Cambaremys langertoni, França & Langer, 2005

Cambaremys langertoni n. sp.

HOLOTYPE. — CPP-0252, cervical vertebra, partial carapace, right mesoplastron, both xiphiplastra, both coracoids, right scapula, both humeri, left radius, both ulnae, both pelvic girdles, right femur, both tibiae, both fibulae, along with other disarticulated remains including carpals, tarsals, metapodials, and phalanges, including an ungual ( Figs 2-8 View FIG View FIG View FIG View FIG View FIG View FIG View FIG ).

ETYMOLOGY. — In honor to Sr. Langerton Neves da Cunha, “field-man” of Llewellyn Ivor Price during the 1960s and early 1970s, and collector of many important fossils in the area of Peirópolis.

TYPE HORIZON. — Serra da Galga Member, Marília Formation, Bauru Basin ( Fernandes & Coimbra 2000). Studies based on microfossils (Dias-Brito et al. 2001; Gobbo-Rodrigues et al. 2003) and vertebrates ( Santucci & Bertini 2001) agree with a latest Cretaceous (most probably Maastrichtian) age for this stratum.

TYPE LOCALITY. — 19°43’12”S, 47°45’04”W. Quarry 2 of Price (see Campos & Kellner 1999), at 900 m high, in the Serra do Veadinho area, municipality of Uberaba, Minas Gerais, Brazil GoogleMaps ; about 2.5 km to the N-NW of the village of Peirópolis ( Fig. 1 View FIG ).

DIAGNOSIS. — Podocnemid with a pectoral scute that does not touch the mesoplastron and an expanded coracoid. Distinct from other named South American Cretaceous members of the group for its thin shell bones, narrow nuchal plate, seven neural plates, and contact between first costal and second neural plates.

DESCRIPTION

Axial skeleton ( Fig. 2 View FIG ; Table 1)

Of the vertebral column, only two cervicovertebral fragments were preserved, one including the centrum and the other most of the neural arch. Both encompass parts of the transverse processes, which are incomplete distally, and located at the middle of the axial length, as common among eupleurodires ( Lapparent de Broin 2000). Those fragments were not found in articulation, but giving their similar size and contact, they will be

A B C

Centrum length 13.5 Centrum cranial articulation width (dv × lm) 5.0 × 7.0 Centrum caudal articulation width (dv × lm) 4.5 × 5.0 Neurocentral articulation length 6.9 Neural arch total length 14.5 Neural arch maximum height (caudal) 7.0 Prezygapophyseal width 7.8 Postzygapophyseal width 6.9 Neural channel middle width 3.1

treated as a single element. Considered together, these account for a vertebra slightly longer than high. The centrum is procoelous, possessing a distinct ventral keel that extends more ventrally at its cranial part. The neural arch bears a low neural spine extending along most of its dorsal surface. The prezygapophyses project cranially as separate elements, while the postzygapophyses are supported by a common elevated process (pedicel), as also typical of eupleurodires ( Lapparent de Broin 2000), that expands caudodorsally. Its dorsal surface bears a pair of rounded protuberances, caudal to which the postzygapophyses extend to form a nearly continuous rounded articulation surface. Differently from Araripemys ( Meylan 1996) , the postzygapophyses are not fused together.

The position in the neck of the recovered vertebral elements of CPP-0252 is not clear. Put together, they differ from the eighth cervical vertebra of extant podocnemids ( Peltocephalus and Podocnemis ) for the caudally inclined pedicel and least developed ventral keel, and from the other caudal cervical vertebrae of those Testudines for the more discernible neural spine. If the cranial position of these elements is confirmed, their procelic centrum suggests a basal phylogenetic position for CPP-0252 in relation to the crown- Podocnemidae ( Joyce et al. 2004) , the cranial cervical vertebra of which have apomorphic heterocelic caudal condyles. According to Kischlat et al. (1994; but see Broin 1991; Lapparent de Broin 2000), such a plesiomorphic condition is shared by Roxochelys and Bauruemys , while in other South American fossil podocnemids ( Broin 1971; Wood 1976) most of the neck is composed of heterocelic vertebrae.

