Abstract
Sirenians are the only extant herbivorous mammals fully adapted to an aquatic lifestyle. They originated in Africa during the Paleocene from an undetermined clade of afrotherian mammals, and by the end of the Eocene they were widely distributed across the tropical latitudes. Here we introduce Sobrarbesiren cardieli gen. et sp. nov. It is the first adequately-known quadrupedal sirenian from Eurasia and the oldest record of this clade from western Europe. Fossils have been recovered from the middle Lutetian (SBZ15) site of Castejón de Sobrarbe-41 (Huesca, Spain), and comprise many cranial and postcranial remains, including pelvic girdle and hind limb bones, from at least six sirenian individuals of different ontogenetic stages. Sobrarbesiren shows a suite of characters previously considered synapomorphies of different clades of derived sirenians, such as the presence of the processus retroversus of the squamosal and the pterygoid fossa, combined with ancestral characters such as the presence of an alisphenoid canal, a permanent P5, at least two sacral vertebrae, a primitive pelvis and functional femora and fibulae. Sobrarbesiren is recovered as the sister taxon of Dugongidae and represents a transitional stage of adaptation to aquatic life between the amphibious quadrupedal prorastomids and the aquatic quadrupedal protosirenids.
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Introduction
Sirenians originated from an undetermined clade of afrotherian mammals in the Paleocene1. The fossil record of the group starts in the late early Eocene of the West Atlantic coast and Africa. The prorastomids Prorastomus sirenoides, from the late early Eocene or early middle Eocene2, and Pezosiren portelli, from the early middle Eocene3, both from Jamaica, are highly plesiomorphic forms and present a semiaquatic lifestyle4. Only fragmentary remains of prorastomids have been recovered from the late early and middle Eocene of the Old World5,6. Instead, the Eocene fossil record is mainly composed of more derived forms: the Protosirenidae (e.g. Protosiren smithae7, Ashokia8, Libysiren9), quadrupedal aquatic forms with reduction of the hind limbs4; and the Dugongidae (e.g. Eotheroides, Eosiren, Halitherium10), completely aquatic sirenians with an advanced stage of hind limb reduction.
All Eocene European sirenians are assigned to the Family Dugongidae10, with the exception of several fragmentary specimens of uncertain affinities11,12. Several dugongid species have been described in Europe: Sirenavus hungaricus13 and Anisosiren pannonica14 from the Lutetian of Hungary; “Halitherium” taulannense from the Priabonian of France15; and Prototherium spp., from the Bartonian of Spain16,17 and the Bartonian and Priabonian of Italy18,19. Until now, Eocene sirenian remains in the Pyrenean region had been scarce and fragmentary20. The new locality found in the central Pyrenees, the site of Castejón de Sobrarbe-41 (CS-41) in the province of Huesca (northeastern Spain), is an exceptional middle Lutetian sirenian bone bed, which has provided more than 300 remains from at least six sirenian individuals, of different ontogenetic stages, assigned to the new taxon. It is the oldest sirenian in western Europe and is represented by cranial and postcranial material including functional hind limbs, constituting the first adequately-known quadrupedal sirenian from Eurasia. The aim of this work is to describe this new sirenian, discuss its phylogenetic significance and study its adaptation to aquatic life.
Geology and age
The Castejón de Sobrarbe-41 sirenian fossil site (CS-41) is located near the small village of Castejón de Sobrarbe (Comarca de Sobrarbe, Huesca, northeastern Spain). Geologically, this sirenian bone bed crops out in the Ainsa Basin (Fig. 1b), which constitutes the westernmost part of the Cenozoic Jaca-Pamplona Basin in the South Pyrenean Central Unit21. During the Eocene, this area was a deep marine gulf (the Bay of Biscay) located between the Iberian Peninsula and Europe (Fig. 1a), which opened northwestwards into the Atlantic Ocean, delimited to the east by the emergence of reliefs associated with the Pyrenean orogen22. The CS-41 fossiliferous level is in the uppermost part of the Sobrarbe Formation and has been correlated with nearby sections dated by magnetostratigraphy and benthic foraminifera21, placing CS-41 within the C19r chron and biozone SBZ15 (middle Lutetian, middle Eocene) and making these the oldest sirenian remains in western Europe. Over 300 disarticulated remains from at least six sirenian individuals, in different ontogenetic stages have been collected. The fossils are oriented but poorly sorted, with no signs of significant transport. This assemblage is interpreted as the infilling of an intertidal channel during a single energetic event, where all the remains dispersed over the tidal flat were trapped. Further data about the geological and taphonomic context of Castejón de Sobrarbe-41 can be found in the supporting information.
Results
Systematic palaeontology
Class Mammalia Linnaeus, 1758
Superorder Afrotheria Stanhope et al., 1998
Mirorder Tethytheria McKenna, 1975
Order Sirenia Illiger, 1811
Family uncertain
Sobrarbesiren cardieli gen. et sp. nov.
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urn:lsid:zoobank.org:act:960D79DB-2E74-4BA7-A7B1-13E8BFAD9B2C
Etymology
In reference to the Sobrarbe region (Huesca, northeastern Spain), and in honour of Jesús Cardiel Lalueza, who discovered the fossil site.
Holotype
MPZ 2017/1 a complete skull of a subadult individual which preserves alveoli of P1-4, a complete left P5, and M1-3 on both sides (Figs 2, 3, 4a,b,g,h and 5). The specimen is housed in the Museo de Ciencias Naturales de la Universidad de Zaragoza (MPZ) (Zaragoza, Spain). S. cardieli is the type species of the genus by monotypy and by original designation.
