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<<=====|||||||||||||||||||||| Four-circlet crinoidsPhylogeny after Ausich (in press).| | | | | ||||||||||||||||| Cladida
Containing clade(s):
Echinodermata
Introduction
Characteristics of Crinoidea
Discussion of Phylogenetic Relationships
Evolution of Crinoidea
Major Subgroups of Crinoidea
References
A persistent, traditional view treats living crinoids as chiefly deep-sea organisms, relicts of their opulent Paleozoic past, holding off final extinction in remote abyssal habitats. This view is generally applied to stalked crinoids, or sea lilies, as typical of the entire group, because they most closely resemble their fossil forebears. It is true that the approximately 80 extant species of stalked crinoids are chiefly restricted to depths greater than 200 m (the shallowest occurs in 100 m). However, 85% of extant crinoids (approximately 540 named species) are unstalked feather stars, or comatulids, the products of a continuing post-Paleozoic radiation (Meyer & Macurda 1977). Comatulids are a monophyletic clade classified within the subclass Articulata (Simms 1988). About 65% of living comatulids occur at shelf depths (<200 m). In the tropical Indo-West Pacific, the richest region, single reefs may support as many as 50 species, almost as many as recorded for any individual fossil assemblage. Here, abundance and diversity reach 115 specimens and 12 species per m2, respectively (Messing 1994). Although far fewer comatulid species exist in cold waters, local abundance may be much greater.
All crinoids are passive suspension feeders. They produce no feeding/respiratory current but, rather, rely on extrinsic, ambient water movement. In extant crinoids, the food-gathering apparatus functions as follows: each featherlike arm that radiates from the central body bears an open ambulacral groove bordered by triads of fingerlike podia, or tube feet, which are terminal extensions of the water vascular system (see figure below). The longest tube foot in each triad, 0.43-0.85 mm in length, is held out at a right angle and flicks passing food particles into the groove. After a food particle is captured by a crinoid, the shortest tube foot wraps it in mucous secretions; ciliary tracts on the groove floor then transport it toward the mouth. In living crinoids, food particle size ranges from about 50 to 400 µm. Diets include a variety of protists (e.g., diatoms and other unicellular algae, foraminiferans, actinopods), invertebrate larvae, small crustaceans, and detrital particles.
Arm and ambulacrum morphology of a living crinoid (from Messing, 1987, copyright © 1987 Charles Messing)
General morphology of a stalked crinoid (modified from Bather, 1900, copyright © 1998 William Ausich)
The crinoid stalk typically consists of numerous discoidal skeletal pieces called columnals, held together by ligaments and penetrated by a central canal containing coelomic and neural tissue. In most species, the stalk serves to anchor the animal permanently to the substrate via one of a variety of terminal structures, e.g., a discoidal or encrusting holdfast, rootlike radix, or grapnel. In others, such as the living isocrinids, whorls of hooklike cirri (sing., cirrus) along the stalk allow the crinoid to release its hold and crawl with its arms. Several crinoid groups, notably the comatulids, which include the only living shallow-water crinoids, have lost the stalk. Comatulids anchor via numerous cirri that arise from the retained topmost columnal (the centrodorsal).
Simms & Sevastopulo (1993) recognized that three major groups of crinoids were already distinct by the Lower to Middle Ordovician: the Camerata, Disparida, and Cladida. They recognized the Camerata as traditionally understood. However, they followed the suggestions of Kelly (1982, 1986) and disregarded the Inadunata as a group, because the disparids and cladids were separate, unrelated lineages. The flexibles and articulates both evolved from the cladids, so Simms and Sevastopulo (1993) placed these within the Cladida. Phylogenetic relationships in Simms and Sevastopulo (1993) were based on a limited number of characters with synapomorphies listed on a cladogram. No quantitative analyses were performed, and an emphasis was placed on Articulata characters.
Simms (1994) presented an alternative phylogeny based on a greatly revised scheme of calyx plate homologies. Rather than the radial plates (the upper plates of an aboral cup, sensu Moore & Teichert, 1978) being homologous among all crinoids and the landmark for determining all calyx plate homologies, Simms (1994) proposed that the lowest plates in the aboral cup (the infrabasal plates of three-circlet forms but the basal plates of two-circlet forms) were homologous and the homology landmarks. This substantially altered more traditional views on crinoid phylogeny, as Simms (1994) illustrated using a cladogram with inferred synapomorphies. Few workers have followed Simms (1994).
