TY  - STD
AU  - Díaz A, Féral J-P
PY  - 2011//
TI  - Evolutionary pathways among shallow and deep-sea echinoids of the genus Sterechinus in the Southern Ocean
BT  - Deep Sea Research Part II: Topical Studies in Oceanography
SP  - 205
EP  - 211
VL  - 58
IS  - 12
KW  - Sea urchins
KW  - Coastal zone
KW  - Deep water
KW  - Phylogeny
KW  - Biogeography
KW  - Evolutionary patterns
KW  - COI
KW  -
N2  - Antarctica is structured by a narrow and deep continental shelf that sustains a remarkable number of benthic species. The origin of these species and their affinities with the deep-sea fauna that borders the continent shelf are not clear. To date, two main hypotheses have been considered to account for the evolutionary connection between the faunas: (1) either shallow taxa moved down to deep waters (submergence) or (2) deep-sea taxa colonized the continental shelf (emergence). The regular sea urchin genus Sterechinus is a good model to explore the evolutionary relationships among these faunas because its five nominal species include Antarctic and Subantarctic distributions and different bathymetric ranges. Phylogenetic relationships and divergence times among Sterechinus species were established using the COI mitochondrial gene by assuming a molecular clock hypothesis. The results showed the existence of two genetically distinct main groups. The first corresponds exclusively to the shallow-water Antarctic species S. neumayeri, while the second includes all the other nominal species, either deep or shallow, Antarctic or Subantarctic. Within the latter group, S. dentifer specimens all formed a monophyletic cluster, slightly divergent from all other specimens, which were mixed in a second cluster that included S. agassizi from the continental shelf of Argentina, S. diadema from the Kerguelen Plateau and S. antarcticus from the deep Antarctic shelf. These results suggest that the deeper-water species S. dentifer and S. antarcticus are more closely related to Subantarctic species than to the shallow Antarctic species S. neumayeri. Thus, for this genus, neither the submergence nor emergence scenario explains the relationships between Antarctic and deep-sea benthos. At least in the Weddell quadrant, the observed genetic pattern suggests an initial separation between Antarctic and Subantarctic shallow species, and a much later colonization of deep water from the Subantarctic region, probably promoted by the geomorphology of the Scotia Arc.
SN  - 0967-0645
UR  - http://dx.doi.org/10.1016/j.dsr2.2010.10.012
N1  - exported from refbase (http://publi.ipev.fr/polar_references/show.php?record=1649), last updated on Tue, 30 Nov 1999 00:00:00 +0100
ID  - DiazA2011
ER  -