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13. Mitochondrial Fatty Acid β-Oxidation Inhibition Promotes Glucose Utilization and Protein Deposition through Energy Homeostasis Remodeling in Fish.

Author

Li, Ling-Yu, Li, Jia-Min, Ning, Li-Jun, Lu, Dong-Liang, Luo, Yuan, Ma, Qiang, Limbu, Samwel Mchele, Li, Dong-Liang, Chen, Li-Qiao, Lodhi, Irfan J, Degrace, Pascal, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
FATTY acids, MUSCLE proteins, MITOCHONDRIAL proteins, HOMEOSTASIS, FISHES, RAPAMYCIN, CARBOHYDRATE content of food, PROTEIN metabolism, GLUCOSE metabolism, ANIMAL experimentation, IMMUNOMODULATORS, CELL culture, COMPARATIVE studies, DNA, ENERGY metabolism, EPITHELIAL cells, HEMOPROTEINS, INSULIN, RESEARCH methodology, MEDICAL cooperation, MITOCHONDRIA, GENETIC mutation, ORGANIC compounds, OXIDATION-reduction reaction, RESEARCH, TRANSFERASES, EVALUATION research, PHARMACODYNAMICS, CELL physiology
Abstract

Background: Fish cannot use carbohydrate efficiently and instead utilize protein for energy supply, thus limiting dietary protein storage. Protein deposition is dependent on protein turnover balance, which correlates tightly with cellular energy homeostasis. Mitochondrial fatty acid β-oxidation (FAO) plays a crucial role in energy metabolism. However, the effect of remodeled energy homeostasis caused by inhibited mitochondrial FAO on protein deposition in fish has not been intensively studied.Objectives: This study aimed to identify the regulatory role of mitochondrial FAO in energy homeostasis maintenance and protein deposition by studying lipid, glucose, and protein metabolism in fish.Methods: Carnitine-depleted male Nile tilapia (initial weight: 4.29 ± 0.12 g; 3 mo old) were established by feeding them with mildronate diets (1000 mg/kg/d) for 6 wk. Zebrafish deficient in the carnitine palmitoyltransferase 1b gene (cpt1b) were produced by using CRISPR/Cas9 gene-editing technology, and their males (154 ± 3.52 mg; 3 mo old) were used for experiments. Normal Nile tilapia and wildtype zebrafish were used as controls. We assessed nutrient metabolism and energy homeostasis-related biochemical and molecular parameters, and performed 14C-labeled nutrient tracking and transcriptomic analyses.Results: The mitochondrial FAO decreased by 33.1-88.9% (liver) and 55.6-68.8% (muscle) in carnitine-depleted Nile tilapia and cpt1b-deficient zebrafish compared with their controls (P < 0.05). Notably, glucose oxidation and muscle protein deposition increased by 20.5-24.4% and 6.40-8.54%, respectively, in the 2 fish models compared with their corresponding controls (P < 0.05). Accordingly, the adenosine 5'-monophosphate-activated protein kinase/protein kinase B-mechanistic target of rapamycin (AMPK/AKT-mTOR) signaling was significantly activated in the 2 fish models with inhibited mitochondrial FAO (P < 0.05).Conclusions: These data show that inhibited mitochondrial FAO in fish induces energy homeostasis remodeling and enhances glucose utilization and protein deposition. Therefore, fish with inhibited mitochondrial FAO could have high potential to utilize carbohydrate. Our results demonstrate a potentially new approach for increasing protein deposition through energy homeostasis regulation in cultured animals. [ABSTRACT FROM AUTHOR]

Published
2020
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14. Tracking pollutants in dietary fish oil: From ocean to table.

Author

Sun, Sheng-Xiang, Hua, Xue-Ming, Deng, Yun-Yun, Zhang, Yun-Ni, Li, Jia-Min, Wu, Zhao, Limbu, Samwel Mchele, Lu, Da-Sheng, Yin, Hao-Wen, Wang, Guo-Quan, Waagbø, Rune, Frøyland, Livar, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
POLLUTANTS, POLYCHLORINATED biphenyls, FISH oils, FISH fillets, BIOACCUMULATION in fishes
Abstract

