Mechanosensing bone osteocytes express large amounts of connexin (Cx)43, the component of gap junctions; yet, gap junctions are only active at the small tips of their dendritic processes, suggesting another function for Cx43. Both primary osteocytes and the osteocyte-like MLO-Y4 cells respond to fluid flow shear stress by releasing intracellular prostaglandin E 2 (PGE 2 ). Cells plated at lower densities release more PGE 2 than cells plated at higher densities. This response was significantly reduced by antisense to Cx43 and by the gap junction and hemichannel inhibitors 18 -glycyrrhetinic acid and carbenoxolone, even in cells without physical contact, suggesting the involvement of Cx43-hemichannels. Inhibitors of other channels, such as the purinergic receptor P2X 7 and the prostaglandin transporter PGT, had no effect on PGE 2 release. Cell surface biotinylation analysis showed that surface expression of Cx43 was increased by shear stress. Together, these results suggest fluid flow shear stress induces the translocation of Cx43 to the membrane surface and that unapposed hemichannels formed by Cx43 serve as a novel portal for the release of PGE 2 in response to mechanical strain.
The connexin 43 (Cx43) hemichannel (HC) in the mechanosensory osteocytes is a major portal for the release of factors responsible for the anabolic effects of mechanical loading on bone formation and remodeling. However, little is known about how the Cx43 molecule responds to mechanical stimulation leading to the opening of the HC. Here, we demonstrate that integrin α5β1 interacts directly with Cx43 and that this interaction is required for mechanical stimulation-induced opening of the Cx43 HC. Direct mechanical perturbation via magnetic beads or conformational activation of integrin α5β1 leads to the opening of the Cx43 HC, and this role of the integrin is independent of its association with an extracellular fibronectin substrate. PI3K signaling is responsible for the shear stress-induced conformational activation of integrin α5β1 leading to the opening of the HC. These results identify an unconventional function of integrin that acts as a mechanical tether to induce opening of the HC and provide a mechanism connecting the effect of mechanical forces directly to anabolic function of the bone.
Bone tissues respond to mechanical loading/unloading regimens to accommodate (re)modeling requirements; however, the underlying molecular mechanism responsible for these responses is largely unknown. Previously, we reported that connexin (Cx) 43 hemichannels in mechanosensing osteocytes mediate the release of prostaglandin, PGE 2 , a crucial factor for bone formation in response to anabolic loading. We show here that the opening of hemichannels and release of PGE 2 by shear stress were significantly inhibited by a potent antibody we developed that specifically blocks Cx43-hemichannels, but not gap junctions or other channels. The opening of hemichannels and release of PGE 2 are magnitude-dependent on the level of shear stress. Insertion of a rest period between stress enhances this response. Hemichannels gradually close after 24 h of continuous shear stress corresponding with reduced Cx43 expression on the cell surface, thereby reducing any potential negative effects of channels staying open for extended periods. These data suggest that Cx43-hemichannel activity associated with PGE 2 release is adaptively regulated by mechanical loading to provide an effective means of regulating levels of extracellular signaling molecules responsible for initiation of bone (re)modeling.The skeleton regulates its architecture and mass to meet structural and metabolic needs. To fulfill its structural functions, this complex tissue must adapt to loading and unloading while simultaneously regulating the metabolic demands of the skeleton. Numerous in vivo animal studies show the essential role of mechanical loading for bone formation and remodeling; however, the underlying molecular mechanisms, in particular how bone cells adapt to mechanical stimulation, remain largely uncharacterized.When mechanical forces are applied to bone, several potential stimuli occur including changes in hydrostatic pressure, direct cell strain, fluid flow, and electric potentials. These changes lead to fluid movement through the bone (1-3). Shear stress induced by mechanical loading facilitates the exchange of nutrients and bone modulators, and elicits biochemical responses. Osteocytes are well positioned in the bone to sense the magnitude of mechanical strain and are essential for the skeleton adaptive response to load. Experimental studies have shown that osteocytes are sensitive to stress applied to both intact bone tissue and in cell culture (4 -6). Encased within mineralized tissue, their dendritic morphology allows them to connect through small tunnels called canaliculi to form a threedimensional network not only with adjacent osteocytes but also to connect to cells on the bone surface and bone marrow.Connexins (Cx), 2 gap junction-forming proteins, belong to a multigene family expressing four transmembrane domains. The regions corresponding to transmembrane and extracellular domains are highly conserved. Cx43 has been identified in most types of bone cells (7-13) and is the major connexin expressed in osteocyte-like MLO-Y4 cells and primary osteocy...
