Increase of uricogenesis in the kuruma shrimp Marsupenaeus japonicus reared under hyper-osmotic conditions

Tissues of kuruma shrimp Marsupenaeus japonicus Bate (5.7+/-1.1 g) reared in salinities of 18, 26, 34 and 42 were examined for levels of nucleotide-related compounds, ammonia, urea and uric acid, and activities of xanthine dehydrogenase (XDH), xanthine oxidase (XOD) and uricase. Levels of total nucleotide-related compounds, including xanthine and hypoxanthine, in gill increased directly with salinity, whereas these same levels in hepatopancreas were inversely related with salinity. Hemolymph ammonia, urea and uric acid levels, and epidermal ammonia, urea and uric acid levels increased directly with salinity, whereas hepatopancreas ammonia and uric acid and gill uric acid levels were inversely related to salinity. Activities of XDH and XOD in hepatopancreas increased directly with salinity level, whereas no significant difference of uricase activity in hepatopancreas was observed among the four salinities. It is concluded M. japonicus exhibited uricogenesis and uricolysis, and an increase of uricogenesis occurred for the shrimp under hyper-osmotic conditions (salinity of 42). Uric acid produced in the hepatopancreas was transported and accumulated in the epidermis, and removed along with the spongy connective tissue at the time of molting.     

Joint action of elevated ambient nitrite and nitrate on hemolymph nitrogenous compounds and nitrogen excretion of tiger shrimp Penaeus monodon

Penaeus monodon (12.13+/-1.14 g) exposed individually to six different nitrite and nitrate regimes (0.002, 0.36 and 1.46 mM nitrite combined with 0.005 and 7.32 mM nitrate), at a salinity of 25 ppt, were examined for hemolymph nitrogenous compounds and whole shrimp's nitrogen excretions after 24 h. Nitrogen excretion increased directly with ambient nitrite and nitrate. Hemolymph nitrite, nitrate, urea and uric acid levels increased, while hemolymph ammonia, oxyhemocyanin and protein were inversely related to ambient nitrite. Exposure of P. monodon to elevated nitrite in the presence of 7.32 mM nitrate did not alter hemolymph nitrite, ammonia, uric acid, oxyhemocyanin and protein levels, but caused an increase in hemolymph nitrate and a decrease in hemolymph urea as compared to exposure to elevated nitrite only. Following exposure to elevated nitrite, nitrite was oxidized to nitrate and P. monodon showed uricogenesis and uricolysis. The shrimp also used strategies to avoid joint toxicities of nitrite and metabolic ammonia by removing ammonia or reducing ammonia production under the stress of elevated nitrite.     

Nitrogenous excretion and arginase specific activity of kuruma shrimp Marsupenaeus japonicus exposed to elevated ambient nitrite

Nitrogenous excretion and arginase specific activity were measured while Marsupenaeus japnoicus Bate (7.4±1.2 g) were exposed to 0 (control), 0.36 and 1.39 mM nitrite at 30‰ (g kg⁻¹) salinity for 24 h. Excretions of total-N, organic-N, urea-N, and ammonia-N increased significantly with an increase of ambient nitrite. Arginase specific activities of hepatopancreas and hemolymph increased directly with ambient nitrite. The fact that M. japonicus following exposure to 1.39 mM nitrite increased its arginase specific activity indicated an argininolysis in reducing joint toxicities of metabolic ammonia and incorporated nitrite.     

Hemolymph ammonia, urea and uric acid levels and nitrogenous excretion of Marsupenaeus japonicus at different salinity levels

Arginase specific activity, hemolymph ammonia, urea and uric acid levels and nitrogenous excretion were measured in Kuruma shrimp Marsupenaeus japonicus (7.29±1.16 g) acclimated to different salinities of 18‰, 26‰, 34‰ and 42‰. Arginase activity in the gill, midgut, hepatopancreas and muscle were higher and lower for the shrimp in 42‰ and 18‰, respectively. Arginase specific activity of hemolymph was higher at 34‰. Hemolymph ammonia, urea and uric acid increased directly with salinity, and excretions of total nitrogen (total-N), organic nitrogen (organic-N) and urea-N increased directly with salinity. However, ammonia-N excretion and nitrite-N excretion were inversely related to salinity. Ammonia-N accounted for 90.9%, 75.0%, 67.9% and 38.5% of total-N, whereas urea-N accounted for 3.1%, 4.5%, 7.9% and 10.9%, and organic accounted for 4.2%, 19.8%, 23.1% and 50.4% of total-N excreted by the shrimp in 18‰, 26‰, 34‰ and 42‰, respectively. Significantly higher levels of hemolymph urea and uric acid together with an increase in arginase activity indicated that ureogenesis and uricogenesis are activated for M. japonicus in hyperosmotic conditions.     

