Endothelial cell functions, such as arachidonic acid metabolism, may be modulated by membrane stresses induced by blood flow. The production of prostacyclin by primary human endothelial cell cultures subjected to pulsatile and steady flow shear stress was measured. The onset of flow led to a sudden increase in prostacyclin production, which decreased to a steady rate within several minutes. The steady-state production rate of cells subjected to pulsatile shear stress was more than twice that of cells exposed to steady shear stress and 16 times greater than that of cells in stationary culture.
It has been known for more than a century that bone tissue adapts to functional stress by changes in structure and mass. However, the mechanism by which stress is translated into cellular activities of bone formation and resorption is unknown. We studied the response of isolated osteocytes derived from embryonic chicken calvariae to intermittent hydrostatic compression as well as pulsating fluid flow, and compared their response to osteoblasts and periosteal fibroblasts. Osteocytes, but not osteoblasts or periosteal fibroblasts, reacted to 1 h pulsating fluid flow with a sustained release of prostaglandin E2. Intermittent hydrostatic compression stimulated prostaglandin production to a lesser extent: after 6 and 24 h in osteocytes and after 6 h in osteoblasts. These data provide evidence that osteocytes are the most mechanosensitive cells in bone involved in the transduction of mechanical stress into a biological response. The results support the hypothesis that stress on bone causes fluid flow in the lacunar-canalicular system, which stimulates the osteocytes to produce factors that regulate bone metabolism.
Hemodynamic shear stress stimulates a number of intracellular events that both regulate vessel structure and influence development of vascular pathologies. The precise molecular mechanisms by which endothelial cells transduce this mechanical stimulus into intracellular biochemical response have not been established. Here, we show that mechanical perturbation of the plasma membrane leads to ligand-independent conformational transitions in a G protein-coupled receptor (GPCR). By using time-resolved fluorescence microscopy and GPCR conformation-sensitive FRET we found that stimulation of endothelial cells with fluid shear stress, hypotonic stress, or membrane fluidizing agent leads to a significant increase in activity of bradykinin B2 GPCR in endothelial cells. The GPCR conformational dynamics was detected by monitoring redistribution of GPCRs between inactive and active conformations in a single endothelial cell under fluid shear stress in real time. We show that this response can be blocked by a B2-selective antagonist. Our data demonstrate that changes in cell membrane tension and membrane fluidity affect conformational dynamics of GPCRs. Therefore, we suggest that GPCRs are involved in mediating primary mechanochemical signal transduction in endothelial cells. We anticipate our experiments to be a starting point for more sophisticated studies of the effects of changes in lipid bilayer environment on GPCR conformational dynamics. Furthermore, because GPCRs are a major target of drug development, a detailed characterization of mechanochemical signaling via the GPCR pathway will be relevant for the development of new antiatherosclerosis drugs.conformational transition ͉ ligand-independent activation ͉ mechanochemical signal transduction ͉ plasma membrane ͉ bradykinin
These experiments demonstrate that exposure of cultured endothelial cells (EC) to well-defined laminar fluid flow results in an elevated rate of NO production. NO production was monitored by release of NOx (NO2- + NO3(2-) and by cellular guanosine 3',5'-cyclic monophosphate (cGMP) concentration. NO synthase (NOS) inhibitor blocked the flow-mediated stimulation of both NOx and cGMP, indicating that both measurements reflect NO production. Exposure to laminar flow increased NO release in a biphasic manner, with an initial rapid production consequent to the onset of flow followed by a less rapid, sustained production. A similar rapid increase in NO production resulted from an increase in flow above a preexisting level. The rapid initial production of NO was not dependent on shear stress within a physiological range (6-25 dyn/cm2) but may be dependent on the rate of change in shear stress. The sustained release of NO was dependent on physiological levels of shear stress. The calcium (Ca2+) or calmodulin (CaM) dependence of the initial and sustained production of NO was compared with bradykinin (BK)-mediated NO production. Both BK and the initial production were inhibited by Ca2+ and CaM antagonists. In contrast, the sustained shear stress-mediated NO production was not affected, despite the continued functional presence of the antagonists. Dexamethasone had no effect on either the initial or the sustained shear stress-mediated NO production. An inducible NOS does not, therefore, explain the apparent Ca2+/CaM independence of the sustained shear stress-mediated NO production.(ABSTRACT TRUNCATED AT 250 WORDS)
The mechanisms that regulate vascular resistance in the liver are an area of active investigation. Previously, we have shown that nitric oxide (NO) modulates hepatic vascular tone in the normal rat liver. In this study, the production of NO is examined in further detail by isolating sinusoidal endothelial cells (SEC) from the rat liver. Endothelial NO synthase (eNOS) was present in SEC based on Western blotting and confocal immunofluorescence microscopy. Exposure of SEC to flow increased the release of NO. To investigate the relevance of these in vitro findings to the intact liver, we modified an in situ perfusion system to allow for direct measurement of NO release from the hepatic vasculature. NO was released from the hepatic vasculature in a time-dependent manner, and administration of N-monomethyl-L-arginine reduced NO release and increased portal pressure. Immunostaining of intact liver demonstrated eNOS localization to endothelial cells lining the hepatic sinusoids. These findings demonstrate that SEC in vitro and in vivo express eNOS and produce NO basally, and increase their production in response to flow. Additionally, an increase in portal pressure concomitant with the blockade of NO release directly demonstrates that endogenous endothelial-derived NO modulates portal pressure.