Fluid flow conditioned medium and PGE 2 stimulated cAMP production and PKA activity suggesting that PGE 2 released by mechanically stimulated cells is responsible for the activation of cAMP and PKA. The adenylate cyclase activators, forskolin and 8-bromo-cAMP, enhanced intercellular connectivity, the number of functional gap junctions, and Cx43 protein expression, whereas the PKA inhibitor, H89, inhibited the stimulatory effect of PGE 2 on gap junctions. These studies suggest that the EP 2 receptor mediates the effects of autocrine PGE 2 on the osteocyte gap junction in response to fluid flow-induced shear stress. These data support the hypothesis that the EP 2 receptor, cAMP, and PKA are critical components of the signaling cascade between mechanical strain and gap junction-mediated communication between osteocytes.
Summary: In this unifying hypothesis directed to the etiology and pathogenesis of atherosclerosis, the importance of focal arterial lesion-prone sites has been emphasized. Key initial participants in these sites include the focal intimal influx and accumulation of low-density lipoprotein (LDL) and a preferential recruitment of blood monocytes. Both are further enhanced in the presence of hyperlipidemia, when the quantity of intimal LDL and the oxidative potential of the intima exceed the capacity of macrophages to remove, via the non-down-regulating scavenger receptor, cytotoxic anionic (Ox-LDL) macromolecules. Foam cells, pathognomonic of the fatty streak, form during the receptor-mediated uptake of Ox-LDL by the macrophages. Interstitial free radicals and the excess of Ox-LDL particles injure and kill cells, including the foam cells, with the formation of the necrotic extracellular lipid core, a key transitional step in lesion progression. Monocytemacrophage recruitment to the intima is likely to be regulated not only by a multiplicity of endothelial adhesive cytokines, integrins, and selectins, but also by the monocyte-specific chemoattractant, MCP-1, constitutively synthesized and secreted by intimal smooth muscle and endothelial cells. Its synthesis and secretion is augmented by mildly oxidized LDL. Free radicals, pivotal in the oxidation of LDL, and derived from activated macrophages, and also endothelial and smooth muscle cells. Smooth muscle cells migrate from the media through the intimal endothelial layer (IEL) and proliferate under the regulation of a number of mitogens, including plateletderived gmwth factor (PDGF).
Endothelial cell-monocyte interaction plays an important role in atherogenesis. The expressions of some endothelial cell adhesion molecules involved in endothelial cell-monocyte interactions are regulated by transcription factor NF-kappa B. Because low shear stress has been known to influence endothelial monocyte adhesion, the differential activation of NF-kappa B under different flow regimens across time (0.5-24 h) was investigated. Nuclear proteins from flow-conditioned human aortic endothelial cells (HAEC) were analyzed by electrophoretic mobility shift assay using [gamma-32P]dATP-labeled NF-kappa B-specific oligonucleotide. Our results demonstrated that NF-kappa B activation was significantly elevated in HAEC exposed to prolonged (> 2 h) steady low shear (2 dyn/cm2) and pulsatile low shear (2 +/- 2 dyn/cm2) compared with HAEC exposed to high shear (16 dyn/cm2). In contrast, at 30 min, high shear-exposed HAEC exhibited an early, transient increase in NF-kappa B activity, relative to low shear-exposed cells, which reversed on continued exposure to high shear. Maximum activity in both low shear- and pulsatile low shear-conditioned HAEC was observed at 16 h compared with HAEC exposed to prolonged high shear. These results indicate that exposure of HAEC to prolonged low shear conditions is associated with significantly increased and prolonged NF-kappa B activity. This observation might provide a mechanism to explain the increased monocyte adhesion in atherosclerosisprone arterial sites exposed to chronic low-shear flow patterns.
Gap junction intercellular communication in osteocytes plays an important role in bone remodeling in response to mechanical loading; however, the responsible molecular mechanisms remain largely unknown. Here, we show that phosphoinositide-3 kinase (PI3K)/Akt signaling activated by fluid flow shear stress and prostaglandin E 2 (PGE 2 ) had a stimulatory effect on both connexin 43 (Cx43) mRNA and protein expression. PGE 2 inactivated glycogen synthase kinase 3 (GSK-3) and promoted nuclear localization and accumulation of -catenin. Knockdown of -catenin expression resulted in a reduction in Cx43 protein. Furthermore, the chromatin immunoprecipitation (ChIP) assay demonstrated an association of -catenin with the Cx43 promoter, suggesting that -catenin could regulate Cx43 expression at the level of gene transcription. We have previously reported that PGE 2 activates cyclic AMP (cAMP)-protein kinase A (PKA) signaling and increases Cx43 and gap junctions. Interestingly, the activation of PI3K/Akt appeared to be independent of the activation of PKA, whereas both PI3K/Akt and PKA signaling inactivated GSK-3 and increased -catenin translocation. Together, these results suggest that shear stress, through PGE 2 release, activates both PI3K/Akt and cAMP-PKA signaling, which converge through the inactivation of GSK-3, leading to the increase in nuclear accumulation of -catenin. -Catenin binds to the Cx43 promoter, stimulating Cx43 expression and functional gap junctions between osteocytes.
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