Cloning and sequencing an ovine interleukin-4-encoding cDNA

We have cloned a cDNA containing the complete coding sequence of ovine(ov) interleukin 4 (IL4) by the polymerase chain reaction using primers based on the 5' and 3' untranslated regions of the human IL4 gene. RNA was isolated from phorbol myristate acetate- and calcium ionphore A23187-stimulated mesenteric lymph node cells. The ovIL4 cDNA is 535 bp in length and contains an open reading frame of 408 nucleotides (nt) coding for a 15.1-kDa IL4 precursor of 135 amino acids (aa). Cleavage of the putative signal peptide of 22 aa yields the mature form of 13.2 kDa. Analysis of the mature aa sequence shows two potential N-linked glycosylation sites and six Cys residues. Ovine and bovine IL4 are shorter than human, mouse and rat IL4, because of a 51-nt deletion in the coding region. Comparison of the predicted aa sequence shows that ovIL4 shares 92, 57, 37 and 42% identity with the bovine, human, mouse and rat IL4s, respectively.     

Glutathone and glutathione ethyl ester supplementation of mice alter glutathione homeostasis during exercise

The present study examined the effect of glutathione (GSH) and glutathione ethyl ester (GSH-E) supplementation on GSH homeostasis and exercise-induced oxidative stress. Male Swiss-Webster mice were randomly divided into 4 groups: starved for 24 h and injected with GSH or GSH-E (6 mmol/kg body wt, i.p.) 1 h before exercise, starved for 24 h and injected with saline (S); and having free access to food and injected with saline (C). Half of each group of mice was killed either after an acute bout of exhaustive swimming (E) or after rest (R). Plasma GSH concentration was 100-160% (P < 0.05) higher in GSH mice vs. C or S mice at rest, whereas GSH-E injection had no effect. Plasma GSH was not affected by exercise in C or S mice, but was 44 and 34% lower (P < 0.05) in E vs. R mice with GSH or GSH-E injection, respectively. S, GSH- and GSH-E-treated mice had significantly lower liver GSH concentration and the GSH:glutathione disulfide (GSSG) ratio than C mice. Hepatic and renal GSH and the GSH:GSSG ratio were significantly lower in E vs. R mice in all groups. GSH-E-treated mice had a significantly smaller exercise-induced decrease in GSH vs. C, S, and GSH-treated mice and no difference in the GSH:GSSG ratio in the kidney. Activities of gamma-glutamylcysteine synthetase and gamma-glutamyltranspeptidase in the liver and kidney were not affected by either GSH treatment or exercise. GSH concentration and the GSH:GSSG ratio in quadriceps muscle were not different among C, S and GSH-treated mice, but significantly lower in GSH-E-treated mice (P < 0.05). Hepatic malondialdehyde (MDA) content was greater in exercised mice in all but GSH-E-treated groups. GSH and GSH-E increased MDA levels in the kidney of E vs. R mice, but attenuated exercise-induced lipid peroxidation in muscle. Swim endurance time was approximately 2 h longer in GSH (351 +/- 22 min) and GSH-E (348 +/- 27) than S mice (237 +/- 17). We conclude that 1) acute GSH and GSH-E supplementation at the given doses does not increase tissue GSH content or redox status; 2) both GSH and GSH-E improve endurance performance and prevent muscle lipid peroxidation during prolonged exercise; and 3) while both compounds may impose a metabolic and oxidative stress to the kidney, this side effect is smaller with GSH-E supplementation.     

Molecular cloning, heterologous expression, and characterization of human glyoxalase II

A clone encoding glyoxalase II has been isolated from a human adult liver cDNA library. The sequence of 1011 base pairs consists of a full-length coding region of 780 base pairs, corresponding to a protein with a calculated molecular mass of 28,861 daltons. Identities (50-60%) were found to partial 5' and 3' cDNA sequences from Arabidopsis thaliana as well as within a limited region of glutathione transferase I cDNA from corn. A vector was constructed for heterologous expression of glyoxalase II in Escherichia coli. For optimal yield of enzyme, silent random mutations were introduced in the 5' coding region of the cDNA. A yield of 25 mg of glyoxalase II per liter of culture medium was obtained after affinity purification with immobilized glutathione. The recombinant enzyme had full catalytic activity and kinetic parameters indistinguishable from those of the native enzyme purified from human erythrocytes.     

