Two salt bridges differentially contribute to the maintenance of cystic fibrosis transmembrane conductance regulator (CFTR) channel function.

Previous studies have identified two salt bridges in human CFTR chloride ion channels, Arg(352)-Asp(993) and Arg(347)-Asp(924), that are required for normal channel function. In the present study, we determined how the two salt bridges cooperate to maintain the open pore architecture of CFTR. Our data suggest that Arg(347) not only interacts with Asp(924) but also interacts with Asp(993). The tripartite interaction Arg(347)-Asp(924)-Asp(993) mainly contributes to maintaining a stable s2 open subconductance state. The Arg(352)-Asp(993) salt bridge, in contrast, is involved in stabilizing both the s2 and full (f) open conductance states, with the main contribution being to the f state. The s1 subconductance state does not require either salt bridge. In confirmation of the role of Arg(352) and Asp(993), channels bearing cysteines at these sites could be latched into a full open state using the bifunctional cross-linker 1,2-ethanediyl bismethanethiosulfonate, but only when applied in the open state. Channels remained latched open even after washout of ATP. The results suggest that these interacting residues contribute differently to stabilizing the open pore in different phases of the gating cycle.

Calcineurin A-ß is required for hypertrophy but not matrix expansion in the diabetic kidney.

Calcineurin is an important signalling protein that regulates a number of molecular and cellular processes. Previously, we found that inhibition of calcineurin with cyclosporine reduced renal hypertrophy and blocked glomerular matrix expansion in the diabetic kidney. Isoforms of the catalytic subunit of calcineurin are reported to have tissue specific expression and functions. In particular, the ß isoform has been implicated in cardiac and skeletal muscle hypertrophy. Therefore, we examined the role of calcineurin ß in diabetic renal hypertrophy and glomerular matrix expansion. Type I diabetes was induced in wild-type and ß(-/-) mice and then renal function, extracellular matrix expansion and hypertrophy were evaluated. The absence of ß produced a significant decrease in total calcineurin activity in the inner medulla (IM) and reduced nuclear factor of activated T-cells (NFATc) activity. Loss of ß did not alter diabetic renal dysfunction assessed by glomerular filtration rate, urine albumin excretion and blood urea nitrogen. Similarly, matrix expansion in the whole kidney and glomerulus was not different between diabetic wild-type and ß(-/-) mice. In contrast, whole kidney and glomerular hypertrophy were significantly reduced in diabetic ß(-/-) mice. Moreover, ß(-/-) renal fibroblasts demonstrated impaired phosphorylation of Erk1/Erk2, c-Jun N-terminal kinases (JNK) and mammalian target of rapamycin (mTOR) following stimulation with transforming growth factor-ß and did not undergo hypertrophy with 48 hrs culture in high glucose. In conclusion, loss of the ß isoform of calcineurin is sufficient to reproduce beneficial aspects of cyclosporine on diabetic renal hypertrophy but not matrix expansion. Therefore, while multiple signals appear to regulate matrix, calcineurin ß appears to be a central mechanism involved in organ hypertrophy.

Involvement of Ca2+-independent phospholipase A2 isoforms in oxidant-induced neural cell death.

This study determined the roles of Ca2+-independent PLA2 (iPLA2) in phospholipid chemistry and oxidant-induced cell death in human astrocytes. A172 cells expressed both cytosolic Group VIA (iPLA2beta) and microsomal Group VIB (iPLA2gamma) PLA2 as determined by activity assays and immunoblot analysis. Inhibition of total iPLA2 activity using racemic bromoenol lactone (BEL, 2.5 microM) decreased the expression of 14:0-16:0 phosphatidylcholine (PtdCho) 15% and increased 18:0-18:1-PtdCho expression 15%. Treatment of cells with the iPLA2gamma specific inhibitor R-BEL decreased 14:0-16:0-PtdCho 35%, 16:0-16:0-PtdCho 15% and induced a 35% increase in 18:0-18:1-PtdCho. In contrast, treatment of cells with the iPLA2beta inhibitor S-BEL did not alter any phospholipid studied. To determine the roles of iPLA2 in oxidant-induced cell death, A172 cells were exposed to hydrogen peroxide (H2O2) or tert-butylhydroperoxide (TBHP); both induced time- and concentration-dependent increases in cell death as assessed by annexin V and propidium iodide staining. Treatment of cells with racemic-BEL alone did not induce cell death. However, pretreatment with BEL prior to H2O2 (500 microM) or TBHP (200 microM) significantly increased necrosis as determined by increases in propidium iodide staining. Treatment with BEL prior to exposure to oxidants accelerated the loss of ATP levels, but not the formation of reactive oxygen species. These data support the hypothesis that iPLA2 mediates oxidant-induced neural cell death and demonstrates differential roles of iPLA2 isoforms in physiological and pathological events.