Abstracts

EARTH SCIENCES

Mesozoic dinosaurs from Brazil and their biogeographic implications

Jonathas S. Bittencourt^I; Max C. Langer^II

^IPrograma de Pós-Graduação em Biologia Comparada, Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto Universidade de São Paulo, Avenida Bandeirantes, 3900, Monte Alegre, 14040-901 Ribeirão Preto, SP, Brasil

^IIDepartamento de Biologia, Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto Universidade de São Paulo, Avenida Bandeirantes 3900, Monte Alegre, 14040-901 Ribeirão Preto, SP, Brasil

^{Correspondence to} Correspondence to: Jonathas Bittencourt E-mail: jonathas@pg.ffclrp.usp.br

ABSTRACT

The record of dinosaur body-fossils in the Brazilian Mesozoic is restricted to the Triassic of Rio Grande do Sul and Cretaceous of various parts of the country. This includes 21 named species, two of which were regarded as nomina dubia, and 19 consensually assigned to Dinosauria. Additional eight supraspecific taxa have been identified based on fragmentary specimens and numerous dinosaur footprints known in Brazil. In fact, most Brazilian specimens related to dinosaurs are composed of isolated teeth and vertebrae. Despite the increase of fieldwork during the last decade, there are still no dinosaur body-fossils of Jurassic age and the evidence of ornithischians in Brazil is very limited. Dinosaur faunas from this country are generally correlated with those from other parts of Gondwana throughout the Mesozoic. During the Late Triassic, there is a close correspondence to Argentina and other south-Pangaea areas. Mid-Cretaceous faunas of northeastern Brazil resemble those of coeval deposits of North Africa and Argentina. Southern hemisphere spinosaurids are restricted to Africa and Brazil, whereas abelisaurids are still unknown in the Early Cretaceous of the latter. Late Cretaceous dinosaur assemblages of south-central Brazil are endemic only to genus or, more conspicuously, to species level, sharing closely related taxa with Argentina, Madagascar, Indo-Pakistan and, to a lesser degree, continental Africa.

Key words: Brazil, Dinosauria, Triassic, Jurassic, Cretaceous, paleobiogeography.

RESUMO

O registro osteológico de dinossauros no Mesozóico brasileiro está restrito a rochas triássicas do Rio Grande do Sul e estratos cretáceos de várias partes do país. Isto inclui 21 espécies nominais, sendo duas referidas como nomina dubia, e 19 consensualmente classificadas como dinossauros. Oito táxons supraespecíficos adicionais baseados em material fragmentado e diversas pegadas são conhecidos no Brasil. De fato, a maior parte dos espécimes é composta de dentes isolados e vértebras. Apesar do aumento em trabalhos de campo na última década, não há exemplar esqueletal de dinossauro no Jurássico brasileiro, e é escassa a evidência de Ornithischia. Faunas dinossaurianas aqui registradas são em geral correlatas com aquelas da Pangéia durante o Mesozóico. No Triássico Superior, há uma correspondência próxima com a Argentina e outras regiões sul-gondwânicas. Faunas do Cretáceo médio do nordeste brasileiro são semelhantes às dos depósitos coevos do norte da África e Argentina. Registros de espinossaurídeos no hemisfério sul estão restritos à África e Brasil, enquanto abelissaurídeos não são conhecidos no Cretáceo Inferior deste último. Assembleias de dinossauros da região sul e central do Brasil são endêmicas apenas em nível de gênero e, mais conspicuamente, espécie, compartilhando táxons proximamente relacionados com assembleias da Argentina, Indo-Paquistão, e, num menor grau, África continental.

Palavras-chave:Brasil, Dinosauria, Triássico, Jurássico, Cretáceo, paleobiogeografia.

INTRODUCTION

The sesquicentennial history of dinosaur research in Brazil (e.g., Allport 1860, Marsh 1869, Mawson and Woodward 1907, Huene 1942, Price 1960, 1961, Colbert 1970, Arid and Vizotto 1971, Bertini and Campos 1987, Frey and Martill 1995, Kellner and Campos 1996) is experiencing, since the last decade, its more prolific period. Taxa from a variety of dinosaur clades have been recorded in the Triassic strata of the Santa Maria and Caturrita formations (Langer et al. 2007a), the mid-Cretaceous of the Araripe and São Luís-Grajaú basins (Frey and Martill 1995, Kellner 1996a, b, 1999, Medeiros et al. 2007), and the Late Cretaceous of Bauru and Parecis groups (Franco-Rosas et al. 2004, Kellner et al. 2004). Although still limited for some geologic periods and taxa (Kellner and Campos 2000), Brazilian dinosaur records have yielded significant data for studies of the phylogeny and evolution of the group in the Mesozoic. Among several aspects of dinosaur research that are drawing attention in the last years, biogeography is particularly noticeable (Forster 1999, Sereno 1999a, Upchurch et al. 2002, Butler et al. 2006, Smith et al. 2008, Nesbitt et al. 2009). Indeed, biogeography is growing as a science (Lomolino et al. 2006, Morrone and Guerrero 2008), and much of its conceptual framework is well set. Nonetheless, as emphasized by several authors (e.g., Lieberman 2002, 2003), accurate interpretations of the fossil record are necessary starting-points for constructing reliable hypotheses of endemic range, upon hich all paleobiogeographic hypotheses are erected. In this paper, we provide a reevaluation of the Brazilian dinosaur record from Triassic to Cretaceous ages based primarily on body-fossils, and discuss their relevance in the light of recent hypotheses dealing with dinosaur biogeography in the Mesozoic (Upchurch et al. 2002, Sereno et al. 2004, Krause et al. 2006, Nesbitt et al. 2009).