Carapace ( Figs 3-5 View FIG View FIG View FIG )

The nuchal plate, the entire neural series, and most costal and marginal elements were preserved, but not the pygal or suprapygal plates. These, as well as the plastron bones, are not particularly thick, differing from forms attributable to the genus Roxochelys ( Price 1953; Broin 1991), and no distinctive ornamentation pattern has been observed on their external surface. The round shape (25 cm long, 20 cm wide) and relatively flat (5 cm high) carapace of Cambaremys n. g e n. i s m o s t s i m i l a r t o t h o s e o f s m a l l? Roxochelys villavilensis ( Broin 1991) and some s p e c i m e n s f r o m t h e B a u r u G r o u p (A r i d & Vizotto 1966; Suárez 1969), but distinct from the deeper, more dorsally convex, and elongated carapace of other South American Cretaceous podocnemids ( Broin 1971; De la Fuente 1993, 2003; Kischlat et al. 1994; Lapparent de Broin 2000). Yet, the shape of the carapace is highly variable among modern members of the group, and might reflect the developmental stage of the individuals ( Broin 1991), the more rounded morphotype representing the juveniles. Accordingly, the size and shape of the type carapace of Cambaremys n. gen. might indicate a subadult condition, but a direct relation between the size and shape of the carapaces is not seen among various observed specimens of Bauruemys elegans (URC-R47, R58, R59).

The nuchal embayment is shallow and restricted to the cranial margin of the nuchal plate. This is elongated, articulates with the first peripheral plates along its slightly concave lateral margins, and expands caudally to contact the first neural and costal plates along a rounded caudal margin. This condition approaches that of Bauruemys elegans , although the nuchal plate of this taxon has a more extensive contact with the pair of first costals. A much broader nuchal plate is, however, characteristic of other South American Cretaceous podocnemids ( Price 1953; Broin 1971; Lapparent de Broin 2000; De la Fuente 2003).

There are seven preserved neural plates, which represent the entire series. As in most nonararipemydid Pelomedusoides ( Meylan 1996), this series does not reach the suprapygal plate. The number of neural plates varies between six and seven within the extant Podocnemidae , while South American fossil forms with six ( Suárez 1969; De la Fuente 1993, 2003) and seven ( Arid & Vizotto 1966; Broin 1971; Wood 1976; Lapparent de Broin 2000; Carvalho et al. 2002) neural plates are also known. The first neural plate is subrectangular and more elongated if compared to the following ones. It meets the nuchal plate cranially, and its slightly convex lateral and caudal margins articulate respectively with the pair of first costals and with the second

A new Cretaceous freshwater turtle ( Reptilia, Podocnemidae ) from Brazil neural plates. This arrangement is similar to that of most fossil podocnemids ( Price 1953; Arid & Vizotto 1966; Broin 1971; Lapparent de Broin 2000; Carvalho et al. 2002), but differs from that of Bauruemys ( Suárez 1969; URC-R47, R58), in which the first neural plate is much broader caudally, and the second neural plate square-shaped. This peculiar arrangement of plates allows the contact between the first neural plate and the pair of second costal plates, preventing a contact between the second neural plate and the pair of first costal plates. Yet, the difference between this and the standard podocnemid morphology must be considered carefully, given that variation seems to occur within major groups ( Gaffney et al. 2001), extant species (E.-E. Kischlat pers. comm.

França M. A. G. de & Langer M. C.

1995), and even individuals ( De la Fuente 2003; see also Lapparent de Broin 2000).

Neural plates 2-6 of Cambaremys n. gen. are hexagonal, their cranial and caudal margins contact the adjacent costal plates, while their lateral margins are divided in shorter laterocra- n i a l a n d l o n g e r l a t e r o c a u d a l f a c e t s, w h i c h respectively contact the anterior and the corre- sponding costal plates. Of these, the sixth neural plate is shorter craniocaudally, possessing a more rounded caudal margin. As with the sixth, the seventh neural plate was not preserved in articulation to the rest of the carapace and its margins are not complete. It has a subpentagonal shape, reflecting its condition as the last plate of the neural series. It has a pinched caudal margin that articulates only with the pair of seventh costal plates.

