Serine racemase (SR) is a brain enzyme present in glial cells, where it isomerizes L-serine into D-serine that, in turn, diffuses and coactivates the N-methyl-D-aspartate receptor through the binding to the so-called "glycine site." We have developed a method for the slow expression of SR in a eukaryotic vector that permits the correct insertion of the prosthetic group into the active site, rendering functional SR with a K m toward L-serine of 4.8 mM. Divalent cations such as calcium or manganese were necessary for complete enzyme activity, whereas the presence of chelators such as EDTA completely inhibited the enzyme. Moreover, direct binding of calcium to SR was evidenced using 45 Ca 2؉ . Gel filtration of the recombinant SR revealed the protein to be in a dimer-tetramer equilibrium. The addition of EDTA to a calcium-saturated serine racemase evokes a profound conformational change, as monitored by both fluorescence and circular dichroism techniques. Fluorescence titration allowed us to calculate a binding constant for calcium of 6.2 M. Reagents that react with sulfhydryl groups, such as cystamine, were potent inhibitors of SR, in a clear reflection that one or more cysteine residues are important for enzyme activity. Additionally, 16 serine analogues were tested as a putative SR substrate or inhibitors. Significant inhibition was only observed for L-Ser-O-sulfate, L-cycloserine, and L-cysteine. Finally, activation of brain SR as a result of the changes in calcium concentration was studied in primary astrocytes. Treatment of astrocytes with the calcium ionophore A23187, as well as with compounds that augment the intracellular calcium levels such as glutamate or kainate led to an increase in the amount of D-serine present in the extracellular medium. These results suggest that there might be a glutamatergic-mediated regulation of SR activity by intracellular calcium concentration.D-Amino acids have been known for decades to be present in bacteria, where they are important constituents of peptidoglycan in the cell wall. Interestingly, recent improvement in the detection techniques has allowed the identification of significant levels of both D-serine (1-3) and D-aspartic acid (3, 4) in the nervous system of vertebrates. Snyder and co-workers (5, 6) have elegantly purified and subsequently cloned the cDNA for a novel enzyme responsible for the synthesis of D-serine in the brain and identified it as a 37-kDa pyridoxal phosphate-containing racemase present in astrocytes. These protoplasmic astrocytes typically ensheath synapses, strongly suggesting a role for D-serine in synaptic transmission. Serine racemase is highly enriched in the brain and co-localizes with D-serine according to immunohistochemical analysis (6). Additionally, D-serine is concentrated in regions enriched in N-methyl-Daspartate (NMDA) 1 receptors (i.e. highest in the forebrain), whereas the levels of the previously identified NMDA receptor coactivator, glycine, are lowest in this region (7,8). Remarkably, recent reports have also identified D-ser...