DINOSAUR RECORD IN THE BRAZILIAN MESOZOIC

GONDWANA II SUPERSEQUENCE (PARANA BASIN)

Triassic dinosaurs in Brazil were exclusively collected from rocks of the Santa Maria and the overlying Caturrita formations, in central Rio Grande do Sul (Fig. 1, Table I, ^II , Langer et al. 2007a). These units belong to the Rosario do Sul Group (Andreis et al. 1980), which corresponds to the Gondwana Supersequence II of the Paraná Basin (Milani 2004). Recent studies explain the origin of this Supersequence as the infilling of tectonically restricted half-graben depocenters (Milani 2001, 2004, Zerfass et al. 2003). The Santa Maria Formation is composed predominantly ofred mudstones (Andreis et al. 1980, Scherer et al. 2000, Silva et al. 2003) and encompasses two distinct faunal associations of Ladinian and Carnian age (Barberena 1977, Langer et al. 2007a), as also suggested by stratigraphic studies (Zerfass et al. 2003). The Ladinian sequence represents a more humid phase within a generally seasonal and semi-arid climate. Fossil tetrapods were preserved either in lacustrine environments or in flood plains of an anastomosed fluvial system (Scherer et al. 2000, Zerfass et al. 2003). The Carnian sequence was formed in a similar environment, but the presence of aeolian deposits suggests an increased aridity (Zerfass et al. 2003). The coarser-grained, red sandstones of the Caturrita Formation represent the establishment of a perennial braided fluvial system, hinting at the return of more humid conditions (Holz and Scherer 2000, Zerfass et al. 2003). The age of this unit has been generally accepted as Norian (Rubert and Schultz 2004, Bonaparte et al. 2007, Langer et al. 2007a).

The only possible dinosaur recovered from the Ladinian sequence of the Santa Maria Formation is Spondylosoma absconditum Huene, 1942 (^{Table II} ). Proposed affinities for this taxon varied from Saurischia (Huene 1942, Langer 2004) to Pseudosuchia (Galton 2000), or even Silesauridae (Dzik 2003). However, the specimens referred to this taxon, which include isolated vertebrae, teeth, elements of the pectoral member and pelvic girdle (Galton 2000), are too incomplete to allow their unequivocal identification as a dinosaur (Langer et al. 2010). No osteological remains from other parts of Pangaea suggest the presence of dinosaurs in the Ladinian, but possible footprints from Europe and Argentina (Haubold and Klein 2002, Marsicano and Barredo 2004, Diedrich 2009) may represent earliest dinosaurs in the fossil record. Although the attribution of several of these Triassic footprints has been disputed (King and Benton 1996), the issue is still unresolved (Melchor and de Valais 2006, Marsicano etal. 2007, Silva et al. 2008).

The Carnian witnessed the beginning of the dinosaur radiation, although taxa attributed to this clade are still rare (Langer et al. 2010, Nesbitt et al. 2009). This radiation has been studied in the light of the climatic changes registered in the end of the Triassic (Tucker and Benton 1982, Golonka and Ford 2000). In the Late Triassic strata of Rio Grande do Sul, these events are represented by an aridity increase during the Carnian (Zerfass et al. 2003), leading to the establishment ofa mesoxerophytic flora dominated by the gymnosperm Dicroidium and concomitant faunal changing (Azevedo et al. 1990).