Costal plates 1-7 were preserved partially articulated on the left side of the carapace, while the eighth plate was not recovered. The first costal plates are longer craniocaudally than the rest. Their rounded cranial margins contact the nuchal plate and peripheral plates 1-4. Costal plates 2-7 are subrectangular, their lateral portion curves cranially in the more cranial plates and caudally in the more caudal ones. Laterally, they contact peripheral plates 4-10 as shown in Figure 5 View FIG , and only the seventh pair contacts one another medially. Although only left peripheral plates 1-7 were found in articulation, it was possible to reconstruct the entire series (1-11) with elements from at least one of the sides of the carapace ( Figs 3-5 View FIG View FIG View FIG ). These are subrectangular and have slightly convex distal margins, which form the carapace border. Cranial and caudal peripheral plates are elongated proximodistally, while those in the middle of the series tends to be shorter.

The plastral bridge is better preserved on the left side of the carapace ( Fig. 4 View FIG ), encompassing peripheral plates 2-8. At the cranial end of the bridge, the axillary process extends medially as a smoothly sigmoid wall that articulates with the internal surface of the first costal plate. Caudally, the articulation facet for the inguinal process extends nearly straight along the distal third of the fifth costal plate. The angle formed between the dorsal and ventral surfaces of the peripheral plates that contribute to the bridge is of about 45° at the third plate, expanding to 90° at the level of plates 5-6. In the seventh plate, the angle is of about 75° at its cranially and of 30° caudally. In the end of the bridge (eighth plate), the angle diminishes to about 5-10°.

Based on the pattern of contact sulci in its carapace, Cambaremys langertoni n. gen., n. sp. possessed no cervical scute, and the first marginal scute met its mate at the cranial border of the carapace, where they covered the cranial portion of the nuchal plate. Caudally, the vertebral scutes covered the entire neural series and the medial portions of the costal plates, while the first of them also covered the caudal half of the nuchal plate and the caudomedial corners of the first peripheral pair. On each of these plates, there is a complex sulcus pattern composed of two triradiated junctions including marginal scutes 1 and 2, vertebral scute 1, and pleural scute 1. It is also possible to reconstruct vertebral scutes 2 and 3, while the parts of scutes 4 and 5 that cover the pygal and suprapygal plates are unknown. The preserved sulci between vertebral scutes 1-2, 2-3, and 3-4 respectively divide neural plates 1, 3, and 5. Each bears a marked cranial convexity at the sagittal axis, which is least marked in the sulcus between scutes 1 and 2. Among the examined podocnemids, this differs from the condition in forms like Peltocephalus (MZUSP-3137), Portezueloemys ( De la Fuente 2003) , and Bauruemys elegans ( Suárez 1969) , which has a caudally convex sulcus between vertebral scutes 1 and 2; Peltocephalus , Roxochelys wanderleyi ( Price 1953) ,? Roxochelys vilavilensis ( Broin 1971) , and Podocnemis negrii ( Carvalho et al. 2002) , the sulcus between vertebral scutes 2 and 3 of which is not markedly convex cranially; and Podocnemis negrii that has a caudally convex sulcus between vertebral scutes 3 and 4.

The four pleural scutes covered the distal twothirds of the costal series, and the sulci between them extend transversely along costal plates 2, 4, and 6. The marginal series covered most of the peripheral plates, each scute occupying adjacent halves of two neighboring plates. The sulci between the marginal and pleural scutes extends along the proximalmost portion of the peripheral plates at the cranial (plates 1-3) and caudal (plates 7-11) segments of the series, while it is displaced proximally at the middle of the series, and superimposed to the peripheral-costal plates contact. This is also seen in most examined podocnemids, but not Bauruemys elegans ( Suárez 1969) , and? Roxochelys vilavilensis ( Broin 1971) .

