Filigorgia schoutedeni ( Stiasny, 1939 ) Sánchez, 2007

Filigorgia schoutedeni ( Stiasny, 1939) View in CoL com. nov.

Leptogorgia schoutedeni Stiasny 1939, p 106 View in CoL .

Leptogorgia schoutedeni: Grasshoff 1988, p 115 View in CoL .

Why are surface layer sclerites so important?

Since surface sclerites modify colony flexion by preventing compressibility of the outer cortex when they contact each other and help the colony to resist drag forces and flow ( Lewis and Von Wallis 1991), a characteristic on which natural selection can act. Their interaction with the environment has produced a great array of forms and these structures are more variable than polyp or axial sheath sclerites ( Sánchez et al. 2003b; Sánchez 2005). It is important to note, however, that the function of surface sclerites can be homoplasious and similar trends exist in many genera (e.g. Figure 12E, G View Figure 12 ). Nonetheless, surface sclerites can be helpful for supra familial classification and provide a better understanding of octocoral phylogeny in general.

It has been demonstrated that colonial characters such as branching and overall colony form are highly homoplasious, providing multiple analogous forms within the family Gorgoniidae , which should not be considered as characters for classification (e.g. whip like, sea fan, pinnate, etc.). For example, Bayer (1953) first proposed convergent evolution for gorgonian colony architectures such as sea fans ( Pacifigorgia spp. and Gorgonia spp. , Figure 2 View Figure 2 ) and sea leaves ( Phycogorgia spp. and Phyllogorgia spp. , Figure 2 View Figure 2 ). Bayer’s hypothesis for sea fans has been corroborated with mitochondrial ( Sánchez et al. 2003b; Sánchez 2004) and nuclear DNA sequences ( Aguilar and Sánchez 2007a, 2007b). Pinnate morphologies such as Pseudopterogorgia spp. and Pinnigorgia spp. seemed to have evolved their branching morphologies separately (e.g. Figure 1 View Figure 1 ). Surface layer sclerites under the resolution of SEM provided a good character to differentiate gorgoniid clades with very similar external characters.

The molecular contribution

The corroboration of Filigorgia as a genus apart from Leptogorgia is another example where recent molecular results have improved our understanding of some morphological characters ( Fukami et al. 2004). The validation of the genus Filigorgia is also supported with previous molecular studies. Mitochondrial DNA sequences from the mut-S homolog gene (MSH1) show additional classification problems within the Gorgoniidae (A. LePard and S. France, personal communication). Although focusing on Leptogorgia , they found that supposed Leptogorgia ‘‘outgroups’’ such as Pseudopterogorgia , Pacifigorgia , and Eugorgia were intermingled with various clades of Leptogorgia , which clearly show that some of the African fauna from Leptogorgia sensu lato are not reciprocally monophyletic. Williams and Lindo (1997) provided a detailed comparison of spindles of Leptogorgia spp. with several gorgoniid genera showing that scaphoid sclerites are not the best character to differentiate gorgoniid genera due to their high similarity, particularly with Indo-Pacific species of Pseudopterogorgia . Although it was not a goal of this paper, it was clearly noticed that Pacific and Atlantic Pseudopterogorgia spp. surface sclerites were not homologous (e.g. Figures 3A View Figure 3 versus 4E), and deserve further study.

Finally, it is important to note that some genera assigned to the Gorgoniidae need careful revision (hopefully both taxonomical and molecular) in order to be unambiguously assigned to this family, such as in the case of Hicksonella and Rumphella ( Grasshoff and Alderslade 1997) , as well as Adelogorgia and Eunicella , whose sclerites are not likely homologous to the species presented here. In addition, there are a number of plexaurid genera such as Swiftia ( Goldberg 2001) and Plexaurella that, with recent molecular analyses ( Sánchez et al. 2003b; Wirshing et al. 2005; McFadden et al. 2006), have been found to resemble some gorgoniids.