Paratypes
Cranial and postcranial elements of at least six individuals, corresponding to different ontogenetic stages (Figs 6–9 and Supplementary Information Figs S2 and S3): MPZ 2017/2, an almost complete subadult skull that preserves the molar series on both sides, and lacks the exoccipital and basioccipital bones; MPZ 2017/3, premaxillary nasal process; MPZ 2017/4, ?first incisor; MPZ 2017/5, ?third incisor; MPZ 2017/6, atlas; MPZ 2017/7, axis; MPZ 2017/8 and MPZ 2017/9, bodies of cervical vertebrae; MPZ 2017/10 and MPZ 2017/11, anterior thoracic vertebrae; MPZ 2017/12, MPZ 2017/13, MPZ 2017/14 and MPZ 2017/15, thoracic vertebrae; MPZ 2017/16, anterior lumbar vertebra; MPZ 2017/17, posterior lumbar vertebra; MPZ 2017/18, sacral vertebra; MPZ 2017/19 and MPZ 2017/20, anterior caudal vertebrae; MPZ 2017/21, posterior caudal vertebrae; MPZ 2017/22, first left rib; MPZ 2017/23 - MPZ 2017/33, right ribs; MPZ 2017/34 - MPZ 2017/39, left ribs; MPZ 2017/40 - MPZ 2017/43, left scapulae; MPZ 2017/44, left humerus; MPZ 2017/45, right humerus, very distorted; MPZ 2017/46, right ulna that lacks the epiphyses; MPZ 2017/47, left innominate bone; MPZ 2017/48, incomplete right innominate bone; MPZ 2017/49 and MPZ 2017/50 juvenile right ischia; MPZ 2017/51 and MPZ 2017/52, patellae; MPZ 2017/53, left femur that lacks the proximal epiphysis; MPZ 2017/54, juvenile left femur; MPZ 2017/55 femoral head and MPZ 2017/56 left fibula.
Locality and horizon
Only known from the Castejón de Sobrarbe-41 fossil site (CS-41), in Castejón de Sobrarbe, Huesca, Ainsa Basin in the southern Pyrenees, Sobrarbe Formation (middle Lutetian, early middle Eocene)21 (Fig. 1b).
Diagnosis
(Ch. Character state following the descriptions and numbering sequence of Domning23 as updated by Vélez-Juarbe et al.24 and Springer et al.1 (e.g., Ch. 102 (0) refers to state 0 of character 102)): sirenian, based on the following synapomorphies: retracted and enlarged external nares (Ch. 8 (1)); premaxilla contacts the frontals (Ch. 9 (1)); and a P1-5, M1-3 postcanine dental formula (Ch. 155 (1)); and characterized by the following combination of characters (autapomorphies highlighted with*): upper dental formula 2.1.5.3 (I2 absent); pterygoid fossa present, extending above the level of the roof of the internal nares (Ch. 102 (1)); alisphenoid canal present (Ch. 101 (0)); rectangular and elongated basioccipital* (Fig. 4a,b and Supplementary Information Fig. S1a); hook-shaped acromion process of the scapula* (Fig. 7d), which extends just to the dorsal border of the glenoid fossa* (Fig. 7b); posterior iliac spine of the innominate bone present* (Fig. 9c); lateral iliac spine that appears abruptly on the lateral surface of the ilium with a flattened ventrolateral surface* (Fig. 9e).
Differential diagnosis
Sobrarbesiren differs from “prorastomids”2,3 in having a deflected rostrum, a foramen ovale that is opened to form a notch (Ch. 103 (1)), a short sphenopalatine region, with a pterygoid process that is enlarged, thickened and downwardly projecting (Ch. 105 (1)), and in lacking the prominent sagittal crest seen in Pezosiren3 (Ch. 51 (1)).
It is distinguished from the Protosirenidae7,8,9 in having an enlarged rostrum (Ch. 3 (2)), a post-tympanic process of the squamosal that distinctly projects anteroventrally from the ventral squamosal border that intersects the paraoccipital process (Ch. 73 (0)), a cranial portion of the squamosal that reaches the parietal roof and the posterior part of the temporal crest (Ch. 76 (1)), a pterygoid fossa extending above the level of the roof of the internal nares (Ch. 102 (1)) (this character is probably absent in Ashokia antiqua8,9), and it differs from all protosirenids except Ashokia antiqua in having an outline of the zygomatic process of the squamosal that is gradually tapered and pointed anteriorly (Ch. 81 (0)). Sobrarbesiren shares with Ashokia antiqua and Libysiren sickenbergi long nasals that are slightly separated by frontals posteriorly8,9.
Sobrarbesiren is distinguished from the Dugongidae in having an alisphenoid canal (Ch. 101 (0)), a permanent fifth premolar present (Ch. 146 (0)), a small infraorbital foramen (Ch. 13 (0)) only shared with Eotheroides aegyptiacum, and in having well-developed (i.e. non-vestigial) innominate bones, presenting a large obturator foramen and a deep acetabulum, and complete hind limbs still present.
Sobrarbesiren is further differentiated from Sirenavus hungaricus12,13 in having a zygomatic-orbital bridge of the maxilla elevated more than 1 cm above the alveolar margin (Ch. 11 (1)); a post-tympanic process of the squamosal present, and M3 larger than the other upper molars. Sobrarbesiren differs from the genus Eotheroides in that the latter has a longer median process of the frontals, resulting in a bigger notch between the nasals. On the other hand, both taxa share swollen and dense (pachyosteosclerotic) anterior ribs that are banana-shaped. Sobrarbesiren is distinguished from Eosiren in having a premaxillary symphysis that extends less than one-third of the skull length, large nasal bones, and swollen anterior ribs. Sobrarbesiren differs from Prototherium in not showing dolichocephaly (see Supplementary Information Table S1), in having a lesser degree of rostral deflection (see table 1 in17) and in having an enlarged rostrum (Ch. 3 (2)) (except Prototherium intermedium). It is distinguished from “Halitherium” taulannense in having I3 present, a zygomatic-orbital bridge of the maxilla elevated more than 1 cm above the alveolar margin (Ch. 11 (1)) and an external auditory meatus that is narrow and slit-like (Ch. 82 (0)).
