Ononin: A candidate anti-parasitic drug isolated from Spatholobi caulis against infections of Dactylogyrus intermedius (Monogenea).

Dactylogyrus is a common parasitic pathogen, which causes high mortality of fish when presents in large numbers, resulting in serious economic losses. Herbal medicines contain myriad of bioactive compounds is a valuable reserve for developing safe and effective anti-parasite drugs. Here, we conducted bioassay-guided fractionation to isolate and identify the anti-parasitic constituents from Spatholobi caulis. Among five extraction solvents (petroleum ether, chloroform, ethyl acetate, methanol and water), S. caulis methanolic extract had the highest parasiticide activity in Carassius auratus, and therefore subjected to further separation and purification using multiple chromatography methods. One compound exhibiting the strongest parasiticidal activity was obtained and identified as ononin by analyzing its spectral data (NMR and ESI-MS). The EC50 value of ononin against Dactylogyrus was 0.655 mg/L and showed 100% parasiticide activity with 3.0 mg/L. The 24, 48, 72, 96 h LC50 for goldfish were 4.691 (the 95% CI of 4.526-4.873) mg/L, 4.612 (4.441-4.800) mg/L, 4.472 (4.345-4.607) mg/L, 4.288 (4.155-4.428) mg/L, respectively. The present results discovered for the first time that ononin had potent parasiticidal activity and have the potential to be developed as new anti-parasitic drug for the control of Dactylogyrus.

Melanocortin Receptor 4 (MC4R) Signaling System in Nile Tilapia.

The melanocortin receptor 4 (MC4R) signaling system consists of MC4R, MC4R ligands [melanocyte-stimulating hormone (MSH), adrenocorticotropin (ACTH), agouti-related protein (AgRP)], and melanocortin-2 receptor accessory protein 2 (MRAP2), and it has been proposed to play important roles in feeding and growth in vertebrates. However, the expression and functionality of this system have not been fully characterized in teleosts. Here, we cloned tilapia MC4R, MRAP2b, AgRPs (AgRP, AgRP2), and POMCs (POMCa1, POMCb) genes and characterized the interaction of tilapia MC4R with MRAP2b, AgRP, α-MSH, and ACTH in vitro. The results indicate the following. (1) Tilapia MC4R, MRAP2b, AgRPs, and POMCs share high amino acid identity with their mammalian counterparts. (2) Tilapia MRAP2b could interact with MC4R expressed in CHO cells, as demonstrated by Co-IP assay, and thus decrease MC4R constitutive activity and enhance its sensitivity to ACTH1-40. (3) As in mammals, AgRP can function as an inverse agonist and antagonist of MC4R, either in the presence or absence of MRAP2b. These data, together with the co-expression of MC4R, MRAP2b, AgRPs, and POMCs in tilapia hypothalamus, suggest that as in mammals, ACTH/α-MSH, AgRP, and MRAP2 can interact with MC4R to control energy balance and thus play conserved roles in the feeding and growth of teleosts.

Adropin induction of lipoprotein lipase expression in tilapia hepatocytes.

The peptide hormone adropin plays a role in energy homeostasis. However, biological actions of adropin in non-mammalian species are still lacking. Using tilapia as a model, we examined the role of adropin in lipoprotein lipase (LPL) regulation in hepatocytes. To this end, the structural identity of tilapia adropin was established by 5'/3'-rapid amplification of cDNA ends (RACE). The transcripts of tilapia adropin were ubiquitously expressed in various tissues with the highest levels in the liver and hypothalamus. The prolonged fasting could elevate tilapia hepatic adropin gene expression, whereas no effect of fasting was observed on hypothalamic adropin gene levels. In primary cultures of tilapia hepatocytes, synthetic adropin was effective in stimulating LPL release, cellular LPL content, and total LPL production. The increase in LPL production also occurred with parallel rises in LPL gene levels. In parallel experiments, adropin could elevate cAMP production and up-regulate protein kinase A (PKA) and PKC activities. Using a pharmacological approach, cAMP/PKA and PLC/inositol trisphosphate (IP3)/PKC cascades were shown to be involved in adropin-stimulated LPL gene expression. Parallel inhibition of p38MAPK and Erk1/2, however, were not effective in these regards. Our findings provide, for the first time, evidence that adropin could stimulate LPL gene expression via direct actions in tilapia hepatocytes through the activation of multiple signaling mechanisms.