Plastron ( Fig. 6 View FIG )

Most of the plastron is missing, probably due to post-mortem disarticulation and transport, but the right mesoplastron and both xiphiplastra were found inside the carapace, which was preserved upside-down. The former is round, restricted to the lateral portion of the plastron. This configuration is typical of podocnemoids (sensu Lapparent de Broin 2000), also seen in other Pelomedusoides ( Broin 1980; Gaffney & Meylan 1991), but distinct from the more lateromedially elongated mesoplastron of basal eupleurodires (De la Fuente & Iturralde-Vinent 2001) and basal chelids ( De la Fuente et al. 2001; De la Fuente 2003). In this context, the mesoplastra were most probably apomorphically connected in Pelusios and independently lost in recent Chelidae and Araripemys ( Meylan 1996) . The mesoplastron of Uberamemys has no sign of interscute sulci. On the contrary, the pectoro-abdominal sulcus of most basal pleurodires ( Broin 1980; Gaffney & Meylan 1991; De la Fuente et al. 2001; De la Fuente & Iturralde-Vinent 2001; De la Fuente 2003) extends along the cranial portion of that plate. Among podocnemoids, the pectoroabdominal sulcus usually enters the cranial bor- der of the mesoplastron in bothremydids (Antunes et al. 1 9 8 8; Gaffney et al. 2 0 0 1; MacPhee et al. 2003), but not in either fossil ( Cattoi & Freiberg 1958; Suárez 1969; Broin 1971; Wood 1976; Carvalho et al. 2002; De la Fuente 2003), or recent podocnemids, although there are exceptions within both groups ( De la Fuente 1993; Tong et al. 1998).

The right xiphiplastron ( Fig. 6A, B View FIG ) is well preserved, sub-orthogonal, and broader cranially. Its cranial and lateral edges form oblique angles to the sagittal line, while the caudolateral corner is rounded. The caudal margin is gently inclined, so that a shallow anal incisure is formed. Among South American Cretaceous podocnemids, this approaches the condition of Bauruemys elegans ( Suárez 1969; URC-R47, R58) and? Roxochelys vilavilensis ( Broin 1991) , differing from the more conspicuous incisure of “ Podocnemis ” brasiliensis ( Price 1953) . Yet, significant intraspecific variation regarding this character was reported among podocnemids ( Wood & Gamero 1971). The visceral surface of the xiphiplastron bears the articulation facets for the pubis and ischium. The pubic articulation is ovoid as in? Roxochelys vilavilensis ( Broin 1971) , and not as elongated as in Bauruemys elegans ( Suárez 1969) and “ Podocnemis ” brasiliensis ( Price 1953) . This does not seem to be fused, since suture scars are apparent. According to Kischlat et al. (1994), this condition is seen in Bauruemys elegans , but not in Roxochelys . The ischiadic articulation is subtriangular, with craniomedial, craniolateral, and caudolateral apexes. This resembles the condition in? Roxochelys vilavilensis ( Broin 1971) , and differs from the more medially expanded suture of Bauruemys elegans ( Suárez 1969) and “ Podocnemis ” brasiliensis ( Price 1953) . However, important variation in the shape of the pubic and ischiadid sutures to the plastron occurs among recent podocnemids. The external surface of the xiphiplastron bears the femoro-anal sulcus, extending obliquely at the level of the pubic articulation scar, well within the cranial half of the xiphiplastron.

Pectoral girdle and forelimb ( Fig. 7 View FIG ; Table 2)

The scapula has elongated rod-like dorsal and acromial processes. These form an angle of about 80° and no bony wall extends distally connecting them. This is typical of podocnemids, and differs from the condition in modern chelids. The dorsal process curves slightly medially, and bears no clearly defined longitudinal ridges or grooves. This differs markedly from the strongly curved and short process of Stupendemys ( Gaffney et al. 1998) , but approaches the condition of recent podocnemids. Its proximal portion is craniocaudally flattened and have an ovoid cross section. The distal tip is incomplete, but seems to be slightly expanded. The shorter acromial process also has an oval proximal cross section. At this point, its craniodorsal corner is composed of a marked longitudinal ridge, bounded ventrally by an elongated excavation. Distally, the cross section of the acromial process gets subtriangular, due to the presence of craniodorsal and ventral grooves, and a longitudinal ridge at the caudal surface. Among modern podocnemids, the development of these elements varies, and different specimens show more transversally rounded or triangular acromia. The scapular part of the glenoid cavity faces laterally as in most podocnemids, and not ventrolaterally as in Stupendemys ( Gaffney et al. 1998) . It is slightly projected from the main part of the bone, and has prominent borders, but no proper glenoid neck is seen. The articulation is subtriangular, with the cranial face the longest, and concave. The coracoid articulation is ovoid, not clearly marked, and placed caudoventrally to the glenoid cavity.