Studies on the Formation of Uricase by Streptomyces

The induced formation of uricase by the cultured cells of Streptomyces sp. and the effect of purine bases on the enzyme formation were studied. The microorganism was grown in media containing urate and/or purine bases (adenine, guanine, hypoxanthine or xanthine) and the development of the uricase activity of the cells were measured at intervals. The disappearance of urate and purine bases from the media was also determined. Without the purine bases, the production of uricase was significantly low even in the presence of urate and the disappearance of urate from the medium was in a slow rate. Upon the addition of hypoxanthine or xanthine in the presence of urate, a significant increase in the uricase activity of the cells and a concomitant rapid decrease of urate in the medium were observed. The purine bases added to the media were incorporated into the cells at a relatively early period of the culture and appeared to be converted into urate within the cells. The repression of uricase formation in the cultured cells and the derepression by the addition of the purine bases were discussed.     

Purification of Uricase by Biospecific Adsorption-Desorption

A simple procedure for the purification of uricase from bovine kidney is described. The procedure involves the following steps: 1) processing of kidney mince by borate/butanol, 2) ammonium sulphate precipitation, and 3) biospecific adsorption-desorption. The adsorbents were prepared by chemical attachment of urate or xanthine to agarose gel beads. The desorption was performed by a xanthine solution. The adsorption-desorption procedure resulted in an 11 000–12 000-fold purification. The specific activity of the purified uricase was 19.8 U/mg using either “urate” or “xanthine” adsorbent. The recovery was about 70%.The adsorbents were also used for the purification of commercial uricase preparations from hog liver. In this case the purified uricase also possessed a specific activity of 19.8 U/mg. The products were homogenous as judged by gradipore electrophoresis and gel filtration.     

Effect of Endogenous and Exogenous Urate on the Uricase Formation by Streptomyces sp.

Cells of a strain of Streptomyces sp. were incubated with an equivalent quantity of urate, xanthine, 6,8-dihydroxypurine or hypoxanthine in a medium deprived of other nitrogen source. The amount of uricase produced by these cells was shown to differ significantly, increasing in the following order of purine bases added to the medium: urate, xanthine, 6,8-dihydroxypurine and hypoxanthine. Of these was only urate indicated to be the inducer of uricase formation, and the difference in the quantity of uricase produced was found to be based on the duration of enzyme formation. The rate of uricase formation was essentially identical regardless of the purine bases supplied to cells.

Allantoin was accumulated in medium in remarkably different manners depending on the purine bases, which suggested the diversity in the mode of generation of urate in cells. Urate was generated at the slowest rate in the cells incubated with hypoxanthine, although the largest amount of uricase was produced, However, urate supplied to cells at the same rate but from medium failed to support the enzyme formation when the activity increased to a certain level. In order that the same amount of uricase was produced by the cells incubated with the different purine bases, the initial concentration of the purine bases should be raised so that they could remain in medium for the same incubation time.

Intracellular compartmentalization that might segregate endogenous and exogenous urate and might cause the difference in “effeciency” of these urate molecules as the inducer of uricase formation has been discussed.     

Purification of uricase by biospecific adsorption-desorption

A simple procedure for the purification of uricase from bovine kidney is described. The procedure involves the following steps: 1) processing of kidney mince by borate/butanol, 2) ammonium sulphate precipitation, and 3) biospecific adsorption-desorption. The adsorbents were prepared by chemical attachment of urate or xanthine to agarose gel beads. The desorption was performed by a xanthine solution. The adsorption-desorption procedure resulted in an 11 000-12 000-fold purification. The specific activity of the purified uricase was 19.8 U/mg using either "urate" adsorbent. The recovery was about 70%. The adsorbents were also used for the purification of commercial uricase preparations from hog liver. In this case the purified uricase also possessed a specific activity of 19.8 U/mg. The products were homogenous as judged by gradipore electrophoresis and gel filtration.     