Description
Sobrarbesiren is a medium-sized quadrupedal sirenian with an estimated total length of 2.7 m (Fig. 10). The skull descriptions are based on the holotype (MPZ 2017/1) and the paratype (MPZ 2017/2).
The holotype skull shows an open basioccipital-basisphenoid suture and a M3 with minor wear, suggesting that the specimen represents a subadult individual24 (Fig. 4a,b,g,h). The holotype skull shows a 32° rostral deflection, which is greater than in prorastomids2,3 but less than in more derived sirenians7,17. The premaxillary symphysis is enlarged (Ch. 3 (2)) and laterally compressed (Ch. 10 (1)). The anteroventralmost end of the suture with the maxilla is on the vertical level of the symphyseal summit. The nasal process of premaxilla is thin and tapering at the posterior end (Ch. 6 (0)). It contacts ventrally the maxilla and posteriorly the nasal, and as in most other sirenians, it contacts the frontals23. The external nares are retracted and enlarged to the level of the anterior margin of the orbit (Ch. 8 (1)). The nasals are large and meet along their dorsomedial borders (Ch. 31 (0)) (internasal suture = 65 mm), as in prorastomids2,3, some protosirenids8,9 and Eocene dugongids15,17,25. The anterior borders of the nasals together form a v-shaped extension beyond the mesorostral´s fossa posterior edge (Ch. 37 (0)). The posterior edges of the nasals are rounded, and they are shallowly separated by the frontals (Fig. 3) in a way similar to Ashokia antiqua8. The lacrimals are partially preserved. The anterior border of each is rounded, and the posterior border is broken. They are surrounded by the maxilla and the frontal (Ch. 93 (0)). A nasolacrimal foramen is present (Ch. 91 (0)). The frontal roof is flat (Ch. 42 (0)) and does not bear knoblike bosses (Ch. 45 (0)). The supraorbital processes of the frontals are stout and dorsoventrally flattened and show a prominent dorsolateral corner (Ch. 36 (0)). Their lateral borders are not divided (Ch. 44 (0)). The lamina orbitalis of the frontal is covered by sediment (Ch. 38 (?)). The elongated and convex parietals show smooth temporal crests that join just in front of the coronal suture for a total of 52.5 mm in craniocaudal length (Fig. 3). A true sagittal crest is absent (Ch. 51 (1)), as in all other sirenians23 except Pezosiren3, because the fused temporal crests are not raised. In the paratype skull (MPZ 2017/2) the temporal crests are separated by 3 mm. The supraoccipital shows a pronounced nuchal crest positioned at the same level as the skull roof, but it is less massive than in protosirenids7. The morphology of the supraoccipital is unclear (Fig. 5a,b, Ch. 64 (?)). Three emissary foramina forming a triangle are situated on the skull roof just anterior to the nuchal crest (Fig. 3). The exoccipitals meet along a suture dorsal to the foramen magnum (Ch. 66 (0)). Their dorsolateral borders are rounded and smooth (Ch. 70 (1)). The hypoglossal foramen is not discernible (Ch. 72 (?)). The basioccipital is elongated and rectangular in ventral view. It measures 37 mm along its ventral length (from the line of fusion with the basisphenoid to the base of the foramen magnum) and 17.5 mm across its body. Its ventral surface shows a median keel that bifurcates into the basisphenoid (Fig. 4a,b). It differs from the basioccipital of prorastomids, which is transversely wider posteriorly than anteriorly2 (Supplementary Information Fig. S1b), and from those of protosirenids and dugongids, which show a waisted body (Supplementary Information Fig. S1,c,d). An alisphenoid canal is present (Ch. 101 (0)), as in prorastomids2,3 and protosirenids7,26. The foramen ovale is converted into an open notch (Ch. 103 (1)). The pterygoid processes are enlarged (Ch. 105 (1)), as in all sirenians except prorastomids3. They project ventrad, showing a shallow pterygoid fossa (Ch. 102 (1)) that is absent in protosirenids7,8,9. The palatines are <1 cm thick at the level of the penultimate cheek tooth (Ch. 16 (0)). Their anterior border extends anteriorly beyond the posterior edge of the zygomatic-orbital bridge (Ch. 99 (0)) (Supplementary Information Fig. S2c). Their posterior border is broken (Ch. 97 (?)). The zygomatic-orbital bridge of the maxilla is long anteroposteriorly (Ch. 14 (0)). Its anterior edge is thin and sharp, and the posterior one is thicker and rounded (Ch. 22 (0)). It is elevated more than 1 cm above the alveolar margin (Ch. 11 (1)), as in prorastomids2 and the protosirenid Ashokia antiqua8. There is a narrow palatal gutter (Ch. 23 (0)) along the midline of the maxillae, as in dugongids but not in protosirenids1. The infraorbital foramen is small (Ch. 13 (0)) (height: 16 mm; width: 8.3 mm) as in basal sirenians24, and unobstructed (Ch. 20 (0)). The squamosal reaches the skull roof and the temporal/nuchal crest (Ch. 76 (1)) (Fig. 2). The zygomatic process of the squamosal is tapered anteriorly (Ch. 81 (0)). Its medial side is concave and inclined inward dorsally (Ch. 84 (0)). The sigmoidal ridge is present, and it is prominent (Ch. 74 (2)). The processus retroversus is present, as in all dugongids23 and Libysiren sickenbergi9, and is moderately inflected (Ch. 77 (1)). The external auditory meatus is narrow (Ch. 82 (0)), as in most basal sirenians, and it is higher dorsoventrally than anteroposteriorly, unlike in the prorastomid Pezosiren3. The post-tympanic process is enlarged and projects anteroventrally, bearing a facet for insertion of the sternomastoid muscle (Ch. 73 (0)). The preorbital process of the jugal is a thin plate (Ch. 88 (0)) that contacts the maxilla (Ch. 87 (0)). The ventral process of the jugal is broken and shifted (Ch. 85 (?)) and the zygomatic process is longer than the anteroposterior diameter of the orbit (Ch. 89 (0)).
