TY - JOUR
T1 - The non-visual opsins
T2 - eighteen in the ancestor of vertebrates, astonishing increase in ray-finned fish, and loss in amniotes
AU - Beaudry, Felix Emile Gastonguay
AU - Iwanicki, Tom W.
AU - Mariluz, Bertha Ruth Zelada
AU - Darnet, Sylvain
AU - Brinkmann, Henner
AU - Schneider, Patricia
AU - Taylor, John Stewart
N1 - Publisher Copyright:
© 2017 Wiley Periodicals, Inc.
PY - 2017/11
Y1 - 2017/11
N2 - Non-visual opsins were discovered in the early 1990s. These genes play roles in circadian rhythm in mammals, seasonal reproduction in birds, light avoidance in amphibian larvae, and neural development in fish. However, the interpretation of such studies and the success of future work are compromised by the fact that non-visual opsin repertoires have not been properly characterized in any of these lineages. Here, we show that non-visual opsins from tetrapods and ray-finned fish are distributed among 18 monophyletic subfamilies. An amphibian sequence occurs in every subfamily, whereas mammalian orthologs occur in only seven. Species in the major ray-finned fish lineages, Holostei, Osteoglossomorpha, Otomorpha, Protacanthopterygii, and Neoteleostei, have large numbers of non-visual opsins (22–32 genes) as a result of gene duplication events including, but not limited to, the teleost genome duplication (TGD). In contrast to visual opsins, where lineage-specific duplication is common, the ray-finned fish non-visual opsin repertoire appears to have stabilized shortly after the TGD event and consequently even distantly related species have repertoires of similar size and composition. Most non-visual opsins have been named without the benefit of a phylogenetic perspective and, accordingly, major revisions are proposed.
AB - Non-visual opsins were discovered in the early 1990s. These genes play roles in circadian rhythm in mammals, seasonal reproduction in birds, light avoidance in amphibian larvae, and neural development in fish. However, the interpretation of such studies and the success of future work are compromised by the fact that non-visual opsin repertoires have not been properly characterized in any of these lineages. Here, we show that non-visual opsins from tetrapods and ray-finned fish are distributed among 18 monophyletic subfamilies. An amphibian sequence occurs in every subfamily, whereas mammalian orthologs occur in only seven. Species in the major ray-finned fish lineages, Holostei, Osteoglossomorpha, Otomorpha, Protacanthopterygii, and Neoteleostei, have large numbers of non-visual opsins (22–32 genes) as a result of gene duplication events including, but not limited to, the teleost genome duplication (TGD). In contrast to visual opsins, where lineage-specific duplication is common, the ray-finned fish non-visual opsin repertoire appears to have stabilized shortly after the TGD event and consequently even distantly related species have repertoires of similar size and composition. Most non-visual opsins have been named without the benefit of a phylogenetic perspective and, accordingly, major revisions are proposed.
UR - http://www.scopus.com/inward/record.url?scp=85032861236&partnerID=8YFLogxK
U2 - 10.1002/jez.b.22773
DO - 10.1002/jez.b.22773
M3 - Article
C2 - 29059507
AN - SCOPUS:85032861236
SN - 1552-5007
VL - 328
SP - 685
EP - 696
JO - Journal of Experimental Zoology Part B: Molecular and Developmental Evolution
JF - Journal of Experimental Zoology Part B: Molecular and Developmental Evolution
IS - 7
ER -