Electrophysiological responses of osteoclasts to hormones

Electrophysiological measurements were carried out on osteoclasts in vitro. Such isolated osteoclasts are able to resorb bone in vitro and contract in response to calcitonin (CT). Our measurements show that individual osteoclasts respond to CT with a significant transient hyperpolarization of membrane potential. Application of parathyroid hormone (PTH) and dibutyryl cAMP produced a transient hyperpolarization in some osteoclasts. Measurements on an osteoblastlike line (ROS 17/2.8) showed a sustained hyperpolarizing response to CT, which is similar to but smaller than the hyperpolarizing response to PTH and dibutyryl cAMP in this and some other osteoblastlike lines. In contrast to osteoblastlike cells, the osteoclasts have no long term membrane potential response to CT, to PTH, or to dibutyryl cAMP. These results show that there are distinct differences between osteoclasts and osteoblasts in their ion transport responses to hormones.     

Xenopus neural crest cell migration in an applied electrical field

Xenopus neural crest cells migrated toward the cathode in an applied electrical field of 10 mV/mm or greater. This behavior was observed in relatively isolated cells, as well as in groups of neural crest cells; however, the velocity of directed migration usually declined when a cell made close contact with other cells. Melanocytes with a full complement of evenly distributed melanosomes did not migrate of their own accord, but could be distorted and pulled by unpigmented neural crest cells. Incompletely differentiated melanocytes and melanocytes with aggregated melanosomes displayed the same behavior as undifferentiated neural crest cells, that is, migration toward the cathode. An electrical field of 10 mV/mm corresponded to a voltage drop of less than 1 mV across the diameter of each cell; the outer epithelium of Xenopus embryos drives an endogenous transembryonic current that may produce voltage gradients of nearly this magnitude within high-resistance regions of the embryo. We, therefore, propose that electrical current produced by the skin battery present in these embryos may act as a vector to guide neural crest migration.     

Critical fields in cell fusion and dielectrophoresis

It is increasingly recognized that exposure to electrical fields can reversibly increase the electrical permeability and conductivity of the cellular membrane. It is therefore worthwhile to determine under what circumstances the critical fields capable of affecting the cellular membrane can be reached. We have evaluated the field intensities E and the gradients of E² in the neighborhood of the more common field electrode shapes, the sphere-sphere and cylinder-cylinder electrodes, and put these in terms of the values useful for the practical electro-fusion and dielectrophoresis (DEP) of cells. The calculations were performed using the charge-image technique. From this it was observed that gross errors (underestimations of up to 1000-fold) of the field would be made if neglect of the electrode polarization were made as in simple electrostatic calculation. The dielectric forces (in terms of (E)²) show interesting spatial character.The electrical breakdown of cellular membranes affects the exchange of information and materials between the cell and its environment, and can be used to fuse cells of the same type or of differing types. It is moreover of importance in handling cells during DEP while obtaining their spectral characteristics or in cell-sorting. It is expected that the results here will aid in the more proper use of electrical fields for such ends.     

Calcium Ion Flow Permeates Cells through SOCs to Promote Cathode-Directed Galvanotaxis

Sensing and responding to endogenous electrical fields are important abilities for cells engaged in processes such as embryogenesis, regeneration and wound healing. Many types of cultured cells have been induced to migrate directionally within electrical fields in vitro using a process known as galvanotaxis. The underlying mechanism by which cells sense electrical fields is unknown. In this study, we assembled a polydimethylsiloxane (PDMS) galvanotaxis system and found that mouse fibroblasts and human prostate cancer PC3 cells migrated to the cathode. By comparing the effects of a pulsed direct current, a constant direct current and an anion-exchange membrane on the directed migration of mouse fibroblasts, we found that these cells responded to the ionic flow in the electrical fields. Taken together, the observed effects of the calcium content of the medium, the function of the store-operated calcium channels (SOCs) and the intracellular calcium content on galvanotaxis indicated that calcium ionic flow from the anode to the cathode within the culture medium permeated the cells through SOCs at the drift velocity, promoting migration toward the cathode. The RTK-PI3K pathway was involved in this process, but the ROCK and MAPK pathways were not. PC3 cells and mouse fibroblasts utilized the same mechanism of galvanotaxis. Together, these results indicated that the signaling pathway responsible for cathode-directed cellular galvanotaxis involved calcium ionic flow from the anode to the cathode within the culture medium, which permeated the cells through SOCs, causing cytoskeletal reorganization via PI3K signaling.     

