Role of Trpc channels, Stim1 and Orai1 in PGF(2α)-induced calcium signaling in NRK fibroblasts.

Normal rat kidney (NRK) fibroblasts exhibit growth-dependent changes in electrophysiological properties and intracellular calcium dynamics. The transition from a quiescent state to a density-arrested state results in altered calcium entry characteristics. This coincides with modulation of the expression of the genes encoding the calcium channels Trpc1, Trpc6 and Orai1, and of the intracellular calcium sensor Stim1. In the present study we have used gene selective short hairpin (sh) RNAs against these various genes to investigate their role in (a) capacitative store-operated calcium entry (SOCE); (b) non-capacitative OAG-induced receptor-operated calcium entry (ROCE); and (c) prostaglandin F(2α) (PGF(2α))-induced Ca(2+)-oscillations in NRK fibroblasts. Intracellular calcium measurements revealed that knockdown of the genes encoding Trpc1, Orai1 and Stim1 each caused a significant reduction of SOCE in NRK cells, whereas knockdown of the gene encoding Trpc6 reduced only the OAG-induced ROCE. Furthermore, our data show that knockdown of the genes encoding Trpc1, Orai1 and Stim1, but not Trpc6, substantially reduced the frequency (up to 60%) of PGF(2α)-induced Ca(2+) oscillations in NRK cells. These results indicate that in NRK cells distinct calcium channels control the processes of SOCE, ROCE and PGF(2α)-induced Ca(2+) oscillations.

Different roles of inositol 1,4,5-trisphosphate receptor subtypes in prostaglandin F(2alpha)-induced calcium oscillations and pacemaking activity of NRK fibroblasts.

We investigated the role of inositol 1,4,5-trisphosphate (IP(3))-receptor isoforms in the prostaglandin F(2alpha) (PGF(2alpha))-induced calcium oscillations and pacemaking activity of normal rat kidney (NRK) fibroblasts. Reverse transcription polymerase chain reaction (RT-PCR) studies revealed that NRK fibroblasts express only the IP(3)-receptor subtypes IP(3)R1 and IP(3)R3. Quantitative RT-PCR analysis demonstrated that their expression levels varied as a function of the growth status of NRK cells; NRK cells made quiescent (Q) by serum deprivation expressed significantly higher levels of subtypes 1 and 3 than cells grown to density-arrest (DA). Using Ca(2+)-imaging techniques, we show that the frequency of PGF(2alpha)-induced calcium oscillations in DA-cells is lower than in Q-cells. To study whether these differences in the frequency of calcium oscillations relate to the relative amounts of IP(3)-receptor subtypes expressed by the cells, we knocked down the genes for either IP(3)-receptor subtype by using an shRNA approach. Knockdown of the IP(3)R1 gene significantly decreased the frequency of the PGF(2alpha)-induced calcium oscillations in both Q- and DA-cells. It also reduced the frequency of the repetitive firing of calcium action potentials by DA-cells. In contrast, knockdown of the IP(3)R3 gene caused an increase in the frequency of both processes, suggesting a role for this receptor subtype as an anti-Ca(2+)-oscillatory unit in NRK fibroblasts. Our findings indicate that the reduction in the frequency of PGF(2alpha)-induced calcium oscillations in DA-cells compared with Q-cells results from the reduced expression ratio of IP(3)R1 versus IP(3)R3 receptors in DA-cells. Moreover, these data provide direct evidence that the frequency of IP(3)-dependent calcium oscillations determines the periodicity of action potential firing by density-arrested NRK fibroblasts.

Role of the prostanoid FP receptor in action potential generation and phenotypic transformation of NRK fibroblasts.

By using an shRNA approach to knockdown the expression of the prostaglandin (PG)-F(2alpha) receptor (FP-R), the role of PGF(2alpha) in the process of phenotypic transformation of normal rat kidney (NRK) fibroblasts has been studied. Our data show that PGF(2alpha) up-regulates Cox-2 expression both at the mRNA and protein level, indicating that activation of FP-R in NRK fibroblasts induces a positive feedback loop in the production PGF(2alpha). Knockdown of FP-R expression fully impaired the ability of PGF(2alpha) to induce a calcium response and subsequent depolarization in NRK cells. However, these cells could still undergo phenotypic transformation when treated with a combination of EGF and retinoic acid, but in contrast to the wild-type cells, this process was not accompanied by a membrane depolarization to -20 mV. Knockdown of FP-R expression also impaired the spontaneous firing of calcium action potentials by density-arrested NRK cells. These data show that a membrane depolarization is not a prerequisite for the acquisition of a transformed phenotype. Furthermore, our data provide the first direct evidence that activity of PGF(2alpha) by putative pacemaker cells underlies the generation of calcium action potentials in NRK monolayers.

Local induction of pacemaking activity in a monolayer of electrically coupled quiescent NRK fibroblasts.

Cultures of normal rat kidney (NRK) fibroblasts may display spontaneous calcium action potentials which propagate throughout the cellular monolayer. Pacemaking activity of NRK cells was studied by patch clamp electrophysiology and vital calcium imaging, using a new experimental approach in which a ring was placed on the monolayer in order to physically separate pacemakers within or under the ring and follower cells outside the ring. Stimulation of cells inside the ring with IP(3)-generating hormones such as prostaglandin F(2alpha) (PGF(2alpha)) resulted in the induction of periodic action potentials outside the ring, which were abolished when the L-type calcium channel blocker nifedipine was added outside the ring, but not inside the ring. PGF(2alpha)-treated cells displayed asynchronous IP(3)-mediated calcium oscillations of variable frequency, while follower cells outside the ring showed synchronous calcium transients which coincided with the propagating action potential. Mathematical modelling indicated that addition of PGF(2alpha) inside the ring induced both a membrane potential gradient and an intracellular IP(3) gradient, both of which are essential for the induction of pacemaking activity under the ring. These data show that intercellular coupling between PGF(2alpha)-treated and non-treated cells is essential for the generation of a functional pacemaker area whereby synchronization of calcium oscillations occurs by activation of L-type calcium channels.

Autocrine production of prostaglandin F2alpha enhances phenotypic transformation of normal rat kidney fibroblasts.

We have used normal rat kidney (NRK) fibroblasts as an in vitro model system to study cell transformation. These cells obtain a transformed phenotype upon stimulation with growth-modulating factors such as retinoic acid (RA) or transforming growth factor-beta (TGF-beta). Patch-clamp experiments showed that transformation is paralleled by a profound membrane depolarization from around -70 to -20 mV. This depolarization is caused by a compound in the medium conditioned by transformed NRK cells, which enhances intracellular Ca2+ levels and thereby activates Ca2+-dependent Cl- channels. This compound was identified as prostaglandin F2alpha (PGF2alpha) using electrospray ionization mass spectrometry. The active concentration in the medium conditioned by transformed NRK cells as determined using an enzyme immunoassay was 19.7 +/- 2.5 nM (n = 6), compared with 1.5 +/- 0.1 nM (n = 3) conditioned by nontransformed NRK cells. Externally added PGF2alpha was able to trigger NRK cells that had grown to density arrest to restart their proliferation. This proliferation was inhibited when the FP receptor (i.e., natural receptor for PGF2alpha) was blocked by AL-8810. RA-induced phenotypic transformation of NRK cells was partially (approximately 25%) suppressed by AL-8810. Our results demonstrate that PGF2alpha acts as an autocrine enhancer and paracrine inducer of cell transformation and suggest that it may play a crucial role in carcinogenesis in general.