N-Methyl-D-aspartate receptor subtype-selectivity of homoquinolinate: an electrophysiological and radioligand binding study using both native and recombinant receptors.

Homoquinolinate, a derivative of the endogenous NMDA agonist, quinolinate, has been shown to display higher affinity for Xenopus oocytes expressing NR2A- and NR2B-containing receptors, compared to NR2C- and NR2D-containing receptors, whilst autoradiographical experiments subsequently showed that [3H]homoquinolinate labelled a subpopulation of NMDA receptors in rat brain sections, with a similar distribution to NR2B-containing receptors. In this study, we have shown that NMDA-specific [3H]homoquinolinate binding to rat brain membranes comprised 44% of total binding with a Bmax value of 5.73 pmol/mg protein, which was inhibited by NMDA with Ki=0.867 micro m. However, NMDA-specific [3H]homoquinolinate binding was not observed for a number of human recombinant NMDA receptors investigated, suggesting that there are subtle differences between the binding sites of recombinant and native receptors. Electrophysiological experiments revealed that homoquinolinate activated human recombinant NR1a/NR2A, NR1a/NR2B and NR1a/NR2A/NR2B receptors with EC50 values of 25.2, 13.8 and 9.04 micro m, respectively, with intrinsic activities of 148, 93.3 and 125%, respectively, compared to glutamate (=100%). In contrast to an autoradiographical study, these radioligand binding and electrophysiological experiments suggest that homoquinolinate is not highly selective for NR2B-containing receptors.

Blood-brain barrier transport of kynurenines: implications for brain synthesis and metabolism.

To evaluate the potential contribution of circulating kynurenines to brain kynurenine pools, the rates of cerebral uptake and mechanisms of blood-brain barrier transport were determined for several kynurenine metabolites of tryptophan, including L-kynurenine (L-KYN), 3-hydroxykynurenine (3-HKYN), 3-hydroxyanthranilic acid (3-HANA), anthranilic acid (ANA), kynurenic acid (KYNA), and quinolinic acid (QUIN), in pentobarbital-anesthetized rats using an in situ brain perfusion technique. L-KYN was found to be taken up into brain at a significant rate [permeability-surface area product (PA) = 2-3 x 10(-3) ml/s/g] by the large neutral amino acid carrier (L-system) of the blood-brain barrier. Best-fit estimates of the Vmax and Km of saturable L-KYN transfer equalled 4.5 x 10(-4) mumol/s/g and 0.16 mumol/ml, respectively. The same carrier may also mediate the brain uptake of 3-HKYN as D,L-3-HKYN competitively inhibited the brain transfer of the large neutral amino acid L-leucine. For the other metabolites, uptake appeared mediated by passive diffusion. This occurred at a significant rate for ANA (PA, 0.7-1.6 x 10(-3) ml/s/g), and at far lower rates (PA, 2-7 x 10(-5) ml/s/g) for 3-HANA, KYNA, and QUIN. Transfer for KYNA, 3-HANA, and ANA also appeared to be limited by plasma protein binding. The results demonstrate the saturable transfer of L-KYN across the blood-brain barrier and suggest that circulating L-KYN, 3-HKYN, and ANA may each contribute significantly to respective cerebral pools. In contrast, QUIN, KYNA, and 3-HANA cross the blood-brain barrier poorly, and therefore are not expected to contribute significantly to brain pools under normal conditions.

Quinolinic acid concentrations in striatal extracellular fluid reach potentially neurotoxic levels following systemic L-tryptophan loading.

Following a systemic tryptophan load, striatal extracellular fluid levels of quinolinic acid in the rat were quantified using intracerebral microdialysis. After an intraperitoneal dose of L-tryptophan (250 mg/kg), quinolinic acid levels in striatal perfusates increased by 230 fold. Peak concentrations of quinolinic acid exceeded 10(-5)M, a concentration previously shown to be neurotoxic in vitro. These results indicate that quinolinic acid is markedly precursor responsive and that its concentration in striatal extracellular fluid may reach neurotoxic levels following an acute tryptophan load.