Craf-1 protein kinase is essential for mouse development

The complete cDNA of the mouse integral membrane protein 2B gene (Itm2b) was determined by sequence analysis of expressed sequence tag (EST) clone L26775 and a clone isolated from a cDNA library of the osteogenic stromal cell line MN7 (Mathieu et al., 1992. Calcif. Tissue Int. 50, 362-371) and by 5' rapid amplification of cDNA ends (RACE). Alignment of different mouse ESTs confirmed the entire sequence. Northern blot analysis of different neonatal and adult mouse tissues showed that Itm2b is ubiquitously expressed. There are three mRNAs with different lengths in neonatal as well as in adult tissues, originating from alternative polyadenylation by usage of one consensus and two additional variant polyadenylation signals. The cDNA sequence of the human Itm2b homolog (ITM2B) was assembled using data from available human ESTs. Both the mouse and the human gene code for a protein of 266 amino acids (aa) that is homologous to a previously described integral membrane protein, Itm2A, of which the expression is restricted to osteo- and chondrogenic tissues. Itm2A and Itm2B belong to a family of type II integral membrane proteins, which contains a third member, Itm2C (Deleersnijder et al., 1996. J. Biol. Chem. 271, 19475-19482). The human ITM2B and mouse Itm2b genes were previously mapped as unknown ESTs to conserved syntenic regions Homo sapiens 13q12-13 and Mus musculus 14.     

The mouse estrogen receptor-related orphan receptor alpha 1: molecular cloning and estrogen responsiveness

We observed that glutathione (GSH) status regulates the Ah receptor inducible cytochrome P4501A (CYP1A) gene expression and catalytic activity in 3,3',4,4'-tetrachlorobiphenyl (TCB) exposed rainbow trout. Tissue GSH status of TCB (1 mg/kg body weight, in corn oil) injected fish was manipulated by a) injecting (i.p.) GSH (0.25 g/kg), b) arresting GSH synthesis by L-buthionine-[S,R]-sulfoximine (BSO; 6 mmol/kg) injection for 3 and 6 days. Our attempt to manipulate GSH levels by lipoate supplementation (16 mg/kg) was not productive. Both BSO- and lipoate-supplemented fish maintained a low tissue redox (GSSG/GSH) ratio. Activities of glutathione peroxidase and glutathione reductase were elevated following 3 days of GSH supplementation in GSH rich tissues. Low activities of these enzymes were observed in BSO treated GSH deficient tissues. TCB injection markedly induced hepatic and renal CYP1A catalytic (ethoxyresorufin O-deethylase [EROD]) activities. This effect was further potentiated (3-fold) in GSH-supplemented fish tissues. In contrast, EROD induction by TCB was markedly suppressed in GSH deficient (BSO-treated) and lipoate-supplemented fish. The suppression of CYP1A catalytic activities in GSH deficient and lipoate-supplemented fish was consistently associated with a suppression of TCB induced CYP1A mRNA and protein expressions in these groups. In glutathione-supplemented fish, TCB induced CYP1A protein expression was markedly higher following 3 days of GSH supplementation. Results of our study suggest that tissue thiol status modulates cytochrome P450 CYP1A gene expression and catalytic activity.     

Modulation of cisplatin chronotoxicity related to reduced glutathione in mice

Intracellular reduced glutathione (GSH) concentrations were measured according to the tissue sampling-time along the 24 h scale in male B6D2F1 mice. A significant circadian rhythm in GSH content was statistically validated in liver, jejunum, colon and bone-marrow (P < or = 0.02) but not in kidney. Tissue GSH concentration increased in the dark-activity span and decreased in the light-rest span of mice. The minimum and maximum of tissue GSH content corresponded respectively to the maximum and minimum of cisplatin (CDDP) toxicity. The role of GSH rhythms with regard to CDDP toxicity was investigated, using a specific inhibitor of GSH biosynthesis, buthionine sulfoximine (BSO). Its effects were assessed on both tissue GSH levels and CDDP toxicity at three circadian times. BSO resulted in a 10-fold decrease of the 24 h-mean GSH in kidney. However a moderate GSH decrease characterized liver (-23%) and jejunum (-30%). BSO pretreatment largely enhanced CDDP toxicity which varied according to a circadian rhythm. Although BSO partly and/or totally abolished the tissue GSH rhythms, it did not modify those in CDDP toxicity. We conclude that GSH have an important influence on CDDP toxicity but not in the circadian mechanism of such platinum chronotoxicity.     