RANKL induces formation of avian osteoclasts from macrophages but not from macrophage polykaryons

We have shown that chick macrophages express RANK at their surface and human RANKL (hRANKL) triggers the formation of osteoclasts able to degrade dentine. As described for mammalian osteoclasts, hRANKL also stimulates the resorbing activity of chick bone-derived osteoclasts. In other hands, in culture, chick macrophages spontaneously form polykaryons sharing most of the osteoclast markers but unable to resorb bone. Since both bone-resorbing osteoclasts and macrophage polykaryons found in inflammatory tissues are multinucleated cells deriving from the fusion of macrophages, we examined whether macrophage polykaryons could be induced toward bone-resorbing osteoclasts. Long-term exposure of macrophage polykaryons to hRANKL failed to activate any resorbing activity, indicating that although deriving from the same precursors macrophage polykaryons and osteoclasts are independent cell types and polykaryons are not immature osteoclasts.     

In-vivo imaging of the fracture healing in medaka revealed two types of osteoclasts before and after the callus formation by osteoblasts

The fracture healing research, which has been performed in mammalian models not only for clinical application but also for bone metabolism, revealed that generally osteoblasts are induced to enter the fracture site before the induction of osteoclasts for bone remodeling. However, it remains unknown how and where osteoclasts and osteoblasts are induced, because it is difficult to observe osteoclasts and osteoblasts in a living animal. To answer these questions, we developed a new fracture healing model by using medaka. We fractured one side of lepidotrichia in a caudal fin ray without injuring the other soft tissues including blood vessels. Using the transgenic medaka in which osteoclasts and osteoblasts were visualized by GFP and DsRed, respectively, we found that two different types of functional osteoclasts were induced before and after osteoblast callus formation. The early-induced osteoclasts resorbed the bone fragments and the late-induced osteoclasts remodeled the callus. Both types of osteoclasts were induced near the surface on the blood vessels, while osteoblasts migrated from adjacent fin ray. Transmission electron microscopy revealed that no significant ruffled border and clear zone were observed in early-induced osteoclasts, whereas the late-induced osteoclasts had clear zones but did not have the typical ruffled border. In the remodeling of the callus, the expression of cox2 mRNA was up-regulated at the fracture site around vessels, and the inhibition of Cox2 impaired the induction of the late-induced osteoclasts, resulting in abnormal fracture healing. Finally, our developed medaka fracture healing model brings a new insight into the molecular mechanism for controlling cellular behaviors during the fracture healing.     

A quantitative cytochemical investigation of osteoclasts and multinucleate giant cells

Summary Quantitative cytochemical, immunocytochemical, autoradiographic and electron cytochemical investigations have been used to compare osteoclasts with multinucleate giant cells that had been freshly obtained from the same animal. The levels of -acid galactosidase activity, the DNA in individual nuclei and the cellular protein content were similar in both cell types. However, osteoclasts generally possessed greater acid phosphatase and NADH dehydrogenase activity but lower levels of fluoride-inhibited non-specific esterase activity than multinucleate giant cells. The acid phosphatase activity in multinucleate giant cells was completely inhibited by 100 mM tartrate, but in osteoclasts only a 20% reduction in activity was observed. Formation of multinucleate giant cells in a bone microenvironment (thin bone slices) did not increase their content of tartrate-resistant acid phosphatase activity. Moreover, in osteoclasts, endogenous peroxidase activity was undetectable but present in several granules within the cytoplasm of multinucleate giant cells. Osteoclasts and multinucleate giant cells displayed a similar microtubular distribution, but calcitonin, which induced rearrangement of microtubules and cellular contraction in osteoclasts, had no effect on multinucleate giant cells. Thus, these investigations reveal both similarities and differences between these two syncytia and support the hypothesis that osteoclasts and multinucleate giant cells are related. Possibly osteoclasts arise from monocyte progenitors before commitment to a macrophage lineage has occurred.     

