Characterization and expression analysis of seven selenoprotein genes in yellow catfish Pelteobagrus fulvidraco to dietary selenium levels

BackgroundSelenium (Se) appears in the selenoproteins in the form of selenocysteine (Sec) and is important for the growth and development of vertebrates. The present study characterized seven selenoproteins, consisting of the GPX1, GPX3, GPX4, SELENOW, SELENOP, TXNRD2 and TXNRD3 cDNAs in various tissues of yellow catfish, explored their regulation to dietary Se addition.Methods3′ and 5′ RACE PCR were used to clone full-length cDNA sequences of seven selenoprotein genes (GPX1, GPX3, GPX4, SELENOW, SELENOP, TXNRD2 and TXNRD3). Their molecular characterizations were analyzed, including conservative motifs and the SECIS elements. The phylogenetic trees were generated through neighbor-joining (NJ) method with MEGA 6.0 with 1000 bootstrap replications. Quantitative real-time PCR was used to explore their mRNA tissue distribution in the heart, anterior intestine, dorsal muscle, head kidney, gill, liver, brain, spleen and mesenteric fat. Yellow catfish (mixed sex) were fed diets with dietary Se contents at 0.03 (low Se), 0.25 (adequate Se) and 6.39 (high Se) mg Se/kg, respectively, for 12 weeks, and their spleen, kidney, testis and brain were used for the determination of the mRNA levels of the seven selenoproteins.ResultsThe seven selenoproteins had similar domains to their corresponding members of other vertebrates. They were widely expressed in nine tissues, including heart, liver, brain, spleen, head kidney, dorsal muscle, mesenteric fat, anterior intestine and gill, but showed tissue-dependent expression patterns. Dietary Se addition affected the expression of the seven genes in spleen, kidney, testis and brain tissues of yellow catfish.ConclusionTaken together, our study demonstrated the characterization, expression and regulation of seven selenoproteins, which increased our understanding of the biological functions of Se and selenoproteins in fish.     

In vitro rates of oxidation and gluconeogenesis from L(+)- and D(-)lactate in bovine tissues

Slices of bovine kidney cortex, liver, heart and sternomandibularis muscle actively metabolized D- and L-lactate. Rates of D-lactate oxidation were greatest in kidney cortex followed by heart and liver with muscle exhibiting the lowest rates. L-lactate oxidation was greatest in kidney cortex followed by heart with liver and muscle exhibiting similar rates. Rates of oxidation of gluconeogenesis were similar for D- and L-lactate at 0.1 mm lactate but D utilization, as a percent of L, decreased as substrate concentrations increased to 50 mM. Bovine tissues appear to possess significant potential for D(-)lactate utilization. Estimates of this and possible interactions are discussed.     

D-Amino acid oxidase in various fishes*

A systematic procedure is provided for determination of D-amino acid oxidase (EC 1.4.3.3) activity in fish tissues. Activity was surveyed in crude liver homogenates of twenty-three species of fish. Activity ranged from 0-047 to 3-12 units (ρmol product produced per min) per gram wet weight of tissue. Activity was highest in liver, with significant levels occurring in kidney and pyloric caecae. It was below the limit of detection in brain, heart, spleen, testis, gill filaments, and muscle. Some properties of the enzyme from sockeye salmon, Oncorhynchus nerka (Walbaum), were studied. Knowledge of occurrence and levels of D-amino acid oxidase in fish may be useful to fish aquaculturists contemplating supplementation of feed with racemic mixtures of amino acids.     

Tissue expression of three structurally different fatty acid binding proteins from rat heart muscle, liver, and intestine

Three structurally different 14-15 kDa fatty acid binding proteins have have been purified from rat liver, small intestinal epithelium, and heart muscle, and were quantitated using specific antisera in rat tissues. Heart muscle fatty acid binding protein comprised 5% of heart muscle cytosol protein and was also expressed in stomach, muscle, testis, ovary, kidney, brain, and adipose tissue, a pattern distinct from both liver protein (expressed in liver, small and large intestinal epithelium, and adipose tissue) and intestinal protein (expressed in small and large intestinal epithelium and stomach). Distinctive patterns of tissue expression of the three different fatty acid binding proteins suggest that they may perform different specific functions in fatty acid transport and metabolism.     

