Hyper-ammonia stress causes induction of inducible nitric oxide synthase gene and more production of nitric oxide in air-breathing magur catfish, Clarias magur (Hamilton).

Nitric oxide (NO) is an important signalling molecule that plays diverse physiological functions in several vertebrates including that of adaptation to various stressful stimuli. The air-breathing magur catfish (Clarias magur) is known to tolerate a very high external ammonia (HEA) stress in its natural habitats. We report here the possible induction of inducible nitric oxide (inos) gene and more generation of NO in magur catfish exposed to HEA. Exposure to HEA (25 mM NH4Cl) for 14 days led to the higher accumulation of NO in different tissues of magur catfish and also more efflux of NO from the perfused liver of NH4Cl-treated fish as a consequence of high build of toxic ammonia in body tissues. More synthesis and accumulation of NO in body tissues was associated with the induction of iNOS activity, which otherwise was not detectable in control fish. The stimulation of iNOS activity in HEA exposed fish was mainly due to induction of inos gene as evidenced by more expression of inos mRNA and also more abundance of iNOS protein in different tissues of magur catfish. Immunocytochemical analysis indicated the zonal specific expression of iNOS protein in different tissues of magur catfish. The augmentation of iNOS in the fish under HEA could be an adaptive strategy of the fish to defend against the ammonia stress through the generation of NO. Therefore, the present finding identifies the potential role of iNOS to enhance the adaptive capacity and survivability of catfish under various adverse environmental and pathological conditions that it faces in its natural habitats.

Expression of inducible nitric oxide synthase and nitric oxide production in the mud-dwelled air-breathing singhi catfish, Heteropneustes fossilis under condition of water shortage.

Nitric oxide (NO) is known to be an important regulator molecule for regulating the multiple signaling pathways and also to play diverse physiological functions in mammals including that of adaptation to various stresses. The present study reports on the production of nitric oxide (NO) and the expression of inducible nitric oxide synthase (iNOS) enzyme that produces NO from l-arginine in the freshwater air-breathing catfish (Heteropneustes fossilis) while dwelling inside the mud peat under semidry conditions. Desiccation stress, due to mud-dwelling for 2 weeks, led to significant increase of NO concentration in different tissues and in plasma of singhi catfish, and also the increase of NO efflux from the perfused liver with an accompanying increase of toxic ammonia level in different tissues. Mud-dwelling also resulted to induction of iNOS activity, expression of iNOS protein in different tissues after 7 days with further increase after 14 days, which otherwise was not detectable in control fish. Further, mud-dwelling also resulted to a significant expression of iNOS mRNA after 7 days with a more increase of mRNA level after 14 days, suggesting that the desiccation stress caused transcriptional regulation of iNOS gene. Immunocytochemical analysis indicated the zonal specific expression of iNOS protein in different tissues. Desiccation stress also led to activation and nuclear translocation of nuclear factor кB (NFкB) in hepatic cells. These results suggest that the activation of iNOS gene under desiccation-induced stresses such as high ammonia load was probably mediated through the activation of one of the major transcription factors, the NFкB. This is the first report of desiccation-induced induction of iNOS gene, iNOS protein expression leading to more generation of NO while living inside the mud peat under condition of water shortage in any air-breathing teleosts.

Lipopolysaccharide causes NFĸB-mediated induction of inducible nitric oxide synthase gene and more production of nitric oxide in air-breathing catfish, Clarias magur (Hamilton).

The magur catfish (Clarias magur) is a facultative air-breather and regularly encounters with various environmental changes along with exposure to various bacterial pathogens in its natural habitats. Occurrence of various biochemical adaptational strategies related to nitrogen metabolism in magur catfish is already known. The present investigation aimed at determining the possible induction of inducible nitric oxide synthase (inos) gene and stimulation of nitric oxide (NO) production in this catfish while challenging with lipopolysaccharide (LPS, a bacterial endotoxin) treatment, and also to determine the involvement of nuclear factor kappa B (NFkB) in induction of inos gene. Intra-peritoneal injection of LPS led to more production and accumulation of NO in different body tissues of magur catfish as a consequence of induction of iNOS activity. The induction of iNOS activity was associated with the induction of inos gene as evidenced by more expression of inos mRNA and more abundance of iNOS enzyme protein in different tissues of magur catfish with certain variations in zonal specific expression patterns. Similar observations related to more production of NO and induction of inos gene were also made when the isolated hepatocytes were treated with LPS in vitro condition. LPS treatment also led to activation of NFĸB in hepatic cells. However, in presence of a specific inhibitor of NFkB, the LPS-mediated induction of inos gene and extra production of NO were almost blocked, thereby suggesting that the induction of inos gene due to LPS treatment was mediated via the NFkB in magur catfish. It is hypothesized that the induction of iNOS activity, and more synthesis and accumulation of NO could serve as indicators to determine the pathophysiological conditions of the fish living in bacterial contaminated water bodies. Further, it can be contemplated that more synthesis of NO through iNOS enzyme probably serves as an important pharmacological tool against fish pathogen and also plays an important role in host defense mechanisms in this unique group of magur catfish.

Induction of Inducible Nitric Oxide Synthase by Lipopolysaccharide and the Influences of Cell Volume Changes, Stress Hormones and Oxidative Stress on Nitric Oxide Efflux from the Perfused Liver of Air-Breathing Catfish, Heteropneustes fossilis.