Electrically regulated cellular morphological and cytoskeletal changes on an optically transparent electrode

Electrically regulated morphological and cytoskeletal changes of HeLa cells were studied on an optically transparent electrode (OTE), on which potential-applied surface cellular behavior and morphogenesis were easily observed. Upon application of a potential, HeLa cells in an OTE exhibited remarkable morphological changes above +0.5 V (vs. Ag/AgCl) and below 0 V. At each potential in this potential range, change in F-actin distribution was observed using a fluorescent probe (rhodamine phalloidin). These results suggest that an electrical field induces a subcellular cytoskeletal change. Electrostimulation of cells with OTE can be a valuable strategy for the manipulation of cultured human cells.     

Osteoimmunology: shared mechanisms and crosstalk between the immune and bone systems

Osteoimmunology is an interdisciplinary research field focused on the molecular understanding of the interplay between the immune and skeletal systems. Although osteoimmunology started with the study of the immune regulation of osteoclasts, its scope has been extended to encompass a wide range of molecular and cellular interactions, including those between osteoblasts and osteoclasts, lymphocytes and osteoclasts, and osteoblasts and haematopoietic cells. Therefore, the two systems should be understood to be integrated and operating in the context of the 'osteoimmune' system, a heuristic concept that provides not only a framework for obtaining new insights by basic research, but also a scientific basis for the discovery of novel treatments for diseases related to both systems.     

Electrical effects on the proliferation of living HeLa cells cultured on optically transparent electrode surface.

Low d.c. potential application induced changes of cellular morphology and growth of living cells on a potential-controlled electrode. At a potential range higher than +0.7 V (vs. Ag/AgCl), serious electric effects on cell viability, membrane permeability, and cytoskeletal morphology of HeLa cells were observed. On the other hand, at lower than +0.5 V no effect was observed. At the boundary potential range between +0.5 V to +0.7 V, where HeLa cells were cultured on the potential-controlled optically transparent In2O3 electrode (OTE) surface, intriguing effects on HeLa cells appeared. At this potential range, where HeLa cells cultured on a potential-applied OTE, all the cells were alive accompanying morphological change. The morphology of HeLa cells returned to their normal spindle shape, when potential application to the electrode was cut off. At a potential of +0.65 V, cell proliferation ratio of cultured cell on an electrode was about one-fifth of that on a non-controlled electrode. These results suggest that low d.c. electrical effects induce significant change in cellular morphology and function.     

Osteoblastic regulation of osteoclast survival: effect of calcitriol

Throughout life, bone is remodelled in a dynamic process which results in a balance between bone formation by osteoblasts and bone resorption by osteoclasts. It is now clearly established that osteoblasts/stromal cells are crucial for differentiation of osteoclasts, through a mechanism involving cell-to-cell contact. However, the possible involvement of osteoblasts and stromal cells in the survival of osteoclasts has not yet been clearly demonstrated. In this study, we assessed the influence of cellular microenvironment, especially osteoblasts, on the osteoclast survival. Our results have shown significant differences in osteoclastic survival between unfractionated bone cells and pure osteoclasts. Furthermore, we have shown that addition of 1.25(OH)2D3 to unfractionated bone cells resulted in a dose-dependent increase in osteoclast survival. Finally, we have shown that a conditioned medium obtained from rat osteoblastic cells cultured with calcitriol was able to increase significantly survival of pure osteoclasts. Taken together, these results strongly suggest that osteoblastic cells present in the bone microenvironment might play a role in the osteoclastic survival by producing soluble factor which modulate osteoclast apoptosis.     