Electrophoretically detectable genetic data for fifteen southern African cichlids

Gene products of 40 loci in 15 species of the cichlid genera Chetia, Hemichromis, Oreochromis, Pharynogochromis, Serranochromis and Tilapia were examined by horizontal starch-gel and vertical polyacrylamide-gel electrophoresis. Electrophoretic analysis of the loci, using aqueous extracts of brain, eye, gill, heart, kidney, liver, serum, stomach muscle, testis and white muscle, revealed the products of 40 loci for routine analysis. Genetic variation within species was observed at 18 loci and average heterozygosities ranged between 0.021 and 0.047 which is less than previous estimates based on fewer loci and smaller sample sizes for the same species. Interspecific variation exists and can be used to identify the species studied. Gene expression is similar among all species studied.     

Determination of Trace Element Level in Different Tissues of the Leaping Mullet (Liza saliens, Mugilidae) Collected from Caspian Sea

The concentrations of Cr, Cu, Fe, Mn, Ni, Pb, Cd, and Zn were determined in the brain, heart, liver, gill, gonad, spleen, kidney, and red and white muscles of Liza saliens (leaping mullet). Trace element levels in fish samples were analyzed by flame atomic absorption spectrometry. Among the non-essential metals, the levels of Ni and Pb in the tissues were higher than limits for fish proposed by FAO/WHO, EU, and TFC. Generally, the levels of the non-essential metals were much higher than those of manganese in the red and white muscles. Fe distribution pattern in tissues was in order of spleen?>?liver?>?heart?>?gill?>?brain?>?kidney?>?gonad?>?red muscle?>?white muscle. Red muscle was not within the safe limits for human consumption because non-essential metal (Ni, Pb) contents were higher than standard limits.     

Dose-effect of dietary oleic acid: oleic acid is conditionally essential for some organs

The minimum dietary intake of oleic acid that is indispensable to maintain a normal content of this fatty acid in several tissues (heart, muscle, kidney and testis) was determined in the rat. For this purpose, a dose-effect study was conducted using an experimental protocol with 7 groups of rats who received a diet in which the oleic acid level varied from 0 to 6000 mg per 100 g diet, but the other ingredients were identical (in particular the essential fatty acids, linoleic and alpha-linolenic acid). Female rats were fed the diets from two weeks before mating, and their pups were killed aged either 21 or 60 days. When the level of oleic acid in the diet was increased, the main modifications observed in 21-day-old deficient pups were as follows: (i) for 18:1n-9, in the liver, muscle, heart, kidney, and testis, a plateau was reached at about 4 g oleic acid per 100 g diet. Below this level, the higher the dose the greater the response; (ii) for 16:1n-7, the concentration decreased in the liver, muscle, heart, kidney and testis; (iii) the concentration of 18:1n-7 decreased in the kidney, muscle, and testis; (iv) some minor modifications were noted for the other fatty acids. In mother's milk at 14 days of lactation, when dietary oleic acid increased, the levels of 18:1(n-9) also increased; the increase was regular and did not reach a plateau. In 60-day-old rats, the results were generally similar to those in 21-day-old rats, but with some differences, in particular a slight decrease in oleic acid concentration in the liver and kidney at the highest dietary oleic acid level.     

Tissue distribution of immunoreactive mouse extracellular superoxide dismutase

Protein content and mRNA expression ofextracellular superoxide dismutase (EC-SOD) were investigated in 16 mouse tissues. We developed a double-antibody sandwich ELISA using theaffinity-purified IgG against native mouse EC-SOD. EC-SOD could bedetected in all of the tissues examined (lung, kidney, testis, brownfat, liver, adrenal gland, pancreas, colon, white fat, thymus, stomach,spleen, heart, skeletal muscle, ileum, and brain, in decreasing order of content measured as µg/g wet tissue). Lung showed a markedly higher value of EC-SOD than other tissues. Interestingly, white fat hada high content of EC-SOD in terms of micrograms per milligram protein,which corresponded to that of lung. Kidney showed the strongestexpression of EC-SOD mRNA. Relatively strong expression of the mRNA wasobserved in lung, white fat, adrenal gland, brown fat, and testis.Heart and brain showed only weak signals, and no such expression couldbe detected in either digestive organs or skeletal muscle.Immunohistochemically, EC-SOD was localized mainly to connectivetissues and vascular walls in the tissues examined. Deep staining inthe cytosol was observed in the cortical tubular cells of kidney. Theseresults suggest that EC-SOD is distributed systemically inmice and that the physiological importance of this enzyme may be acompensatory adaptation to oxidative stress, particularly in lung andkidney.