The air-breathing singhi catfish (Heteropneustes fossilis) is frequently being challenged by bacterial contaminants, and different environmental insults like osmotic, hyper-ammonia, dehydration and oxidative stresses in its natural habitats throughout the year. The main objectives of the present investigation were to determine (a) the possible induction of inducible nitric oxide synthase (iNOS) gene with enhanced production of nitric oxide (NO) by intra-peritoneal injection of lipopolysaccharide (LPS) (a bacterial endotoxin), and (b) to determine the effects of hepatic cell volume changes due to anisotonicity or by infusion of certain metabolites, stress hormones and by induction of oxidative stress on production of NO from the iNOS-induced perfused liver of singhi catfish. Intra-peritoneal injection of LPS led to induction of iNOS gene and localized tissue specific expression of iNOS enzyme with more production and accumulation of NO in different tissues of singhi catfish. Further, changes of hydration status/cell volume, caused either by anisotonicity or by infusion of certain metabolites such as glutamine plus glycine and adenosine, affected the NO production from the perfused liver of iNOS-induced singhi catfish. In general, increase of hydration status/cell swelling due to hypotonicity caused decrease, and decrease of hydration status/cell shrinkage due to hypertonicity caused increase of NO efflux from the perfused liver, thus suggesting that changes in hydration status/cell volume of hepatic cells serve as a potent modulator for regulating the NO production. Significant increase of NO efflux from the perfused liver was also observed while infusing the liver with stress hormones like epinephrine and norepinephrine, accompanied with decrease of hydration status/cell volume of hepatic cells. Further, oxidative stress, caused due to infusion of t-butyl hydroperoxide and hydrogen peroxide separately, in the perfused liver of singhi catfish, resulted in significant increase of NO efflux accompanied with decrease of hydration status/cell volume of hepatic cells. However, the reasons for these cell volume-sensitive changes of NO efflux from the liver of singhi catfish are not fully understood with the available data. Nonetheless, enhanced or decreased production of NO from the perfused liver under osmotic stress, in presence of stress hormones and oxidative stress reflected its potential role in cellular homeostasis and also for better adaptations under environmental challenges. This is the first report of osmosensitive and oxidative stress-induced changes of NO production and efflux from the liver of any teleosts. Further, the level of expression of iNOS in this singhi catfish could also serve as an important indicator to determine the pathological status of the external environment.

Environmental hypertonicity causes induction of gluconeogenesis in the air-breathing singhi catfish, Heteropneustes fossilis.

The air-breathing singhi catfish (Heteropneustes fossilis) is frequently being challenged by different environmental insults such as hyper-ammonia, dehydration and osmotic stresses in their natural habitats throughout the year. The present study investigated the effect of hyperosmotic stress, due to exposure to hypertonic environment (300 mM mannitol) for 14 days, on gluconeogenesis in this catfish. In situ exposure to hypertonic environment led to significant stimulation of gluconeogenic fluxes from the perfused liver after 7 days of exposure, followed by further increase after 14 days in presence of three different potential gluconeogenic substrates (lactate, pyruvate and glutamate). Environmental hypertonicity also caused a significant increase of activities of key gluconeogenic enzymes, namely phosphoenolpyruvate carboxykinase, fructose 1, 6-bisphosphatase and glucose 6-phosphatase by about 2-6 fold in liver, and 3-6 fold in kidney tissues. This was accompanied by more abundance of enzyme proteins by about 1.8-3.7 fold and mRNAs by about 2.2-5.2 fold in both the tissues with a maximum increase after 14 days of exposure. Hence, the increase in activities of key gluconeogenic enzymes under hypertonic stress appeared to be as a result of transcriptional regulation of genes. Immunocytochemical analysis further confirmed the tissue specific localized expression of these enzymes in both the tissues with the possibility of expressing more in the same localized places. The induction of gluconeogenesis during exposure to environmental hypertonicity possibly occurs as a consequence of changes in hydration status/cell volume of different cell types. Thus, these adaptational strategies related to gluconeogenesis that are observed in this catfish under hypertonic stress probably help in maintaining glucose homeostasis and also for a proper energy supply to support metabolic demands mainly for ion transport and other altered metabolic processes under various environmental hypertonic stress-related insults.

Influence of environmental ammonia on the production of nitric oxide and expression of inducible nitric oxide synthase in the freshwater air-breathing catfish (Heteropneustes fossilis).

Nitric oxide (NO) is a highly versatile and unique ubiquitous signaling molecule, and is known to play diverse physiological functions in mammals including those of adaptation to various stresses. The present study reports on the influence of exposure to high external ammonia (HEA) on the production of nitric oxide (NO) and the expression of inducible nitric oxide synthase (iNOS), that produces NO from l-arginine in the freshwater air-breathing catfish (Heteropneustes fossilis), which is reported to tolerate a very HEA. Some levels of NO were found to be present in all the tissues and also in plasma of control fish, which further enhanced significantly in fishes treated with high concentrations of environmental ammonia (25 and 50 mM ammonium chloride) for 7 days, accompanied by more efflux of NO from the perfused liver. This was accomplished by the induction of iNOS activity in different tissues of fish exposed to HEA, which otherwise was not detectable in control fish. Exposure to 25 mM ammonium chloride also led to a significant expression of iNOS protein in different tissues, followed by further increase at 50mM ammonium chloride. Further, there was an increase in the expression of iNOS mRNA in ammonia-treated fish, thus suggesting that the expression of iNOS gene under hyper-ammonia stress was probably regulated at the transcriptional level. Immunocytochemical analysis indicated that the expression of iNOS in different tissues was zonal specific and not expressed uniformly throughout the organ. Hyper-ammonia stress also led to activation and nuclear translocation of nuclear factor κB (NFκB) in hepatic cells. These results suggest that the activation of iNOS gene under hyper-ammonia stress was probably mediated through the activation of one of the major transcription factors, the NFκB. This is the first report of ammonia-induced expression of iNOS gene, iNOS protein expression leading to more generation of NO under hyper-ammonia stress in any teleosts.