Dietary fish oil used in aquafeed transfers marine pollutants to farmed fish. However, the entire transfer route of marine pollutants in dietary fish oil from ocean to table fish has not been tracked quantitatively. To track the entire transfer route of marine pollutants from wild fish to farmed fish through dietary fish oil and evaluate the related human health risks, we obtained crude and refined fish oils originating from the same batch of wild ocean anchovy and prepared fish oil-containing purified aquafeeds to feed omnivorous lean Nile tilapia and carnivorous fatty yellow catfish for eight weeks. The potential human health risk of consumption of these fish was evaluated. Marine persistent organic pollutants (POPs) were concentrated in fish oil, but were largely removed by the refining process, particularly dioxins and polychlorinated biphenyls (PCBs). The differences in the POP concentrations between crude and refined fish oils were retained in the fillets of the farmed fish. Fillets fat content and fish growth were positively and negatively correlated to the final POPs deposition in fillets, respectively. The retention rates of marine POPs in the final fillets through fish oil-contained aquafeeds were 1.3%–5.2%, and were correlated with the POPs concentrations in feeds and fillets, feed utilization and carcass ratios. The dietary crude fish oil-contained aquafeeds are a higher hazard ratio to consumers. Prohibiting the use of crude fish oil in aquafeed and improving growth and feed efficiency in farmed fish are promising strategies to reduce health risks originating from marine POPs. [ABSTRACT FROM AUTHOR]

Published
2018
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15. Environmental concentrations of antibiotics impair zebrafish gut health.

Author

Zhou, Li, Limbu, Samwel Mchele, Shen, Meilin, Zhai, Wanying, Qiao, Fang, He, Anyuan, Du, Zhen-Yu, and Zhang, Meiling

Subjects
ANTIBIOTICS, ENVIRONMENTAL impact analysis, OXYTETRACYCLINE, HEALTH risk assessment, PHOSPHATASES
Abstract

Antibiotics have been widely used in human and veterinary medicine to both treat and prevent disease. Due to their high water solubility and low bioavailability, many antibiotic residues have been found in aquatic environments. Fish are an indispensable link between the environmental pollution and human health. However, the chronic effects of environmental concentrations of antibiotics in fish have not been thoroughly investigated. Sulfamethoxazole (SMX) and oxytetracycline (OTC) are frequently detected in aquatic environments. In this study, zebrafish were exposed to SMX (260 ng/L) and OTC (420 ng/L) for a six-week period. Results indicated that exposure to antibiotics did not influence weight gain of fish but increased the metabolic rate and caused higher mortality when treated fish were challenged with Aeromonas hydrophila . Furthermore, exposure to antibiotics in water resulted in a significant decrease in intestinal goblet cell numbers, alkaline phosphatase (AKP), acid phosphatase (ACP) activities, and the anti-oxidant response while there was a significant increase in expression of inflammatory factors. Antibiotic exposure also disturbed the intestinal microbiota in the OTC-exposed group. Our results indicated that environmental antibiotic concentrations can impair the gut health of zebrafish. The potential health risk of antibiotic residues in water should be evaluated in the future. [ABSTRACT FROM AUTHOR]

Published
2018
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16. Dietary docosahexaenoic acid reduces fat deposition and alleviates liver damage induced by D-galactosamine and lipopolysaccharides in Nile tilapia (Oreochromis niloticus).

Author

Liu, Yi-Chan, Limbu, Samwel Mchele, Wang, Jin-Gang, Wang, Mai, Chen, Li-Qiao, Qiao, Fang, Luo, Yuan, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
*NILE tilapia, *DOCOSAHEXAENOIC acid, *LIPOPOLYSACCHARIDES, *LIVER, *SUSTAINABLE aquaculture, *FISH oils, *ASPARTATE aminotransferase
Abstract