The upper dental formula is 2.1.5.3 (Ch. 145 (0); Ch. 146 (0); Ch. 150 (0); Ch. 155 (1)). There is a broken alveolus for the tusk at the tip of each premaxilla (Ch. 139 (0)) (Fig. 4a,b), which are shorter than half of the premaxillary symphysis length (Ch. 140 (0)). There is no sign of I2. The left alveolus situated at the posterior end of the premaxilla, just before the premaxilla-maxilla suture, is thus assigned to I3 (Ch. 143 (0)) (Fig. 4a,b and Supplementary Information Fig. S2c). The absence of I2 is a derived condition with respect to the 3.1.5.3 dental formula of other basal sirenians27. Two isolated teeth are tentatively identified as a ?I1 and a ?I3 (Fig. 4c–f). The tusk is lens-shaped (Ch. 141 (1)) with enamel on all sides of the crown (Ch. 142 (0)), which is differentiated from the root (Ch. 137 (0)). The cross section of the ?I3 crown is suboval and its length (6,5 mm) is considerably smaller than that of ?I1 (15 mm). Alveoli of canines and premolars in both skulls indicate that these teeth were single-rooted (Ch. 144 (1) and (Ch. 157 (1)) (Fig. 4a,b and Supplementary Information Fig. S2c). The left P5 is preserved in the holotype, which is a plesiomorphic state shared with prorastomids and protosirenids2,3,7. The P5 is a tiny tooth in comparison with molars, with a main central cusp surrounded by much lower lingual and labial accessory cuspules. There is an anterior cingulum with small cingular cuspules too. The length of each molar is greater than its width, with this condition being more pronounced on M2-3 (see Supplementary Information Table S2). The three teeth are bilophodont three-rooted molars, with trigon higher than talon, and thus with protoloph (protocone, protoconule and paracone) higher than the paraloph (hypocone, metaconule and metacone) (Fig. 4g,h). Both lophs are quite worn in the M1-2 but well developed protoconule and metaconule are present in the three molars. The lophs are separated by a deep transverse valley, open labially but closed lingually by a cingulum; in the M1-2 it is closed in its half way through due to the presence of the highly worn metaconule. The labial and lingual cusps seem not to be transversally aligned along the labial-lingual axis but slightly oblique. There are anterior and posterior cingulae present, which are more prominent distally in the dental arcade, and several anterior accessory cusps located mesial to paracone and protocone, and with a large posterior accessory cusp distal to metacone in the M3. In the M2-3 the posterior cingular valley is present, though it is incipient in the M2.
The full vertebral formula is unknown (Ch. 200 (?) and Ch. 204 (?)). The vertebrae lack the horizontally projecting flanges at the tip of the neural spine described in prorastomids3,5 or the bifurcated neural spines shown by protosirenids7 (Fig. 6d and Supplementary Information Fig. S3a). The atlas is wider than high (Supplementary Information Table S3) with a low dorsal arch, and has large posterior cotyles as in prorastomids2, but the transverse processes are rounded and knob-like, like those of basal dugongids25 (Fig. 6a,b). The axis has a robust and swollen neural spine strongly inclined cranially (Fig. 6c,d). The odontoid process is as long as the vertebral centrum. The centra of the cervical vertebrae are compressed craniocaudally. The anterior thoracic vertebrae have high neural spines like prorastomids3 and protosirenids7, but teardrop-shaped neural canals, as in dugongids16,25 (Supplementary Information, Fig. S3a).
Sobrarbesiren has a sacrum that comprises at least two unfused sacral vertebrae (Ch. 205 (1)), by contrast with protosirenids and dugongids, which are characterized by a single sacral vertebra4. The transverse processes are short (Fig. 6e) compared to non-prorastomid sirenians7,25. The articular surfaces for the ilium are diamond-shaped, short anteroposteriorly and dorsoventrally expanded (47.5 mm in dorsoventral height), unlike the large articular surfaces of Pezosiren portelli3. The posterior border of the transverse process is flattened and shows a bevelled rhomboidal articular surface for a more posterior sacral vertebra that is still unknown (Fig. 6e,f). The caudal vertebrae have dorsoventrally flattened transverse processes and chevron facets. The presence/absence of a fluke cannot be determined based on the available specimens (Ch. 207 (?)).
The ribs are pachyosteosclerotic. The first rib has a broadened, truncated and flattened distal end (Supplementary Information Fig. S3b) as in some dugongids16,25. On the ventral side of its neck, there is no process for origin of the longus capitis muscle. The succeeding anterior ribs are banana-like (Supplementary Information Fig. S3c, see also Supplementary Information Table S4 for rib measurements), similar to the dugongid Eotheroides25. The posterior ribs are slender, lacking the swollen diaphysis of the anterior ribs. The smooth articular surfaces of the rib heads indicate a synovial articulation unlike in protosirenids28.
The scapula is sickle-shaped and stout (see Supplementary Information Table S5 for measurements), as in Eocene dugongids16,25. The acromion process of the scapula is hook-shaped, protruding laterodistally and turning posteriorly, showing a well-marked anterior angle (Fig. 7a,b), and the acromion extends just to the dorsal border of the glenoid fossa, features not observed in any other sirenian. The acromion process is very fragile and is not preserved in many of the Eocene taxa. Nevertheless, the morphology and extension of the acromion process of the left scapulae MPZ 2017/40 (Fig. 7) and MPZ 2017/42 of Sobrarbesiren are different from any other known sirenian. In the holotype right scapula of Protosiren smithae (CGM 42292, Cairo Geological Museum (Egypt); cast, USNM 94810, US National Museum of Natural History), the distance between the edge of the acromial process and the dorsal border of the glenoid cavity is 15 mm and the acromion is more robust and massive, without such a marked turn at the distal end. Eosiren libyca also has a massive acromial process that ends before reaching the dorsal border of the glenoid cavity (see29, plate III, figure 1a,b). “Halitherium” taulannense shows a distance of 30 mm between the acromion and the glenoid cavity. The distal edge of the process is not complete in this taxon. Eotheroides sandersi shows an acromial process that continues, without turning, in the direction of the spine axis until its end, and does not reach the glenoid cavity (see25, figure 59, A).