Herbivorous dicynodonts were the dominant primary consumers in pre-Carnian stages of the Santa Maria Formation paleoenvironment. In the Carnian-Norian, this dominance decreased with the diversification of rhynchosaurs, with a maxillomandibular apparatus specialized in crushing hard plant material (Benton 1983b), and the arising of small herbivorous/omnivorous dinosauriforms as Saturnalia tupiniquim Langer et al. 1999, and Sacisaurus agudoensis Ferigolo and Langer 2007. In addition, recent fieldwork in the Santa Maria Formation suggests the presence of larger-bodied sauropodomorphs anatomically similar to Saturnalia (Da Rosa et al. 2006). Secondary consumers, predominantly composed by rauisuchian taxa in the Ladinian, became more diversified in the Carnian with the arising of small-bodied saurischians represented by the herrerasaurid Staurikosaurus pricei Colbert, 1970. Herrerasaurids are well known in South American Carnian strata (Sereno and Novas 1992, Novas 1997, Langer 2004, Bittencourt and kellner 2009, Alcober and Martinez 2010, Langer et al. 2010). Norian records from the Chinle Formation (Long and Murry 1995, Nesbitt et al. 2007) and Dockum Group (Nesbitt and Chatterjee 2008) have been recurrently mentioned (Irmis et al. 2007a, Nesbitt et al. 2009, 2010), but these are based on less complete material. Herrerasaurids have been preliminary reported in India (Novas et al. 2009a), but additional data is needed to fully evaluate these occurrences. Basal members of the sauropodomorph lineage are represented by Saturnalia and other Gondwanan records, such as Panphagiaprotos Matinez and Alcober 2009 and Chromogisaurus novasi Ezcurra 2010, both from the Ischigualasto Formation, Argentina, and a possible occurrence in southern frica (Raath 1996, Langer et al. 1999). Some authors have proposed a close relationship between these widespread taxa/specimens (Ezcurra and Novas 2009, Ezcurra 2010). If this hypothesis is confirmed, the saturnalian lineage would represent the first sauropodomorph-related radiation in the southern hemisphere.

From a global perspective, dinosaur diversification becomes more evident in the Norian, when sauropodomorphs and theropods are variably registered in Argentina, North America, Europe, and South Africa (Benton 1983a, Crompton and Attridge 1986, Galton 1990, Colbert 1989). The dinosaur record of the Caturrita Formation follows that pattern: Guaibasaurus candelariensis probably represents a theropod (Fig. 2) (Bonaparte et al. 1999, Langer et al. 2007b, Bittencourt 2008), although this classification has been disputed in favor of a sauropodomorph affinity (Bonaparte et al. 2007, Ezcurra 2010), while the plateosaurid Unaysaurus tolentinoi, described by Leal et al. (2004), represents a South American branch of the worldwide prosauropod diversification (Fig. 2) (Buffetaut et al. 1995, Galton and Upchurch 2004a, Yates 2007a). Additional saurischian specimens recovered from the Caturrita Formation require further inquiry to allow a robust classification within any dinosaurian clade (Kischlat and Barberena 1999, Lyrio et al. 2004).

The recent discovery of two new dinosaur-related forms from the Santa Maria beds provides significant biogeographic data on the origin and early evolution of dinosaurs. Cabreira et al. (2007) announced an alleged primitive neotheropod with coelophysoid affinities from the Carnian of Santa Maria Formation based on cranial and postcranial remains. However, this specimen bears similarities with some basal sauropodomorphs (e.g., Langer et al. 1999, Martinez and Alcober 2009). The dinosauriform Sacisaurus agudoensis from the Caturrita Formation (Ferigolo and Langer 2007) is allied with Silesaurus opolensis from the Carnian of Poland (Dzik 2003), in the Silesauridae. This clade encompasses other species from North America, Africa, and South America (Irmis et al. 2007a, Bittencourt and Langer 2009, Nesbitt et al. 2009, 2010, Langer et al. 2010), ranging from Anisian to Norian times. In this context, S. agudoensis is a late representative of the silesaurids. The phylogenetic position of this group as basal dinosauriforms is better supported by cladistic analyses (Langer 2004, Ezcurra 2006, Langer and Benton 2006, Yates 2007a, b, Irmis et al. 2007a, Nesbitt et al. 2009, 2010), although an ornithischian affinity has been suggested by many authors (Dzik and Sulej 2007, Ferigolo and Langer 2007, Langer et al. 2007a, Niedzwiedzki et al. 2009). The biogeographic and biochronological implication of this conundrum is evident. Ifsilesaurids are treated as ornithischians, the occurrence of silesaurids in Anisian strata of the African Manda Formation (Nesbitt et al. 2010) results in a ghost lineage for Saurischia, because the oldest (Carnian) unambiguous record of this clade is at least 10 million years younger (Rogers et al. 1993). Alternatively, if silesaurids are not ornithischians, the low diversity of the latter group in comparison with saurischians in Late Triassic vertebrate assemblages remains to be satisfactorily explained. This is especially intriguing for the Carnian-Norian of south Brazil, as ornithischian taxa are known from correlated deposits of both Argentina and South Africa (Casamiquela 1967, Baez and Marsicano 2001, Irmis et al. 2007b, Butler et al. 2007).