The coracoid is composed of a proximal articulation and a distal body. The former is round- ed, but flattened craniodorsally. This is where the scapula articulates, while the rest of that area forms the glenoid cavity. The main body of the bone is cylindrical proximally, but e x p a n d s d i s t a l l y t o f o r m a d o r s o v e n t r a l l y flattened lamina. Its dorsal surface is slightly convex as in Peltocephalus , lacking the sharp longitudinal ridge typical of Podocnemis . The ventral surface is concave, more deeply excavated laterally, and the distal margin is flattened. Kischlat et al. (1994) characterized two distinct coracoid morphotypes among fossil and recent podocnemids. Cambaremys n. gen. shares the plesiomorphic type with Bauruemys elegans and? Roxochelys vilavilensis . This is expanded and slim (= dorsoventrally flat), as also seen in chelids ( De la Fuente 1993), Araripemys ( Meylan 1996) , and pelomedusids ( Wood 1976). The apomorphic condition, on the other hand, is an unexpanded and deep coracoid, as seen in modern podocnemids, Erymnochelys , Stupendemys , and apparently Roxochelys wanderleyi ( Kischlat et al. 1994) .

Both humeri were preserved, although the distal half of the left bone is missing. The head forms a nearly equidimensional hemisphere, and the lateral and medial processes expand at the same ventral plane. These are connected to the dorsally projecting head by bony expansions, forming a ventrally concave surface. Shallow excavations mark the proximal limits between both processes and the head. The lateral process projects cranioproximally as in other podocnemids, and differs from the more laterally directed process of chelids. At its distal margin, lies a dorsocranial ovoid excavation for the insertion of the M. deltoideus. An equally marked muscle scar is seen in Podocnemis , but not in Peltocephalus or the examined recent chelids. The medial process is caudoproximally directed and somewhat larger than the lateral. Its proximal tip extends slightly proximal to the head. This condition is shared by Stupendemys ( Broin et al. 1993) and recent Chelidae , while the humeral head of Podocnemis tends to project more proximally than that process. According to Walker (1973) the medial process is more developed in highly aquatic Testudines such as marine turtles and trionychids. Accordingly, this condition in Cambaremys n. gen. might, at the same time, represent a plesiomorphy and an adaptation to its aquatic lifestyle. Also differently from recent Podocnemis , no clear scar for the M. subscapularis is seen on the medial process, which lacks marked crests or grooves.

The humeral shaft of Cambaremys n. gen. is dorsally arched and ovoid in cross section. As in recent podocnemids, the proximal and distal expansions of the bone are longitudinally restrict- ed, so that the shaft is proportionally longer than that of chelids. At the distal end of the humerus, the radial and ulnar condyles are ventrally direct- ed. These are of about the same size and there is no strong incisure between them. The entepicondyle and ectepicondyle are inconspicuous, but the latter is slightly larger and bears a deeply excavated groove. This extends longitudinally along the dorsomedial surface of the bone, and is homologous to the ectepicondylar foramen ( Romer 1956; Gaffney 1990), but does not perforate the humerus.

Both radia are incompletely preserved, the left bone lacks most of its distal expansion, while the right radius lacks portions of both the proximal and distal ends. The latter can, however, be reconstructed based on the impression with fragments it left on the matrix. The proximal articulation is nearly flat and roughly semicircular: longer dorsoventrally than lateromedially and flatter laterally to contact the ulna. Right distal to this contact there is a rugosity that represents the attachment of the proximal branch of the radioulnar ligament ( Haines 1942). The distal end of the radius is dorsoventrally flattened and lateromedially expanded to contact the intermedium and medial centrale. This expansion is more remarkable in Cambaremys n. gen. than in recent Podocnemis , and its lateral portion projects further distally in the former, so that its distal margin is less obliquely inclined, as also seen in Araripemys ( Meylan 1996) .