Liver health is important to maintain survival and growth of fish. Currently, the role of dietary docosahexaenoic acid (DHA) in improving fish liver health is largely unknown. This study investigated the role of DHA supplementation in fat deposition and liver damage caused by D-galactosamine (D-GalN) and lipopolysaccharides (LPS) in Nile tilapia (Oreochromis niloticus). Four diets were formulated as control diet (Con), Con supplemented with 1 % DHA, 2 % DHA and 4 % DHA diets, respectively. The diets were fed to 25 Nile tilapia (2.0 ± 0.1 g, average initial weight) in triplicates for four weeks. After the four weeks, 20 fish in each treatment were randomly selected and injected with a mixture of 500 mg D-GalN and 10 μL LPS per mL to induce acute liver injury. The results showed that the Nile tilapia fed on DHA diets decreased visceral somatic index, liver lipid content and serum and liver triglyceride concentrations than those fed on the Con diet. Moreover, after D-GalN/LPS injection, the fish fed on DHA diets decreased alanine aminotransferase and aspartate transaminase activities in the serum. The results of liver qPCR and transcriptomics assays together showed that the DHA diets feeding improved liver health by downregulating the expression of the genes related to toll-like receptor 4 (TLR4) signaling pathway, inflammation and apoptosis. This study indicates that DHA supplementation in Nile tilapia alleviates the liver damage caused by D-GalN/LPS through increasing lipid catabolism, decreasing lipogenesis, TLR4 signaling pathway, inflammation, and apoptosis. Our study provides novel knowledge on the role of DHA in improving liver health in cultured aquatic animals for sustainable aquaculture. [Display omitted] • Dietary DHA alleviates liver fat deposition in Nile tilapia. • Dietary DHA alleviates liver damage induced by D-GalN/LPS in Nile tilapia. • DHA regulates TLR4 signaling pathway, inflammation and apoptosis in Nile tilapia. [ABSTRACT FROM AUTHOR]

Published
2023
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17. High carbohydrate diet partially protects Nile tilapia (Oreochromis niloticus) from oxytetracycline-induced side effects.

Author

Limbu, Samwel Mchele, Zhang, Han, Luo, Yuan, Chen, Li-Qiao, Zhang, Meiling, and Du, Zhen-Yu

Subjects
HIGH-carbohydrate diet, NILE tilapia, DRUG side effects, SIDE effects of antibiotics, CARBOHYDRATE content of food, LIPID metabolism
Abstract

Antibiotics used in global aquaculture production cause various side effects, which impair fish health. However, the use of dietary composition such as carbohydrate, which is one of the dominant components in fish diets to attenuate the side effects induced by antibiotics, remains unclear. We determined the ability of high carbohydrate diet to protect Nile tilapia (Oreochromis niloticus) from oxytetracycline-induced side effects. Triplicate groups of thirty O. niloticus (9.50 ± 0.08 g) were fed on medium carbohydrate (MC; 335 g/kg) and high carbohydrate (HC; 455 g/kg) diets without and with 2.00 g/kg diet of oxytetracycline (80 mg/kg body weight/day) hereafter, MCO and HCO for 35 days. Thereafter, we assessed growth performance, hepatic nutrients composition and metabolism, microbiota abundance, immunity, oxidative and cellular stress, hepatotoxicity, lipid peroxidation and apoptosis. To understand the possible mechanism of carbohydrate protection on oxytetracycline, we assessed the binding effects and efficiencies of mixtures of medium and high starch with oxytetracycline as well as the MCO and HCO diets. The O. niloticus fed on the MCO and HCO diets had lower growth rate, nutrients utilization and survival rate than those fed on the MC and HC diets, respectively. Dietary HCO increased hepatosomatic index and hepatic protein content of O. niloticus than MCO diet. The O. niloticus fed on the HCO diet had lower mRNA expression of genes related to protein, glycogen and lipid metabolism compared to those fed on the MCO diet. Feeding O. niloticus on the HCO diet increased innate immunity and reduced pathogenic bacteria, pro-inflammation, hepatotoxicity, cellular stress and apoptosis than the MCO diet. The high starch with oxytetracycline and HCO diet had higher-oxytetracycline binding effects and efficiencies than the medium starch with oxytetracyline and MCO diet, respectively. Our study demonstrates that, high carbohydrate partially protects O. niloticus from oxytetracycline-induced side effects by binding the antibiotic. Incorporating high carbohydrate in diet formulation for omnivorous fish species alleviates some of the side effects caused by antibiotics. Image 1 • Dietary carbohydrate does not affect OTC on Nile tilapia growth and antioxidants. • High carbohydrate diet protects Nile tilapia from OTC by lessening hepatotoxicity. • High carbohydrate diet protects Nile tilapia from OTC-elevated nutrients metabolism. • High carbohydrate diet protects Nile tilapia from OTC-reduced immunity. • High carbohydrate diet protects Nile tilapia from OTC cellular stress and apoptosis. High carbohydrate diet partially protects fish from oxytetracycline-impaired liver function, increased energy expenditure, reduced immunity and increased stresses. [ABSTRACT FROM AUTHOR]

Published
2020
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18. Inhibiting mitochondrial citrate shuttling induces hepatic triglyceride deposition in Nile tilapia (Oreochromis niloticus) through lipid anabolic remodeling.