ARARIPE BASIN

Dinosaurs from the Araripe Basin (Fig. 3, Table I, ^II ) are restricted to the Santana Formation, which was deposited in the context of post-rift tectonic events that led to the fragmentation of Gondwana and opening of the South Atlantic Ocean (Ponte and Appi 1990, Ponte 1996, Ponte and Ponte Filho 1996). This includes the Rio da Batateira Formation, which initiates a regressive transgressive sedimentary cycle with the deposition of fluviolacustrine sediments into the depressions formed during rifting (Ponte and Ponte Filho 1996). The overlying Santana Formation is associated with the subsequent development of an extensive lacustrine system and an eventually massive marine incursion (Maisey 1991, Arai and Coimbra 1990). This sequence ends with the regressive phase of the cycle, represented by the fluvial sandstones of the Exu Formation (Beurlen 1971, Assine 1992). The main fossil bearing localities of the Santana Formation, in the northeastern region of Brazil, are widespread along the borders of the Araripe Plateau (Kellner and Campos 1999, 2000, Kellner 2002a, Kellner et al. 2002, Viana and Neumann 2002, Martill 2007a). Several authors divide the Santana Formation into Crato, Ipubi, and Romualdo members (Beurlen 1971, Ponte and Ponte Filho 1996, Kellner and Campos 1999, 2000, Fara et al. 2005). This proposal will be followed here, although the treatment of these subunits as individual formations has also gained support in the literature (Assine 1992, Martill 1993, Martill and Wilby 1993, Neumann and Cabrera 1999, Maisey 2000, Martill 2007a, Martill and Heimhofer 2007).

The geology of the Crato Member has been recently reviewed (see Martill et al. 2007a) and only a brief summary is presented here. This unit is composed of laminated limestone deposited in a lacustrine context during Aptian-Albian times (Pons et al. 1990, Ponte and Ponte Filho 1996, Maisey 2000, Neumann et al. 2002, Silva et al. 2002, Viana and Neumann 2002). The depositional settings have variously been interpreted as either fresh, brackish, or hypersaline waters (Martill 2007a, Martill and Bechly 2007, Martill et al. 2007b), but their fauna better corresponds to that of a non-marine environment (Maisey 1990, 1991, 2000). Due to the exquisite fossil preservation, the Crato Member is the first of two Lagerstatten of the Santana Formation (Kellner and Campos 1999). The Ipubi Member represents a transitional evaporitic phase (Beurlen 1971, Ponte and Ponte Filho 1996, Martill and Wilby 1993), and its fossil content, which does not include dinosaurs, is insignificant if compared to the other stratigraphic units of the Santana Formation (Kellner 1999). The Romualdo Member is mainly composed of shale and marls whose fossils are three-dimensionally preserved in calcareous nodules (Kellner and Campos 1999, 2000). Due to the high diversity, abundance and excellent preservation of the specimens, this member represents the second Lagerstatte of the Santana Formation (Kellner and Campos 1999, Fara et al. 2005). The sediments of this unit are Albian in age (Pons et al. 1990, but see Martill 2007b) and were deposited in a shallow brackish environment, which was formed during an episodic marine incursion (Ponte and Ponte Filho, 1996). For some authors (Arai and Coimbra 1990, Arai 1999), the Santana Formation is part of a massive transgressive event, which formed an epicontinetal sea over a significant portion of north-northeastern Brazil (but see Martill 2007a). Whichever scenario is better supported by available data, the dinosaurs are land-dwelling, and can be regarded as allochtonous components of the Romualdo Member thanatocenoses (Naish et al. 2004).

All dinosaurs from the Santana Formation are theropods (Table I, ^II ), and at least four different clades have been identified. The only mention of ornithischians (Leonardi and Borgomanero 1981) was based on a bone fragment interpreted as part of an ischium, later reidentified as a rib and tentatively assigned to a spinosaurid due to its size (Machado and Kellner 2007). Several types of feathers from the Crato Member (Martins Neto and Kellner 1988, Kellner 2002b, Kellner et al. 1994, Martill and Figueira 1994, Martill and Frey 1995) initially hint at the presence of avian taxa in the Aptian-Albian of northeastern Brazil. However, this hypothesis has been challenged by the occurrence of asymmetrical feathers in non-avian eumaniraptorans (Witmer 2002). On the other hand, based on two poorly preserved specimens, Naish et al. (2007) reported possible birds from the Crato Member. One of the specimens is quite incomplete and housed in Frankfurt; the other is more complete and held in a private collection in Japan. The authors did not provide further data on the provenance of the specimens, as occur with most materials from the Santana Formation often collected without any stratigraphical control (Fara et al. 2005). Among the relevant features described by Naish et al. (2007, plates 25-26), the Frankfurt specimen bears evidence ofasymmetrical feathers, while the Japan individual shows a reversed hallux. The occurrence of Aves in the Crato Formation is expected both chronostratigraphically and biogeographically, as this clade is known since the Late Jurassic and widespread in the Early Cretaceous (Fig. 2, ^4b ) (Padian 2004).