Role of quinone reductase in in vivo ethanol metabolism and toxicity

The activation of microsomal glutathione S-transferase in oxidative stress was investigated by perfusing isolated rat liver with 1 mM tert-butyl hydroperoxide (t-BuOOH). When the isolated liver was perfused with t-BuOOH for 7 min and 10 min, microsomal, but not cytosolic, glutathione S-transferase activity was increased 1.3-fold and 1.7-fold, respectively, with a concomitant decrease in glutathione content. A dimer protein of microsomal glutathione S-transferase was also detected in the t-BuOOH-perfused liver. The increased microsomal glutathione S-transferase activity after perfusion with t-BuOOH was reversed by dithiothreitol, and the dimer protein of the transferase was also abolished. When the rats were pretreated with the antioxidant alpha-tocopherol or the iron chelator deferoxamine, the increases in microsomal glutathione S-transferase activity and lipid peroxidation caused by t-BuOOH perfusion of the isolated liver was prevented. Furthermore, the activation of microsomal GSH S-transferase by t-BuOOH in vitro was also inhibited by incubation of microsomes with alpha-tocopherol or deferoxamine. Thus it was confirmed that liver microsomal glutathione S-transferase is activated in the oxidative stress caused by t-BuOOH via thiol oxidation of the enzyme.     

Organochlorine pesticide residues in cow''s milk and butter in Mexico

In the chipmunk, a mammalian hibernator, a 140 kDa protein complex found in the blood, drastically decreases in concentration during hibernation. This complex contains four species of proteins, HP-20, -25, -27 and -55. In the present study, cDNA clones coding for the chipmunk HP-55 were isolated from a liver cDNA library. Sequence analysis revealed that HP-55 is produced as a precursor protein of 413 amino acids (aa), that it has a signal peptide of 24 aa, and that it contains four potential N-glycosylation sites. The deduced aa sequence shows 63% identity with that of rat alpha1-antitrypsin (alpha1-AT); however, the sequence corresponding to the reactive center P1-P1' residues was found to be Met-Leu, whereas it is Met-Ser in the rat alpha1-AT. During screening of the chipmunk liver cDNA library, four other related classes of cDNA clones were obtained, each also coding for an alpha1-AT-like protein. In spite of more than 86% overall aa sequence identity among the five chipmunk alpha1-AT-like proteins, they are highly divergent in the putative reactive center region; the putative P1-P1' sequences are Met-Leu (HP-55 or CM55-ML), Met-Met (CM55-MM), Met-Ser (CM55-MS), Ser-Ile (CM55-SI) and Ser-Thr (CM55-ST). Each of the alpha1-AT-like protein mRNAs was expressed in chipmunk liver, and the HP-55 mRNA level was greatly reduced during hibernation. Genomic Southern blot analysis and screening of a liver cDNA library from another hibernating squirrel species, the ground squirrel, also revealed expression of multiple members of the alpha1-AT gene family, whereas analysis of a cDNA library from a non-hibernating species, the tree squirrel, found only a single alpha1-AT gene.     

A mammalian homolog of the bacterial monomeric sarcosine oxidases maps to mouse chromosome 11, close to Cryba1

We have cloned a cDNA from a mouse gene, Pso (peroxisomal sarcosine oxidase). Pso appears to encode a homolog of the single-subunit (40 kDa) bacterial sarcosine oxidases. The mouse Pso gene product would contain a peroxisomal localization sequence, like that of the recently reported rabbit enzyme, Mouse Pso lies between 20 and 50 kb upstream of the promoter of the Sez6 gene, close to Crybal on chromosome 11. Pso is expressed very strongly and specifically in liver and kidney. The gene appears to be present widely in eutherian mammals.     

Mouse liver nicotinamide N-methyltransferase: cDNA cloning, expression, and nucleotide sequence polymorphisms