     

Effects of 6-aminonicotinamide on levels of soluble proteins and enzyme activities in various tissues of Japanese quail

The effects of 6-aminonicotinamide (6-AN) on the levels of soluble proteins and enzyme activities in various tissues of Japanese quail were investigated. SDS-polyacrylamide gel electrophoresis showed that the soluble proteins with molecular masses corresponding to 160.4 and 52.5 kDa were either missing or present at lower concentrations in the brain of the 6-AN treated group compared to those in the control group. The soluble liver proteins with molecular masses 200, 120 and 70.5 kDa were missing in the treated group compared to those in the control while those of a molecular mass 15.1 kDa were found to be present at higher concentrations. Similarly, treatment with 6-AN decreased the concentration of soluble proteins in pectoral muscle with molecular masses 92.3, 54.5, 43.5, 41.2, 34.5, 27.5, 20.1 and 17.5 kDa and increased those with molecular masses 96.5, 37.7, 25.0, 19.3, 16.6, 13.8 and 10.8 kDa. In the heart, soluble proteins with molecular mass 84.6 kDa were increased. There was a marked reduction in the treatment group in the concentration of NAD in pectoral muscle but not in other tissues. A similar observation was also made with total RNA levels. The specific activity of malic enzyme was markedly increased by 6-AN treatment in the kidney and pectoral muscle but reduced in the liver. 6-Phosphogluconate dehydrogenase and lactate dehydrogenase activities were markedly reduced in the liver. Glyceraldehyde-3-phosphate dehydrogenase activity was significantly decreased in liver and pectoral muscle. NAD glycohydrolase activity was markedly decreased in pectoral muscle. Acetylcholinesterase activity was markedly reduced in liver but was enhanced in pectoral muscle. The results suggest that the metabolic actions of 6-AN are specific for certain proteins in the liver and muscle with the effect being most pronounced in muscle. The effects are also quite distinct from those shown by its analogue 3-acetylpyridine.     

Sublethal effects of textile dye stuff effluent on selected oxidative enzymes and tissue respiration of Cyprinus carpio (Linn.).

Toxic effects of sublethal concentration of dye stuff effluent on succinic dehydrogenase (SDH) and lactic dehydrogenase (LDH) activities and tissue respiration were studied in C. carpio. While the sublethal exposure significantly reduced SDH activity and tissue respiration, LDH activity increased in gill, brain, liver, muscle and kidney. The maximum inhibition of SDH activity (74%) was recorded in gill and the minimum (38%) in liver. The percentage reduction of oxygen consumption in the tested tissues was in the order of gill greater than brain greater than liver greater than muscle greater than kidney. The muscle showed the highest level (96%) of increase in LDH activity whereas the kidney cells showed the minimum increase. Exposure to sublethal concentration suppressed the aerobic respiration and triggered the anaerobic respiration.     

Culture of cells from tissues of adult and larval sea lamprey

Methods were developed for the culture of cells derived from tissues of the sea lamprey (Petromyzon marinus). Cultures were initiated from gill, liver, muscle and gut from larvae and newly transformed individuals and brain, heart, kidney and ovary from sexually mature adults. The lamprey cells were viable for up to six months in culture and cells from ovary, muscle, gut, gill and liver were propagated for multiple passages. For all cultures except liver, optimal cell attachment and spreading was obtained on surfaces coated with fibronectin and collagen. Optimal liver cell attachment was achieved on basement membrane. Cells synthesizing DNA were detected by precursor incorporation in five week-old cultures derived from adult and larval tissues. Metabolic labeling experiments with [³⁵S]-methionine demonstrated that cultures initiated from liver and ovary continued to synthesize and release proteins into the medium for several weeks. Ultrastructural examination revealed the presence of ciliated cells in cultures from brain and the accumulation of lipid in epithelial cells derived from liver and gill.     

