Mechanically stimulated osteocytes regulate osteoblastic activity via gap junctions.

The strong correlation between a bone's architectural properties and the mechanical forces that it experiences has long been attributed to the existence of a cell that not only detects mechanical load but also structurally adapts the bone matrix to counter it. One of the most likely cellular candidates for such a "mechanostat" is the osteocyte, which resides within the mineralized bone matrix and is perfectly situated to detect mechanically induced signals. However, as osteocytes can neither form nor resorb bone, it has been hypothesized that they orchestrate mechanically induced bone remodeling by coordinating the actions of cells residing on the bone surface, such as osteoblasts. To investigate this hypothesis, we developed a novel osteocyte-osteoblast coculture model that mimics in vivo systems by permitting us to expose osteocytes to physiological levels of fluid shear while shielding osteoblasts from it. Our results show that osteocytes exposed to a fluid shear rate of 4.4 dyn/cm(2) rapidly increase the alkaline phosphatase activity of the shielded osteoblasts and that osteocytic-osteoblastic physical contact is a prerequisite. Furthermore, both functional gap junctional intercellular communication and the mitogen-activated protein kinase, extracellular signal-regulated kinase 1/2 signaling pathway are essential components in the osteoblastic response to osteocyte communicated mechanical signals. By utilizing other nonosteocytic coculture models, we also show that the ability to mediate osteoblastic alkaline phosphatase levels in response to the application of fluid shear is a phenomena unique to osteocytes and is not reproduced by other mesenchymal cell types.

Mechanical stimulation effects on functional end effectors in osteoblastic MG-63 cells.

Receptor activator of Nf-kappaB ligand (RANKL) and osteoprotegerin (OPG) have been implicated in bone metabolism. Specifically, the balance of these factors in conjunction with receptor activator of Nf-kappaB (RANK) is believed to be key in determining the rate of osteoclastogenesis and the net outcome of bone formation/resorption. While it is well accepted that mechanical loading in vivo affects bone formation/resorption and that alterations in the responsiveness of bone cells to mechanical loading have been implicated in metabolic bone diseases, the effect of in vitro mechanical loading on osteoblastic production of OPG and RANKL has not been extensively studied. Thus, in the current study, we developed an in vitro model to load human osteoblasts and studied levels of OPG, RANKL, PGE(2) and macrophage colony stimulating factor (M-CSF). We hypothesized that stimulating osteoblastic cells would increase the release of soluble OPG relative to RANKL favoring a bone-forming (and resorption-inhibiting) event. To accomplish this, we developed a small-scale loading machine that imparts via bending, well-defined substrate deformation to bone cells cultured on artificial substrates. Following 2h of loading and a 1h incubation period, media was collected and levels of soluble OPG, RANKL, PGE(2) and M-CSF were quantified using ELISA and western blotting. We found that mechanical loading significantly increased soluble OPG levels relative to RANKL at this 3h time point. Levels of soluble and cellular RANKL detected were not significantly affected by mechanical stimulation. The relative shift in abundance of OPG over RANKL associated with applied mechanical stimulation suggests the soluble OPG:RANKL ratio may be important in load-induced coupling mechanisms of bone cells.

Annexin V disruption impairs mechanically induced calcium signaling in osteoblastic cells.

The mechanical environment of the skeleton plays an important role in the establishment and maintenance of structurally competent bone. Biophysical signals induced by mechanical loading elicit a variety of cellular responses in bone cells, however, little is known about the underlying mechanotransduction mechanism. We hypothesized that bone cells detect and transduce biophysical signals into biological responses via a mechanism requiring annexin V (AnxV). AnxV, a calcium-dependent phospholipid binding protein, has several attributes, which suggest it is ideally suited for a role as a mechanosensor, possibly a mechanosensitive ion channel. These include the ability to function as a Ca2+ selective ion channel, and the ability to interact with both extracellular matrix proteins and cytoskeletal elements. To test the hypothesis that AnxV has a role in mechanosensing, we studied the response of osteoblastic cells to oscillating fluid flow, a physiologically relevant physical signal in bone, in the presence and absence of AnxV inhibitors. In addition, we investigated the effects of oscillating flow on the cellular location of AnxV. Oscillating fluid flow increased both [Ca2+]i levels and c-fos protein levels in osteoblasts. Disruption of AnxV with blocking antibodies or a pharmacological inhibitor, K201 (JTV-519), significantly inhibited both responses. Additionally, our data show that the cellular location of AnxV was modulated by oscillating fluid flow. Exposure to oscillating fluid flow resulted in a significant increase in AnxV at both the cell and nuclear membranes. In summary, our data suggest that AnxV mediates flow-induced Ca2+ signaling in osteoblastic cells. These data support the idea of AnxV as a Ca2+ channel, or a component of the signaling pathway, in the mechanism by which mechanical signals are transduced into cellular responses in the osteoblast. Furthermore, the presence of a highly mobile pool of AnxV may provide cells with a powerful mechanism by which cellular responses to mechanical loading might be amplified and regulated.

