Clare E. Yellowley

Differential effect of steady versus oscillating flow on bone cells

Loading induced fluid flow has recently been proposed as an important biophysical signal in bone mechanotransduction. Fluid flow resulting from activities which load the skeleton such as standing, locomotion, or postural muscle activity are predicted to be dynamic in nature and include a relatively small static component. However, in vitro fluid flow experiments with bone cells to date have been conducted using steady or pulsing flow profiles only. In this study we exposed osteoblast-like hFOB 1.19 cells (immortalized human fetal osteoblasts) to precisely controlled dynamic fluid flow profiles of saline supplemented with 2% fetal bovine serum while monitoring intracellular calcium concentration with the fluorescent dye fura-2. Applied flows included steady flow resulting in a wall shear stress of 2 N m(-2), oscillating flow (+/-2 Nm(-2)), and pulsing flow (0 to 2 N m(-2)). The dynamic flows were applied with sinusoidal profiles of 0.5, 1.0, and 2.0 Hz. We found that oscillating flow was a much less potent stimulator of bone cells than either steady or pulsing flow. Furthermore, a decrease in responsiveness with increasing frequency was observed for the dynamic flows. In both cases a reduction in responsiveness coincides with a reduction in the net fluid transport of the flow profile. Thus. these findings support the hypothesis that the response of bone cells to fluid flow is dependent on chemotransport effects.

Substrate deformation levels associated with routine physical activity are less stimulatory to bone cells relative to loading-induced oscillatory fluid flow

Although it is well accepted that bone tissue metabolism is regulated by external mechanical loads, it remains unclear to what load-induced physical signals bone cells respond. In this study, a novel computer-controlled stretch device and parallel plate flow chamber were employed to investigate cytosolic calcium (Ca2+i) mobilization in response to a range of dynamic substrate strain levels (0.1-10 percent, 1 Hz) and oscillating fluid flow (2 N/m2, 1 Hz). In addition, we quantified the effect of dynamic substrate strain and oscillating fluid flow on the expression of mRNA for the bone matrix protein osteopontin (OPN). Our data demonstrate that continuum strain levels observed for routine physical activities (< 0.5 percent) do not induce Ca2+i responses in osteoblastic cells in vitro. However, there was a significant increase in the number of responding cells at larger strain levels. Moreover, we found no change in osteopontin mRNA level in response to 0.5 percent strain at 1 Hz. In contrast, oscillating fluid flow predicted to occur in the lacunar-canalicular system due to routine physical activities (2 N/m2, 1 Hz) caused significant increases in both Ca2+i and OPN mRNA. These data suggest that, relative to fluid flow, substrate deformation may play less of a role in bone cell mechanotransduction associated with bone adaptation to routine loads.

Functional gap junctions between osteocytic and osteoblastic cells.

Morphological evidence shows that osteocytes, bone cells that exist enclosed within bone matrix, are connected to one another and to surface osteoblasts via gap junctions; however, it is unknown whether these gap junctions are functional. Using a newly established murine osteocytic cell line MLO‐Y4, we have examined functional gap junctional intercellular communication (GJIC) between osteocytic cells and between osteocytic and osteoblastic cells. In our hands, MLO‐Y4 cells express phenotypic characteristics of osteocytic cells including a stellate morphology, low alkaline phosphatase activity, and increased osteocalcin messenger RNA (mRNA) compared with osteoblastic cells. Northern and Western blot analysis revealed that MLO‐Y4 cells express abundant connexin 43 (Cx43) mRNA and protein, respectively. Lucifer yellow dye transferred from injected to adjacent cells suggesting that osteocytic cells were functionally coupled via gap junctions. Functional GJIC between osteocytic and osteoblastic (MC3T3‐E1) cells was determined by monitoring the passage of calcein dye between the two cell types using a double labeling technique. The ability of bone cells to communicate a mechanical signal was assessed by mechanically deforming the cell membrane of single MLO‐Y4 cells, cocultured with MC3T3‐E1 cells. Deformation induced calcium signals in MLO‐Y4 cells and those elicited in neighboring MC3T3‐E1 cells were monitored with the calcium sensitive dye Fura‐2. Our results suggest that osteocytic MLO‐Y4 cells express functional gap junctions most likely composed of Cx43. Furthermore, osteocytic and osteoblastic cells are functionally coupled to one another via gap junctions as shown by the ability of calcein to pass between cells and the ability of cells to communicate a mechanically induced calcium response. (J Bone Miner Res 2000;15:209–217)

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.

Inhibiting gap junctional intercellular communication alters expression of differentiation markers in osteoblastic cells.

