Lysophospholipid receptor activation of RhoA and lipid signaling pathways.

The lysophospholipids sphingosine 1-phosphate (S1P) and lysophosphatidic acid (LPA) signal through G-protein coupled receptors (GPCRs) which couple to multiple G-proteins and their effectors. These GPCRs are quite efficacious in coupling to the Gα(12/13) family of G-proteins, which stimulate guanine nucleotide exchange factors (GEFs) for RhoA. Activated RhoA subsequently regulates downstream enzymes that transduce signals which affect the actin cytoskeleton, gene expression, cell proliferation and cell survival. Remarkably many of the enzymes regulated downstream of RhoA either use phospholipids as substrates (e.g. phospholipase D, phospholipase C-epsilon, PTEN, PI3 kinase) or are regulated by phospholipid products (e.g. protein kinase D, Akt). Thus lysophospholipids signal from outside of the cell and control phospholipid signaling processes within the cell that they target. Here we review evidence suggesting an integrative role for RhoA in responding to lysophospholipids upregulated in the pathophysiological environment, and in transducing this signal to cellular responses through effects on phospholipid regulatory or phospholipid regulated enzymes. This article is part of a Special Issue entitled Advances in Lysophospholipid Research.

Activation of volume regulated chloride channels protects myocardium from ischemia/reperfusion damage in second-window ischemic preconditioning.

Activation of volume regulated chloride channels (VRCCs) has been shown to be cardioprotective in ischemic preconditioning (IPC) of isolated hearts but the underlying molecular mechanisms remain unclear. Recent independent studies support that ClC-3, a ClC voltage-gated chloride channel, may function as a key component of the VRCCs. Thus, ClC-3 knockout (Clcn3(-/-)) mice and their age-matched heterozygous (Clcn3(+/-)) and wild-type (Clcn3(+/+)) littermates were used to test whether activation of VRCCs contributes to cardioprotection in early and/or second-window IPC. Targeted disruption of ClC-3 gene caused a decrease in the body weight but no changes in heart/body weight ratio. Telemetry ECG and echocardiography revealed no differences in ECG and cardiac function under resting conditions among all groups. Under treadmill stress (10 m/min for 10 min), the Clcn3(-/-) mice had significant slower heart rate (648±12 bpm) than Clcn3(+/+) littermates (737±19 bpm, n=6, P<0.05). Ex vivo IPC in the isolated working-heart preparations protected cardiac function during reperfusion and significantly decreased apoptosis and infarct size in all groups. In vivo early IPC significantly reduced infarct size in all groups including Clcn3(-/-) mice (22.7±3.7% vs control 40.1±4.3%, n=22, P=0.004). Second-window IPC significantly reduced apoptosis and infarction in Clcn3(+/+) (22.9±3.2% vs 45.7±5.4%, n=22, P<0.001) and Clcn3(+/-) mice (27.5±4.1% vs 42.2±5.7%, n=15, P<0.05) but not in Clcn3(-/-) littermates (39.8±4.9% vs 41.5±8.2%, n=13, P>0.05). Impaired cell volume regulation of the Clcn3(-/-) myocytes may contribute to the failure of cardioprotection by second-window IPC. These results strongly support that activation of VRCCs may play an important cardioprotective role in second-window IPC.

Characterization of a critical role for CFTR chloride channels in cardioprotection against ischemia/reperfusion injury.

AIM: To further characterize the functional role of cystic fibrosis transmembrane conductance regulator (CFTR) in early and late (second window) ischemic preconditioning (IPC)- and postconditioning (POC)-mediated cardioprotection against ischemia/reperfusion (I/R) injury. METHODS: CFTR knockout (CFTR(-/-)) mice and age- and gender-matched wild-type (CFTR(+/+)) and heterozygous (CFTR(+/-)) mice were used. In in vivo studies, the animals were subjected to a 30-min coronary occlusion followed by a 40-min reperfusion. In ex vivo (isolate heart) studies, a 45-min global ischemia was applied. To evaluate apoptosis, the level of activated caspase 3 and TdT-mediated dUTP-X nick end labeling (TUNEL) were examined. RESULTS: In the in vivo I/R models, early IPC significantly reduced the myocardial infarct size in wild-type (CFTR(+/+)) (from 40.4% ± 5.3% to 10.4% ± 2.0%, n=8, P<0.001) and heterozygous (CFTR(+/-)) littermates (from 39.4% ± 2.4% to 15.4% ± 5.1%, n=6, P<0.001) but failed to protect CFTR knockout (CFTR(-/-)) mice from I/R induced myocardial infarction (46.9% ± 6.2% vs 55.5% ± 7.8%, n=6, P>0.5). Similar results were observed in the in vivo late IPC experiments. Furthermore, in both in vivo and ex vivo I/R models, POC significantly reduced myocardial infarction in wild-type mice, but not in CFTR knockout mice. In ex vivo I/R models, targeted inactivation of CFTR gene abolished the protective effects of IPC against I/R-induced apoptosis. CONCLUSION: These results provide compelling evidence for a critical role for CFTR Cl(-) channels in IPC- and POC-mediated cardioprotection against I/R-induced myocardial injury.

RhoA protects the mouse heart against ischemia/reperfusion injury.

The small GTPase RhoA serves as a nodal point for signaling through hormones and mechanical stretch. However, the role of RhoA signaling in cardiac pathophysiology is poorly understood. To address this issue, we generated mice with cardiomyocyte-specific conditional expression of low levels of activated RhoA (CA-RhoA mice) and demonstrated that they exhibited no overt cardiomyopathy. When challenged by in vivo or ex vivo ischemia/reperfusion (I/R), however, the CA-RhoA mice exhibited strikingly increased tolerance to injury, which was manifest as reduced myocardial lactate dehydrogenase (LDH) release and infarct size and improved contractile function. PKD was robustly activated in CA-RhoA hearts. The cardioprotection afforded by RhoA was reversed by PKD inhibition. The hypothesis that activated RhoA and PKD serve protective physiological functions during I/R was supported by several lines of evidence. In WT mice, both RhoA and PKD were rapidly activated during I/R, and blocking PKD augmented I/R injury. In addition, cardiac-specific RhoA-knockout mice showed reduced PKD activation after I/R and strikingly decreased tolerance to I/R injury, as shown by increased infarct size and LDH release. Collectively, our findings provide strong support for the concept that RhoA signaling in adult cardiomyocytes promotes survival. They also reveal unexpected roles for PKD as a downstream mediator of RhoA and in cardioprotection against I/R.