Development of a cost-effective loading machine for biomechanical evaluation of mouse transgenic models.

Recent advances in molecular biology have enabled the widespread use of transgenic mouse models. Whether these transgenics present with a skeletal phenotype is often of interest, particularly to orthopedic researchers. Unfortunately, the expense of commercial mechanical testing systems often impedes their routine use in biology laboratories. In this article, the development of a small-scale, relatively inexpensive loading machine, that is ideal for the biomechanical bend testing of mouse long bones, is detailed and the system in transgenic mouse tibiae testing is utilized.

Increases in cytosolic calcium, but not fluid flow, affect aggrecan mRNA levels in articular chondrocytes.

Fluctuations in intracellular free calcium concentration ([Ca2+]i) is thought to be one mechanism by which cells transduce mechanical signals into biological responses. Primary cultures of bovine articular chondrocytes (BAC) respond to oscillating fluid flow with a transient rise in [Ca2+]i. However, specific down-stream effects of [Ca2+]i on gene expression and phenotype in BAC remain to be defined. The present work was designed to determine whether [Ca2+]i mobilization regulates aggrecan mRNA levels. [Ca2+]i was transiently elevated by exposing BAC to the [Ca2+]-specific ionophore, ionomycin. The results show that ionomycin increases [Ca2+]i in a dose-dependent fashion. Semi-quantitative real time (RT)-PCR was used to study the effects of increased [Ca2+]i on steady state levels of aggrecan mRNA. Four hours after a brief exposure to 1.5 microM ionomycin, BAC displayed a nearly four-fold decrease in aggrecan mRNA levels compared to control cells. This effect of ionomycin on aggrecan mRNA was no longer evident 6 or 10 h later. Despite previous observations that oscillating fluid flow elicits increased [Ca2+]i in BAC, it did not affect aggrecan mRNA levels. Taken together, these data suggest that ionomycin-induced [Ca2+]i fluctuations regulate aggrecan mRNA levels, but that flow induced [Ca2+]i fluctuations do not.

Oscillating fluid flow regulates gap junction communication in osteocytic MLO-Y4 cells by an ERK1/2 MAP kinase-dependent mechanism.

The present work was designed to investigate the effects of oscillating fluid flow on gap junctional intercellular communication (GJIC) and the gap junction protein connexin (Cx) 43 in osteocyte-like MLOY-4 cells. Cells were exposed for 1 h to oscillating fluid flow at a shear stress of +/-10 dyn/cm(2) and a frequency of 1 Hz in a parallel plate flow chamber. Control cells were incubated in the chamber but were not exposed to oscillating fluid flow. Functional analysis of GJIC indicated that MLOY-4 cells exposed to oscillating fluid flow established more gap junctions with an independent population of dye-labeled cells than did control cells. Phosphorylation of Cx43 was quantified by immunoprecipitation with an anti-Cx43 antibody followed by immunoblot analysis using an anti-phosphoserine antibody. Phosphoserine was normalized to Cx43 in each sample. Compared to control cells, phosphoserine content of Cx43 increased approximately twofold in cells exposed to oscillating fluid flow. The possible role of the extracellular signal regulated kinase (ERK1/2) in the flow-induced upregulation of GJIC was also investigated. The ERK1/2 inhibitor PD-98059 significantly attenuated the effects of oscillating fluid flow on MLOY-4 cells GJIC. These results indicate that oscillating fluid flow regulates GJIC in MLOY-4 cells via the ERK1/2 MAP kinase. In addition, increased serine phosphorylation of Cx43 correlates with the flow-induced increase in GJIC.

Mechanosensitivity of bone cells to oscillating fluid flow induced shear stress may be modulated by chemotransport.

