Impact of cellular microenvironment and mechanical perturbation on calcium signalling in meniscus fibrochondrocytes.

Mechanical signals regulate a multitude of cell functions and ultimately govern fibrous tissue growth, maintenance and repair. Such mechanotransduction processes often involve modulation of intracellular calcium concentration ([Ca2+]i). However, most studies interrogate these responses in cells in simplified culture systems, thereby removing potentially important inputs from the native extracellular microenvironment. The objective of this study was to test the hypothesis that the intracellular calcium response of meniscus fibrochondrocytes (MFCs) is dependent on both the microenvironmental context in which this perturbation is applied and on the tensile deformation. Using a custom micro-mechanical tester mounted on a confocal microscope, intracellular calcium activity in MFCs in response to incremental tissue strains (0, 3, 6 and 9 %) was monitored in situ (i.e., in the native tissues) on MFC-seeded aligned scaffolds and MFC-seeded silicone membranes. The [Ca2+]i regulation by MFCs within the native meniscus tissue microenvironment was considerably different from [Ca2+]i regulation by MFCs on either aligned nanofibrous scaffolds or flat silicone membranes. Additionally, increasing levels of tensile deformation resulted in a greater number of responding cells, both in situ and in vitro, while having no effects on temporal characteristics of [Ca2+]i signalling. Collectively, these findings have significant implications for mechanobiology of load-bearing fibrous tissues and their responses to injury and degeneration. In addition, from a tissue engineering perspective, the findings establish cellular benchmarks for maturing engineered constructs, where native tissue-like calcium mechano-regulation may be an important outcome parameter to achieve mechanical functionality comparable to native tissue.

Skeletal phenotype of mice with a null mutation in Cav 1.3 L-type calcium channel.

This study aimed to understand the role of Cav1.3, one of the four L-type voltage sensitive calcium channels (VSCC) alpha(1) subunits, in the skeletal response to mechanical loading and intermittent PTH treatment. The Cav1.3 mRNA is expressed in osteoblasts. The Cav1.3 mRNA level in male wild type mice is higher than those in female. Loss of Cav1.3 resulted in a smaller skeleton in male mice as indicated by significantly lower body weight, less bone mineral content and smaller cross-sectional area of femoral midshaft. However, the osteogenic response to mechanical loading of the ulna was normal in Cav1.3(-/-) compared to the normal control mice. Male mice Cav1.3(-/-) were then treated daily with PTH at a dose of 40 microg/kg. A 6-week course of intermittent PTH treatment enhanced bone mineral content and mechanical strength equally in wild type control and Cav1.3 null mice. We also found that Cav1.2 subunit significantly increases in the absence of Cav1.3 gene. In conclusion, Cav1.3 is involved in bone metabolism, especially in male mice. Cav1.3 does not mediate osteoblast response to mechanical loading and PTH. Our data suggest that Cav1.1 and Cav1.2 subunits may substitute for Cav1.3 to maintain bone response to mechanical loading.

Parathyroid hormone enhances fluid shear-induced [Ca2+]i signaling in osteoblastic cells through activation of mechanosensitive and voltage-sensitive Ca2+ channels.

Osteoblasts respond to both fluid shear and parathyroid hormone (PTH) with a rapid increase in intracellular calcium concentration ([Ca2+]i). Because both stimuli modulate the kinetics of the mechanosensitive cation channel (MSCC), we postulated PTH would enhance the [Ca2+]i response to fluid shear by increasing the sensitivity of MSCCs. After a 3-minute preflow at 1 dyne/cm2, MC3T3-E1 cells were subjected to various levels of shear and changes in [Ca2+]i were assessed using Fura-2. Pretreatment with 50 nM bovine PTH(1-34) [bPTH(1-34)] significantly enhanced the shear magnitude-dependent increase in [Ca2+]i. Gadolinium (Gd3+), an MSCC blocker, significantly inhibited the mean peak [Ca2+]i response to shear and shear + bPTH(1-34). Nifedipine (Nif), an L-type voltage-sensitive Ca2+ channel (VSCC) blocker, also significantly reduced the [Ca2+]i response to shear + bPTH(1-34), but not to shear alone, suggesting VSCC activation plays an interactive role in the action of these stimuli together. Activation of either the protein kinase C (PKC) or protein kinase A (PKA) pathways with specific agonists indicated that PKC activation did not alter the Ca2+ response to shear, whereas PKA activation significantly increased the [Ca2+]i response to lower magnitudes of shear. bPTH(1-34), which activates both pathways, induced the greatest [Ca2+]i response at each level of shear, suggesting an interaction of these pathways in this response. These data indicate that PTH significantly enhances the [Ca2+]i response to shear primarily via PKA modulation of the MSCC and VSCC.