Nicotinamide N-methyltransferase (NNMT) catalyzes the N-methylation of nicotinamide and structurally related compounds. We cloned mouse liver NNMT cDNA to make it possible to test the hypothesis that large differences among strains in levels of hepatic NNMT activity might be associated with strain-dependent variation in NNMT amino acid sequence. Mouse liver NNMT cDNA was 1015 nucleotides in length with a 792 nucleotide open reading frame (ORF) that was 83% identical to the nucleotide sequence of the human liver NNMT cDNA ORF. The mouse liver cDNA encoded a 264 amino acid protein with a calculated Mr value of 29.6 kDa. NNMT cDNA ORF sequences were then determined in five inbred strains of mice with very different levels of hepatic NNMT enzymatic activity. Although multiple differences among strains in nucleotide sequence were observed, none altered encoded amino acids. cDNA sequences for C57BL/6J and C3H/HeJ mice, prototypic strains with "high" and "low" levels of hepatic NNMT activity, respectively, were then expressed in COS-1 cells. Both expression constructs yielded comparable levels of enzyme activity, and biochemical properties of the expressed enzyme, including apparent Km values for substrates and IC50 values for inhibition by N1-methylnicotinamide, were very similar to those of mouse liver NNMT. Growth and development experiments were then conducted, which demonstrated that, although at 8 weeks of age average hepatic NNMT activity in C57BL/6J mice was 5-fold higher than that in C3H/HeJ mice, activities in the two strains were comparable by 30 weeks of age--indicating strain-dependent variation in the developmental expression of NNMT in mouse liver. These observations will serve to focus future studies of strain-dependent differences in murine hepatic NNMT on the regulation of the enzyme activity during growth and development.     

Ipsilateral neglect: reversal of bias or exaggerated cross-over phenomenon?

We have shown previously that plating primary cultures of rat hepatocytes under low density, which stimulates hepatocytes to shift from the G0 to the G1 phase of the cell cycle, resulted in increased levels of glutathione (GSH) and cysteine, and increased activity of gamma-glutamylcysteine synthetase (GCS), the rate-limiting enzyme in GSH synthesis (Lu et al., Am. J. Physiol. 1992;263:C1181-C1189). In the current work we examined changes in GSH homeostasis after two-thirds partial hepatectomy (PH). Male Sprague-Dawley rats underwent two-thirds PH or sham operation. GSH, oxidized glutathione (GSSG), cysteine, GSH efflux, DNA synthesis, changes in GCS subunit messenger RNA (mRNA), and protein levels were measured 12 and 24 hours after PH. Both liver GSH and cysteine levels were doubled at 12 hours and remained elevated at 24 hours after PH. GSSG levels also increased, but the ratio of GSH to GSSG levels remained unchanged. The increase in GSH and cysteine levels preceded the increase in DNA synthesis. Sinusoidal GSH efflux was unchanged after two-thirds PH, but biliary GSH efflux decreased. However, total GSH efflux was minimally altered after two-thirds PH. The increase in GSH can be largely accounted for by the increase in both cysteine availability and the activity of GCS. The steady-state mRNA and protein levels of the GCS heavy subunit were increased at 12 hours after PH. The mRNA level of the GCS light subunit was unchanged. In summary, early in the course of liver regeneration the steady-state hepatic GSH levels double because of an increase in the biosynthesis of GSH.     

Glutathione depletion in rested and exercised mice: biochemical consequence and adaptation

The effect of chronic in vivo glutathione (GSH) depletion by L-buthionine-[S,R]-sulfoximine (BSO) on intracellular and interorgan GSH regulation was investigated in mice both at rest and after an acute bout of exhaustive swim exercise. BSO treatment for 12 days decreased concentrations of GSH in the liver, kidney, quadriceps muscle, and plasma to 28, 15, 7, and 35%, respectively, compared to GSH-adequate mice. In most tissues, with the exception of the kidney, this decrease was associated with a concomitant decrease of glutathione disulfide (GSSG) such that the GSH/GSSG ratio was maintained. GSH depletion caused adaptive changes in several enzymes related to GSH regulation, such as liver glutathione peroxidase (-25%), kidney gamma-glutamyltranspeptidase (+20%), glutathione disulfide reductase (+131%) and glutathione sulfur-transferase (+53%). There was an apparent down-regulation of muscle gamma-glutamyltranspeptidase (-56%) in the GSH-depleted mice, which contributed to a conservation of plasma GSH. Exhaustive exercise in the GSH-adequate state severely depleted GSH content in the liver (-55%) and kidney (-35%), whereas plasma and muscle GSH levels remained constant. However, exercise in the GSH-depleted state exacerbated GSH deficit in the liver (-57%), kidney (-33%), plasma (-65%), and muscle (-25%) in the absence of adequate reserves of liver GSH. Hepatic lipid peroxidation increased by 220 and 290%, respectively, after exhaustive exercise in the GSH-adequate and -depleted mice. We conclude that GSH homeostasis is essential for the prooxidant-antioxidant balance during prolonged physical exercise.     

