Distinct spatiotemporal distributions of the N‐Methyl‐D‐aspartate receptor channel subunit mRNAs in the mouse cervical cord

Abstract

The distribution of five N‐methyl‐D‐aspartate (NMDA) receptor channel subunit mRNAs in the mouse spinal cord from embryonic day 13 (E13) through postnatal day 56 (P56) was semiquantitatively examined at the cervical level via in situ hybridization with subunit‐specific oligonucleotide probes. Signals for the ξ1 subunit mRNA were restricted to the most ventral portion of the spinal cord during embryonic stages. They extended to all laminae of the spinal cord except for the lamina 2 (substantia gelatinosa) during postnatal development. A wide expression of the ϵ2 subunit mRNA was found in the spinal gray matter from E13 through neonatal stages, but the signals became restricted to the lamina 2 by P21. No significant signals for the ϵ3 subunit mRNA were detected in the spinal cord at any developmental stages. The ϵ4 subunit mRNA was distributed widely in the spinal cord during embryonic and early postnatal periods but decreased nearly to background levels by P21. In contrast to the differential distribution of the ϵ subunit mRNAs, the ξ1 subunit mRNA was found ubiquitously at each developmental stage examined. These findings suggest that the molecular organization of the ϵ subunits may be difference between the dorsal horn and the remaining regions in the mature spinal cord, which provides a molecular basis for functional heterogeneity of the NMDA receptor channel. Moreover, this spatial heterogeneity might be generated through drastic alterations in the subunit composition of the channel complex during spinal cord development.