Eugenol and carvone as relaxants of arsenic and mercury hypercontracted rat trachea.

Exposure to arsenic and mercury is known to cause respiratory problems in both humans and animals. In this study, we elicit and compare maximum contraction caused by As(III) and Hg(II) when the pollutants are fully equilibrated with contractile machinery in resting mode. Hypercontraction of 27% and 69% was obtained following exposure of tracheal rings to 25 µM As(III) and 6 nM Hg(II) for 40 min, respectively. Co-incubation of tracheal rings with pollutants and verapamil, sodium nitroprusside or apocynin indicates that major contributors to As(III) and Hg(II) caused hypercontraction are reactive oxygen species (ROS) elevation and nitric oxide (NO) depletion. Changes in calcium influx have minor contribution in As(III) and Hg(II) caused increased contraction of tracheal tissues. Eugenol and carvone caused relaxation of 38% and 45% in pollutant unexposed rings, 56% and 49% in As(III)-exposed tracheal rings, and 54% and 47% in Hg(II)-exposed tracheal rings. Pathway delineation studies indicate that the major effect of eugenol originates from quenching of ROS whereas that of carvone originates from the blockage of extracellular calcium influx. Both molecules also show a minor stimulatory effect on NO generation. In line with their suggested mode of relaxation, eugenol is found to better ameliorate both As(III)- and Hg(II)-caused hypercontraction. Carvone, though a better relaxant than eugenol, comes out as poor ameliorator of both As(III)- and Hg(II)-caused hypercontraction, as the pathway on which it acts is not elevated following exposure to these pollutants.

Inhibition of spleen tyrosine kinase signaling protects against acute lung injury through blockade of NADPH oxidase and IL-17A in neutrophils and γδ T cells respectively in mice.

Acute lung injury (ALI) is one of the most serious complications in critically ill patients which often leads to morbidity and mortality. ALI characterized by severe inflammation of lungs occurs due to uncontrolled inflammatory immune response. However, the immunological mechanism(s) are far from being understood. The spleen tyrosine kinase (SYK), a key component of immune receptor signaling, plays a critical role in the modulation of inflammatory signaling in different immune cells. However, its role in ALI remains to be explored. Therefore, in this study, we investigated the effect of R406, a SYK inhibitor in lipopolysaccharide (LPS)-induced ALI mouse model. LPS led to increased SYK expression in neutrophils and gamma delta (γδ) T cells. This was associated with increased neutrophilic airway inflammation, vascular permeability, myeloperoxidase activity in the lung with upregulated expression of NADPH oxidase (NOX2)/MCP-1/TNF-α in neutrophils and IL-17A in γδ T cells/lung. Pulmonary inflammation was associated with higher mortality in mice with ALI. Inhibition of SYK signaling using R406 in the lung led to blockade of neutrophilic airway inflammation, vascular permeability, pro-inflammatory cytokine release and oxidative stress in innate immune cells, i.e. γδ T cells and neutrophils and the lung. R406 administered LPS group had better survival rate than LPS group. This suggests that SYK upregulation in γδ T cells and neutrophils plays an important role in inflammatory process during ALI. In conclusion, R406 exhibited a great potential to block the LPS-induced airway inflammation and mortality which could be developed as a potential future therapy in ALI.

Modulation of Pb(II) caused aortal constriction by eugenol and carvacrol.

Exposure to lead is known to cause vasoconstriction, exact mechanism of which remains to be elucidated. In this study, we investigate contractile responses of rat aortal rings equilibrated with Pb(II) in organ bath system, explore pathways responsible for hypercontraction and examine two ameliorators of lead-induced hypercontraction. At 1 µmol L(-1) Pb(II), aortal rings showed an average increase of 50% in isometric contraction. Incubation of rings, unexposed to Pb(II), with 1 µmol L(-1) sodium nitroprusside (nitric oxide (NO) donor), 100 µmol L(-1) apocynin (reactive oxygen species (ROS) inhibitor), and 100 µmol L(-1) indomethacin (cyclooxygenase inhibitor) lead to decrease in phenylephrine-induced contraction by 31, 27, and 29%, respectively. This decrease of contraction for Pb(II)-exposed rings was 48, 53, and 38%, respectively, indicating that ROS- and NO-dependent components of contractions are significantly elevated in Pb(II)-induced hypercontraction. Cyclooxygenase-dependent contractile component did not show significant elevation. Eugenol and carvacrol are plant-derived phenols known to possess antioxidant activity and hence could act as possible ameliorators of hypercontraction. At saturating concentrations of 100 µmol L(-1), eugenol and carvacrol caused a decrease in contraction by 38 and 42% in unexposed rings and 46 and 50% in Pb(II)-exposed rings. Co-incubation of rings with eugenol/carvacrol and various inhibitors suggests that both these active principles exert their relaxant effect via quenching of ROS and stimulation of NO synthesis. To conclude, Pb(II) is shown to induce hypercontraction of aortal rings through elevation of ROS and depletion of NO. This hypercontraction is effectively mitigated by eugenol and carvacrol.

Inhibition of As(III) and Hg(II) caused aortic hypercontraction by eugenol, linalool and carvone.

Acute and chronic exposure to arsenic and mercury is known to produce vasoconstriction. There is, however, no clarity concerning the pathways leading to this increased contraction. In this study we elicit and compare maximum contractility of rat aortas under resting conditions in the presence of arsenic and mercury, and delineate pathways mediating this effect. Phenylephrine (PE) induced hypercontraction of 37% and 32% were obtained when isolated aortic segments were exposed to 25 ?M As(III) and 6 nM Hg(II), respectively. Isometric contraction measurements in presence of apocynin, verapamil and sodium nitroprusside indicates that the major causes of increased contraction are reactive oxygen species (ROS) and depletion of nitric oxide (NO). Calcium influx plays a minor role in arsenic and mercury caused hypercontraction. In unexposed aorta, eugenol causes relaxation by inhibiting ROS and elevating NO, linalool by blocking voltage dependent calcium channel (VDCC) and elevating NO, and carvone by blocking calcium influx through VDDC. Since the arsenic and mercury hypercontraction is mediated by increased ROS and depleted NO, we hypothesize that molecules which neutralize ROS or elevate NO will be better ameliorators. In line with this argument, we found eugenol to be the best ameliorator of arsenic and mercury hypercontraction followed by linalool and carvone.