The humerus is robust (Ch. 221 (1)), with strongly developed proximal and distal epiphyses that are similar in width (Fig. 8a,b, and Supplementary Information Table S6), as in protosirenids7 and Egyptian Eocene dugongids25, but unlike the humerus of Pezosiren, which shows a proportionally broader distal epiphysis3. The bicipital groove is wide (Ch. 213 (0)) (see Supplementary Information Table S6 for measurements), and the olecranon and coronoid fossae are distinct and deep.
The ulna has a straight shaft and is not fused to the radius, but this is probably due to inmaturity of the specimen (Fig. 8c,d). The olecranon is long (30 mm), as in Protosiren smithae (see7, figure 10). It is straight and coaxially aligned with the main axis of the shaft, and its cranial side is convex unlike in other sirenians, where it slopes backward7,25.
The innominate is long and narrow with a long pubic symphysis (Ch. 215 (0)) (Fig. 9a,c). The rod-like ilium resembles that of protosirenids30, but the expanded ischium is directed posterolaterally and is less curved. The deep acetabulum (Fig. 9b, see also Supplementary Information Table S7 for measurements), the well-developed, teardrop-shaped obturator foramen, and the distance between this foramen and the beginning of the sacroiliac joint, resemble the conditions in Pezosiren3. The innominate of Sobrarbesiren differs from those of all other sirenians in having a posterior iliac spine, and a lateral iliac spine that arises abruptly on the lateral surface of the ilium (Fig. 9c–e). This lateral spine shows a flattened ventrolateral surface (Fig. 9a,c). The patella (Fig. 9j,k) is similar to the teardrop-shaped patella of Pezosiren3. The femur lacks the proximal epiphysis. This bone resembles that of Pezosiren3 and protosirenids7 in having a deep intertrochanteric fossa, and a distal epiphysis with robust condyles (Fig. 9f–i). Sobrarbesiren differs from Pezosiren3 in having a reduced third trochanter, which is absent in protosirenids7. The fibula of Sobrarbesiren is the oldest sirenian fibula known. It is slender and shows a triangular distal articular surface, whereas this is rounded in the holotype fibula of Protosiren smithae (CGM 42292; cast, USNM 94810). A distolateral crest is present (Fig. 9l,m), though absent in USNM 94810.
Discussion
Phylogenetic analysis
Results
The analysis resulted in 96 most-parsimonious trees of 268 steps (Consistency Index, CI 0.433; Retention Index, RI 0.776, Rescaled Consistency Index, RC 0.336). Sobrarbesiren is recovered at the base of the clade that includes all sirenians except Prorastomus sirenoides, Pezosiren portelli and the clade Protosirenidae, as the sister taxon of all dugongids and trichechids (Fig. 11). The general topology of the tree resembles that of other authors1, but important differences arise. First, Protosirenidae is recovered as a monophyletic group, formed by the genera Protosiren, Libysiren and Ashokia, although with low support. Second, Trichechidae is returned to a more derived position, nesting within Dugongidae, as the sister group of the most exclusive clade that includes Kaupitherium (=Halitherium schinzii of other authors), Dugonginae and Hydrodamalinae. Another notable result of our analysis is that the genera Eotheroides and Prototherium are not recovered as monophyletic.
Sobrarbesiren cardieli is recovered as the sister taxon of Dugongidae. We refrain from including it within this family for two reasons: first, the current diagnosis of Dugongidae is synapomorphy-based and requires the members of the clade to lack the P5, the alisphenoid canal, and well-developed hind limbs1,23, a diagnosis not shared by Sobrarbesiren. Second, we consider that the current topology of the tree may change in the future, as a deeper split between Dugongidae and Trichechidae is plausible considering the available data. In this scenario, Sobrarbesiren will probably remain stable as a stem sirenian.
Lifestyle
Sobrarbesiren shows several characters proving that it retained some capacity for supporting its own weight on land. The anterior thoracic vertebrae have tall neural spines, indicating the presence of a nuchal ligament that could support the head3,7. The long and rugose pubic symphysis of the innominate bone shows that there is a bony connection between the two pubes. This feature, together with the presence of a bony sacroiliac joint, is a prerequisite for supporting the body weight on land30, in contrast to the weak sacroiliac joint of protosirenids, which probably ruled out quadrupedal locomotion on land in favour of a pinniped-like motion27.
The presence of an unfused sacrum composed of at least two sacral vertebrae is a plesiomorphic state compared with the sacra of protosirenids and dugongids, which are composed of only one vertebra4. Nevertheless, the elongated and anteroposteriorly shortened transverse processes of the sacral vertebrae of Sobrarbesiren suggest an adaptation to an aquatic lifestyle, in contrast to the short transverse processes with anteroposteriorly expanded articular surfaces of Pezosiren, which are similar to those of land mammals3.
The large femoral acetabulum of the innominate bone shows a well-marked attachment area for the round ligament (Fig. 9b), indicating that the femoral head was strongly anchored in the acetabulum. This implies an active role of the femur in either walking or swimming (or both), which contrasts with the evidently vestigial function of this bone in more derived sirenians4. The distal crest observed on the fibula of Sobrarbesiren is probably the processus lateralis fibulae described in the quadrupedal proboscidean Numidotherium koholense31, to which the peroneal muscles were presumably attached. This may well be a plesiomorphic feature, and it is absent in the fibula cast (USNM 94810) of the protosirenid Protosiren smithae, the only other sirenian fibula known. Even though no autopodial elements from the hind limb have been identified, the presence of articulation structures of the knee such as the patellar articular surface of the femur (Fig. 9g), the preserved patella, and a well-formed fibula supports the presence of a complete hind limb with a mobile foot7.