Author

Wang, Jun-Xian, Luo, Yuan, Limbu, Samwel Mchele, Qian, Yu-Cheng, Zhang, Yan-Yu, Li, Rui-Xin, Zhou, Wen-Hao, Qiao, Fang, Chen, Li-Qiao, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
*NILE tilapia, *LIPID metabolism, *FATTY acids, *PROTEIN stability, *PROTEIN metabolism, *ACETYLCOENZYME A, *HOMEOSTASIS
Abstract

• Slc25a1 inhibition shapes an obesity-like phenotype accompanied by fat deposition. • Acetate-derived acetyl-CoA replenishes the decrease in citrate-derived acetyl-CoA. • Slc25a1 inhibition enhances Acss2-dependent hepatic fatty acids esterification. • Slc25a1 inhibition enhances Acss2-dependent acetylation and stability of Lipin1. The solute carrier family 25 member 1 (Slc25a1)-dependent mitochondrial citrate shuttle is responsible for exporting citrate from the mitochondria to the cytoplasm for supporting lipid biosynthesis and protein acetylation. Previous studies on Slc25a1 concentrated on pathological models. However, the importance of Slc25a1 in maintaining metabolic homeostasis under normal nutritional conditions remains poorly understood. Here, we investigated the mechanism of mitochondrial citrate shuttle in maintaining lipid metabolism homeostasis in male Nile tilapia (Oreochromis niloticus). To achieve the objective, we blocked the mitochondrial citrate shuttle by inhibiting Slc25a1 under normal nutritional conditions. Slc25a1 inhibition was established by feeding Nile tilapia with 250 mg/kg 1,2,3-benzenetricarboxylic acid hydrate for 6 weeks or intraperitoneal injecting them with dsRNA to knockdown slc25a1b for 7 days. The Nile tilapia with Slc25a1 inhibition exhibited an obesity-like phenotype accompanied by fat deposition, liver damage and hyperglycemia. Moreover, Slc25a1 inhibition decreased hepatic citrate-derived acetyl-CoA, but increased hepatic triglyceride levels. Furthermore, Slc25a1 inhibition replenished cytoplasmic acetyl-CoA through enhanced acetate pathway, which led to hepatic triglycerides accumulation. However, acetate-derived acetyl-CoA caused by hepatic Slc25a1 inhibition did not activate de novo lipogenesis, but rather modified protein acetylation. In addition, hepatic Slc25a1 inhibition enhanced fatty acids esterification through acetate-derived acetyl-CoA, which increased Lipin1 acetylation and its protein stability. Collectively, our results illustrate that inhibiting mitochondrial citrate shuttle triggers lipid anabolic remodeling and results in lipid accumulation, indicating the importance of mitochondrial citrate shuttle in maintaining lipid metabolism homeostasis. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Cyhexatin causes developmental toxic effects by disrupting endocrine system and inducing behavioral inhibition, apoptosis and DNA hypomethylation in zebrafish (Danio rerio) larvae.

Author

Jiao, Fang, Zhao, Yang, Limbu, Samwel Mchele, Kong, Lingfu, Zhang, Daitao, Liu, Xianghe, Yang, Sha, Gui, Wenjun, and Rong, Hua

Subjects
*POISONS, *RESPONSE inhibition, *ZEBRA danio, *ENDOCRINE system, *HEART beat, *ENDOCRINE glands, *LARVAE, *THYROID hormone receptors, *ESTRADIOL
Abstract