Comprehensive analysis of mechanism underlying hypouricemic effect of glucosyl hesperidin

Hyperuricemia is caused by hepatic overproduction of uric acid and/or underexcretion of urate from the kidneys and small intestine. Although increased intake of citrus fruits, a fructose-rich food, is associated with increased risk of gout in humans, hesperidin, a flavonoid naturally present in citrus fruits, reportedly reduces serum uric acid (SUA) levels by inhibiting xanthine oxidase (XOD) activity in rats. However, the effects of hesperidin on renal and intestinal urate excretion were previously unknown. In this study, we used glucosyl hesperidin (GH), which has greater bioavailability than hesperidin, to clarify comprehensive mechanisms underlying the hypouricemic effects of hesperidin in vivo. GH dose-dependently decreased SUA levels in mice with hyperuricemia induced by potassium oxonate and a fructose-rich diet, and inhibited XOD activity in the liver. GH decreased renal urate excretion without changes in kidney URAT1, ABCG2 or GLUT9 expressions, suggesting that reducing uric acid pool size by inhibiting XOD decreased renal urate excretion. We also found that GH had no effect on intestinal urate excretion or protein expression of ABCG2. Therefore, we concluded that GH exhibits a hypouricemic effect by inhibiting XOD activity in the liver without increasing renal or intestinal urate excretion. Of note, this is the first study to elucidate the effect of a flavonoid on intestinal urate excretion using a mice model, whose findings should prove useful in future food science research in the area of urate metabolism. Taking these findings together, GH may be useful for preventing hyperuricemia, especially in people with the overproduction type.     

Discovery of novel curcumin derivatives targeting xanthine oxidase and urate transporter 1 as anti-hyperuricemic agents

A series of curcumin derivatives as potent dual inhibitors of xanthine oxidase (XOD) and urate transporter 1 (URAT1) was discovered as anti-hyperuricemic agents. These compounds proved efficient effects on anti-hyperuricemic activity and uricosuric activity in vivo. More importantly, some of them exhibited proved efficient effects on inhibiting XOD activity and suppressing uptake of uric acid via URAT1 in vitro. Especially, the treatment of 4d was demonstrated to improve uric acid over-production and under-excretion in oxonate-induced hyperuricemic mice through regulating XOD activity and URAT1 expression. Docking study was performed to elucidate the potent XOD inhibition of 4d. Compound 4d may serve as a tool compound for further design of anti-hyperuricemic drugs targeting both XOD and URAT1.     

Hypouricemic Actions of Exopolysaccharide Produced by Cordyceps militaris in Potassium Oxonate-Induced Hyperuricemic Mice

The hypouricemic actions of exopolysaccharide produced by Cordyceps militaris (EPCM) in potassium oxonate-induced hyperuricemia in mice were examined. Hyperuricemic mice were administered intragastrically with EPCM (200, 400 and 800 mg/kg body weight) or allopurinol (5 mg/kg body weight) once daily. Serum uric acid, blood urea nitrogen and liver xanthine oxidase (XOD) activities of each treatment were measured after administration for 7 days. EPCM showed dose-dependent uric acid-lowering actions. EPCM at a dose of 400 mg/kg body weight and allopurinol showed the same effect in serum uric acid, blood urea nitrogen and liver XOD activities in hyperuricemic mice. An increase in liver XOD activities was observed in hyperuricemic mice due to administration of EPCM at a dose of 200 mg/kg body weight. EPCM at a dose of 800 mg/kg body weight did not show significant effects on serum uric acid and XOD activities. We conclude that EPCM has a hypouricemic effect caused by decreases in urate production and the inhibition of XOD activities in hyperuricemic mice, and this natural product exhibited more potential efficacy than allopurinol in renal protection.     

Accumulation of urea in the haemolymph and ammonia excretion of Penaeus japonicus exposed to ambient nitrite

Penaeus japonicus (15.7 ± 1.4 g) were exposed individually in 30 ppt seawater to 0.01 (control), 5, 10, 20 and 50 mg/l nitrite-N for 24 hr. Haemolymph ammonia, urea, nitrite and whole shrimp ammonia-N excretion and nitrite-N uptake were then determined. Ammonia excretion of P. japonicus increased with increased ambient nitrite, and with a concomitant decrease of haemolymph ammonia, as occurring increased concentrations of nitrite. Concentrations of nitrite-N and urea-N in the haemolymph of shrimp increased with increased ambient nitrite-N. However, no urea-N excretion was observed for shrimp exposed to any nitrite treatments.     