Sobrarbesiren shows further adaptations to life in water, such as pachyosteosclerotic bones, an enlarged rostrum and retracted nares, together with an unfused sacrum, a rod-like ilium and relatively short femur and fibula. This combination of aquatic and terrestrial adaptations suggests an amphibious lifestyle, whereby Sobrarbesiren spent most of its time feeding in shallow waters but was capable of moving over land between water masses. This is congruent with the finding of a parautochthonous accumulation of bones from several individuals in an intertidal floodplain. Sobrarbesiren thus represents an intermediate stage in the evolution towards a fully aquatic life, between the amphibious quadrupedal prorastomids and the more aquatic quadrupedal protosirenids4. This contradicts our phylogenetic results, where Protosirenidae is constantly recovered as a sister taxon of Sobrarbesiren + Dugongidae. Further fossils and phylogenetic analyses are needed to test whether this represents a case of convergent evolution, where protosirenids and dugongids reduced their hind limbs independently during their adaptation to a fully aquatic lifestyle.
Conclusions
We describe a new stem sirenian species, Sobrarbesiren cardieli, from the early middle Eocene (Lutetian, SBZ15) of the southern Pyrenees. This is the first adequately known quadrupedal sirenian from the northeastern Atlantic coast (Bay of Biscay, Spain) and the oldest sirenian from western Europe. It is represented by three skulls, cervical, dorsal, lumbar, sacral and caudal vertebrae, complete anterior, middle and posterior ribs, four scapulae, two hemipelvises, and fore and hind limb bones. This large collection of skeletal elements in different ontogenetic stages constitutes the most complete sample of an early middle Eocene sirenian in the Old World. Our phylogenetic analyses place Sobrarbesiren cardieli most parsimoniously as the sister taxon of a paraphyletic Dugongidae, which gives rise to Trichechidae. Sobrarbesiren is the only Eurasian sirenian that preserves terrestrially-functional pelvic girdle and hind limb bones. These indicate an intermediate state of adaptation to the aquatic lifestyle between other groups of quadrupedal sirenians, (namely the plesiomorphic pelvis and hind limbs of prorastomids, versus the slightly more derived limbs of the protosirenids). A further study of the functional morphology of sirenian hind limbs may be one of the keys to understanding the first stages of adaptation to aquatic life by these marine mammals.
Methods
Specimens
Fifty-six sirenian fossil bones were studied, including cranial and postcranial elements. The fossils were recovered in several field campaigns, using the usual methodology for macrovertebrate excavations. A metre-square grid system was applied and the spatial location of each element >1 cm in maximum dimension was recorded on a graph. The fossils are housed in the Museo de Ciencias Naturales de la Universidad de Zaragoza (Aragón, Spain).
The total body length of Sobrarbesiren was estimated using Sarko et al.32’s equation 9, which uses skull condylobasal length as a proxy.
Phylogenetic analysis
To assess the phylogenetic position of Sobrarbesiren cardieli we included it in the most recently updated dataset for the group1. We also added seven Eocene sirenian taxa to this dataset, Eotheroides lambondrano, Eotheroides sandersi, Eotheroides clavigerum, Prototherium veronense, Prototherium intermedium, Prototherium ausetanum and Libysiren sickenbergi. Eotheroides lambondrano was coded based on Samonds et al.33 and the examination of a high-quality cast housed in the USNM. Eotheroides sandersi and Eotheroides clavigerum were coded based on the descriptions by Zalmout and Gingerich25, and pictures of the specimens provided by Iyad S. Zalmout. Libysiren was coded based on descriptions in Domning et al.9 and direct observations of the holotype. Prototherium ausetanum, Prototherium veronense and Prototherium intermedium were coded based on published descriptions and codifications of Balaguer y Alba17, Domning23 and Sickenberg29.
The resulting dataset includes a total of 50 taxa, including 48 sirenians with the proboscidean Phosphatherium escuilliei Gheerbrant et al.34, plus the multitaxic Elephantidae as the outgroup (Supplementary Information Data matrix 1). Following Springer et al.1, of the total of 74 parsimony-informative characters scored, characters 1, 6, 7, 16, 31, 36, 38, 44, 49, 50, 51, 60, 65, 67, 68, 70 and 71 were treated as additive (ordered) characters, whereas relative steps between states of characters 10, 27, and 47 are defined by step matrices. The name Halitherium schinzii was replaced by Kaupitherium gruelli, following Voss et al.35.
The dataset was analysed using the current version of TNT 1.536. A heuristic search with 1000 replicates using Wagner trees as starting seeds, followed by branch swapping by tree-bisection-reconnection (TBR), holding ten trees per replicate, was conducted for each dataset. An additional round of TBR was performed, using the existing trees as starting trees, but this failed to recover any further trees. TNT does not support multiple outgroups but allows the re-rooting of trees after the search to a multiple-taxon outgroup by using the taxonomy option. This procedure was applied in order to resemble more closely the topology of the consensus shown by Springer et al.1. As advised by the documentation included with TNT, when using step matrices there is a possibility that re-rooting the trees to a taxonomic outgroup will influence the tree scores, but this was not the case for this dataset. Branch support was calculated using decay indexes with the script included in TNT, and 1000 replicates of bootstrap analysis. The resulting consensus recovers Sobrabresiren cardieli as sister taxon to a paraphyletic Dugongidae, which includes the family Trichechidae nested as the sister taxon of the clade including Kaupitherium, Priscosiren, Caribosiren, Metaxytherium, Hydrodamalinae and Dugonginae. To increase the resolution of the tree, Eotheroides lambondrano, known only by a partial skull and recovered as a wild card taxon, was a posteriori pruned from the consensus. The possible placements of E. lambondrano are shown by the stars in Fig. 11. The supplementary information attached to his manuscript includes a modified version of the matrix (Supplementary Information Data matrix 2). In this dataset, dummy parsimony-uninformative characters where added to the original dataset to alter the numbering sequence of the characters, as proposed by Domning23. This somewhat unorthodox numbering sequence has been kept in subsequent works for the purpose of consistency1,9,24. This modified matrix does produce the same exact results that the first dataset but simplifies the interpretation of the results on the light of previous work.
