Omega-3 polyunsaturated fatty acids alleviate adenine-induced chronic renal failure via regulating ROS production and TGF-ß/SMAD pathway.

OBJECTIVE: To explore the role of omega-3 polyunsaturated fatty acids (ω-3 PUFAs) in adenine-induced rat chronic renal failure and its underlying mechanism. MATERIALS AND METHODS: 30 Sprague Dawley (SD) rats were randomly assigned into three groups, namely sham group, adenine induction group (adenine group) and adenine induction + ω-3 PUFAs treatment group (ω-3 PUFAs group), with 10 rats in each group. Serum and kidney samples were collected after rats were sacrificed. Serum levels of Cr (creatinine) and BUN (urea nitrogen) were detected using commercial kits. HE (hematoxylin and eosin) staining was performed to evaluate the pathological changes of kidneys. Levels of oxidative stress indicators in rat kidney homogenate were detected by relative commercial kits, including SOD (superoxide dismutase), GSH (reduced glutathione), CAT (catalase), and T-AOC (total antioxidant capacity). Reactive oxygen species (ROS) production was also detected by immunofluorescence. Protein expressions of nuclear factor E2 related factor 2 (Nrf2) and transforming growth factor-beta (TGF-ß)/SMAD pathway-related genes were detected by Western blot. RESULTS: Serum levels of Cr and BUN in ω-3 PUFAs group were remarkably decreased compared with those of adenine group. Higher contents of SOD, GSH, CAT and T-AOC were observed in ω-3 PUFAs group compared with those of adenine group. Besides, MAD content and ROS production were lower in ω-3 PUFAs group than those of adenine group. Pathological changes of kidneys were alleviated after ω-3 PUFAs treatment. Western blot results demonstrated that ω-3 PUFAs treatment remarkably upregulates Nrf2, HO-1, NQO1, but downregulates relative genes in TGF-ß/SMAD pathway. CONCLUSIONS: ω-3 PUFAs alleviated adenine-induced chronic renal failure through enhancing antioxidant stress and inhibiting inflammatory response via regulating Nrf2 and TGF-ß/SMAD pathway.

Synthesis, bioactivity, and cloning of the L-type calcium channel blocker omega-conotoxin TxVII.

omega-Conotoxin TxVII is the first conotoxin reported to block L-type currents. In contrast to other omega-conotoxins, its sequence is characterized by net negative charge and high hydrophobicity, although it retains the omega-conotoxin cysteine framework. In order to obtain structural information and to supply material for further characterization of its biological function, we synthesized TxVII and determined its disulfide bond pairings. Because a linear precursor with free SH groups showed a strong tendency to aggregate and to polymerize, we examined many different conditions for air oxidation and concluded that a mixture of cationic buffer and hydrophobic solvent was the most effective for the folding of TxVII. Synthetic TxVII was shown to suppress the slowly inactivating voltage-dependent calcium current in cultured Lymnaea RPeD1 neurons and furthermore to suppress synaptic transmission between these neurons and their follower cells. In contrast, TxVII did not block calcium flux through L-type channels in PC12 cells, suggesting a phyletic or subtype specificity in this channel family. Disulfide bond pairings of TxVII and its isomers were determined by enzymatic fragmentation in combination with chemical synthesis, thus revealing that TxVII has the same disulfide bond pattern as other omega-conotoxins. Furthermore, the CD spectrum of TxVII is similar to those of omega-conotoxins MVIIA and MVIIC. The precursor sequence of TxVII was determined by cDNA cloning and shown to be closest to that of delta-conotoxin TxVIA, a sodium channel inactivation inhibitor. Thus TxVII conserves the structural fold of other omega-conotoxins, and the TxVIA/TxVII branch of this family reveals the versatility of its structural scaffold, allowing evolution of structurally related peptides to target different channels.

Developmental changes in the delayed rectifier K+ channels in mouse heart.

Expression of cardiac transient outward current and inwardly rectifying K+ current is age dependent. However, little is known about age-related changes in cardiac delayed rectifier K+ current (IK, with rapidly and slowly activating components, IKr and IKs, respectively). Accordingly, the purpose of the present study was to assess developmental changes in IK channels in fetal, neonatal, and adult mouse ventricles. Three techniques were used: conventional microelectrode to measure the action potential, voltage clamp to record macroscopic currents of IK, and radioligand assay to examine [3H]dofetilide binding sites. The extent of prolongation of action potential duration at 95% repolarization (APD95) by a selective IKr blocker, dofetilide (1 mumol/L), dramatically decreased from fetal (137% +/- 18%) to day-1 (75% +/- 29%) and day-3 (20% +/- 15%) neonatal mouse ventricular tissues (P < .01). Dofetilide did not prolong APD95 in adult myocardium. IKr is the sole component of IK in day-18 fetal mouse ventricular myocytes. However, both IKr and IKs were observed in day-1 neonatal ventricular myocytes. With further development, IKs became the dominant component of IK in day-3 neonates. In adult mouse ventricular myocytes, neither IKr nor IKs was observed. Correspondingly, a high-affinity binding site for [3H]dofetilide was present in fetal mouse ventricles but was absent in adult ventricles. The complementary data from microelectrode, voltage-clamp, and [3H]dofetilide binding studies demonstrate that expression of the IK channel is developmentally regulated in the mouse heart.