Human osteoblast-like cells respond to mechanical strain with increased bone matrix protein production independent of hormonal regulation.

Exposure of osteosarcoma cell lines to chronic intermittent strain increases the activity of mechano-sensitive cation (SA-cat) channels. The impact of mechano-transduction on osteoblast function has not been well studied. We analyzed the expression and production of bone matrix proteins in human osteoblast-like osteosarcoma cells, OHS-4, in response to chronic intermittent mechanical strain. The OHS-4 cells exhibit type I collagen production, 1,25-Dihydroxyvitamin D-inducible osteocalcin, and mineralization of the extracellular matrix. The matrix protein message level was determined from total RNA isolated from cells exposed to 1-4 days of chronic intermittent strain. Northern analysis for type I collagen indicated that strain increased collagen message after 48 h. Immunofluorescent labeling of type I collagen demonstrated that secretion was also enhanced with mechanical strain. Osteopontin message levels were increased several-fold by the application of mechanical load in the absence of vitamin D, and the two stimuli together produced an additive effect. Osteocalcin secretion was also increased with cyclic strain. Osteocalcin levels were not detectable in vitamin D-untreated control cells. However, after 4 days of induced load, significant levels of osteocalcin were observed in the medium. With vitamin D present, osteocalcin levels were 4 times higher in the medium of strained cells compared to nonstrained controls. We conclude that mechanical strain of osteoblast-like cells is sufficient to increase the transcription and secretion of matrix proteins via mechano-transduction without hormonal induction.

A corticosterone metabolite produced by A6 (toad kidney) cells in culture: identification and effects on Na+ transport.

A6 cells form typical tight epithelia when grown in culture on permeable supports and exhibit active Na+ transport [short circuit current (Isc)], which is stimulated by aldosterone and corticosterone. Previous studies demonstrated nuclear binding of polar corticosterone metabolites produced by the cells. This study was performed to determine whether sufficient quantities of the metabolite(s) are released into the medium of A6 cells for identification and to test for agonist activity on active Na+ transport. Cells were incubated in [3H]corticosterone (10(-8)-10(-4) M) for 24 h. Approximately 25-35% of the radiolabel, recovered in ethyl acetate extracts of medium, chromatographed on reverse phase HPLC as a single peak more polar than corticosterone. This derivative cochromatographed with 6 beta-hydroxycorticosterone (6 beta-OH-corticosterone) on HPLC and normal phase high performance TLC. Mass spectroscopy of 6 beta-OH-corticosterone and the unknown yielded 10 identical molecular ions, including the molecular ion with a mass to charge ratio of 362 corresponding to the mol wt of 6 beta-OH-corticosterone stimulated Isc in A6 epithelia with a time course typical of a steroid and an EC50 of 10(-6) M. The Isc induced by 6 beta-OH-corticosterone was equivalent to net Na+ flux, indicating active Na+ transport stimulation. At maximum effective concentrations of corticosteroids, 6 beta-OH-corticosterone plus aldosterone induced a greater Isc stimulation than aldosterone alone, suggesting that at least a portion of the effect of 6 beta-OH-corticosterone is mediated by a steroidal pathway other than that used by aldosterone. Also, corticosterone produced twice the Isc increase produced by aldosterone. Thus, 6 beta-OH-corticosterone may contribute to the enhanced corticosterone effect on Isc compared to aldosterone alone.

Parathyroid hormone activation of stretch-activated cation channels in osteosarcoma cells (UMR-106.01).

Cell-attached patches of membrane of osteoblast-like cells UMR-106.01 respond to bath application of parathyroid hormone (PTH) with an increase in the average activity, as well as the single channel conductance, of a stretch-activated non-selective cation channel. Correlations with whole cell membrane potential and conductance changes are considered.

(1-(3-(Phenothiazin-10-yl)propyl)-4-piperidinyl)phenylmethanones, a novel class of long-acting neuroleptic agents.

In previous studies the phenyl-4-piperidinylmethanone moiety was shown to be a neuroleptic pharmacophore. A short series of [1-[3-(phenothiazin-10-yl)propyl]-4-piperidinyl]phenylmethanones was prepared and tested for neuroleptic activity using the blockade of d-amphetamine lethality in aggregated mice and suppression of conditioned avoidance behavior as the end points. Most compounds were shown to be potent neuroleptic agents and two were found to possess a long duration of action.