Nomenclatural Acts
The electronic edition of this article conforms to the requirements of the amended International Code of Zoological Nomenclature, and hence the new names contained herein are available under that Code from the electronic edition of this article. This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the ICZN. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix “http://zoobank.org/”. The LSID for this publication is: urn:lsid:zoobank.org:pub:17F24394-9E02-4794-99E9-DB85817EE54B.
Data Availability
All data generated or analysed during this study are included in this published article and its supplementary information files. The TNT files are also available at MORPHOBANK http://morphobank.org/permalink/?P2628.
References
Springer, M. S. et al. Interordinal gene capture, the phylogenetic position of Steller’s sea cow based on molecular and morphological data, and the macroevolutionary history of Sirenia. Mol. Phylogenet. Evol. 91, 178–193 (2015).
Savage, R. J. G., Domning, D. P. & Thewissen, J. G. M. Fossil Sirenia of the west Atlantic and Caribbean region. V. The most primitive known sirenian, Prorastomus sirenoides Owen, 1855. J. Vertebr. Paleontol. 14, 427–449 (1994).
Domning, D. P. The earliest known fully quadrupedal sirenian. Nature 413, 625–627 (2001).
Domning, D. P. The readaptation of Eocene sirenians to life in water. Hist. Biol. 14, 115–119 (2000).
Hautier, L. et al. First prorastomid sirenian from Senegal (Western Africa) and the Old World origin of sea cows. J. Vertebr. Paleontol. 32, 1218–1222 (2012).
Benoit, J. et al. Cranial remain from Tunisia provides new clues for the origin and evolution of Sirenia (Mammalia, Afrotheria) in Africa. PLOS ONE 8, e54307 (2013).
Domning, D. P. & Gingerich, P. D. Protosiren smithae, new species (Mammalia, Sirenia), from the late middle Eocene of Wadi Hitan, Egypt. Contrib. Mus. Paleontol. Univ. Mich. 29, 69–87 (1994).
Bajpai, S., Domning, D. P., Das, D. P. & Mishra, V. P. A new middle Eocene sirenian (Mammalia, Protosirenidae) from India. Neues Jahrb. für Geol. Paläontol. - Abh. 257–267 https://doi.org/10.1127/0077-7749/2009/0252-0257 (2009).
Domning, D. P., Heal, G. J. & Sorbi, S. Libysiren sickenbergi, gen. et sp. nov.: a new sirenian (Mammalia, Protosirenidae) from the middle Eocene of Libya. J. Vertebr. Paleontol. 37, e1299158 (2017).
Domning, D. P. Bibliography and index of the Sirenia and Desmostylia. Smithson. Contrib. Paleobiology 80, 1–611 (1996).
Hooijer, D. A. Fact and fiction in Hippopotamology (sampling the history of scientific error). Osiris 10, 109–116 (1952).
Kordos, L. Eocene sea cows (Sirenia, Mammalia) from Hungary. Fragm. Palaeontol. Hung. 20, 43–48 (2002).
Kretzoi, M. Sirenavus hungaricus n. g., n. sp., ein neuer Prorastomide aus dem Mitteleozän (Lutetium) von Felsőgalla in Ungarn. Ann. Musei Natl. Hung. Pars Mineral. Geol. Palaeontol. 34, 146–156 (1941).
Kordos, L. Major finds of scattered fossils in the Palaeovertebrate Collection of the Hungarian Geological Institute (Communication No. 4). Annu. Rep. Geol. Inst. Hung. 1977, 313–326 (1979).
Sagne, C. Halitherium taulannense, nouveau sirénien (Sirenia, Mammalia) de l’Éocène supérieur provenant du domaine Nord-Téthysien (Alpes-de-Haute-Provence, France). Comptes Rendus Académie Sci. - Ser. IIA - Earth Planet. Sci. 333, 471–476 (2001).
Pilleri, G., Biosca, J. & Via, L. The Tertiary Sirenia of Catalonia. (Brain Anatomy Institute, University of Berne, Ostermundingen, 1989).
Balaguer, J. & Alba, D. M. A new dugong species (Sirenia, Dugongidae) from the Eocene of Catalonia (NE Iberian Peninsula). Comptes Rendus Palevol 15, 489–500 (2016).
Bizzotto, B. Prototherium intermedium n. sp. (Sirenia) dell’Eocene Superiore di Possagno e proposta di revisione sistematica del taxon Eotheroides Palmer, 1899. Mem Ist Geol Miner. Univ Padova 36, 95–116 (1983).
de Zigno, A. Sirenii fossili trovati nel Veneto. Mem Ist Veneto SciLett 18, 427–456 (1875).
Astibia, H. et al. New fossils of Sirenia from the middle Eocene of Navarre (Western Pyrenees): the oldest West European sea cow record. Geol. Mag. 147, 665–673 (2010).
Mochales, T. et al. Chronostratigraphy of the Boltaña anticline and the Ainsa Basin (southern Pyrenees). GSA Bull. B30418, 1, https://doi.org/10.1130/B30418.1 (2012).
Plaziat, J.-C. Late Cretaceous to late Eocene palaeogeographic evolution of southwestEurope. Palaeogeogr. Palaeoclimatol. Palaeoecol. 36, 263–320 (1981).
Domning, D. P. A phylogenetic analysis of the Sirenia. Proceedings of the San Diego Society of Natural History 29, 177–189 (1994).