The role of nitric oxide (NO) in the genesis of cerebral malaria is controversial. Most investigators propose that the unfortunate consequence of the high concentrations of NO produced to kill the parasite is the development of cerebral malaria. Here we have tested this high NO bioavailability hypothesis in the setting of experimental cerebral malaria (ECM), but find instead that low NO bioavailability contributes to the genesis of ECM. Specifically, mice deficient in vascular NO synthase showed parasitemia and mortality similar to that observed in control mice. Exogenous NO did not affect parasitemia but provided marked protection against ECM; in fact, mice treated with exogenous NO were clinically indistinguishable from uninfected mice at a stage when control infected mice were moribund. Administration of exogenous NO restored NO-mediated signaling in the brain, decreased proinflammatory biomarkers in the blood, and markedly reduced vascular leak and petechial hemorrhage into the brain. Low NO bioavailability in the vasculature during ECM was caused in part by an increase in NO-scavenging free hemoglobin in the blood, by hypoargininemia, and by low blood and erythrocyte nitrite concentrations. Exogenous NO inactivated NO-scavenging free hemoglobin in the plasma and restored nitrite to concentrations observed in uninfected mice. We therefore conclude that low rather than high NO bioavailability contributes to the genesis of ECM.
A flow apparatus has been developed f o r t h e study of t h e metabolic response o f anchorage-dependent c e l l s t o a wide range o f s t e a d y and p u l s a t i l e s h e a r stresses under well-controlled conditions. Human umb i l i c a l vein e n d o t h e l i a l c e l l monolayers were s u b j e c t e d t o s t e a d y shear stresses of up t o 24 dynes/cm2, and t h e production o f p r o s t a c y c l i n was determined. The onset of flow l e d t o a b u r s t i n p r o s t a c y c l i n production which decayed t o a long-term s t e a d y s t a t e rate (SSR). The SSR of c e l l s exposed t o flow was greater than the basal release l e v e l , and increased l i n e a r l y w i t h i n c r e a s i n g shear stress.T h i s s t u d y demonstrates t h a t shear stress i n c e r t a i n ranges may not be d e t r i m e n t a l t o mammalian c e l l metabolism.I n f a c t , throughout t h e range o f shear stresses s t u d i e d , metabolite production is maximized by maximizing shear stress.
The effect of shear stress on the release of endothelin-1 (ET-1) from endothelial cells is at present controversial with various investigators observing an increase and others observing a decrease. Our data reveal that the release of ET-1 from primary cultures of human umbilical vein endothelial cells varies with the duration and the level of shear. Sustained exposure to low levels of shear (1.8 dyn/cm2) or a brief exposure (< 1 h) to 10 dyn/cm2 caused a sustained stimulation of ET-1 release. Staurosporine (STPN) completely blocked the stimulation in both cases, suggesting that ET-1 release is increased via activation of protein kinase C (PKC). Exposure to 6-25 dyn/cm2 for > or = 6 h dramatically inhibited ET-1 release and led to 0-70% inhibition of cumulative release by 16 h. Pretreatment with N omega-nitro-L-arginine (L-NNA) reversed this suppression in a dose-dependent manner, implicating either nitric oxide (NO) and/or guanosine 3',5'-cyclic monophosphate (cGMP) as a requirement for shear-mediated inhibition of ET-1 release. Treatment of stationary cultures with 8-bromo-cGMP and atrial natriuretic peptide mimicked the inhibition of ET-1 release caused by shear and revealed that cGMP is capable of inhibiting ET-1. Likewise, the inhibitory effects of shear were potentiated and diminished by 3-isobutyl-1-methylxanthine (IBMX) and methylene blue, respectively. Thus cGMP also appears to exert an inhibitory effect in cells exposed to shear.(ABSTRACT TRUNCATED AT 250 WORDS)
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