The effect of marrow secretome and culture environment on the rate of metastatic breast cancer cell migration in two and three dimensions

Metastasis is responsible for over 90% of cancer-related deaths, and bone is the most common site for breast cancer metastasis. Metastatic breast cancer cells home to trabecular bone, which contains hematopoietic and stromal lineage cells in the marrow. As such, it is crucial to understand whether bone or marrow cells enhance breast cancer cell migration toward the tissue. To this end, we quantified the migration of MDA-MB-231 cells toward human bone in two- and three-dimensional (3D) environments. First, we found that the cancer cells cultured on tissue culture plastic migrated toward intact trabecular bone explants at a higher rate than toward marrow-deficient bone or devitalized bone. Leptin was more abundant in conditioned media from the cocultures with intact explants, while higher levels of IL-1β, IL-6, and TNFα were detected in cultures with both intact bone and cancer cells. We further verified that the cancer cells migrated into bone marrow using a bioreactor culture system. Finally, we studied migration toward bone in 3D gelatin. Migration speed did not depend on stiffness of this homogeneous gel, but many more dendritic-shaped cancer cells oriented and migrated toward bone in stiffer gels than softer gels, suggesting a coupling between matrix mechanics and chemotactic signals.     

Photosynthetic reaction center-functionalized electrodes for photo-bioelectrochemical cells

During the last few years, intensive research efforts have been directed toward the application of several highly efficient light-harvesting photosynthetic proteins, including reaction centers (RCs), photosystem I (PSI), and photosystem II (PSII), as key components in the light-triggered generation of fuels or electrical power. This review highlights recent advances for the nano-engineering of photo-bioelectrochemical cells through the assembly of the photosynthetic proteins on electrode surfaces. Various strategies to immobilize the photosynthetic complexes on conductive surfaces and different methodologies to electrically wire them with the electrode supports are presented. The different photoelectrochemical systems exhibit a wide range of photocurrent intensities and power outputs that sharply depend on the nano-engineering strategy and the electroactive components. Such cells are promising candidates for a future production of biologically-driven solar power.     

Electrotaxis of lung cancer cells in a multiple-electric-field chip

We report a microfluidic cell culture chip that was used for long-term electrotaxis study on a microscope. The cellular response under three different electric field strengths was studied in a single channel microfluidic chip. Electric field (EF) inside the microchamber was numerically simulated and compared to the measured value. Lung cancer cell lines with high and weak metastasis potential, CL1–5 and CL1–0, respectively, were used to demonstrate the function of the multi-field chip (MFC). The two cell lines exhibited greatly different response under the applied EF of E = 74–375 mV/mm. CL1–5 cells migrated toward the anode while CL1–0 cells did not show obvious response. Under the applied EF, cell orientation was observed accompanying the cell migration. Judging from the different temporal responses of the orientation and the migration, it is proposed that the two EF-induced responses may involve different signaling pathways.     

Effects of electromagnetic stimulation on the functional responsiveness of isolated rat osteoclasts

We report the effects of pulsed electromagnetic fields (PEMFs) on the responsiveness of osteoclasts to cellular, hormonal, and ionic signals. Osteoclasts isolated from neonatal rat long bones were dispersed onto either slices of devitalised cortical bone (for the measurement of resorptive activity) or glass coverslips (for the determination of the cytosolic free Ca²⁺ concentration, [Ca²⁺]). Osteoclasts were also cocultured on bone with osteoblastlike, UMR-106 cells. Bone resorption was quantitated by scanning electron microscopy and computer-assisted morphometry. PEMF application to osteoblast–osteoclast cocultures for 18 hr resulted in a twofold stimulation of bone resorption. In contrast, resorption by isolated osteoclasts remained unchanged in the presence of PEMFs, suggesting that osteoblasts were necessary for the PEMF-induced resorption simulation seen in osteoblast–osteoclast cocultures. Furthermore, the potent inhibitory action of the hormone calcitonin on bone resorption was unaffected by PEMF application. However, PEMFs completely reversed another quite distinct action of calcitonin on the osteoclast: its potent inhibitory effect on the activation of the divalent cation-sensing (or Ca²⁺) receptor. For these experiments, we made fura 2-based measurements of cytosolic [Ca²⁺] in single osteoclasts in response to the application of a known Ca²⁺ receptor agonist, Ni²⁺. We first confirmed that activation of the osteoclast Ca²⁺ receptor by Ni²⁺ (5 mM) resulted in a characteristic monophasic elevation of cytosolic [Ca²⁺]. As shown previously, this response was attenuated strongly by calcitonin at concentrations between 0.03 and 3 nM but remained intact in response to PEMFs. PEMF application, however, prevented the inhibitory effect of calcitonin on Ni²⁺-induced cytosolic Ca²⁺ elevation. This suggested that the fields disrupted the interaction between the calcitonin and Ca²⁺ receptor systems. In conclusion, we have shown that electromagnetic fields stimulate bone resorption through an action on the osteoblast and, by abolishing the inhibitory effects of calcitonin, also restore the responsiveness of osteoclasts to divalent cations. J. Cell. Physiol. 176:537–544, 1998. © 1998 Wiley-Liss, Inc.     

