The effect of mechanical deformation on the distribution of potassium ions across the cell membrane of sutural cells

Ion channels in osteoblasts: A story of two intracellular organelles

Recent advances have highlighted a synchronous coordination of osteoblast and osteoclast activity, whereby, the osteoblast collates all signals applied to the bone and activates osteoclastic resorption. The resorption of the bone and its matrix then releases growth factors held within the matrix (bone morphogenetic proteins, insulin-like growth factors and transforming growth factors) which then stimulate the osteoblast to lay down new osteoid. In healthy adults there is a balance between bone deposition and bone loss and there is no net gain or loss, and the amount of calcium (Ca2+) ingested in the diet is equal to that which is excreted. In the early stages of life, the emphasis is on bone building and more Ca2+ is retained from the diet and more bone deposited as the skeleton matures. As we age, and, in particular in postmenopausal women, the osteoclastic activity outweighs the bone deposition and the patient loses bone becoming osteoporotic. The focus of the work reported here was to identify and dissect the various cytosolic intracellular signalling pathways within osteoblasts and establish the importance of each under different physiological conditions. In brief, two basic signalling pathways exist; one is linked with a seven transmembrane spanning protein and specific receptors for ligands (the G protein linked pathways) and one pathway is linked with protein phosphorylation especially of the tyrosine kinases. In general, G protein activity is associated with endocrine ligands such as parathyroid hormone (PTH) and (calcitonin has been linked with tyrosine kinase activity) tyrosine kinase activity is linked with adhesion of osteoblasts and recognition of the substrate to which they are attached. Our specific areas of interest are the ways in which Ca2+ activity within the cell is modified and used as a signal for further activation and possibly differential gene activation.

Bone as an ion exchange system: evidence for a link between mechanotransduction and metabolic needs

To detect whether the mutual interaction occurring between the osteocytes-bone lining cells system (OBLCS) and the bone extracellular fluid (BECF) is affected by load through a modification of the BECF-extracellular fluid (ECF; systemic extracellular fluid) gradient, mice metatarsal bones immersed in ECF were subjected ex vivo to a 2-min cyclic axial load of different amplitudes and frequencies. The electric (ionic) currents at the bone surface were measured by a vibrating probe after having exposed BECF to ECF through a transcortical hole. The application of different loads and different frequencies increased the ionic current in a dose-dependent manner. The postload current density subsequently decayed following an exponential pattern. Postload increment's amplitude and decay were dependent on bone viability. Dummy and static loads did not induce current density modifications. Because BECF is perturbed by loading, it is conceivable that OBLCS tends to restore BECF preload conditions by controlling ion fluxes at the bone-plasma interface to fulfill metabolic needs. Because the electric current reflects the integrated activity of OBLCS, its evaluation in transgenic mice engineered to possess genetic lesions in channels or matrix constituents could be helpful in the characterization of the mechanical and metabolic functions of bone.

Decreased mineralization and increased calcium release in isolated fetal mouse long bones under near weightlessness

Mechanical loading plays an important role in the development and maintenance of skeletal tissues. Subnormal mechanical stress as a result of bed rest, immobilization, but also in spaceflight, results in a decreased bone mass and disuse osteoporosis, whereas supranormal loads upon extremities result in an increased bone mass. In this first in vitro experiment with complete fetal mouse cartilaginous long bones, cultured under microgravity conditions, we studied growth, glucose utilization, collagen synthesis, and mineral metabolism, during a 4-day culture period in space. There was no change in percent length increase and collagen synthesis under microgravity compared with in-flight 1x gravity. Glucose utilization and mineralization were decreased under microgravity. In addition, mineral resorption, as measured by 45Ca release, was increased. These data suggest that weightlessness has modulating effects on skeletal tissue cells. Loss of bone during spaceflight could be the result of both impaired mineralization as well as increased resorption.