Cyhexatin (CYT), an organotin acaricide, is extensively utilized in developing countries to mitigate plant diseases caused by mites and minimize agricultural crop losses. However, the comprehensive mechanisms underlying the developmental stage of non-target organisms remain largely unexplored. In this study, zebrafish embryos were firstly exposed to CYT (0.06, 0.12, and 0.20 ng/mL, referred to as CYTL, CYTM, and CYTH, respectively) from 2 hpf (hours post fertilization) to 30 dpf (days post fertilization). No developmental toxicity was observed in the CYTL and CYTM groups, except for induced deformed phenotypes in the CYTM group at 120 hpf. However, exposure to CYTH resulted in significant reductions in spontaneous movement (24 hpf), heart rate (48 hpf), hatching rate (48 and 72 hpf), body weight (30 dpf), whole body length (30 dpf), and locomotion (30 dpf). Additionally, CYTH exposure induced morphological malformations, including spinal curvature, pericardial edema, and tail curvature in zebrafish larvae. Moreover, CYTH treatment induced apoptosis, increased reactive oxygen species (ROS) production, and resulted in significant reductions in free T3, cholesterol, estradiol, and testosterone levels in zebrafish larvae, while free T4 levels were increased. RNA-Seq analysis indicated that CYTH exposure led to significant alterations in the genome-wide gene expression profiles of zebrafish, particularly in the thyroid hormone and steroid biosynthesis signaling pathways, indicating endocrine disruption. Furthermore, CYTH exposure induced global DNA hypomethylation, reduced S-adenosylmethionine (SAM) levels and the SAM/S-adenosylhomocysteine (SAH) ratio, elevated SAH levels, and suppressed the mRNA expression of DNA methyltransferases (DNMTs) while also downregulating DNMT1 at both the gene and protein levels in zebrafish larvae. Overall, this study partially elucidated the developmental toxicity and endocrine disruption caused by CYT in zebrafish, providing evidence of the environmental hazards associated with this acaricide. [Display omitted] • Cyhexatin caused developmental and endocrine toxicities on zebrafish larvae. • Cyhexatin impaired locomotion of zebrafish larvae. • Cyhexatin induced global DNA hypomethylation in zebrafish larvae. • Cyhexatin disrupted thyroid hormone and steroid biosynthesis signaling pathways. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Lipolysis and lipophagy play individual and interactive roles in regulating triacylglycerol and cholesterol homeostasis and mitochondrial form in zebrafish.

Author

Han, Si-Lan, Qian, Yu-Cheng, Limbu, Samwel Mchele, Wang, Jing, Chen, Li-Qiao, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
*LIPOLYSIS, *HOMEOSTASIS, *CHOLESTEROL metabolism, *BRACHYDANIO, *CHOLESTEROL, *OXYGEN consumption, *LIPID metabolism
Abstract

Neutral lipases-mediated lipolysis and acid lipases-moderated lipophagy are two main processes for degradation of lipid droplets (LDs). However, the individual and interactive roles of these metabolic pathways are not well known across vertebrates. This study explored the roles of lipolysis and lipophagy from the aspect of neutral and acid lipases in zebrafish. We established zebrafish strains deficient in either adipose triglyceride lipase (atgl −/−; AKO fish) or lysosomal acid lipase (lal −/−; LKO fish) respectively, and then inhibited lipolysis in the LKO fish and lipophagy in the AKO fish by feeding diets supplemented with the corresponding inhibitors Atglistatin and 3-Methyladenine, respectively. Both the AKO and LKO fish showed reduced growth, swimming activity, and oxygen consumption. The AKO fish did not show phenotypes in adipose tissue, but mainly accumulated triacylglycerol (TAG) in liver, also, they had large LDs in the hepatocytes, and did not stimulate lipophagy as a compensation response but maintained basal lipophagy. The LKO fish reduced total lipid accumulation in the body but had high cholesterol content in liver; also, they accumulated small LDs in the hepatocytes, and showed increased lipolysis, especially Atgl expression, as a compensatory mechanism. Simultaneous inhibition of lipolysis and lipophagy in zebrafish resulted in severe liver damage, with the potential to trigger mitophagy. Overall, our study illustrates that lipolysis and lipophagy perform individual and interactive roles in maintaining homeostasis of TAG and cholesterol metabolism. Furthermore, the interactive roles of lipolysis and lipophagy may be essential in regulating the functions and form of mitochondria. • Atgl or Lal mutation causes different lipid metabolism patterns. • Lipolysis and lipophagy have different preferences for substrate selection. • Lipolysis and lipophagy are not necessarily substitutional in fish liver. • Mitochondrial form is changed when lipolysis and lipophagy are both suppressed. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Reduced fatty acid β-oxidation improves glucose catabolism and liver health in Nile tilapia (Oreochromis niloticus) juveniles fed a high-starch diet.

