such as Cd. The maximal increase of hepatic MT took place 12 to 24 hr after administration of 5 mmol DEM/kg. This rise in MT was preceded by a 60% depletion of hepatic glutathione 3 hr after DEM and increases in both MT-I and MT-II mRNA, which reached a peak 6 to 9 hr after DEM. Administration of DEM (3-5 mmol/kg, sc) also increased MT levels in Sprague-Dawley rats. Pretreatment with DEM protected against Cd-induced hepatotoxicity in a fashion which suggested that a functional MT was being synthesized. In summary, DEM is a highly effective inducer of MT which increases MT at the mRNA level.     

Induction of multidrug resistance protein 3 in rat liver is associated with altered vectorial excretion of acetaminophen metabolites.

Treatment with the microsomal enzyme inducer trans-stilbene oxide (TSO) can decrease biliary excretion of acetaminophen-glucuronide (AA-GLUC) and increase efflux of AA-GLUC into blood. The hepatic canalicular multidrug resistance protein (Mrp) 2 and sinusoidal protein Mrp3 transport AA-GLUC conjugates into bile and blood, respectively. Thus, TSO-induced alterations in the vectorial excretion of AA-GLUC may occur via increased hepatic Mrp3 levels. The goal of this study was to determine whether TSO, diallyl sulfide (DAS), and oltipraz (OLT) treatments can up-regulate Mrp3 protein expression, and whether treatment with DAS and OLT can correspondingly increase hepatovascular efflux of AA metabolites. Rats were administered phenobarbital, TSO, DAS, OLT, or vehicle for 4 days. Interestingly, all of the chemicals increased the plasma concentration and urinary excretion of AA-GLUC and decreased its biliary excretion. In control animals, approximately 77% and 23% of AA-GLUC was excreted into bile or urine, respectively, whereas with inducer-pretreated animals, <32% of AA-GLUC was excreted into bile and >68% was excreted into urine. Correspondingly, all of the compounds increased hepatic Mrp3 mRNA levels by 13- to 37-fold and protein levels by 2- to 6-fold, respectively. In conclusion, these studies correlate increased Mrp3 protein levels in liver with increased hepatovascular excretion of AA-GLUC and suggest that induction of Mrp3 affects the route of drug excretion.     

Role of hepatic lysosomes in the degradation of metallothionein.

The degradation of metallothionein (MT) by rat liver was examined. Degradation of MT by liver homogenate was greater than by cytosol. In addition, MT degradation by the homogenate at pH 5.5 was more than that at pH 7.2. Because lysosomal proteases function at acidic pH, these findings suggest the importance of lysosomes in MT degradation. The degradation by the lysosomal fraction was about 400-fold greater than that by the cytosol. Because cathepsins are the principal lysosomal proteases, we used cathepsin-specific inhibitors, such as leupeptin, E-64 and pepstatin, to determine the relative importance of different cathepsins in degrading MT. The study reveals that cathepsin B and/or L is (are) probably the most important enzyme(s) in degrading hepatic MT, because leupeptin, which blocks cathepsin B and L activity, inhibited the degradation of apo-MT by about 80%. Cathepsin D appears to be of least importance in MT degradation, because inhibition of this enzyme by pepstatin reduced degradation by only 20%. Studies on the degradation of apo-MT, ZnMT, and CdMT indicated that apo-MT is about 1500-fold more sensitive to degradation than ZnMT and CdMT. These data suggest that metals protect MT from degradation. This is further supported by a reconstitution experiment, which shows that with a progressive decrease of MT: metal ratio following titration of apo-MT by metals, there is a concomitant reduction in degradation. At a lysosomal pH of around 4.7, about 60% of Zn and 20% of Cd are displaced from MT, thereby making it susceptible to degradation. We propose, therefore, that lysosomes are probably important for MT degradation in vivo and that metal release is a prerequisite for degradation. With the release of metals, MT becomes susceptible to degradation, which is probably accomplished by the lysosomal cathepsins, in particular cathepsins B and L.     