Hepatopancreatic nuclease of black tiger shrimp Penaeus monodon unlikely to be involved in viral triggered apoptosis

Nucleases are phosphodiesterases that hydrolyze DNA and/or RNA. In a search for shrimp nucleases involved in apoptosis, we discovered a nuclease from hepatopancreatic cDNA of the black tiger shrimp Penaeus monodon. The full-length nuclease gene was amplified and revealed to contain 1668bp corresponding to 381 deduced amino acid residues in the mature enzyme. Sequence analysis indicated 83% nucleic acid identity and 89% amino acid identity to a nuclease from the Kuruma shrimp Penaeus japonicus (also called Marsupenaeus japonicus). Comparative analysis of sequences, conserved motifs and phylogenetic trees indicated that P. monodon nuclease (PMN) belonged to the family of DNA/RNA non-specific endonucleases (DRNSN). RT-PCR analysis using primers specific for PMN mRNA with seven different shrimp tissues revealed that expression in normal shrimp was restricted to the hepatopancreas. Semiquantitative RT-PCR analysis of PMN using hepatopancreatic mRNA from normal shrimp and from shrimp challenged with white spot syndrome virus (WSSV) indicated significant up-regulation of PMN in the hepatopancreas (P<0.05) at the early stage of viral infection but a return to baseline levels as gross signs of disease developed. At the same time, expression was always confined to the hepatopancreas and never seen in other tissues, including those reported to be prime targets for WSSV and subject to increased levels of apoptosis after infection. The results suggested that PMN is probably a digestive enzyme that is unlikely to be involved in hallmark DNA digestion associated with apoptosis.     

Enzymes of urate synthesis and catabolism in the Gecarcinid land crab Gecarcoidea natalis

This study investigated the sites of urate synthesis and catabolism in the gecarcinid land crab Gecarcoidea natalis by assaying spongy connective tissue, midgut gland, muscle and gill for xanthine oxidoreductase, the last enzyme involved in urate synthesis, and uricase and urease, the first and last enzymes involved in urate catabolism. The spongy connective tissue and midgut gland of the G. natalis contained activities of xanthine oxidoreductase and were considered to be sites of urate synthesis. The midgut gland had a high activity of xanthine oxidoreductase [(58.87±4.6 (SE) nmol urate produced g^-1 wet wt. tissue min^-1], 2.7 times the xanthine oxidoreductase activity contained within the spongy connective tissue, and was thought to be the main site of urate synthesis. Xanthine dehydrogenase (EC 1.1.1.204) was the only form of xanthine oxidoreductase detected within the tissues. Its presence means that the cost of synthesising urate de novo is relatively small (between 1 and 3 ATP). Uricase (EC 1.7.3.3) and urease (EC 3.5.1.5) activities were present in the tissues of G. natalis. Spongy connective tissue contained the highest activities of uricase [48.44±4.29 (SE) nmol urate consumed g^-1 wet wt. tissue min^-1] while the highest activities of urease [365.31±37.21 (SE) nmol urate consumed g^-1 wet wt tissue min^-1] were contained within the gills. From this evidence it is clear that G. natalis possesses the uricolytic pathway and hence the ability to catabolise urate, and urate catabolism is begun at the site of urate storage, the spongy connective tissue, and is completed at the gills. As the gills are the site of ammonia excretion in this species the ammonia produced from the catabolism of urate is probably excreted. The urate deposits within the body of G. natalis may be involved in temporary storage of nitrogenous wastes.     

Loose shell syndrome of farmed Penaeus monodon in India is caused by a filterable agent

Loose shell syndrome (LSS) of farmed black tiger shrimp Penaeus monodon has been reported from Indian shrimp farms since 1998 and is recognized as a major disease problem causing significant economic loss to the shrimp aquaculture sector. Unlike the rapid mortalities associated with viral pathogens such as white spot syndrome virus and yellow head virus, progression of LSS is gradual, leading to low-level progressive mortalities. The signs of LSS include a flaccid spongy abdomen due to muscular dystrophy, space between the exoskeleton and muscle, and a shrunken hepatopancreas. The feed conversion efficiency is reduced, and shrimp have poor meat quality, caused by impairment of the hepatopancreatic functions such as digestion and absorption as evidenced by the atrophy of the hepatopancreas. Histopathological investigations on LSS-affected shrimp showed shrinkage of extensor and flexor muscles with occasional hemocytic infiltration. The hepatopancreas showed inflammation of hepatopancreatic tubules with enlargement of intertubular spaces, hemocytic infiltration, and low levels of lipid reserves in the R cells. In advanced stages of LSS, many tubules were in highly necrotic condition with a sloughed epithelium, reflecting the dysfunction of the digestive gland. LSS could be induced in healthy tiger shrimp by challenge studies using membrane-filtered LSS-affected shrimp tissues, suggesting involvement of a filterable infectious agent.     