Gap junctional intercellular communication (GJIC) may contribute to cellular differentiation. To examine this possibility in bone cells we examined markers of cellular differentiation, including alkaline phosphatase, osteocalcin, and osteopontin, in ROS17/2.8 cells (ROS), a rat osteoblastic cell line expressing phenotypic characteristics of fully differentiated osteoblasts. We utilized ROS rendered communication deficient either by stable transfection with antisense cDNA to connexin 43 (Cx43), the predominant gap junction protein in bone (RCx16 cells), or by overexpression of Cx45, a gap junction protein not normally expressed in ROS (ROS/Cx45 cells). Both RCx16 and ROS/Cx45 cells displayed reduced dye coupling and Cx43 protein expression relative to ROS, control transfectants, and ROS/Cx45tr, ROS cells expressing carboxylterminal truncated Cx45. Steady-state mRNA levels for osteocalcin as well as alkaline phosphatase activity, two markers of osteoblastic differentiation, were also reduced in poorly coupled RCx16 and ROS/Cx45 cells. On the other hand, steady-state mRNA levels for osteopontin increased slightly in RCx16 and ROS/Cx45 cells. These results suggest that GJIC at least partly contributes to the regulation of expression of markers of osteoblastic differentiation.

Mechanisms contributing to fluid-flow-induced Ca2+ mobilization in articular chondrocytes

We previously showed that fluid flow, which chondrocytes experience in vivo and which results in a variety of morphological and metabolic changes in cultured articular chondrocytes, can also stimulate a rise in intracellular calcium concentration ([Ca2+]i). However, the mechanism by which Ca2+ is mobilized in response to flow is unclear. In this study, we investigated the roles of intracellular Ca2+ stores, G‐proteins, and extracellular ATP in the flow‐induced Ca2+ response in bovine articular chondrocytes (BAC). Cells loaded with the Ca2+ sensitive dye Fura‐2 were exposed to steady flow at 34 ml/min (37 dynes/cm2) in a parallel plate flow chamber. Whereas ryanodine and caffeine had no effect, both neomycin and thapsigargin significantly decreased the Ca2+i response to flow, suggesting a role for Ca2+ store release, possibly through an inositol 1,4,5‐trisphosphate (IP3)‐dependent mechanism. Twenty‐four‐hour treatment with pertussis toxin also significantly decreased the response, suggesting that the mechanism may be G‐protein regulated. In addition, ATP release by chondrocytes does not appear to mediate the flow‐induced Ca2+ response because suramin, a P2 purinergic blocker, had no effect. These results suggest that BAC respond rapidly to changes in their mechanical environment, such as increased fluid flow, by a mechanism that involves IP3 stimulated Ca2+i release and G‐protein activation. J. Cell. Physiol. 180:402–408, 1999.

Effects of cell swelling on intracellular calcium and membrane currents in bovine articular chondrocytes

Chondrocytes experience a dynamic extracellular osmotic environment during normal joint loading when fluid is forced from the matrix, increasing the local proteoglycan concentration and therefore the ionic strength and osmolarity. To exist in such a challenging environment, chondrocytes must possess mechanisms by which cell volume can be regulated. In this study, we investigated the ability of bovine articular chondrocytes (BAC) to regulate cell volume during a hypo‐osmotic challenge. We also examined the effect of hypo‐osmotic stress on early signaling events including [Ca2+]i and membrane currents. Changes in cell volume were measured by monitoring the fluorescence of calcein‐loaded cells. [Ca2+]i was quantified using fura‐2, and membrane currents were recorded using patch clamp. BAC exhibited regulated volume decrease (RVD) when exposed to hypo‐osmotic saline which was inhibited by Gd3+. Swelling stimulated [Ca2+]i transients in BAC which were dependent on swelling magnitude. Gd3+, zero [Ca2+]o, and thapsigargin all attenuated the [Ca2+]i response, suggesting roles for Ca2+ influx through stretch activated channels, and Ca2+ release from intracellular stores. Inward and outward membrane currents significantly increased during cell swelling and were inhibited by Gd3+. These results indicate that RVD in BAC may involve [Ca2+]i and ion channel activation, both of which play pivotal roles in RVD in other cell types. These signaling pathways are also similar to those activated in chondrocytes subjected to other biophysical signals. It is possible, then, that these signaling events may also be involved in a mechanism by which mechanical loads are transduced into appropriate cellular responses by chondrocytes. J. Cell. Biochem. 86: 290–301, 2002.

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+).

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.

Intracellular Calcium Changes in Rat Aortic Smooth Muscle Cells in Response to Fluid Flow

AbstractVascular smooth muscle cells (VSM) are normally exposed to transmural fluid flow shear stresses, and after vascular injury, blood flow shear stresses are imposed upon them. Since Ca2+ is a ubiquitous intracellular signaling molecule, we examined the effects of fluid flow on intracellular Ca2+ concentration in rat aortic smooth muscle cells to assess VSM responsiveness to shear stress. Cells loaded with fura 2 were exposed to steady flow shear stress levels of 0.5–10.0 dyn/cm2 in a parallel-plate flow chamber. The percentage of cells displaying a rise in cytosolic Ca2+ ion concentration ([Ca2+]i) increased in response to increasing flow, but there was no effect of flow on the ([Ca2+]i) amplitude of responding cells. Addition of Gd3+ (10 μM) or thapsigargin (50 nM) significantly reduced the percentage of cells responding and the response amplitude, suggesting that influx of Ca2+ through ion channels and release from intracellular stores contribute to the rise in ([Ca2+]i) in response to flow. The addition of nifedipine (1 or 10 μM) or ryanodine (10 μM) also significantly reduced the response amplitude, further defining the role of ion channels and intracellular stores in the Ca2+ response.