Author

Li, Ling-Yu, Wang, Yue, Limbu, Samwel Mchele, Li, Jia-Min, Qiao, Fang, Chen, Li-Qiao, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
*NILE tilapia, *ASPARTATE aminotransferase, *HIGH-carbohydrate diet, *PYRUVATES, *CORNSTARCH, *FATTY acids, *CATABOLISM, *GLUCOSE
Abstract

Fish are poor users of dietary carbohydrates and often display prolonged hyperglycemia and fat deposition after feeding high digestible carbohydrate diets. Recently, fatty acid β-oxidation (FAO) inhibition has been reported to increase glucose oxidation in fish. Therefore, this study tested the assumption that the inhibition of FAO with mildronate (MD, a carnitine synthesis inhibitor) might also increase glucose utilization and alleviate adverse effects induced by high starch diet (HSD) in Nile tilapia, Oreochromis niloticus. Nile tilapia juveniles (6.13 ± 0.11 g) were cultured in nine 200-L tanks (30 fish per tank) and divided into three groups (three tanks per group). The fish were fed twice a day (9:00 and 18:30) at 4% body weight by using a normal starch diet (NSD, 30% corn starch), a HSD (45% corn starch), or a HSD supplemented with MD (25 g/kg of diet, HSD + MD) for eight weeks. These three feeds contained approximately 35.8% protein and 6.4% lipid. The fish each tank were weighed every two weeks, and the feeding amount was adjusted accordingly. After the feeding trial, the fish fed on HSD showed higher hepatosomatic index (HSI), visceral somatic index (VSI), serum triglyceride concentration and whole-body and tissue (liver and muscle) lipid contents than those fed on NSD. The fish fed on HSD also had higher relative area of vacuolation in the liver, hepatic malondialdehyde (MDA) content, and aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activities in the serum than those fed on NSD. Moreover, the fish fed on HSD increased serum glucose and insulin concentrations, and hepatic lactate, pyruvate and glycogen contents, but reduced whole-body protein content and dietary protein utilization than those fed on NSD, indicating that HSD induced fat deposition, liver damage, glucose intolerance and lowered protein-sparing effect. However, the fish fed on HSD + MD decreased hepatic carnitine content and FAO activity, attenuated the indexes related to fat deposition and liver damage, improved blood glucose clearance and whole-body protein deposition than those fed on HSD, suggesting that the adverse effects caused by HSD were reversed after FAO inhibition. Furthermore, the fish fed on HSD down-regulated the expression of genes associated with glucose uptake, glycolysis, FAO process, and lipolysis compared to those fed on HSD + MD and NSD, yet up-regulated lipogenic and proteolytic genes. These data suggested that inhibition of FAO improved glucose utilization and alleviated the HSD-induced adverse effects in Nile tilapia. This work demonstrates that, modifying mitochondrial FAO activity regulates the ability of fish to adapt to HSD intake through remodeling energy homeostasis. Our study provides new insights into improving carbohydrate utilization in aquatic animals. • Mildronate reduced fatty acid β-oxidation (FAO) in high-starch diet (HSD)-fed tilapia. • Reduced FAO accelerated glucose oxidation in HSD-fed tilapia. • Reduced FAO alleviated lipid deposition in HSD-fed tilapia. • Reduced FAO increased protein deposition in HSD-fed tilapia. • Reduced FAO increased adaptation to HSD in tilapia. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Molecular cloning and functional characterization of elongase (elovl5) and fatty acyl desaturase (fads2) in sciaenid, Nibea diacanthus (Lacepède, 1802).

Author

Zou, Weiguang, Lin, Zhideng, Huang, Yisheng, Limbu, Samwel Mchele, and Wen, Xiaobo

Subjects
*PROTONIBEA diacanthus, *MOLECULAR cloning, *FISH enzymes, *DESATURASES, *ANTISENSE DNA, *NUCLEOTIDE sequence
Abstract