Fluid flow has been shown to be a potent physical stimulus in the regulation of bone cell metabolism. In addition to membrane shear stress, loading-induced fluid flow will enhance chemotransport due to convection or mass transport thereby affecting the biochemical environment surrounding the cell. This study investigated the role of oscillating fluid flow induced shear stress and chemotransport in cellular mechanotransduction mechanisms in bone. Intracellular calcium mobilization and prostaglandin E(2) (PGE(2)) production were studied with varying levels of shear stress and chemotransport. In this study MC3T3-E1 cells responded to oscillating fluid flow with both an increase in intracellular calcium concentration ([Ca(2+)](i)) and an increase in PGE(2) production. These fluid flow induced responses were modulated by chemotransport. The percentage of cells responding with an [Ca(2+)](i) oscillation increased with increasing flow rate, as did the production of PGE(2). In addition, depriving the cells of nutrients during fluid flow resulted in an inhibition of both [Ca(2+)](i) mobilization and PGE(2) production. These data suggest that depriving the cells of a yet to be determined biochemical factor in media affects the responsiveness of bone cells even at a constant peak shear stress. Chemotransport alone will not elicit a response, but it appears that sufficient nutrient supply or waste removal is needed for the response to oscillating fluid flow induced shear stress.

Fluid flow-induced prostaglandin E2 response of osteoblastic ROS 17/2.8 cells is gap junction-mediated and independent of cytosolic calcium.

It has been well demonstrated that bone adapts to mechanical loading. To accomplish this at the cellular level, bone cells must be responsive to mechanical loading (mechanoresponsive). This can occur via such mechanisms as direct cell deformation or signal transduction via complex pathways involving chemotransport, hormone response, and/or gene expression, to name a few. Mechanotransduction is the process by which a bone cell senses a biophysical signal and elicits a response. While it has been demonstrated that bone cells can respond to a wide variety of biophysical signals including fluid flow, stretch, and magnetic fields, the exact pathways and mechanisms involved are not clearly understood. We postulated that gap junctions may play an important role in bone cell responsiveness. Gap junctions (GJ) are membrane-spanning channels that physically link cells and support the transport of small molecules and ions in the process of gap junctional intercellular communication (GJIC). In this study we examined the role of GJ and GJIC in mechanically stimulated osteoblastic cells. Following fluid flow stimulation, we quantified prostaglandin E(2) (PGE(2)) (oscillatory flow) and cytosolic calcium (Ca(2+)) (oscillatory and steady flow) responses in ROS 17/2.8 cells and a derivative of these cells expressing antisense cDNA for the gap junction protein connexin 43 (RCx16) possessing significantly different levels of GJIC. We found that the ROS17/2.8 cells possessing increased GJIC also exhibited increased PGE(2) release to the supernatant following oscillatory fluid flow stimulation in comparison to coupling-decreased RCx16 cells. Interestingly, we found that neither osteoblastic cell line responded to oscillatory or steady fluid flow stimulation with an increase in Ca(2+). Thus, our results suggest that GJ and GJIC may be important in the mechanotransduction mechanisms by which PGE(2) is mechanically induced in osteoblastic cells independent of Ca(2+).

Pulsed electromagnetic fields affect phenotype and connexin 43 protein expression in MLO-Y4 osteocyte-like cells and ROS 17/2.8 osteoblast-like cells.

Osteocytes, the predominant cells in bone, are postulated to be responsible for sensing mechanical and electrical stimuli, transducing signals via gap junctions. Osteocytes respond to induced shear by increasing connexin 43 (Cx43) levels, suggesting that they might be sensitive to physical stimuli like low-frequency electromagnetic fields (EMF). Immature osteoblasts exhibit decreased intercellular communication in response to EMF but no change in Cx43. Here, we examined long term effects of pulsed EMF (PEMF) on MLO-Y4 osteocyte-like cells and ROS 17/2.8 osteoblast-like cells. In MLO-Y4 cell cultures, PEMF for 8 h/day for one, two or four days increased alkaline phosphatase activity but had no effect on cell number or osteocalcin. Transforming growth factor beta-1 (TGF-beta 1) and prostaglandin E(2) were increased, and NO(2-) was altered. PEMFs effect on TGF-beta1 was via a prostaglandin-dependent mechanism involving Cox-1 but not Cox-2. In ROS 17/2.8 cells, PEMF for 24, 48 or 72 h did not affect cell number, osteocalcin mRNA or osteocalcin protein. PEMF reduced Cx43 protein in both cells. Longer exposures decreased Cx43 mRNA. This indicates that cells in the osteoblast lineage, including well-differentiated osteoblast-like ROS 17/2.8 cells and terminally differentiated osteocyte-like MLO-Y4 cells, respond to PEMF with changes in local factor production and reduced Cx43, suggesting decreased gap junctional signaling.