The most common theropods from the Santana Formation are the spinosaurids, with two described species and additional postcranial remains (Martill et al. 1996, Kellner and Campos 1996, Kellner 1996b, Sues et al. 2002, Bittencourt and Kellner 2004, Machado and Kellner 2005). This clade (Fig. 2) has been recorded in the Barremian of Europe (Charig and Milner 1997, Buffetaut 2007) and Early Cretaceous of Thailand and China (Buffetaut and Ingavat 1986, Buffetaut et al. 2008), but reached its greatest diversity in the Aptian-Cenomanian of northern Africa (^{Fig. 4b} , Stromer 1915, Taquet and Russell 1998, Sereno et al. 1998, Buffetaut and Ouaja 2002, Dal Sasso et al. 2005, Smith et al. 2006), when faunistic similarities with northeastern Brazil are evident. Typical Laurasian theropod clades have been tentatively reported in the Romualdo Member of the Santana Formation. Frey and Martill (1995) referred an incomplete sacrum to Oviraptorosauria, a group that has also been registered in other parts of the Gondwana, as Australia (Currie et al. 1996) and Argentina (Frankfurt and Chiappe 1999). However, more recent studies contested these evidences (Makovicky and Sues 1998, Kellner 1996b, Agnolin and Martinelli 2007), and further work is needed to confirm the Gondwanan occurrence of this clade. The small-bodied Santanaraptor placidus, based on an incomplete postcranial skeleton not yet described in detail, was initially related to Maniraptoriformes (Kellner 1999) and later to Tyrannoraptora (Kellner 2001). Although both clades have controversial definitions in the literature (Sereno 1999b, Holtz 2004, Holtz et al. 2004, Senter 2007), their representatives are kno n in virtually all continents at the end of the Early Cretaceous (Rauhut 2003). Holtz (2004) referred S. placidus to Tyrannosauroidea (Fig. 2), which is congruent with at least another Gondwanan occurrence of the group (Benson et al. 2010). The clade Compsognathidae was identified in the Santana Formation based on the skeletal remains attributed to Mirischia asymmetrica (Martill et al. 2000, Naish et al. 2004). This is both the only Gondwanan and the youngest record of the group, otherwise known only from the Late Jurassic and Early Cretaceous of China and Europe (Zhou et al. 2003, Holtz et al. 2004, Hwang et al. 2004, Naish et al. 2004).

SÃO LUÍS-GRAJAÚ BASIN

The São Luís-Grajaú Basin was formed by partial subsidence of the former Parnaiba Basin (Fig. 3), following the uplift of the Ximbioa Arc during the opening of the South Atlantic Ocean, in an area corresponding to the north of the Maranhao State (Goes and Rossetti 2001, Santos and Carvalho 2004). The dinosaurs from this region (Carvalho et al. 2003, Medeiros et al. 2007) were all recovered from rocks of the Itapecuru Group, which overly the lacustrine deposits of the Codo Formation and the aeolian sandstones of the Grajau Formation, both of Aptian age (Rossetti et al. 2001a). According to Rossetti (2001), but see also Rossetti and Truckenbrodt (1997) and Santos and Carvalho (2004), the Itapecuru Group is divided in three stratigraphic units: a) the Albian age "Undifferentiated Unit", represented by several localities with complex and diverse lithology associated with marine, lacustrine, and floodplain environments; b) the Alcântara Formation, composed of stratified sandstones, mudstones, and limestones deposited during the early Cenomanian in an estuarine environment; c) the Cujupe Formation whose age ranges from the Late Cretaceous to Paleocene, and devoid of dinosaur records. Rossetti et al. (2001b) suggested a dry, warm climate during the deposition of the "Undifferentiated Unit", whereas the Alcântara Formation is associated with an increasingly humid, but still seasonal semi-arid climate. The so-called "Itapecuru Formation", which crops out in the Itapecuru-Mirim region (Ferreira et al. 1992, Carvalho et al. 2003), is an informal unit that roughly corresponds to the "Undifferentiated Unit" (Rossetti et al. 2001a, Santos and arvalho 2004). The ost ipor tant fossil localities with dinosaur remains of the São Luis-Grajau Basin are: Coroata and Mata ("Undifferentiated Unit"/"Itapecuru Formation": Carvalho et al. 2003, Ribeiro et al. 2003, Castro et al. 2007) and Ilha do Cajual and Praia da Baronesa (Alcântara Formation: Elias et al. 2007, Medeiros et al. 2007).

