taxonID	type	description	language	source
03B187E33839FFA761484D24FF6EA117.taxon	type_taxon	Type species Cymbospondylus piscosus Leidy, 1868 (14)	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33839FFA761484D24FF6EA117.taxon	synonymic_list	Referred species Cymbospondylus petrinus Leidy, 1868 (14); Cymbospondylus buchseri (15); Cymbospondylus nichollsi (16); Cymbospondylus duelferi (17); Cymbospondylus youngorum sp. nov.	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33839FFA761484D24FF6EA117.taxon	diagnosis	Genus diagnosis For a recent detailed diagnosis of the genus, see (17). In addition, the results of the phylogenetic analysis in this study offer an apomorphy-based diagnosis.	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	description	(Fig. 2 and figs. S 1 to S 5)	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	etymology	Etymology The species is named in honor of Tom and Bonda Young.	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	materials_examined	Holotype and only specimen LACM DI 157871 is the holotype and, as of now, the only recognized individual. LACM DI 157871 is largely articulated and complete from the anterior of the trunk region to the skull, preserved ventral side up. The cervical column back to the middle dorsal vertebrae is present with ribs in articulation. The shoulder girdle is articulated, and the two humeri are situated close to their respective glenoid. At present, the skull (Fig. 2, A to F; figs. S 1 and S 2; and table S 1), the right humerus (Fig. 2, G to K), parts of the shoulder girdle (fig. S 3), and some vertebrae are prepared (fig. S 3) Horizon and locality LACM DI 157871 comes from the Anisian age Fossil Hill Member of the Favret Formation at Favret Canyon, Augusta Mountains, Pershing County, Nevada, USA. The type locality, LACM 8025, is on the northern slope of the rear of Favret Canyon at an elevation of 1676 m. Exact coordinates are on file at the repository. LACM DI 157871 originates from the same general level as the holotype of the macropredatory ichthyosaur Thalattoarchon saurophagis (8) and the pistosaur Augustasaurus hagdorni (10) in the lower third of the Fossil Hill member and pertains to the middle Anisian Taylori Zone (18).	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	diagnosis	Diagnosis C. youngorum sp. nov. is diagnosed by a unique combination of the following eight characters (see data S 1 for character descriptions and data S 3 for a list of synapomorphies): squamosal, participates in supratemporal fenestra (character 72, state 0; Fig. 2); dentary, labial shelf present (character 117, state 1; fig. S 2 C); angular, extent of anterior lateral exposure is extensive, at least as high and anteriorly as the surangular’ s exposure (character 120, state 1; Fig. 2); angular, extent of posterior lateral exposure is extensive, with surangular exposure reduced to a thin strip on the lateral surface of the retroarticular process (character 121, state 1; Fig. 2); lower jaw glenoid, deeply excavated and present (character 126, state 1; Fig. 2); dentition, definition of the base of the enamel layer is well defined and precise (character 147, state 1; fig. S 2, E and F); humerus, anterior flange is absent (character 200, state 0; Fig. 2 and fig. S 6); and humerus, relative anteroposterior width in dorsal view, excluding dorsal and ventral processes, is approximately equal or the proximal end is wider than the distal end (character 206, state 1; Fig. 2 and fig. S 6). The new taxon is characterized by the following autapomorphies: a thick base of bone of attachment of the teeth (Fig. 2 and fig. S 2, C and E), the distinctive shape of the scapula with a very large and wide dorsal blade and a narrow ventral part (figs. S 3 and S 6), the distinctive humerus morphology with a wider proximal than distal end, and a triangular proximal head and triangular shaft cross section (Fig. 2 and fig. S 6). Note that these autapomorphies were not added as characters to our character matrix. A differential diagnosis and detailed anatomical descriptions (figs. S 2 and S 3) and comparisons (figs. S 4 to S 6 and tables S 2 and S 3) are provided in the supplementary materials (10).	