Ausich (1996a, 1997, 1998, in press) presented a phylogeny based on another alternative calyx plate homology scheme (Ausich 1996b), a differing outgroup, and parsimony-based character analyses. In this scheme, the most primitive crinoid aboral cup construction had four circlets of plates, inherited directly from rhombiferan echinoderm ancestors (Ausich in press). An early rhombiferan echinoderm is suggested as the putative ancestor to crinoids because of shared characters among some early rhombiferans and some early crinoids. Also, Conway Morris (1993) and Ausich & Babcock (1996, in press) do not regard Echmatocrinus from the Middle Cambrian as a crinoid. Thus, the oldest known crinoids are Early Ordovician. However, note that Sprinkle & Collins (1995), Sprinkle & Guensburg (1997), and Guensburg & Sprinkle (1997) do not follow this revision. The fourth, lowermost circlet of plates was previously unrecognized. Homologies of Ausich (1996b) only require revisions for four-circlet crinoids and disparids. The phylogeny of crinoids presented above is based on the homology scheme and PAUP parsimony analyses of Ausich (1996a, 1998). Primitive crinoids have four circlets. Ausich followed Simms & Sevastopulo (1993) by eliminating the Inadunata and recognizing the Disparida and Cladida as separate, early crinoid lineages . The camerates are recognized by Ausich (1998) as are the Flexibilia and Articulata. Furthermore, the camerates, flexibles, and articulates all evolved from different cladid lineages.
Major evolutionary steps in the crinoid phylogeny discussed above include the following (see phylogenetic tree below): Crinoids diverged from rhombiferan echinoderms through (1) loss of pore rhombs, gonopore, and biserial brachioles; development of true arms with extension of the ambulacra; movement of the anus to the tegmen; addition of anal plates; and better pentameral symmetry. The resulting primitive crinoids were four-circlet forms constituting a low diversity, basal group (Ausich, 1998). From this four-circlet construction, disparids arose through loss of the basal circlet (2). The cladid lineage, arose by loss of the lintel circlet (3) and gave rise to three additional very successful lineages: camerates (4) with fixed brachials and fixed interradials incorporated into the calyx, symmetrical posterior plating, and rigid plate sutures; flexibles (5) with the mouth exposed on the tegmen and loose plate sutures; and the articulates (6) with loss of the anal plate and an entoneural system enclosed within the calyx plates. The monophyletic nature of the subclass Articulata has been argued by Simms & Sevastopulo (1993).
Phylogenetic hypothesis of crinoid relationships, based on Ausich (1996b, in press).
In current classification hypotheses, the Cladida, Disparida, and Camerata are regarded as subclasses (Simms and Sevastopulo 1993; Ausich 1998). Simms and Sevastopulo (1993) group the Flexibilia and Articulata within the Cladida as a single monophyletic lineage. These relationships are not disputed by Ausich (1998), but he proposes a partially paraphyletic classification to more accurately describe the evolutionary history of the Crinoidea. Thus, the Flexibilia and Articulata are designated as monophyletic subclasses leaving the Cladida as a paraphyletic subclass. Furthermore, the Camerata are also derived from cladids in the phylogeny of Ausich (1998). The primitive, four-circlet crinoids are constructionally distinctive from all other crinoids and cannot be placed within any existing subclass. A new subclass is erected for these forms, however it also is paraphyletic because it gave rise to both disparids and cladids (Ausich, in press).
Five distinct groups of articulates survive in modern seas. Their
interrelationships will be treated on a separate page. The bathyal and
abyssal hyocrinids have long stalks, thin discoidal columnals, and a
terminal attachment disk. The bathyal and abyssal bourgueticrinids have
columnals articulated by synarthries (two ligament bundles flanking a
fulcral ridge) and attach via a terminal disk or rootlike radix. The
bathyal isocrinids have whorls of hooklike cirri along the stalk. In the
bathyal cyrtocrinids, a short stalk consists of up to two columnals, or an
expanded, thickened calyx cements directly to the substrate. The
comatulids, which occur from intertidal to abyssal depths, retain a stalk
as postlarvae, but shed all but the topmost segment and take up a free
existence as juveniles and adults.
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Charles G. Messing
E-mail: messingc@ocean.nova.edu.
Nova Oceanographic Center
8000 N. Ocean Drive
Dania, FL 33004 USA
Correspondence regarding this page should be directed to William I. Ausich, at ausich@mps.ohio-state.edu.
Page copyright © 1998 William I. Ausich and Charles G. Messing
First online 1 April 1998
Content changed 21 April 1998
Last saved 1 December 2000
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