Neural crest cell galvanotaxis: new data and a novel approach to the analysis of both galvanotaxis and chemotaxis

The galvanotaxis response of neural crest cells that had migrated out of the neural tube of a 56-hr-old quail embryo onto glass coverslips was observed using time-lapse video microscopy. These cells exhibit a track velocity of about 7 microns/min and actively translocate toward the negative pole of an imposed DC electric field. This nonrandom migration could be detected for fields as low as 7 mV/mm (0.4 mV/cell length). We find that this directional migration is independent of the speed of migration and have generated a rather simple mathematical equation that fits these data. We find that the number of cells that translocate at a given angle, phi, with respect to the field is given by the equation N(phi) = exp(a0 + a1cos phi), where a1 is linearly proportional to the electric field strength for fields less than 390 mV/mm with a constant of proportionality equal to KG, the galvanotaxis constant. We show that KG = (150 mV/mm)-1, and at this field strength the cellular response is approximately half maximal. This approach to cellular translocation data analysis is generalizable to other directed movements such as chemotaxis and allows the direct comparison of different types of directed movements This analysis requires that the response of every cell, rather than averages of cellular responses, is reported. Once an equation for N(phi) is derived, several characteristics of the cellular response can be determined. Specifically, we describe 1) the critical field strength (390 mV/mm) below which the cellular response exhibits a simple, linear dependence on field strength (for larger field strengths, an inhibitory constant can be used to fit the data, suggesting that larger field strengths influence a second cellular target that inhibits the first); and 2) the amount of information the cell must obtain in order to generate the observed asymmetry in the translocation distribution (for a field strength of 100 mV/mm, 0.3 bits of information is required).     

Studies on the alignment of fibroblasts in uniform applied electrical fields

Uniform electrical fields have been applied to human gingival fibroblasts by means of uniform ionic currents passed through a thin chamber. Cells were observed to align in fields between 0.1 and 1.5 V/mm but did not display directed motion toward the anode or the cathode of the chamber. Statistical analysis of directional data was used to distinguish threshold levels of orientation at low field intensities, to quantify the dependence of alignment on time and field intensity, and to analyze differences between alignment of cells treated with the Ca2+ transport modifiers A23187, verapamil, and lanthanum. Alignment occurred at a steady rate and was dependent in a saturating fashion on field strength. The Ca2+ ionophore A23187 had a significant inhibitory effect on cell alignment in applied electrical fields; however, the Ca2+ channel blockers lanthanum and verapamil did not have a significant effect on alignment.     

Cellular specificity of the cure for neonatal osteopetrosis in the ia rat

Osteopetrosis in the ia/ia rat is known to be the result of reduced bone resorption due to abnormal osteoclasts. Studies in this mutant have shown that mononuclear cells from normal littermates could cure the skeletal sclerosis and result in the formation of normal osteoclasts when transplanted into ia/ia rats. This investigation was pursued in an attempt to determine the cellular source of this cure by transplanting various populations of cells from 21-day-old normal rats to unrelated newborn ia/ia recipients. The effects of treatment were evaluated radiographically and by measuring the size of the tibial marrow cavity. The cellular suspensions that were effective in curing the disease were the Ficoll-Hypaque isolate of spleen, bone marrow, and newborn livers. The Ficoll-Hypaque isolates of lymph node, thymus, and blood, and the adherent pool of peritoneal cells and splenic cells did not produce a cure in the ia/ia recipients. These results suggest that the cellular source of the cure is a stem cell. This conclusion is further substantiated by the finding that Thy 1.1 antigen (a stem cell marker in the rat) is expressed on a majority of the cells from the donor sources that affected a cure.