| First Author | Lo W | Year | 1998 |
| Journal | Vision Res | Volume | 38 |
| Issue | 10 | Pages | 1399-410 |
| PubMed ID | 9667007 | Mgi Jnum | J:49921 |
| Mgi Id | MGI:1289586 | Doi | 10.1016/s0042-6989(98)00008-x |
| Citation | Lo W, et al. (1998) Ionotropic glutamate receptors in the retina: moving from molecules to circuits. Vision Res 38(10):1399-410 |
| abstractText | The cloning of the glutamate-gated ion channels of the brain revealed an unexpected level of complexity: there are many different genes that encode distinct subunits of the receptor/channel complex and an even larger number of possible receptor subunit combinations. Many--nearly all--of these gene products are expressed in the retina, and the questions that we face today are: how are they used and why are there so many? Answers to these questions will be found at several levels. At the level of transcription, we have learned that different sets of subunits are expressed by different retinal neurons. Little is known about the transcriptional control of these genes, so it remains to be determined whether these patterns of expression reflect the need for different gene products in different retinal neurons or whether these patterns of expression reflect the functional constraints of gene expression. Another level of complexity is caused by alternative splicing, and here we report that at least four and possibly all eight of the different NMDAR1 transcripts are present in the mouse retina. The consequences of this alternative splicing are poorly understood, but antibodies directed against the two different possible C-termini of NMDAR1 label many of the same cell types. It is possible that these different splice variants are combined to generate the channels. While immunohistochemistry provides us with a glimpse of the subunit proteins, much remains to be learned about their half-life within a retinal cell, their intracellular trafficking, their regulation at the synapse, and the proteins associated with their cytoplasmic domains. An approach we have taken towards studying the dynamic properties of receptor subunits has been to fuse them to the cDNA encoding the jellyfish Green Fluorescent Protein. This makes it possible to follow functional subunits in transfected cells over time and to begin to measure the mobility of the protein. |