Only the right ulna of Cambaremys n. gen. was preserved, and its laterodistal corner is missing. The proximal surface is subrectangular, longer dorsoventrally than lateromedially. This is given by the ventral projection of the articulation surface, as seen in Podocnemis but not in Peltocephalus . The dorsal part of this surface is proximally projected, forming the inconspicuous olecranon process. The medial ulnar surface bears a well developed bicipital tubercle. It lays at the middle of the proximal half of the bone, clearly separated from its proximal articulation. Distal to this tendon attachment area, the medial margin of the ulna is composed of a pinched crest. At its distal third, the bone gets dorsoventrally flattened, with an elongated cross section. The ulna expands markedly at its distal margin, bearing a oblique and flat medial articulation facet for the intermedium.

Pelvic girdle and hind limb ( Fig. 8 View FIG ; Table 3)

Both pelvic girdles were preserved disarticulated from the shell and are nearly complete, although the right one is partially covered by matrix. As typical of eupleurodires ( Lapparent de Broin & Murelaga 1999; Lapparent de Broin 2000; De la Fuente & Iturralde-Vinent 2001), the pelvis of Cambaremys n. gen. has a mainly vertical orientation, and the thyroid fenestrae are united as a single large aperture. This condition is shared by other fossil podocnemoids ( Wood 1972, 1976; De la Fuente 1993, 2003; Lapparent de Broin & Werner 1998; Carvalho et al. 2002). The pelvic bones are firmly attached, and their medial contact is represented by a serrated suture. Laterally, there is a small gap between the bones that was probably filled by cartilage of the acetabular capsule. Each ilium is formed of a central waist, with dorsal and ventral expansions. The former articulated to costal plates 7-8, only the first of which is preserved in Cambaremys n. gen. This articulation is triradiated in dorsal aspect, with cranial, caudal, and caudolateral projections, the first of which is longer and more pinched. This differs from the condition of non-Pelomedusoides (sensu Lapparent de Broin 2000) pleurodires, the iliac articulation of which seems to lack well developed projections ( Meylan 1996; Lapparent de B r o i n & M u r e l a g a 1 9 9 9; D e l a F u e n t e & Iturralde-Vinent 2001). The iliac articulation of pelomedusids has a less developed cranial projection ( Lapparent de Broin & Murelaga 1999), which is better defined in other Pelomedusoides ( Broin 1991; Broin & Werner 1998; Lapparent de Broin & Murelaga 1999). In Cambaremys n. gen., from the more conspicuous cranial and caudolateral projections of the dorsal iliac margin, two crests extend ventrally along the main body of the bone, demarcating two surfaces: a more excavated laterocranial, and a rounded medial to caudal surface. The iliac acetabulum is ovoid, an there is no visible excavation on its dorsal edge.

The pubis has expanded dorsal and ventral portions, and is craniocaudally constricted in the middle. Its dorsal segment forms the cranioventral portion of the acetabulum, connecting the ilium dorsally and the ischium caudally. Distally, the bone bifurcates into medial epipubis and the lateral process. The latter is craniocaudally flattened, but expands in all directions for the articulation to the plastron. The much thinner epipubis is incomplete distally. It extends craniomedially, but it is not possible to determine if there was an expanded distal end. These two processes diverge at an almost right angle, forming a typical embayment between them. The ischium also has expanding dorsal and ventral portions. The shaft is oval in cross section, emphasizing the general craniocaudal compression of the bone. The distal portion of the better preserved left bone has a subtriangular cross section, but is incomplete distally, lacking the typical podocnemid caudal and medial projections. The former can, however, be identified in the right side.