The Itapecuru Group dinosaur fauna (Fig. 3, Table I, ^II ) based on skeletal remains includes specimens attributed to Sauropoda and Theropoda (Carvalho et al. 2003, Medeiros et al. 2007), and a possible ornithischian record (Avilla et al. 2003). Carvalho and Pedrao (2000) have recorded theropod and ornithischians footprints. The fossil preservation is, however, not exceptional, hampering their identification. Among theropods, several genera from North Africa as Carcharodontosaurus, Sigilmassasaurus (Sereno et al. 1996, Novas et al. 2005a, 2006, Brusatte and Sereno 2007), and Spinosaurus have been reported based on isolated vertebrae and teeth (Vilas Boas et al. 1999, Medeiros 2006, Medeiros and Schultz 2001, 2002, Medeiros et al. 2007, Ribeiro et al. 2003). Yet, the diagnoses of these taxa include anatomical details not available in the Itapecuru Group material, and they are here treated only as indeterminate Carcharodontosauridae and Spinosauridae (Table I, ^II ). Additionally, the record (Medeiros and Schultz 2002, p. 156) of "Baharijasaurus" [sic] (= Bahariasaurus Stromer 1934), a possible carcharodontosaurid from North Africa (Rauhut 1995, Holtz et al. 2004), is also uncertain and here referred to as an indeterminate theropod. Carcharodontosauridae and Spinosauridae specimens are known from both the "Undifferentiated Unit" and the Alcântara Formation, the latter also yielding a new spinosaurid (see Kellner et al. 2011), increasing to 19 the number of dinosauriform species from Brazil consensually assigned to Dinosauria. These records are congruent with the already mentioned abundance of spinosaurids in the Cenomanian of North Africa (Fig. 2, ^4b ) (Russell 1996, Sereno etal. 1998, Dal Sasso etal. 2005, Smith etal. 2006). Carcharodontosaurids are also common in the Aptian to Cenomanian ofAfrica and South America (Holtz et al. 2004, Sereno et al. 2004, Novas et al. 2005a, Brusatte and Sereno 2007, 2008, Casal et al. 2009), as well as in older Laurasian deposits (Holtz et al. 2004).

Further isolated teeth fro the Itapecuru roup were referred to Velociraptorinae (Elias et al. 2007), a maniraptoran group of disputed taxonomic validity within Dromaeosauridae (Makovicky et al. 2005), recorded in the Early Cretaceous of North America and Late Cretaceous of Eurasia (Norell and Makovicky 2004). In this work, we consider all Brazilian records of Velociraptorinae (see below: Bauru Supersequence) as indeterminate Deinonychosauria (Table I, ^II ), pending new findings that would allow a more accurate identification of these specimens. In Gondwana, dromaeosaurid deinonychosaurs are known based on several species from the Cenomanian-Maastrichtian of Argentina (Novas and Puerta 1997, Novas and Pol 2005, Calvo et al. 2004, Makovicky et al. 2005, Novas et al. 2009b), with possible records in the Cenomanian of central Africa (Rauhut and Werner 1995) and Albian of Australia (^{Fig. 4b} ) (Currie et al. 1996).

The sauropod fauna of the Itapecuru Group (Tables I, ^II ) includes Diplodocoidea and Titanosauria, as well as specimens of uncertain affinities (e.g., Astrodon" , Medeiros and Schultz 2001, Medeiros et al. 2007). Diplodocoids are represented by Amazonsaurus maranhensis (Carvalho et al. 2003) and indeterminate remains (Castro et al. 2007) recovered from the "Undifferentiated Unit" ("Itapecuru Formation"). Some authors regarded A. maranhensis as a basal macronarian(Rauhut et al. 2005, Lloyd et al. 2008), but most phylogenetic studies refer this species to as diplodocoid (Salgado et al. 2004). This taxon is both geographically and chronologically widespread, with coeval records in Argentina, Africa and North America (Figs. 2, ^4b ) (Upchurch et al. 2004, Wilson 2005). Several isolated specimens have been regarded as Rebbachisauridae (Medeiros and Schultz 2001, 2004, Medeiros et al. 2007), a group with an abundant record in Aptian-Coniacian deposits of Argentina and North Africa (Upchurch et al. 2004, Gallina and Apesteguia, 2005), but also from older strata of Europe (Sereno and Wilson 2005, Sereno et al. 2007, Mannion 2009) and possibly South Africa (Figs. 2, ^4b ) (Canudo and Salgado 2003). According to Medeiros and Schultz (2004), some specimens from the Alcântara Formation have affinities with "Rebbachisaurus" tamesnensis (Lapparent 1960), a North African taxon with uncertain status (Calvo and Salgado 1995, Sereno et al. 1999, pchurch et al. 2004), and ith the better known Rayososaurus tessonei. The latter has been referred to Limaysaurus by Salgado et al. (2004) and recorded in the Aptian-Cenomanian of Argentina (Calvo and Salgado 1995). Among Titanosauria, a group better discussed in the next section, indeterminate fragments were recovered from both the "Undifferentiated Unit" (Castro et al. 2007) and the Alcântara Formation, i.e., ?Aegyptosaurus, ?Malawisaurus, and "Titanosauridae" (Medeiros and Schultz 2001, Medeiros et al. 2007). Medeiros and Schultz (2002) also mentioned the presence of andesaurid remains in the Alcântara Formation. This poorly known and probably paraphyletic group has been described from the Cretaceous ofArgentina (Bonaparte and Coria 1993, Salgado et al. 1997) with possible records in the Albian of North Africa (Russell 1996).

