Phylogenetic analysis of the vertebrate excitatory/neutral amino acid transporter (SLC1/EAAT) family reveals lineage specific subfamilies
- Authors
- Gesemann, M., Lesslauer, A., Maurer, C.M., Schönthaler, H.B., and Neuhauss, S.C.
- ID
- ZDB-PUB-110413-2
- Date
- 2010
- Source
- BMC Evolutionary Biology 10: 117 (Journal)
- Registered Authors
- Lesslauer, Annegret, Neuhauss, Stephan, Schönthaler, Helia Berrit, vom Berg, Colette
- Keywords
- none
- MeSH Terms
-
- Amino Acid Transport Systems, Neutral/genetics*
- Animals
- Evolution, Molecular*
- Humans
- Phylogeny*
- Receptors, Somatostatin/genetics
- Vertebrates/genetics*
- PubMed
- 20429920 Full text @ BMC Evol. Biol.
BACKGROUND: The composition and expression of vertebrate gene families is shaped by species specific gene loss in combination with a number of gene and genome duplication events (R1, R2 in all vertebrates, R3 in teleosts) and depends on the ecological and evolutionary context. In this study we analyzed the evolutionary history of the solute carrier 1 (SLC1) gene family. These genes are supposed to be under strong selective pressure (purifying selection) due to their important role in the timely removal of glutamate at the synapse.
RESULTS: In a genomic survey where we manually annotated and analyzing sequences from more than 300 SLC1 genes (from more than 40 vertebrate species), we found evidence for an interesting evolutionary history of this gene family. While human and mouse genomes contain 7 SLC1 genes, in prototheria, sauropsida, and amphibia genomes up to 9 and in actinopterygii up to 13 SLC1 genes are present. While some of the additional slc1 genes in ray-finned fishes originated from R3, the increased number of SLC1 genes in prototheria, sauropsida, and amphibia genomes originates from specific genes retained in these lineages.Phylogenetic comparison and microsynteny analyses of the SLC1 genes indicate, that theria genomes evidently lost several SLC1 genes still present in the other lineage. The genes lost in theria group into two new subfamilies of the slc1 gene family which we named slc1a8/eaat6 and slc1a9/eaat7.
CONCLUSIONS: The phylogeny of the SLC1/EAAT gene family demonstrates how multiple genome reorganization and duplication events can influence the number of active genes. Inactivation and preservation of specific SLC1 genes led to the complete loss of two subfamilies in extant theria, while other vertebrates have retained at least one member of two newly identified SLC1 subfamilies.