The right femur was the only preserved. It is slightly longer than the humerus, as common for freshwater turtles ( Walker 1973). The shaft is cylindrical and discreetly arched dorsally, while the head projects dorsally. This forms a proximally opened and strongly concave intertrochanteric fossa, and a dorsoproximally directed rounded articulation. The latter is ovoid, as typical of aquatic Testudines ( Walker 1973) : caudoproximally to craniodistally elongated in dorsal aspect. The minor trochanter extends cranioproximally. Its connection to the head is damaged, but it seems to be marked by a constriction. On its distal margin, at the dorsocranial surface of the femur, there is a marked longitudinally elongated groove for the insertion of the M. puboischiofemoralis externus. The major trochanter does not split so markedly from the main body of the bone, and forms a nearly continuous proximal articulation to the femoral head. Its medial surface bears strong longitudinal striations, possibly related to the insertion of the iliofemoral musculature. The distal part of the femur is obliterated on its cranioventral portion, but the ven- t r o d i s t a l l y d i r e c t e d c o n d y l e s, a n d a s u b t l e intercondylar fossa can be distinguished. On the caudal surface of the femur, proximal to the slightly larger fibular condyle, lays a small striated area that corresponds to the origin of the M. flex- or digitorum longus. Dorsally, the distal part of the bone bears strong longitudinal striations, possibly related to the patelar tendon.

Both tibiae of Cambaremys n. gen. are well preserved. Each of them is nearly straight, although concave ventrally. Both proximal and caudal portions are expanded in relation to the shaft, but the former is much broader, so that the bone has a distally tapering outline. The proximal articulation is subtriangular, with a sharp medial corner. It bears a shallow mediocaudal excavation that receives the femoral condyle, and is convex for the rest of its surface. Starting at the dorsal corner of the proximal articulation, the cnemial crest extends distally along the dorsal surface of the bone for about one third of its length, and bears strong longitudinal striations on its medial surface. Medial to this, the tibia is pinched, with dorsal and ventral shallow longitudinal excavation that leads to an elongated protuberance at the medial margin of the bone. This is somewhat continuous to the sharp medial angle of the proximal articulation, and represents the insertion of the M. gastrocnemius. Distally, the shaft is dorsoventrally compressed and slightly excavated at the lateral and medial margins. The distal articulation surface bear two condyles separated by a notch. The medial condyle is larger, more convex, and more distally projected. The lateral condyle is flatter, but expands ventrally to its medial counterpart.

Both fibulae are preserved, but the right is distally incomplete. This is a slender bone, dorsoventrally flattened for its entire length. Its proximal portion is slightly expanded, with an ovoid and convex articulation: lateromedially broader than dorsoventrally deep. Slightly distal to that articulation, the lateral margin of the fibula bears a longitudinally elongated rugose area. This represents the typically projected origin area of the M. iliofibularis. The fibular shaft is relatively straight and ovoid in cross section. The distal end is lateromedially expanded and dorsoventrally broadened. It is laterally pinched, forming a sharp border. The distal articulation is convex and subtriangular. Two subtle condyles can be identified, and that correspondent to the calcaneum is slightly larger.