Effects of chloroquine treatment on antioxidant enzymes in rat liver and kidney

The effect of chloroquine (CHQ) administration on antioxidant enzymes in rat liver and kidney was studied. Male Sprague-Dawley rats were administered 20 mg/kg CHQ once a week for 4 weeks (chronic treatment) or a single dose at 10 or 20 mg/kg (acute treatment). Antioxidant enzyme activities were determined in cytosolic fractions of liver and kidney, whereas reduced glutathione (GSH) and malondialdehyde (MDA) were determined in tissue samples. Results indicate minimal effects of acute CHQ treatment, whereas chronic treatment with CHQ differentially affected antioxidant enzymes in the two organs. Superoxide dismutase activity was increased nearly twofold, while activities of selenium glutathione peroxidase (GPX), catalase, and NAD (P) H: quinone oxidoreductase were decreased in livers of CHQ-treated rats compared to controls. No significant effects of CHQ on glutathione reductase, GSH, and MDA levels were seen in the liver. Fewer effects of CHQ were observed in the kidney where a decrease in GPX activity and an increase in MDA levels was seen. Lowering of antioxidant enzymes activities in the liver by CHQ could render the organ more susceptible to subsequent oxidative stress; while increased MDA production after CHQ treatment in the kidney indicate that the organ is being subjected to oxidative stress. This could have implications for prolonged chloroquine intake.     

Effect of co-planar polychlorinated biphenyl on the hepatic glutathione peroxidase redox system in rats and guinea pigs

The effect of 3,3',4,4',5-pentachlorobiphenyl (PCB 126) on hepatic glutathione peroxidase (GPx) redox system was studied in vivo in rats and guinea pigs. PCB 126 treatment caused significant reduction of Se-dependent and -non-dependent GPx activity in rats. In agreement with this, the content of glutathione (GSH) and the activities of GSH reductase (GR) and gamma-glutamyl transpeptidase (gamma-GTP) were also decreased in this species. On the contrary, guinea pig liver Se-non-dependent GPx activity was significantly enhanced by PCB 126 treatment, while no effect on Se-dependent activity was observed. Neither the content of GSH nor the enzyme activities responsible for GSH supply in guinea pig liver was affected by PCB 126. These result suggested that the damage on GPx redox system is, at least, one of mechanisms by which co-planar PCB induces the toxicity in rats. However, in guinea pigs, this is not the case, and different mechanism from the damage on active oxygen quenching system is likely to be involved.     

Multi-center European evaluation of HIV testing on serum and saliva samples

Sulphur dioxide (SO2) is an air pollutant implicated in the initiation of asthmatic symptoms. Glutathione (GSH) has been proposed to play a role in detoxification of SO2 through the sulfitolysis of glutathione disulphide (GSSG) to S-sulphoglutathione (GSSO3-). Rats were exposed to concentrations of SO2 between 5 and 100 ppm for 5 hr a day between 7 and 28 days. Lung injury as assessed by bronchoalveolar lavage and tissue GSH status were evaluated. SO2 5 ppm failed to elicit any lung injury or inflammatory response but did deplete GSH pools in lung, liver, heart and kidney. Activities of gamma-glutamylcysteine synthetase (GCS), glutathione peroxidase (GPx), glutathione S-transferase (GST) and glutathione reductase (GRed) in lung were lowered relative to those in control animals. In liver, GRed activity was decreased. SO2 50 ppm exposure also failed to elicit injury or inflammation but did lower inflammatory cell numbers in the circulation. Rats exposed to 50 ppm SO2 maintained tissue GSH status, but activities of GCS, GPx, GRed and gamma-glutamyltranspeptidase in lung and hepatic GRed and GPx were significantly lower than in control rats. Unaltered GST activity in lung and liver was suggestive of an impairment of the sulfitolysis reaction in these animals, perhaps through lower substrate flux through the GPx reaction, as GSSO3- is a known inhibitor of GST in the rat. Rats exposed to 100 ppm SO2 exhibited evidence of inflammation (120-fold increase in neutrophil numbers recovered in lavage fluid) and like the 5 ppm exposed rats had lower tissue GSH concentrations and GSH-related enzyme activities in lung. We conclude that sulfitolysis of GSSG does occur in vivo during SO2 exposure and that SO2, even in the absence of pulmonary injury, is a potent glutathione depleting agent.