In the central nervous system Na(+)-dependent glutamate transporters bind extracellular glutamate and transport it into cells surrounding the synapse, terminating excitatory signals. These glutamate transporters also function as ion channels. The glutamate transporter, GLAST-1, is expressed in the plasma membrane of osteoblasts and osteocytes and is the same molecular weight as in brain. Thus in bone cells GLAST-1 may transport glutamate or operate as a glutamate gated ion channel. A splice variant, GLAST-1a, is also expressed in bone. Hydropathy and Western blot analysis suggest GLAST-1a adopts a reversed orientation within the cell membrane. Sodium and potassium ion gradients drive glutamate transport but glycosylation, oxidation and phosphorylation modulate transporter activity. Reversal of GLAST-1a would alter these modifications varying its transport activity under the same ionic gradients. The significance of GLAST-1/1a in bone in vivo is unknown. GLAST-1 knockout mice show no major disruption of skeletal development but have not been investigated in detail. Glutamate affects both osteoclast and osteoblast biology and the regulation of GLAST-1 by mechanical loading in bone suggests a role for glutamate transporters in osteogenesis. Differential regulation and modification of GLAST variants may provide an intricate mechanism controlling extracellular glutamate levels and thus its downstream signalling effects in bone.