DISCUSSION AND CONCLUSION

The pleurodire affinity of Cambaremys langertoni n. gen., n. sp. is given by its pelvic girdle that is suturated to the shell, and narrower than the bifid caudal lobe of the plastron ( Lapparent de Broin 2000; De la Fuente & Iturralde-Vinent 2001). Cambaremys n. gen. is also more derived that the Jurassic representatives of the group for its cervical vertebra with a postzygapophysesbearing pedicel, narrow nuchal plate, inguinal process contacting the fifth costal plate, and vertically oriented pelvis with a single large thyroid fenestra, all of which are features that characterize Eupleurodira ( Lapparent de Broin & Murelaga 1999; De la Fuente & Iturralde-Vinent 2001). Within that clade, Cambaremys n. gen. belongs into the stem-lineage to Pelomedusoidea (sensu Meylan 1996), which is generally characterized (see Lapparent de Broin 2000; De la Fuente 2003) by traits such as the absence of the cervical scute, a nuchal plate longer than broad, a neural series that does not reach the suprapygal plate, and rounded mesoplastra. Yet, none of these characters has an unambiguous distribution, to clearly diagnose a particular eupleurodire group. This is often due to polymorphism/homoplasy within major clades such as Chelidae and Pelomedusidae , which show variation in the completeness of the neural series and/or the shape/presence-absence of the mesoplastra. That uncertainty can also reflect the extreme modification of the shell, as seen in Araripemys ( Meylan 1996) , or simply the occurrence of plesiomorphies within supposedly derived taxa, such as the broader nuchal plate of Roxochelys ( Broin 1971) . Nonetheless, the presence of all those features in Cambaremys n. gen. seems enough to assure its pelomedusoid affinity. Within that clade, De la Fuente (2003) defined an elongated plastral bridge as synapomorphic for Podocnemoidae (sensu Meylan 1996) . Besides, a pectoro-abdominal sulcus that does not encroach the mesoplastron is more typical of Podocnemidae , than of Pelomedusidae or Bothremydidae ( Gaffney et al. 2001; De la Fuente 2003), and Cambaremys n. gen. seems to belong to that group of pelomedusoids. The phylogeny of podocnemids is still a controversial issue ( Noonan 2000), especially when it comes to fossil forms ( Broin 1988; Lapparent de Broin 2000; De la Fuente 2003), and no unambiguous framework can be employed to assess the position of Cambaremys langertoni n. gen., n. sp. Nonetheless, this new species differs from recent podocnemids for its thin and expanded coracoid and proximally projected medial process of the humerus, suggesting a basal position in relation to the crown-Podocnemidae. In addition, its coracoid shape also indicates a basal position in relation to Stupendemys . No autapomorphic feature was recognised for Cambaremys n. gen., but it differs from all well known South American Cretaceous podocnemids based on a unique suite of shell features. It is distinct from Roxochelys wanderleyi ( Table 4) and? Roxochelys vilavilensis for its thinner shell bones and narrower nuchal plate, from Portezueloemys patagonica for the presence of a seventh neural plate, from Bauruemys elegans ( Table 4) for that same character and the contact between the first costal and second neural plates, and from the undetermined podocnemid described by De la Fuente (1993) for a pectoroabdominal sulcus that does not touch the mesoplastron.

The differentiation of Cambaremys langertoni n. gen., n. sp. from “ Podocnemis ” brasiliensis is not so straightforward, due to the small overlapping of elements preserved in both taxa. Yet, the anal notch of Cambaremys n. gen. is shallower, and the pelvic sutures to its plastron less transversely expanded. This is clearer in the ischiadic suture, which only briefly contacts its mate medially. Wood & Gamero (1971) demonstrated that among three specimens of Bairdemys venezuelensis (gen. Gaffney & Wood 2002) the larger ones have a more incised “U-shaped” anal notch. Likewise, it is expected of older individuals to have a more extensive suture of pelvic bones to the shell. Accordingly, both features that putatively distinguish Cambaremys n. gen. from “ Podocnemis ” brasiliensis could be explained if the former was considered a younger individual. This fits the larger size of “ Podocnemis ” brasiliensis , the xiphiplastron of which is 2.4 times longer than that of Cambaremys n. gen., and the roundshaped carapace of the latter, which is more typical of juvenile podocnemids ( Broin 1991). Accordingly, based on these features, the possibility that C. langertoni n. gen., n. sp. represents a juvenile of “ P.” brasiliensis cannot be dismissed until more complete specimens of both taxa are recovered. On the other hand, the type locality of C. langertoni n. gen., n. sp. has yielded a larger (1.4 times longer and almost two times broader) isolated xiphiplastron of uncertain affinities, but possibly referable to that taxon by topotypy ( Fig. 6F View FIG ). This resembles the type specimen of C. langertoni n. gen., n. sp. in the shape of the anal notch and ischiadic suture, pointing to the taxonomic uniqueness of that taxon, and to its distinction from “ P.” brasiliensis .

In terms of palaeoecology, Cambaremys langertoni n. gen., n. sp. was surely an aquatic turtle, as given by its flat shell and parameters such as the more distally projected medial process of the humerus and elongated femoral head ( Walker 1973). This fits into the depositional environment proposed for the Sarra da Galga Member in the area of Uberaba ( Fernandes & Coimbra 2000), which was dominated by braided fluvial systems and medial to distal alluvial fans, in a semi-arid climate.