ASTERINIDAE, Gray, 1840

THE ASTERINIDAE View in CoL , GANERIIDAE, AND SOLASTERIDAE

The Asterinidae View in CoL has occupied a controversial position in the history of asteroid classification, having been placed in Spinulosida View in CoL in Fisher (1911) and others (e.g. Sladen, 1889) but later independently reassigned to the Valvatida View in CoL by Blake (1987) and Gale (1987b). Classification and revision within the Asterinidae View in CoL has been a constant source of activity (e.g. A.M. Clark, 1983; O’Loughlin & Waters, 2004), but the distinctive morphology of asterinids has generally suggested a derived and potentially monophyletic assemblage with only limited subdivision (e.g. the Tremasterinae Sladen, 1889 View in CoL ; Anseropodinae Fisher, 1906; summary in Spencer & Wright, 1966). Waters et al. (2004a) provided the first molecular phylogenetic treatment of the Asterinidae View in CoL that included taxa beyond Asterina View in CoL + Patiriella View in CoL , using mitochondrial COI, 12S, and 16S rRNA data, primarily from Australasian taxa. Their phylogenetic tree did not support monophyly for the Asterinidae View in CoL , but was the basis for subsequent far-reaching taxonomic revisions ( O’Loughlin & Waters, 2004).

Basal relationships in the large clade subtended by node P in Figure 1 View Figure 1 were mostly unresolved. Somewhat better resolution was obtained in the two-gene tree ( Fig. 2 View Figure 2 ) for some groups, such as Parvulastra View in CoL and Kampylaster View in CoL + Anseropoda antarctica View in CoL . However, support for all basal nodes in the asterinid clade of our two-gene tree (i.e. those subtended by node 1 in Figure 2 View Figure 2 ) was also relatively poor (<50%), suggesting that basal relationships within this group will require further study. However, when placed into the context of greater taxonomic sampling, our phylogenetic results mirror the results of Waters et al. (2004a) and cast substantial doubt on the monophyly of the Asterinidae View in CoL . This strongly suggests that the Asterinidae View in CoL , as traditionally defined, is a paraphyletic assemblage. The stemward positions on node P of all the asterinid taxa suggest that they occupy a relatively plesiomorphic condition, forming more of a grade relative to more derived taxa, such as the solasterids and the ganeriids. This represents a significant shift in perception of the Asterinidae View in CoL , which has historically been supported by distinct morphological autapomorphies and has been perceived more as a derived, terminal branch (e.g. Blake, 1987; Gale, 1987b) rather than as an ancestral grouping.

Several of the other phylogenetic and taxonomic results produced by Waters, O’Loughlin & Roy (2004a) and O’Loughlin & Waters (2004), especially the monophyly of the higher branches, such as Meridiastra , Patiria , Paranepanthia , Aquilonastra , and Parvulastra , are upheld by our results. The basal branches in Waters, O’Loughlin & Roy (2004a) are clarified in our results. Dermasterias , which was shown embedded within the ingroup Asterinidae , is clearly removed from the Asterinidae by our trees. Our examplar species of Nepanthia , Nepanthia grangei , differs from that of Waters, O’Loughlin & Roy (2004a) who used Nepanthia troughtoni but our result shows Nepanthia as the sister to the ganeriid Tarachaster australis .

Tremaster View in CoL has traditionally been placed in the Asterinidae View in CoL but has been separated by some workers (e.g. Sladen, 1889; Smith & Tranter, 1985) into the Tremasterinae View in CoL , which included Tremaster View in CoL , Stegnaster View in CoL , and two fossil tremasterines ( Spencer & Wright, 1966). Jangoux (1982) disagreed with this classification and removed Stegnaster View in CoL from the Tremasterinae View in CoL , a conclusion that is consistent with our mitochondrial-only tree ( Fig. 2 View Figure 2 ). Available data support Tremaster View in CoL as a divergent lineage within the Asterinidae View in CoL with uncertain affinities.

Derived members of the ‘asterinid’ clade include primarily former members of the Solasteridae View in CoL and the Ganeriidae , plus the Leilasteridae View in CoL . The solasterid + asterinid relationship, as supported by molecular data, was first observed by Wada, Komatsu & Satoh (1996) and later developed by Matsubara et al. (2004). The presence of ganeriid taxa, such as Cycethra and Perknaster , within the asterinid clade is consistent with historical classifications that have demonstrated affinities between asterinids and ganeriids. The Ganeriidae have always been supported as similar to or morphologically close to the Asterinidae View in CoL . Early classifications (e.g. Sladen, 1889) included Cycethra and Ganeria as members of the Ganeriinae, part of a subfamily within the Asterinidae View in CoL . This affinity has been further supported by contemporary morphology-based phylogenies ( Blake, 1987; Gale, 1987b). Further sampling will be necessary to test the monophyly and affinities of the Ganeriidae .

The Solasteridae, sensu A. M. Clark (1996) View in CoL was largely supported as monophyletic with the sole exception of the Antarctic Cuenotaster involutus , which was included as the sister clade to the ganeriid Perknaster . Although much work remains to be completed regarding this question, some morphological characters are consistent with Cuenotaster as a member of the Ganeriidae .

Jurassic fossils are known for taxa within the clade subtended by node P ( Solasteridae View in CoL + Asterinidae View in CoL + Ganeriidae + Leilasteridae View in CoL ) but are limited to the Asterinidae View in CoL and the Solasteridae View in CoL . Asterinid fossils are limited to those showing affinities with Tremaster View in CoL in the subfamily Tremasterinae View in CoL .

Tremaster View in CoL is supported on a long branch as sister group to a clade containing Nepanthia View in CoL and Tarachaster View in CoL ( Fig. 2 View Figure 2 ). Tremasterine fossils, such as Mesotremaster felli Hess, 1972 View in CoL and Mesotremaster zbindeni Hess, 1981 View in CoL from Germany and Protremaster uniserialis Smith & Tranter, 1985 View in CoL from Antarctica have been collected from Jurassic strata. Nontremasterine asterinid fossils are unknown.

Plesiosolaster (described as Brachisolaster View in CoL ) moretonis was re-described and discussed by Blake (1993) and further discussed by Villier, Charbonnier & Bernard (2009) from the Jurassic of England and is the only well-preserved fossil solasterid known. Although a full phylogenetic analysis was not undertaken, Blake hypothesized that the multiarmed condition for solasterids was derived relative to a more ancestral Lophaster View in CoL or Rhipidaster View in CoL -like morphology. Blake’s hypothesis is consistent with our phylogenetic tree ( Figure 1 View Figure 1 ). This may imply that the lineage containing multiarmed taxa ( Solaster View in CoL and Crossaster View in CoL ) may be closely associated with the Jurassic occurrence of multiple arms in the Solasteridae View in CoL .