BAURU AND PARECIS GROUPS

The Cretaceous of the Bauru Group (sensu Soares et al. 1980) has so far provided the most significant record of Brazilian dinosaurs (Kellner and Campos 2000). Its strata are also referred to as Bauru Supersequence (Fig. 1, sensu Milani 2001) and were formed in an extensive subsidence area created by the lithostatic load of the Early Cretaceous basalts of the Serra Geral Formation, upon which the Bauru beds are discordantly deposited (Fulfaro and Perinotto 1996, Fernandes and Coimbra 2000, Milani 2004). Concentrated in the central-northern portion of the Paraná Basin, depocenter of the preceeding massive basalt flood (Zalan et al. 1990), the main body of the Bauru Supersequence ranges from São Paulo and western Minas Gerais to northwestern Paraná, eastern Mato Grosso do Sul and southern Goias (Fig. 1). Some authors consider that the Bauru beds were deposited in a differentiated tectonic context (i.e., the Bauru Basin, see Fulfaro and Perinotto 1996, Fernandes and Coimbra 2000, Fernandes 2004), but we follow the more traditional view, which includes the Bauru strata within the Paraná Basin (Baptista et al. 1984, Soares et al. 1980, Mezzalira 1981, Milani 2004).

The Bauru dinosaurs (Table I, ^II ) are commonly found in localities of western São Paulo and Minas Gerais, where the Adamantina and Marilia formations are widely known for their rich fossiliferous content (Bertini et al. 2003, Candeiro etal. 2006a, 2008). These stratigraphic units have been split in several salle r units (Fernandes and Coimbra 2000, Fernandes 2004), but the traditional nomenclature of Soares et al. (1980) is still largely used in paleontological studies. This occurs mainly because of the problem of referring earlier fossil findings to the new units of more elaborated stratigraphic frameworks. In an attempt to fully exploit the biogeographic data, we will again follow this traditional interpretation. The age of the Adamantina Formation as Campanian-Maastrichtian (Gobbo-Rodrigues et al. 1999, Santucci and Bertini 2001) has been challenged by Dias-Brito et al. (2001) who proposed an older (i.e., Turonian-Santonian) age for this unit. However, we agree with Gobbo-Rodrigues et al. (2003) that the concomitant occurrence of microfossils typical of Aptian-Cenomanian and Campanian-Maastrichtian intervals (Dias-Brito et al. 2001, p. 278) are not conclusive evidence for ascribing an intermediate age for the Adamantina Formation. However, it should be noted that this stratigraphical unit originated from different depositional cycles, as suggested by its division into superposed smaller units (Fernandes and Coimbra 2000). In addition, some dinosaur records that indicate a younger age for the Adamantina Formation (R.M. Santucci unpublished data) apparently comes from upper cycles (Localities L2 and L26 of Dias-Brito et al. 2001), suggesting that the Adamantina Formation congregates rocks of significantly different ages, with still poorly sampled individual biotas. The geological setting of this stratigraphic unit encompasses aeolian, lacustrine, and fluvial, i.e. braided meandering rivers, deposits (Fernandes 2004). Current data support a warm, seasonal, and arid to semi-arid climate with more humid periods (Goldberg and Garcia 2000, Dias-Brito etal. 2001). According to Goldberg and Garcia (2000), the arid conditions increased towards the top of the Bauru Group, represented by the Marilia Formation. This unit is divided into the Serra da Galga, Ponte Alta, and Echaporã members, composed of alluvial fans associatedwith braided canals and subordinated levels of aeolian sediments and calcrete (Fernandes and Coimbra 2000). The age of the Marilia Formation is generally accepted as Maastrichtian (Gobbo-Rodrigues et al. 1999, Dias-Brito et al. 2001, Campos et al. 2005).