Gap junctions and fluid flow response in MC3T3-E1 cells.

In the current study, we examined the role of gap junctions in oscillatory fluid flow-induced changes in intracellular Ca(2+) concentration and prostaglandin release in osteoblastic cells. This work was completed in MC3T3-E1 cells with intact gap junctional communication as well as in MC3T3-E1 cells rendered communication deficient through expression of a dominant-negative connexin. Our results demonstrate that MC3T3-E1 cells with intact gap junctions respond to oscillatory fluid flow with significant increases in prostaglandin E(2) (PGE(2)) release, whereas cells with diminished gap junctional communication do not. Furthermore, we found that cytosolic Ca(2+) (Ca) response was unaltered by the disruption in gap junctional communication and was not significantly different among the cell lines. Thus our results suggest that gap junctions contribute to the PGE(2) but not to the Ca response to oscillatory fluid flow. These findings implicate gap junctional intercellular communication (GJIC) in bone cell ensemble responsiveness to oscillatory fluid flow and suggest that gap junctions and GJIC play a pivotal role in mechanotransduction mechanisms in bone.

Flow-induced calcium oscillations in rat osteoblasts are age, loading frequency, and shear stress dependent.

Bone adaptation to mechanical loading is dependent on age and the frequency and magnitude of loading. It is believed that load-induced fluid flow in the porous spaces of bone is an important signal that influences bone cell metabolism and bone adaptation. We used fluid flow-induced shear stress as a mechanical stimulus to study intracellular calcium (Ca) signaling in rat osteoblastic cells (ROB) isolated from young, mature, and old animals. Fluid flow produced higher magnitude and more abundant [Ca(2+)](i) oscillations than spontaneous oscillations, suggesting that flow-induced Ca signaling encodes a different cellular message than spontaneous oscillations. ROB from old rats showed less basal [Ca(2+)](i) activity and were less responsive to fluid flow. Cells were more responsive to 0.2 Hz than to 1 or 2 Hz and to 2 Pa than to 1 Pa. These data suggest that the frequency and magnitude of mechanical loading may be encoded by the percentage of cells displaying [Ca(2+)](i) oscillations but that the ability to transduce this information may be altered with age.

Oscillating fluid flow regulates cytosolic calcium concentration in bovine articular chondrocytes.

Mechanical loading is a well-known regulator of cartilage metabolism. This suggests that a loading-induced physical signal regulates chondrocyte behavior. Previous studies have focused on the effects of steady fluid flow on chondrocytes. In contrast to steady flow, loading induced fluid flow occurs in an oscillatory pattern and includes a reversal of flow direction with each loading event. In this study we examined the hypothesis that oscillating fluid flow increases cytosolic Ca2+ concentration ([Ca2+]i) in bovine articular chondrocytes (BAC) in a frequency-dependent manner and that the presence of serum affects this response. The aims of our study were to examine (1) whether BAC respond to physiologic oscillating fluid flow in vitro and compare these results to steady fluid flow, (2) the effect of fetal bovine serum on fluid flow responsiveness of BAC and (3) whether the response of BAC to fluid flow is flow rate and/or frequency dependent. [Ca2+]i was quantified using the fluorescent dye fura-2. BAC were exposed to steady, 0.5, 1, or 5 Hz sinusoidal oscillating fluid flow at five different flow rates in a parallel plate flow chamber. Our findings demonstrate that BAC respond to oscillating fluid flow with an increase in [Ca2+]i (p > 0.05), and furthermore, chondrocyte responsiveness to fluid flow increases with peak flow rate (p < 0.0001) and decreases with increasing frequencies (p < 0.0001). Finally, the presence of serum in the media potentiated the responsiveness of BAC to fluid flow (p < 0.0001). Our results suggest an important role for mechanical load-induced oscillating fluid flow in chondrocyte mechanotransduction.

Osteopontin gene regulation by oscillatory fluid flow via intracellular calcium mobilization and activation of mitogen-activated protein kinase in MC3T3-E1 osteoblasts.