Calcium signals and calcium channels in osteoblastic cells.

Calcium (Ca2+) channels are present in non-excitable as well as in excitable cells. In bone cells of the osteoblast lineage, Ca2+ channels play fundamental roles in cellular responses to external stimuli including both mechanical forces and hormonal signals. They are also proposed to modulate paracrine signaling between bone-forming osteoblasts and bone-resorbing osteoclasts at local sites of bone remodeling. Calcium signals are characterized by transient increases in intracellular Ca2+ levels that are associated with activation of intracellular signaling pathways that control cell behavior and phenotype, including patterns of gene expression. Development of Ca2+ signals is a tightly regulated cellular process that involves the concerted actions of plasma membrane and intracellular Ca2+ channels, along with Ca2+ pumps and exchangers. This review summarizes the current state of knowledge concerning the structure, function, and role of Ca2+ channels and Ca2+ signals in bone cells, focusing on the osteoblast.

Insulin increases sodium (Na+) channel density in A6 epithelia: implications for expression of hypertension.

Essential or primary hypertension is a multifactorial disease that is expressed as a result of complex interactions between genes and environmental influences. Several mutations in many different proteins are associated with expression of hypertension, including abnormalities in the epithelial sodium channel (ENaC) found in absorptive organs (i.e., distal colon, distal tubule of the nephron). Some of these mutations result in structural and/or functional alterations in ENaC-mediated Na+ entry in epithelia responsible for fluid and electrolyte balance and are associated with expression of hypertension. Studies support the notion that there is a link between ENaC and hypertension of both the monogenic (single gene mutation) and primary or essential type (a multifactorial disease). Alterations of other aspects of the environment of absorptive cells (e.g., hyperinsulinemia, hyperaldosteronemia, high plasma cortisol, high plasma Na+) have also been shown to elicit hyperabsorption of Na+ via ENaC and therefore could contribute significantly to expression of hypertension in people with intermediate phenotypes. This article describes an initial study in which the effects of an environmental factor, extracellular levels of insulin, on ENaC were examined in a normal kidney cell model. Electrophysiologic techniques revealed that ENaC density rapidly increased in response to addition of insulin to the basolateral bath. This autoregulatory recruitment of Na+ total channel density masked a slight decrease in open channel probability. Insulin's effect on ENaC function and implications on fluid and electrolyte balance and expression of primary hypertension is discussed.

Effect of aldosterone on 86Rb fluxes in cultured kidney cells (A6).

This study was designed to evaluate the relative contributions of hormone induced changes in active and passive K+ transport in an epithelial cell line in continuous culture derived from toad kidney (A6) using 86Rb as a tracer for measuring unidirectional K+ fluxes. The effects of 24 h exposure to aldosterone (A) and aldosterone plus insulin (A+I) on unidirectional K+ fluxes were evaluated under short-circuited conditions and under open circuit conditions. In epithelia exposed to A, a small but significant amount of active K+ secretion was found, although it was not significantly greater than in control epithelia. The bidirectional fluxes in both A and A+I treated epithelia, under short-circuited conditions, increased by a similar amount over control values indicating an increase in apparent permeability of passive transepithelial K+ transport. Under open circuit conditions, A stimulated net K+ transport by about 5-fold over controls. The increase in K+ secretion produced by A under open circuit conditions could be explained by the combined effects of an increase in transepithelial K+ permeability and an increase in the transepithelial electrical potential difference (PD). The presence of I produced no additional effects to that of A on K+ transport under the conditions used in this study. It is concluded that the substantial increase in K+ secretion induced in A6 cells by 24 h exposure to A is primarily passive in nature. It is possible that the changes in both PD and transepithelial K+ permeability, which can account for the observed increase in K+ secretion, are secondary to the stimulation of active Na+ transport.

Sodium transport and distribution of electrolytes in frog skin.