Malignant mesothelioma of the tunica vaginalis in a dog

A 12-year-old Scottish terrier had a scrotal mass which was diagnosed as a malignant mesothelioma of the tunica vaginalis. The tumour resulted in a rapidly fatal clinical course with direct extension into the peritoneal cavity via the inguinal canal; there were no haematogenous or lymphatic metastases. This is the first case report of such a tumour in the dog. The histology and differential diagnoses of these tumours and a review of similar tumours in other species and possible causative agents are given.     

Gastric capacity, test meal intake, and appetitive hormones in binge eating disorder

Binge eating disorder (BED), characterized by ingestion of very large meals without purging afterwards, is found in a subset of obese individuals. We showed previously that stomach capacity is greater in obese than in lean subjects, and in this study, we investigated capacity in obese individuals with BED. We also determined ad-libitum intake of a test meal until extremely full. Furthermore, we measured various appetitive hormones (insulin, leptin, glucagon, CCK, ghrelin) and glucose before a fixed meal and for 120 min afterwards. An acetaminophen tracer was used to assess gastric emptying rate. We compared three groups of overweight women: 11 BED, 13 BE (subthreshold BED), and 13 non-binge-eating normals. The BED individuals had the largest stomach capacity as assessed by either maximum volume tolerated (P=.05) or by gastric compliance to pressure (P=.02) using an intragastric balloon. Although test meal intake did not differ between groups, it correlated (P=.03) with gastric capacity. The BED group showed a tendency (P=.06) to have greater area under the curve (AUC) and had higher values at 5 and 60 min (P<.05) for insulin compared to normals. Moreover, the BED subjects had lower ghrelin baselines premeal, and lower AUC for ghrelin, which then declined less postmeal than for the normals (P<.05). None of the other blood values differed, including glucose, leptin glucagon, and CCK, as well as acetaminophen, reflecting gastric emptying. The lower ghrelin in BED, although contrary to what was expected, is consistent with lower ghrelin in obesity, and suggests down-regulation of ghrelin by overeating. The lack of differences in CCK is consistent with the lack of differences in gastric emptying rate, given that CCK is released when nutrients reach the intestine. The results show that BED subjects have a large gastric capacity as well as abnormalities in meal-related ghrelin and insulin patterns that may be factors in binge eating.     

Validation of intensity modulation on a commercial treatment planning system

For two years now, a study on intensity modulated radiotherapy (IMRT) has been in progress at the Antoine Lacassagne Hospital Center for Cancer Therapy (in Nice) in collaboration with the University of Nice-Sophia Antipolis. The kind of intensity modulation that was used is the "step and shoot" technique in which the modulated beam is created both by adding andjoining elementary fields. Before carrying out clinical tests, several problems regarding the production of modulated beams has to be mastered. The current developments of our study enable us to dosimetrically produce (in water phantom and in the PMMA phantom) complexmodulated whose segmentation was calculated by one commercial treatment planning system (TPS). Nevertheless, we showed and studied some critical discrepancies between standard clinical calculations and the calculations using field segmentation. We showed that with nonoptimal conditions of segmentation the discrepancies, which are due to the type of algorithm used, could bring about significant errors inside the field of up to 10% of maximum dose. Another point of our study is the quantification and resolution of differences between measurements and calculations due to the internal segmentation of calculated modulated fields and their realization on Linac. Once again, in none optimal conditions of segmentation and inside the field we obtained discrepancies up to 20% of maximum dose between calculations using field segmentation and measurements. That was mainly due to the tongue and groove effect and penumbra phenomena. This study allows us to show that the discrepancies between segmentation calculations and standard clinical calculations should be solved by the use of penumbra models during segmentation calculations. We will introduce both the study and its near-future perspectives.     

Sun Exposure,Tanning Behaviors,and Sunburn: Examining Activities Associated With Harmful Ultraviolet Radiation Exposures in College Students

Journal of Prevention - Understanding the behaviors that lead to sunburn is an important objective toward developing intervention strategies to reduce risk for skin cancers. Our cross-sectional...