Ontogenic Profile and Synaptic Distribution of GluN3 Proteins in the Rat Brain and Hippocampal Neurons.

N-Methyl-D-aspartate receptors are localized to synaptic and extrasynaptic sites of dendritic spines and shafts. Here, the ontogenic profiles of GluN3A and GluN3B subunits in the rat brain were determined. A developmental switch from GluN3A to GluN3B proteins was detected within the first two postnatal weeks of crude synaptosomes prepared from forebrain and midbrain. Further fractionation of crude synaptosomes revealed the preferential localization of GluN3B to synaptic regions from P7 onwards. Immunolabeling and biochemical fractionation of rat P7 cultured hippocampal neurons showed that GluN3B was predominantly at synaptic sites. Unlike GluN2A and GluN2B, both GluN3 subunits were mostly associated with peripheral components of the postsynaptic density (PSD) rather than its core. When considering the non-PSD fraction, the overall extrasynaptic/synaptic spatial profile of GluN3B differed from GluN3A. Heterologous expression of GluN3B with GluN1 in HEK293FT cells could not be co-immunoprecipitated with PSD-95 unless co-expressed with a PSD-95-interacting GluN2 subunit, suggesting that anchoring of GluN3B at synaptic sites may require co-assembly with another scaffold-interacting NMDAR subunit.

Contractile and vasorelaxant effects of hydrogen sulfide and its biosynthesis in the human internal mammary artery.

This study aimed to test these hypotheses: cystathionine gamma-lyase (CSE) is expressed in a human artery, it generates hydrogen sulfide (H(2)S), and H(2)S relaxes a human artery. H(2)S is produced endogenously in rat arteries from cysteine by CSE. Endogenously produced H(2)S dilates rat resistance arteries. Although CSE is expressed in rat arteries, its presence in human blood vessels has not been described. In this study, we showed that both CSE mRNA, determined by reverse transcription-polymerase chain reaction, and CSE protein, determined by Western blotting, apparently occur in the human internal mammary artery (internal thoracic artery). Artery homogenates converted cysteine to H(2)S, and the H(2)S production was inhibited by dl-propargylglycine, an inhibitor of CSE. We also showed that H(2)S relaxes phenylephrine-precontracted human internal mammary artery at higher concentrations but produces contraction at low concentrations. The latter contractions are stronger in acetylcholine-prerelaxed arteries, suggesting inhibition of nitric oxide action. The relaxation is partially blocked by glibenclamide, an inhibitor of K(ATP) channels. The present results indicate that CSE protein is expressed in human arteries, that human arteries synthesize H(2)S, and that higher concentrations of H(2)S relax human arteries, in part by opening K(ATP) channels. Low concentrations of H(2)S contract the human internal mammary artery, possibly by reacting with nitric oxide to form an inactive nitrosothiol. The possibility that CSE, and the H(2)S it generates, together play a physiological role in regulating the diameter of arteries in humans, as has been demonstrated in rats, should be considered.