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	discussion	Phylogenetic position Phylogenetic analyses (10) (table S 4) indicate that C. youngorum sp. nov. is nested within a clade of closely related Cymbospondylus species that account for much of the lineage diversity and morphological disparity of large-bodied Early and Middle Triassic ichthyosaurs (Fig. 3 and fig. S 7). The close relationship of these species points to an adaptive radiation (as much as one can be recognized in the fossil record of Mesozoic reptiles). Further evidence for such a radiation is that there are no other four seemingly sympatric species of any ichthyosaur genus in the ichthyosaur record and that other finds of Cymbospondylus from the late Early and early Middle Triassic are widely distributed across the Northern Hemisphere (16). Our analysis with TNT (a software for phylogenetic analysis) and its “ new technology ” search algorithm resulted in a tree length of 1225 steps. The four most parsimonious trees were retained (table S 4), and the nearly fully resolved strict consensus of the four trees is shown in Fig. 3 and fig. S 7. The consistency index of this tree is 0.259, coupled with a retention index of 0.627. The absolute Bremer support of the nodes varies from 1 to 5 (fig. S 7). Additional analyses (table S 4) confirmed the placement of LACM DI 157871 in a clade with other cymbospondylids, yet the position of the Cymbospondylus clade varies with the selection of taxa that were included in the analyses (10). We note that the interrelationships of ichthyosaurs remain difficult to resolve, both in the Triassic and the Jurassic part of the tree. This uncertainty reflects the difficulty in resolving ichthyosaur interrelationships in general (19) and the need for a concerted effort of redefining and rescoring characters.	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
03B187E33838FFA4651D4E70FADEA2AA.taxon	biology_ecology	Inferred diet and estimated body size The conical, bluntly pointed tooth crowns of C. youngorum sp. nov., in conjunction with the elongate snout, suggest a generalist diet of fish and squid (20), as inferred for most ichthyosaurs from teeth and stomach contents (21). Considering its size, C. youngorum sp. nov. could also have preyed on smaller and juvenile marine reptiles (10). The right lower jaw of C. youngorum sp. nov. measures 1970 mm from the tip of the dentary to the end of the retroarticular process (table S 1). At a total length of 1890 mm (table S 1), the skull of LACM DI 15787 is one of the largest complete ichthyosaur skulls known. Although post-Triassic ichthyosaurs never reached the size of Triassic ones again (7), there are skulls of Temnodontosaurus from the Lower Jurassic of England and Germany (22) that are the same length as that of LACM DI 15787 within the limits of preservation. However, these large ichthyosaurs probably were less than 9 m long, having proportionally larger skulls (22). Larger skulls than those of LACM DI 15787 and these largest Temnodontosaurus specimens are only known from Late Triassic ichthyosaurs, specifically Shonisaurus popularis and Shastasaurus sikanniensis, with estimated skull lengths of 2750 and 3000 mm, respectively (7). Humerus length is another commonly used proxy for ichthyosaurian body size [(16, 17, 23); fig. S 8 A], even though it is available for fewer ichthyosaur taxa than skull length. At 453 mm, the humerus of the holotype of C. youngorum sp. nov. is the second largest ichthyosaurian humerus known, translating into a total length of 17.65 m (10). The lower 95 % prediction interval of its length is 12.48 m; the upper 95 % prediction interval is 24.96 m (10) (fig. S 8 A). We also estimated body mass based on a recent dataset for ichthyosaurs (10, 24) (table S 5). The regression function (fig. S 8 B) yielded a body mass estimate of 44,699 kg for the 17.65 - msized LACM DI 15787 specimen (table S 5). The lower mass based on the 95 % prediction interval of both regressions is 14,712 kg (lower limit of the 95 % prediction interval of body mass against length evaluated for 12.48 m); the upper mass is 135,809 kg (upper limit of the 95 % prediction interval of body mass against length evaluated for 24.96 m). These body size metrics of C. youngorum sp. nov. result in one of the highest length and mass estimates for any ichthyosaur and the largest taxon of the Middle Triassic: Based on length and scaled-up mass data in Gutarra et al. (24), S. popularis from the late Carnian (about 230 Ma ago) was 13.5 m long and had a mass of 21,651 kg, whereas the middle Norian (about 212 Ma ago) S. sikanniensis was 21 m long and had an estimated body mass of 81,497 kg. Taken together, these length and mass estimates place ichthyosaurs in the range of body sizes of living cetaceans, but it appears that ichthyosaurs reached their largest sizes much earlier in clade history than whales.	en	Sander, P. Martin, Griebeler, Eva Maria, Klein, Nicole, Juarbe, Jorge Velez, Wintrich, Tanja, Revell, Liam J., Schmitz, Lars (2021): Early giant reveals faster evolution of large body size in ichthyosaurs than in cetaceans. Science (New York, N. Y.) 374 (6575): 1-15, DOI: 10.1126/science.abf5787, URL: http://dx.doi.org/10.1126/science.abf5787