The objective of this study on frog skin was to examine correlations between transepidermal active Na-transport and intracellular [Na]c, [K]c, [Cl]c homeostasis. Isolated, whole skins, and "split skins" were used in measurements of short-circuit current (SCC) and open skin potential (PD). Water and ion contents were estimated on split skins. Absolute [Na]c and [K]c varied over the range of 18 to 46, and 113 to 80 mM, respectively (Figure 7), but a complementary relationship existed between Na and K, such that [Na]c + [K]c remained approximately equal to 129 mM. Average values for [Na]c and [K]c were approximately equal to 31 and approximately equal to 96 mM, respectively. [Cl]c remained constant at approximately equal to 38 mM. This complementary relationship does not seem to be an artifact, caused by collagenase, used in the preparation of split skins. Whole skins and split skins in Ringer's solution, when treated with fluoroacetate (FAc), ouabain (Ou), or vanadate (Va) over wide ranges of concentrations, showed that FAc greatly depressed the SCC and the PD, without changing [Na]c, [K]c, [Cl]c. FAc acted only from the corium side of the skin. The decreasing SCC remained a Na-current, as in control skins. By comparison, such a separation of cellular functions could not be established with Ou, or Va. These inhibitors either affected SCC, PD, and cellular ion concentration, or they had no effect on any of these parameters. The complementary relationship between [Na]c and [K]c, with [Cl]c remaining again at approximately equal to 38 mM, was also found in tissues exposed to inhibitors. These results indicate that transcellular active Na transport and electrolyte homeostasis are not always rigidly coupled, suggesting that these processes may not be uniformly distributed within the epithelial cells, or among the interconnected cell layers of the frog skin epidermis.

Transduction of mechanical strain in bone.

One physiologic consequence of extended periods of weightlessness is the rapid loss of bone mass associated with skeletal unloading. Conversely, mechanical loading has been shown to increase bone formation and stimulate osteoblastic function. The mechanisms underlying mechanotransduction, or how the osteoblast senses and converts biophysical stimuli into cellular responses has yet to be determined. For non-innervated mechanosensitive cells like the osteoblast, mechanotransduction can be divided into four distinct phases: 1) mechanocoupling, or the characteristics of the mechanical force applied to the osteoblast, 2) biochemical coupling, or the mechanism through which mechanical strain is transduced into a cellular biochemical signal, 3) transmission of signal from sensor to effector cell and 4) the effector cell response. This review examines the characteristics of the mechanical strain encountered by osteoblasts, possible biochemical coupling mechanisms, and how the osteoblast responds to mechanical strain. Differences in osteoblastic responses to mechanical strain are discussed in relation to the types of strain encountered and the possible transduction pathways involved.

Chronic, intermittent loading alters mechanosensitive channel characteristics in osteoblast-like cells.

The effects of chronic, intermittent strain on the mechanosensitive cation (SA-cat) channels in UMR-106.01 osteoblast-like osteosarcoma cells were studied using patch-clamp techniques. Chronically strained cells demonstrated significantly larger increases in whole cell conductance when subjected to additional mechanical strain than nonstrained controls (69.0 +/- 15.1 vs. 14.1 +/- 3.1%; P < 0.001). This increase could be blocked by the SA-cat channel inhibitor, gadolinium, and corresponded to a three- to fivefold increase in SA-cat channel activity. Chronic strain increased the number of open channels in response to stretch and induced spontaneous SA-cat channel activity in 33% of the patches of strained cells. Graded increases in negative patch pressure demonstrated that SA-cat channels in chronically strained cells were activated at significantly lower levels of mechanical perturbation than nonstrained controls. These data suggest that chronic, cyclic strain reduces the activation threshold of the SA-cat channel and further strengthen our hypothesis that this channel may act as a mechanotransducer for the activation of bone remodeling by physical strain.

Parathyroid hormone modulates the response of osteoblast-like cells to mechanical stimulation.

Mechanical loading stimulates many responses in bone and osteoblasts associated with osteogenesis. Since loading and parathyroid hormone (PTH) activate similar signaling pathways in osteoblasts, we postulate that PTH can potentiate the effects of mechanical stimulation. Using an in vitro four-point bending device, we found that expression of COX-2, the inducible isoform of cyclooxygenase, was dependent on fluid forces generated across the culture plate, but not physiologic levels of strain in MC3T3-E1 osteoblast-like cells. Addition of 50 nM PTH during loading increased COX-2 expression at both subthreshold and threshold levels of fluid forces compared with either stimuli alone. We also demonstrated that application of fluid shear to MC3T3-E1 cells induced a rapid increase in [Ca(2+)](i). Although PTH did not significantly change [Ca(2+)](i) levels, flow and PTH did produce a significantly greater [Ca(2+)](i) response and increased the number of responding cells than is found in fluid shear alone. The [Ca(2+)](i) response to these stimuli was significantly decreased when the mechanosensitive channel inhibitor, gadolinium, was present. These studies indicate that PTH increases the cellular responses of osteoblasts to mechanical loading. Furthermore, this response may be mediated by alterations in [Ca(2+)](i) by modulating the mechanosensitive channel.