ALBERT

Description: Cellular Ca 2+ homeostasis is tightly regulated and is pivotal to life. Inositol 1,4,5-trisphosphate receptors (IP 3 Rs) and ryanodine receptors (RyRs) are the major ion channels that regulate Ca 2+ release from intracellular stores. Although these channels have been extensively investigated in multicellular organisms, an appreciation of their evolution and the biology of orthologs in unicellular organisms is largely lacking. Extensive phylogenetic analyses reveal that the IP 3 R gene superfamily is ancient and diverged into two subfamilies, IP 3 R-A and IP 3 R-B/RyR, at the dawn of Opisthokonta. IP 3 R-B/RyR further diversified into IP 3 R-B and RyR at the stem of Filozoa. Subsequent evolution and speciation of Holozoa is associated with duplication of IP 3 R-A and RyR genes, and loss of IP 3 R-B in the vertebrate lineages. To gain insight into the properties of IP 3 R important for the challenges of multicellularity, the IP 3 R-A and IP 3 R-B family orthologs were cloned from Capsaspora owczarzaki, a close unicellular relative to Metazoa (designated as CO.IP 3 R-A and CO.IP 3 R-B). Both proteins were targeted to the endoplasmic reticulum. However, CO.IP 3 R-A, but strikingly not CO.IP 3 R-B, bound IP 3 , exhibited robust Ca 2+ release activity and associated with mammalian IP 3 Rs. These data indicate strongly that CO.IP 3 R-A as an exemplar of ancestral IP 3 R-A orthologs forms bona fide IP 3 -gated channels. Notably, however, CO.IP 3 R-A appears not to be regulated by Ca 2+ , ATP or Protein kinase A-phosphorylation. Collectively, our findings explore the origin, conservation, and diversification of IP 3 R gene families and provide insight into the functionality of ancestral IP 3 Rs and the added specialization of these proteins in Metazoa.