Intracellular cyclic nucleotide analogues inhibit in vitro mitogenesis and activation of fibroblasts derived from obstructed rat kidneys.

As several studies indirectly suggest that inhibiting the intracellular breakdown of cyclic nucleotides may inhibit fibrogenesis, this study used membrane permeable cyclic nucleotide analogues to examine the role of cAMP and cGMP signaling pathways in the regulation of renal fibroblast function. Fibroblasts were isolated by explant outgrowth culture of rat kidneys post unilateral ureteric obstruction. Subcultured cells were exposed to 10- 1,000 microM of the cyclic nucleotide analogues 8-bromo-cAMP (8br-cAMP) and 8-bromo-cGMP (8br-cGMP). Functional parameters examined included mitogenesis (thymidine incorporation), collagen synthesis (proline incorporation), myofibroblast differentiation (Western blotting for alpha-smooth muscle actin; alpha-SMA) and expression of CTGF (Northern blotting), a TGF-beta(1)-driven immediate early response gene. Serum-stimulated mitogenesis was decreased 27 +/- 4% by 100 microM 8br-cAMP (p < 0.01), 49 +/- 6% by 1,000 microM 8br-cAMP (p < 0.001) and 43 +/- 7% by 1,000 microM 8br-cGMP (p < 0.01). 1,000 microM 8br-cAMP and 8br-cGMP reduced basal collagen synthesis by 80 +/- 5 and 60 +/- 21% respectively (both p < 0.05). Maximum dose of 8br-cAMP but not 8br-cGMP inhibited basal expression of the differentiation marker alpha-SMA by 43 +/- 33 (p < 0.05), resulted in a more rounded cell morphology and reduced expression of CTGF by 39 +/- 24% (p < 0.05). Measurement of mitochondrial activity confirmed that effects were independent of cell toxicity. In conclusion, cyclic nucleotides inhibit fibrogenesis in vitro. Strategies which elevate intracellular cyclic nucleotide concentrations may therefore be therapeutically valuable in preventing the proliferation and activation of fibroblasts in progressive renal disease.

Pirfenidone reduces in vitro rat renal fibroblast activation and mitogenesis.

BACKGROUND: Fibroblasts have been universally recognised in tubulointerstitial injury, where their presence has been shown to be a marker of disease progression. Recently, pirfenidone (PF) has been shown to both ameliorate progressive fibrosis and reduce established scarring after ureteric obstruction (UUO) in the rat, suggesting that it is a novel anti-fibrotic agent. The objective of this study was therefore to determine if these effects include down-regulation of fibroblast function. METHODS: Cortical fibroblasts were obtained from outgrowth cultures of renal tissue isolated from kidneys 3 days after UUO and constituted 100% of cells studied. Functional studies examined the effects of 20 and 200 microg/ml PF on basal serum stimulated activity. Activation was examined by western blotting for alpha smooth muscle actin (alphaSMA) and connective tissue growth factor (CTGF). Cell proliferation, collagenase activity and collagen production were determined from kinetic studies, zymography for MMP2 and [3H] proline incorporation in collagenous proteins respectively. RESULTS: Proliferation, as measured by [3H] thymidine incorporation, was reduced in dose dependent manner by 20 and 200 microg/ml PF (p<0.05; 200 vs 0 microg/ml). Likewise, 200 microg/ml PF reduced cell population growth over 5 days of culture (p<0.05 vs 0 microg/ml). PF (200 microg/ml) decreased alphaSMA and CTGF protein expression to 66+/-13 and 37+/-26% of basal levels respectively (both p<0.05 vs 0 microg/ml). Synthesis of collagen was unaffected by PF. Maximal dose of PF produced a modest reduction in MMP2 lytic activity (p=0.05). Effects of PF were independent of cell toxicity. CONCLUSIONS: Down-regulation of renal fibroblast activation and proliferation are specific actions of PF.