Abstract In the present paper, we investigated the molecular cloning and functional characterization of elongase of very long chain fatty acid (elovl) and fatty acyl desaturase (fads) genes in a marine teleost, Nibea diacanthus. The elongase cDNA sequence encoded a polypeptide of 294 amino acids exhibiting Elovl5 activity, which effectively elongated both C18 (18:2n−6, 18:3n−3 and 18:3n−6) and C20 (20:4n−6 and 20:5n−3) polyunsaturated fatty acids. The desaturase cDNA sequence specified a polypeptide of 445 amino acids indicating Δ6 desaturation activity, which coul converted C18:2n−6 and C18:3n−3 to C18:3n−6 and C18:4n−3, respectively. Tissue distribution analysis by quantitative real-time PCR revealed that the elovl5 was primarily expressed in intestine and liver, while the fads2 was mainly expressed in liver and brain. These results increase our knowledge of the ability of endogenous highly unsaturated fatty acids (HUFA) biosynthesis in marine carnivorous fish. Highlights • The elovl5 and Δ6 fad genes of Nibea diacanthus were reported for the first time. • N. diacanthus had the transformation ability of C20 and C18. • Liver may play an important role in fatty acid metabolism and HUFA biosynthesis in N. diacanthus. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Forskolin reduces fat accumulation in Nile tilapia (Oreochromis niloticus) through stimulating lipolysis and beta-oxidation.

Author

Zhang, Han, Wen, Jia-Jing, Zhang, Yun-Ni, Limbu, Samwel Mchele, Du, Zhen-Yu, Qin, Jian G., and Chen, Li-Qiao

Subjects
*FORSKOLIN, *NILE tilapia, *LIPOLYSIS, *LIVER cells, *HOMEOSTASIS
Abstract

Abstract High fat diets are commonly used in aquaculture to reduce feed cost in Nile tilapia, but impair its lipid homeostasis. This study evaluated the role of forskolin on reducing fat accumulation in Nile tilapia (Oreochromis niloticus) by using in vitro and in vivo experiments. The use of 50 μM forskolin in vitro increased free fatty acid and glycerol release, but decreased triglyceride in adipocytes and hepatocytes. The adipose triglyceride lipase (ATGL), protein kinase cAMP-dependent type I regulatory subunit alpha (PKAR I) and other genes related to β-oxidation (peroxisome proliferator activated receptor alpha, PPARα and carnitine O-palmitoyltransferase 1, CPT1) were significantly up-regulated. After feeding a high-fat diet for six weeks, O. niloticus were fed with 0 (control), 0.5 and 1.5 mg/kg forskolin for two weeks to determine whether forskolin could reduce fat accumulation in vivo. Fish fed the two levels of forskolin decreased significantly the hepatosomatic and mesenteric fat indices. The total lipid in the whole fish and liver together with the serum glycerol content were lower in fish fed on forskolin than in the control. The fish fed on forskolin diets exhibited smaller areas of lipid droplets in adipose and liver tissues. Lipolysis related genes (ATGL, hormone-sensitive lipase, HSL; monoacylglycerol lipase, MGL; and protein kinase cAMP-activated catalytic subunit, PKAC) and β-oxidation genes (PPARα; fatty acid binding protein 1, FABP1; and CPT1) in the adipose were up-regulated. Similarly, in the liver lipolysis genes such as ATGL and PKAR I and β-oxidation genes (PPARα, FABP1, CPT1 and acyl-CoA oxidase, ACO) showed an increasing trend with the increase of forskolin doses. This study indicates that forskolin can reduce fat accumulation in the adipose and liver by stimulating lipolysis and β-oxidation in O. niloticus. Highlights • Forskolin supplementation in the diet reduced fat accumulation in Nile tilapia. • Lipolysis and β-oxidation in adipocytes and hepatocytes were stimulated by 50 μM forskolin in vitro. • The oral doses of 0.5 and 1.5 mg/kg forskolin reduced fat in the liver and whole fish. • Forskolin up-regulated the expression of genes relevant to lipolysis and β-oxidation. [ABSTRACT FROM AUTHOR]

Published
2019
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24. Sources and preservation dynamics of organic matter in surface sediments of Narmada River, India – Illustrated by amino acids.

Author

Fernandes, Dearlyn, Wu, Ying, Shirodkar, Prabhaker Vasant, Pradhan, Umesh Kumar, Zhang, Jing, and Limbu, Samwel Mchele

Subjects
*AMINO acids, *ESTUARINE sediments, *ORGANIC compounds, *FLUVISOLS, *WATER, *RIVER sediments, *WATER depth, *GEOCHEMICAL modeling
Abstract