Recently fluid flow has been shown to be a potent physical stimulus in the regulation of bone cell metabolism. However, most investigators have applied steady or pulsing flow profiles rather than oscillatory fluid flow, which occurs in vivo because of mechanical loading. Here oscillatory fluid flow was demonstrated to be a potentially important physical signal for loading-induced changes in bone cell metabolism. We selected three well known biological response variables including intracellular calcium (Ca(2+)i), mitogen-activated protein kinase (MAPK) activity, and osteopontin (OPN) mRNA levels to examine the response of MC3T3-E1 osteoblastic cells to oscillatory fluid flow with shear stresses ranging from 2 to -2 Newtons/m(2) at 1 Hz, which is in the range expected to occur during routine physical activities. Our results showed that within 1 min, oscillatory flow induced cell Ca(2+)i mobilization, whereas two MAPKs (ERK and p38) were activated over a 2-h time frame. However, there was no activation of JNK. Furthermore 2 h of oscillatory fluid flow increased steady-state OPN mRNA expression levels by approximately 4-fold, 24 h after exposure to fluid flow. The presence of both ERK and p38 inhibitors and thapsigargin completely abolished the effect of oscillatory flow on steady-state OPN mRNA levels. In addition, experiments using a variety of pharmacological agents suggest that oscillatory flow induces Ca(2+)i mobilization via the L-type voltage-operated calcium channel and the inositol 1,4,5-trisphosphate pathway.

Breast cancer metastatic potential correlates with a breakdown in homospecific and heterospecific gap junctional intercellular communication.

Breast cancer progresses toward increasingly malignant behavior in tumorigenic and metastatic stages. In the series of events in the metastatic stage, tumor cells leave the primary tumor in breast and travel to distant sites where they establish secondary tumors, or metastases. In this report, we demonstrate that cell-cell communication via gap junctions is restored in the metastatic human breast carcinoma cell line MDA-MB-435 when it is transfected with breast metastasis suppressor 1 (BRMS1) cDNA. Furthermore, the expression profile of connexins (Cxs), the protein subunits of gap junctions, changes. Specifically, the expression of BRMS1 in MDA-MB-435 cells increases Cx43 expression and reduces Cx32 expression, resulting in a gap junction phenotype more similar to normal breast tissue. Taken together, these results suggest that gap junctional communication and the Cx expression profile may contribute to the metastatic potential of these breast cancer cells.

Aged bone displays an increased responsiveness to low-intensity resistance exercise.

The ability of bone to respond to increased loading as a function of age was tested by use of three-point bending and histomorphometry. The hindlimbs of male Fischer 344 rats of three age groups (young = 4 mo, adult = 12 mo, and old = 22 mo; n = 10 per age group) were progressively overloaded by training the rats to depress a lever high on the side of a cage while wearing a weighted backpack. This squatlike movement required full extension of the hindlimbs. Exercised (Exer) rats performed 50 repetitions three times per week for 9 wk. Pack weight was gradually increased to 65% of body weight. Controls (n = 10 per age group) performed the same exercise without additional weight. Neither the mechanical properties of the femur nor histomorphometry in the proximal tibia was significantly affected in young or adult rats. However, old Exer rats were found to have significantly smaller medullary areas and a decreased trabecular spacing than their age-matched controls. These results suggest a greater sensitivity to increased loading in aged rats.

Connexin expression by alveolar epithelial cells is regulated by extracellular matrix.

Extracellular matrix (ECM) proteins promote attachment, spreading, and differentiation of cultured alveolar type II epithelial cells. The present studies address the hypothesis that the ECM also regulates expression and function of gap junction proteins, connexins, in this cell population. Expression of cellular fibronectin and connexin (Cx) 43 increase in parallel during early type II cell culture as Cx26 expression declines. Gap junction intercellular communication is established over the same interval. Cells plated on a preformed, type II cell-derived, fibronectin-rich ECM demonstrate accelerated formation of gap junction plaques and elevated gap junction intercellular communication. These effects are blocked by antibodies against fibronectin, which cause redistribution of Cx43 protein from the plasma membrane to the cytoplasm. Conversely, cells cultured on a laminin-rich ECM, Matrigel, express low levels of Cx43 but high levels of Cx26, reflecting both transcriptional and translational regulation. Cx26 and Cx43 thus demonstrate reciprocal regulation by ECM constituents.