Vélez-Juarbe, J. & Domning, D. P. Fossil Sirenia of the West Atlantic and Caribbean region. IX. Metaxytherium albifontanum, sp. nov. J. Vertebr. Paleontol. 34, 444–464 (2014).
Zalmout, I. S. & Gingerich, P. D. Late Eocene seacows (Mammalia, Sirenia) from Wadi Al Hitan in the Western Desert of Fayum, Egypt. Univ. Mich. Pap. Paleontol. 37, 1–158 (2012).
Gingerich, P., Domning, D., Blane, C. & Uhen, M. Cranial morphology of Protosiren fraasi (Mammalia, Sirenia) from the middle Eocene of Egypt. Contrib. Mus. Paleont. Univ. Mich. 29, 41–67 (1994).
Domning, D. P., Zalmout, I. S. & Gingerich, P. D. Sirenia. in Cenozoic Mammals of Africa 147–160 (University of California Press, 2010).
Zalmout, I. S., Ul-haq, M. & Gingerich, P. D. New species of Protosiren (Mammalia, Sirenia) from the early middle Eocene of Balochistan (Pakistan). Contributions from the Museum of Paleontology, University of Michigan 31, 79–87 (2003).
Sickenberg, O. Beiträge zur Kenntnis Tertiärer Sirenen. I. Die eozänen Sirenen des Mittelmeergebietes. II. Die Sirenen des Belgischen Tertiärs. Mém. Mus. R. D’Histoire Nat. Belg. 63, 1–352 (1934).
Gingerich, P. D., Arif, M., Bhatti, M. A., Raza, H. A. & Raza, S. M. Protosiren and Babiacetus (Mammalia, Sirenia and Cetacea) from the middle Eocene Drazinda Formation, Sulaiman Range, Punjab (Pakistan). Contributions from the Museum of Paleontology, University of Michigan 29, 331–357 (1995).
Court, N. Limb posture and gait in Numidotherium koholense, a primitive proboscidean from the Eocene of Algeria. Zool. J. Linn. Soc. 111, 297–338 (1994).
Sarko, D. K., Domning, D. P., Marino, L. & Reep, R. L. Estimating body size of fossil sirenians. Marine Mammal Science 26, 937–959 (2010).
Samonds, K. E. et al. Eotheroides lambondrano, new middle Eocene seacow (Mammalia, Sirenia) from the Mahajanga Basin, northwestern Madagascar. J. Vertebr. Paleontol. 29, 1233–1243 (2009).
Gheerbrant, E., Sudre, J., Cappetta, H. & Bignot, G. Phosphatherium escuilliei du Thanétien du Bassin des Ouled Abdoun (Maroc), plus ancien proboscidien (Mammalia) d’Afrique. Geobios 31, 247–269 (1998).
Voss, M. & Hampe, O. Evidence for two sympatric sirenian species (Mammalia, Tethytheria) in the early Oligocene of Central Europe. J. Paleontol. 91, 337–367 (2017).
Goloboff, P. A. & Catalano, S. A. TNT version 1.5, including a full implementation of phylogenetic morphometrics. Cladistics 32, 221–238 (2016).
Mochales, T., Pueyo, E. L., Casas, A. M., Barnolas, A. & Oliva‐Urcia, B. Anisotropic magnetic susceptibility record of the kinematics of the Boltaña Anticline (Southern Pyrenees). Geol. J. 45(5–6), 562–581 (2010).
Acknowledgements
We thank D. Domning (Smithsonian Institution National Museum of Natural History, Washington D.C.), C. Sagne (Muséum national d’Histoire naturelle, Paris), P. Brewer (Natural History Museum, London), M. Gasparik (Magyar Természet Tudományi Museum, Budapest), L. Kordos and L. Makádi (Magyar Földtani és Geofizikai Intézet, Budapest) and T. Schossleitner (Museum für Naturkunde, Berlin) for access to comparative specimens, and especially D. Domning for his advice and comments during our stay in Washington D.C. We thank Iyad S. Zalmout for providing high resolution photographs of Eotheoides clavigerum and Eotheroides sandersi. We also thank M. Voss (Museum für Naturkunde Berlin) and L. Hautier (Museum of Zoology, University of Cambridge) for their comments in an early revision of the manuscript. We also thank the anonymous referees of Scientific Reports for their comments. Financial support was provided by the Ministerio de Economía y Competitividad (CGL2013-47521-P and CGL2017-85038-P, MINECO/FEDER, UE), the Research Groups IT834-13, IT1004-16 Gobierno Vasco/Eusko Jaurlaritza, and PPG17/05 (Universidad del País Vasco/Euskal Herriko Unibertsitatea), the Geoparque de Sobrarbe, the European Regional Development Fund and the Government of Aragón (‘DGA’ and ‘Grupos Consolidados’). E.D.B. received support from the SYNTHESYS project (HU-TAF-4793). M.M.A. is supported by the Fundação para a Ciência e a Tecnologia, Portugal (Grant Number SFRH/BPD/113130/2015). R. Silva and colleagues from Aragosaurus-IUCA provided assistance during fieldwork. A. Escapada allowed access to his land. Z. Herrera photographed the specimens and R. Glasgow edited the English.
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A.B. and J.I.C. designed the research plan. E.D.B., A.B., M.M.A. and J.I.C. wrote the paper. E.D.B. performed the comparative and analytical work. E.D.B. and M.M.A. performed the phylogenetic analyses. All authors discussed and commented on the manuscript.
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Díaz-Berenguer, E., Badiola, A., Moreno-Azanza, M. et al. First adequately-known quadrupedal sirenian from Eurasia (Eocene, Bay of Biscay, Huesca, northeastern Spain). Sci Rep 8, 5127 (2018). https://doi.org/10.1038/s41598-018-23355-w
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DOI: https://doi.org/10.1038/s41598-018-23355-w
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