The preservation process of organic matter (OM) in estuarine environments determines the recycling and sinking of nutrients. This process requires the identification of sources, degradation states and the main processes affecting OM transformations. Unfortunately, our understandingof the sources, degradation and factors affecting OM distribution in tropical rivers experiencing strong seasonality and monsoonal influence is still limited. This study examined the sources, degradation and factors affecting OM distribution along the Narmada River and its estuary during different seasons. Surface waters and sediments were analyzed seasonally for selected physico-chemical parameters and bulk compositions of sediments, together with amino acids (AA, including the bacterial biomarker, D-AA). The sources of OM were soils containing detrital terrestrial plant material, with C 4 and C 3 plants dominating the estuarine and riverine stations, respectively. The other sources of OM were in-situ production, together with bacteria and their remnants. Strong seasonality and monsoonal conditions control the sources and distribution of OM in the river. Higher concentrations of total hydrolysable amino acids (THAA) were observed in riverine stations, suggesting the presence of relatively fresher OM. The lower OC:SA ratios recorded in the estuarine sediments indicated a limited OM preservation in the studied river. Positive degradation index (DI) values were obtained during the pre-monsoon season, suggesting seasonal changes in OM diagenesis. Physical (strong tidal currents, rainfall, reduced water flow due to seasonal variations and shallow water depth within the estuary) and geochemical (mineral surface adsorption processes) factors control the distribution and transport of OM. Taken together, the sources, preservation and diagenesis of terrestrial OM along the Narmada River was controlled differentially by the strong seasonal variability of the region. Thus, under variable temporal conditions, tropical estuaries and rivers form important realms for examining, determining, evaluating and assessing OM in order to better interpret nutrient budgets of the seas and oceans. Heat map of the extracted principal components (labels on the y-axis represent the principal components and the labels on the x-axis represents the different parameters; the values on color bar 1 - red, 0 - black, and −1 - green indicate the loadings). Unlabelled Image • The C 3 and C 4 plants and in-situ production contribute to OM in the river. • Microbes, tides and hydrodynamics influence the preservation of OM in the river. • Physical and geochemical factors control the transport and distribution of OM. • The degradation index experiences seasonal shifts during different seasons. [ABSTRACT FROM AUTHOR]

Published
2020
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25. Concentration-dependent effects of 17β-estradiol and bisphenol A on lipid deposition, inflammation and antioxidant response in male zebrafish (Danio rerio).

Author

Sun, Sheng-Xiang, Zhang, Yun-Ni, Lu, Dong-Liang, Wang, Wei-Li, Limbu, Samwel Mchele, Chen, Li-Qiao, Zhang, Mei-Ling, and Du, Zhen-Yu

Subjects
*ESTRADIOL, *BISPHENOL A, *ZEBRA danio, *BRACHYDANIO, *LIPIDS, *FREE fatty acids, *XENOESTROGENS
Abstract

Environmental estrogenic compounds are important pollutants, which are widely distributed in natural water bodies. They produce various adverse effects on fish, but their concentration-dependent toxicities in fish metabolism and health are not fully understood. This study investigated the effects of 17β-estradiol (E2) and bisphenol A (BPA) at low and high concentrations on lipid deposition, inflammation and antioxidant response in male zebrafish. We measured fish growth parameters, gonad development, lipid contents and the activities of inflammatory and antioxidant enzymes, as well as their mRNA expressions. All E2 and BPA concentrations used increased body weight, damaged gonad structure and induced feminization in male zebrafish. The exposure of zebrafish to E2 and BPA promoted lipid accumulation by increasing total fat, liver triglycerides and free fatty acid contents, and also upregulated lipogenic genes expression, although they decreased total cholesterol content. Notably, zebrafish exposed to low concentrations of E2 (200 ng/L) and BPA (100 μg/L) had higher lipid synthesis and deposition compared to high concentrations (2000 ng/L and 2000 μg/L, respectively). However, the high concentrations of E2 and BPA increased inflammation and antioxidant response. Furthermore, BPA caused greater damage to fish gonad development and more severe lipid peroxidation compared to E2. Overall, the results suggest that the toxic effects of E2 and BPA on zebrafish are concentration-dependent such that, the relative low concentrations used induced lipid deposition, whereas the high ones caused adverse effects on inflammation and antioxidant response. • E2 and BPA damaged gonad structure and induced feminization in male fish. • E2 and BPA promoted lipid deposition mainly in relatively low concentrations. • Inflammation was enhanced by high concentrations of E2 and BPA. • BPA caused more severe lipid peroxidation and gonad damage to zebrafish than E2. • The toxicity of environmental estrogens to zebrafish was affected by concentrations. [ABSTRACT FROM AUTHOR]

Published
2019
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