Accumulation of intra-arterially administered [3H]adrenaline and [3H]noradrenaline in various tissues of the Atlantic cod, Gadus morhua

The accumulation of intra-arterially administered radiolabelled adrenaline and noradrenaline was studied in various tissues of the Atlantic cod, Gadus morhua. The largest uptake was seen in the posterior cardinal vein (chromaffin tissue), head kidney, kidney, heart and gill filaments. All these tissues, except the heart, also accumulated noradrenaline to a greater extent than adrenaline. The heart, spleen, gas gland and muscularis mucosae of the swimbladder instead favoured adrenaline accumulation. Small amounts of the injected label (both adrenaline and noradrenaline) were also recovered in the intestine, liver and hypothalamus. The lowest detectable amine accumulation was seen in the rest of the brain and in the skeletal muscle. It is suggested that innervation density, blood flow to the tissue and the concentration of circulating and endogenously stored amine, as well as the affinity of the amine for the degrading enzymes and a possible stereospecificity of the uptake mechanisms, determine the rate and preference of accumulation between the amines.     

Glucose dehydrogenase in teleosts: tissue distribution and proposed function

Tissue extracts of skeletal muscle, heart, eye, brain, liver, kidney, gill and stomach were electrophoretically examined for glucose dehydrogenase (EC 1.1.1.47) activity in 21 species of marine teleost fishes. Glucose dehydrogenase expression was detected only in liver extracts. Considerable interordinal variation was found in levels of enzymatic activity. Available data support the hypothesis that glucose dehydrogenase provides NADPH for the mixed-function oxidase system in teleosts.     

Effect of short- and long-term diabetes on carnitine and myo-inositol in rats.

1. The effect of short- (2 wk) and long-term (20 wk) streptozotocin diabetes was studied on urine, blood, liver, heart, brain, skeletal muscle, pancreas and kidney concentrations of acid-soluble carnitine and free myo-inositol. 2. Short-term diabetic rats excreted significantly higher concentrations of carnitine as well as myoinositol than normal rats. Blood carnitine and myo-inositol were not different between normal and diabetic rats. Diabetes caused a decrease in liver, brain and pancreatic carnitine, but not in heart, skeletal muscle and kidney. Myo-inositol concentration was decreased in liver, heart and kidney but not in brain, pancreas and skeletal muscle. 3. Long-term diabetic rats had higher urinary excretions of both carnitine and myo-inositol. Blood carnitine did not change; however, myo-inositol was higher in diabetic than in normal rats. Diabetes caused a significant increase in liver and a decrease in heart, brain, skeletal muscle and pancreatic content of carnitine; no difference in kidney carnitine was noted. Myo-inositol content was elevated only in liver of diabetic rats. 4. We suggest that carnitine and myo-inositol concentrations are influenced both by short- and long-term diabetes through changes in tissue metabolism.     

The effect of intraperitoneally administered gold thioglucose on growth, food consumption and accumulation of gold in various organs of the chicken (Gallus domesticus)

1. Gold thioglucose (GTG) was intraperitoneally injected into 10-day-old male and female chickens in a dose of 0, 0.2, 0.4 or 0.8 mg per gram of body wt. 2. Mortality of the GTG-injected chickens was 100% and 25% for doses of 0.8 and 0.4 mg/gBW respectively, in both sexes and 25% for a dose of 0.2 mg in females, which were all found within 14.5 hr after the GTG treatment. 3. Body weight gain, food consumption and food efficiency of surviving chickens for 23 days after the GTG injection were not affected by GTG in spite of dose level. 4. Gold detected in blood, heart, liver, gallbladder, spleen, proventriculus, gizzard, duodenum, kidney, pectoral muscle, small intestine, lung and brain of the dead chickens accumulated most highly in heart and followed by spleen, but in the surviving chicken a little gold was only found in liver, spleen and kidney of some GTG-treated chickens.