Facilitated geranylgeranylation of shrimp ras-encoded p25 fusion protein by the binding with guanosine diphosphate

A cDNA was isolated from the shrimp Penaeus japonicus by homology cloning. Similar to the mammalian Ras proteins, this shrimp hepatopancreas cDNA encodes a 187-residue polypeptide whose predicted amino acid sequence shares 85% homology with mammalian KB-Ras proteins and demonstrates identity in the guanine nucleotide binding domains. Expression of the cDNA of shrimp in Escherichia coli yielded a 25-kDa polypeptide with positive reactivity toward the monoclonal antibodies against Ras of mammals. As judged by nitrocellulose filtration assay, the specific GTP binding activity of ras-encoded p25 fusion protein was approximately 30,000 units/mg of protein, whereas that of GDP was 5,000 units/mg of protein. In other words, the GTP bound form of ras-encoded p25 fusion protein prevails. Fluorography analysis demonstrated that the prenylation of both shrimp Ras-GDP and shrimp Ras-GTP by protein geranylgeranyltransferase I of shrimp Penaeus japonicus exceeded that of nucleotide-free form of Ras by 10-fold and four-fold, respectively. That is, the protein geranylgeranyl transferase I prefers to react with ras-encoded p25 fusion protein in the GDP bound form.     

Thermodynamics and stoicheiometry of the binding of substrate analogues to uricase.

The subunit composition, metal content, substrate-analogue binding and thermal stability of Aspergillus flavus uricase were determined. A. flavus uricase is a tetramer and contains no copper, iron or any other common prosthetic group. Analytical-gel-filtration and equilibrium-dialysis experiments showed one binding site per subunit for urate analogues. The free energy of xanthine binding was -30.5 kJ (-7.3 kcal)/mol of subunit by equilibrium dialysis and -30.1 kJ (-7.2 kcal)/mol of subunit by microcalorimetry. The enthalpy change for xanthine binding was -15.9 kJ (-3.8 kcal)/mol of subunit when determined from the temperature-dependence of the equilibrium constant and -18.0 kJ (-4.3 kcal)/mol of subunit when measured microcalorimetrically. The thermal inactivation rate of A. flavus uricase increases as protein concentration is decreased. This concentration-dependent instability is not due to subunit dissociation.     

Relevance of purine catabolism to hypoxia and recovery in euryoxic and stenoxic marine invertebrates,particularly bivalve molluscs

1. Activities of xanthine dehydrogenase (XDH) and xanthine oxidase (XOD) were measured in a variety of euryoxic and stenoxic marine molluscs.2. Euryoxic bivalves contain only XDH activity which, unlike the mammalian enzyme, is not converted to XOD during anoxic exposure.3. XOD activity was detected predominantly in stenoxic bivalves such as Pecten maximus, Placopeclen magellanicus, and in the cephalopod Loligo opalescens. Although extremely variable, XOD activity increased 4-fold in Cardium edule and 13-fold in Pecten maximus during anoxic exposures of 56 hr and 0.5 hr respectively.4. The data suggest that euryoxic species may tolerate anoxic-normoxic transitions in part by possessing a form of XDH that resists conversion to XOD (a source of Superoxide radicals responsible for ischemia-reperfusion tissue injury in mammals).5. XDH activities in Carcinus maenas digestive gland are sufficient to account fully for the urate reported to accumulate during hypoxia.     

Uric acid degradation by Bacillus fastidiosus strains.

Seven Bacillus strains including one of the original Bacillus fastidiosus strains of Den Dooren de Jong could grow on urate, allantoin, and, except one, on allantoate. No growth could be detected on adenine, guanine, hypoxanthine, xanthine, and on degradation products of allantoate. Some strains grew very slowly in complex media. The metabolic pathway from urate to glyoxylate involved uricase, S(+)-allantoinase, allantoate amidohydrolase, S(-)-ureidoglycolase, and, in some strains, urease.