Mechanically regulated expression of a neural glutamate transporter in bone: a role for excitatory amino acids as osteotropic agents?

Without habitual exercise, bone is lost from the skeleton. Interactions between the effects of loading of bone and other osteotropic influences are thought to regulate bone mass. In an attempt to identify potential targets for therapeutic manipulation of bone mass, we used differential RNA display to investigate early changes in osteocyte gene expression following mechanical loading of rat bone in vivo. One gene found to be down-regulated by loading had high homology to a glutamate/ aspartate transporter (GLAST) previously identified only the mammalian CNS. RT-PCR analysis using primers targeted to the coding region of the published GLAST sequence amplified identical products from bone and brain (but not a range of other tissues). The amplicons were sequenced and found to be identical to the published CNS GLAST sequence. Northern analysis confirmed expression of GLAST mRNA in bone and brain, but not other tissues. In situ hybridization localized GLAST mRNA expression in rat bone to osteoblasts and osteocytes. A GLAST antibody localized high levels of protein expression to osteoblasts, and newly incorporated osteocytes. Interestingly, older osteocytes also expressed detectable levels of GLAST. Another neural glutamate transporter, GLT-1 was immunolocalized to the pericellular region of mononuclear bone marrow cells, while a further antibody to the EAAC-1 transporter failed to bind to bone cells. Five days after loading, GLAST protein expression was undetectable in osteocytes of loaded bone but present in control nonloaded sections, confirming the downregulation detected by differential display. On quiescent periosteal surfaces, GLAST expression was almost absent, while on surfaces where loading had induced cellular proliferation and bone formation, GLAST protein expression was elevated. In the CNS, the expression of glutamate transporters on neuronal membranes is associated with reuptake of released neurotransmitters at synapses, where they have a role in the termination of transmitter action. In this study, we describe for the first time, the expression of GLAST (and GLT-1) in bone, raising the possibility that excitatory amino acids may have a role in paracrine intercellular communication in bone. Manipulation of bone cell function by moderators of glutamate action could therefore provide novel treatments for bone diseases such as osteoporosis.

Constitutive in vivo mRNA expression by osteocytes of beta-actin, osteocalcin, connexin-43, IGF-I, c-fos and c-jun, but not TNF-alpha nor tartrate-resistant acid phosphatase.

Osteocytes have been proposed to be the cells primarily responsible for sensing the effects of mechanical loading in bone. Osteocytes respond to loading in vivo, and have been shown to express osteotropic agents and their receptors, and cell/matrix adhesion molecules in vitro, but the functional significance of such findings is not clear. One obstacle to increased understanding of the role of osteocytes in the regulation of bone mass is that the cells are not easily accessible for study. In situ studies are difficult, and although it is possible to extract and culture osteocytes from neonatal bones, the responses of such cells might be very different from those in older bones in situ. We have developed a technique to investigate osteocyte gene expression in vivo, using the reverse transcriptase linked polymerase chain reaction (PCR), and have shown that they express mRNA for beta-actin (beta-ACT), osteocalcin (OC), connexin-43 (Cx43), insulin-like growth factor I (IGF-I), c-fos and c-jun, but not tumor necrosis factor alpha (TNF-alpha) or tartrate-resistant acid phosphatase (TRAP). The principle behind the method is that after removal of the periosteum, tangential cryostat sections of a tubular bone contain RNA only from osteocytes and a very small number of endothelial cells as long as the marrow cavity is not broached. Using this method, we have investigated gene expression in cells from rat ulnar cortical bone under forming and resorbing bone surfaces. In addition, we have investigated the effect on gene expression of mechanical loading which, if repeated daily, initiates new bone formation on quiescent or resorbing surfaces. Although the expression of the genes we have studied in osteocytes is different from those expressed by the periosteal surfaces overlying the cortex, we have not detected loading-related changes in osteocyte gene expression in any cortical bones. This may be because of the extreme sensitivity of the PCR technique which can only resolve large differences in expression. The use of quantitative methods in the future may allow demonstration of regulated gene expression in osteocytes.

Inhibition of bone resorption and stimulation of formation by mechanical loading of the modeling rat ulna in vivo.

During normal growth of the rat ulna, bone is resorbed from the medial periosteal surface. This occurs as part of the modeling process by which the bone achieves its adult shape. By attaching strain gauges to the ulnae of rats in vivo, we measured the strains imposed on that surface of the bone during normal locomotion. We then applied mechanical loads to the ulnae of other rats in vivo for 6 consecutive days, inducing strains approximately double those we had measured. Fluorochromes were given on the 1st and 5th days. The histology of the medial ulnar periosteal surface was correlated with the amount of fluorochrome incorporation and tartrate resistant acid phosphatase (TRAP) activity in serial sections. In the nonloaded ulnae, the surfaces were lined with bone resorbing cells. Corresponding areas of the loaded bones were lined with osteoid and osteoblasts. There was insignificant label incorporation in the nonloaded bones but almost continuous label incorporation in the corresponding regions of the loaded bones, which was significantly different from the nonloaded bones. TRAP activity of the periosteal cells in the loaded bones was significantly less than in the nonloaded limbs. It is widely acknowledged that loading induces bone formation, and this implies that it also has the ability to inhibit resorption. However, to date there has been little direct evidence for the inhibition of resorption in vivo by mechanical loading. The changes we have observed are similar to the sequence of cellular events that occur during the reversal phase of bone remodeling, in which osteoclastic resorption ceases and osteoblasts are recruited and begin formation. This model may help increase understanding of that process.