SURVIVORSHIP ANALYSIS OF PALEOZOIC CRINOIDEA - EFFECT OF FILTER MORPHOLOGY ON EVOLUTIONARY RATES

The evolutionary rates of Paleozoic Crinoidea were obtained using dynamic survivorship analysis. The stratigraphic ranges of 838 genera were used in the analyses, revealing a mean generic duration of 12.0 m.y. and a mean species duration of 6.7 m.y., values within the range of longevities reported for other taxa. Further analyses showed differences in evolutionary rates among crinoid taxa: camerate species and genera were shorter-lived than species and genera of flexibles and inadunates. This pattern may result from ecological differences among these taxa: an energy budget equation solved for crinoids with various filter morphologies revealed that crinoids with fine-mesh filters require higher current velocities to supply them with sufficient particulate nutrients than do crinoids with coarse-mesh filters. A hypothesis stipulating that these differences control the distribution of crinoids among different environments is supported by patterns of occurrence of Mississippian crinoids: the pinnulate camerates (fine filter) dominate higher energy settings while the non-pinnulate inadunates and flexibles (coarse filter) are found in all environments. The ''specialized'' pinnulate crinoids may therefore be more prone to speciation and extinction than the non-pinnulate ''generalists,'' thus accounting for the observed differences in the evolutionary rates of the three subclasses. The above hypothesis was tested by comparing evolutionary rates of two morphological groups: fine-filtered crinoids (camerates) and coarse-filtered crinoids (non-pinnulate Paleozoic crinoids). As predicted, fine-filtered taxa had higher extinction and origination rates. A ''bootstrapping'' technique revealed that the differences in extinction rates were significant at the p < 0.10 level.