Cretaceous deposits of the northestern argin of the Paraná asin crop out in the state of ato rosso (Fig. 1). Their strata have been referred to the Cambambe Formation (sensu Weska et al. 1996), which was deposited in a fluviolacustrine system associated to distal parts of alluvial fans under a semi-arid to extremely arid climate (Rosa et al. 1991, Weska 2006). This unit has been traditionally referred to the Bauru Group (Franco-Rosas et al. 2004, Lacerda Filho et al. 2004), but recent work suggests that all Cretaceous rocks deposited south of the Paraguai fold belt (Almeida 1984) in Mato Grosso should be included in the Parecis Group (Weska 2006). These deposits accumulated on a crust depression formed by tectonic distension events related to the magmatic plume of Trindade (Weska 2006). The basalts of the Paredao Grande Formation, at the base of the Parecis Group, were dated 83.9 ± 0.4 Ma (Gibson et al. 1997), i.e. Late Santonian (Gradstein and Ogg 2004). This geophysical and other paleontological evidence (Franco-Rosas et al. 2004) suggest a Campanian-Maastrichtian age for the dinosaur fauna of the Parecis Group.

Most dinosaur specimens collected from the Cretaceous of the Paraná Basin (^{Table II} ) are isolated teeth and vertebrae (Bertini et al. 1993, Santucci and Bertini 2001, Kellner and Campos 2000, Franco-Rosas 2001, Candeiro et al. 2006a, b), while dinosaur eggs were also recorded in western Minas Gerais ('Triangulo Mineiro' region, Ribeiro 1999, Gobbo-Rodrigues et al. 2005). The majority of these were attributed to Titanosauria (Candeiro et al. 2006a), including those referred to the controversial group "Titanosauridae" (see Salgado et al. 1997, Wilson and Upchurch 2003, Curry Rogers 2005). In the present work, these fragmentary records are all referred to indeterminate Titanosauria. In general, titanosaur species from the Brazilian Cretaceous (Table I, ^II ), i.e. Adamantisaurus mezzalirai, Baurutitan brittoi, Trigonosaurus pricei, Gondwanatitan faustoi, Maxakalisaurus topai, and Uberabatitan ribeiroi, have rarely been analyzed in a phylogenetic context. The most complete study is the doctorate thesis of R.M. Santucci (unpublished data), in which the former three taxa cited above are positioned in the base of a clade that also includes Aeolosaurus, Gondwanatitan, Argentinosaurus, Rinconsaurus and Ampelosaurus. The genus Titanosaurus was also recorded in the Marilia Formation of São Paulo and Minas Gerais (Bertini et al. 2001), but the validity of this taxon as contested by ilson and pchurch (2003), demanding a revision of this material. A significant occurrence is that of the clade Aeolosaurini (Franco-Rosas et al. 2004). Specimens of this group, referred to as Aeolosaurus and Gondwanatitan, were recovered in the Adamantina Formation of São Paulo (Monte Alto and Alvares Machado areas, Bertini et al. 1999a, Kellner and Azevedo 1999) and Minas Gerais (Prata region, Candeiro et al. 2006b); in the base of the Serra da Galga Member in western Minas Gerais (Bertini et al. 1999b); and in the Cambambe Formation of Mato Grosso (Franco-Rosas et al. 2004). These records allow the correlation with Campanian-Maastrichtian aeolosaur-bearing strata of Argentina (e.g., Angostura Colorada, Allen, Los Alamitos and Bajo Barreal formations, see Casal et al. 2007). Another relevant finding is a partial skeleton referred to Nemegtosauridae from the Adamantina Formation, in the area of Presidente Prudente (Avilla et al. 2005). This clade has been previously recorded only in the Campanian-Maastrichtian of Mongolia (Upchurch 1995, 1999) and alternatively classified within Diplodocoidea (Upchurch et al. 2004) or Titanosauria (Wilson 2005).

The theropod record in the Cretaceous of the Paraná Basin (Table I, ^II ) encompasses a number of isolated teeth attributed to Abelisauridae (Bittencourt and Kellner 2002, Candeiro et al. 2002, 2004, 2006a, b), Carcharodontosauridae (Silva and Kellner 1999, Candeiro et al. 2006a), and Deinonychosauria (Bertini et al. 1997, Bertini and Franco-Rosas 2001, Franco-Rosas 2001, 2002). Among these, only the first has further skeletal evidence, i.e., the partial skeleton of Pycnonemosaurus nevesi Kellner and Campos, 2002, a maxillary fragment described by Bertini (1996), and the partial remains (vertebra, femur and phalanges) described by Novas et al. (2008). Other theropod skeletal records include a scapula (Machado et al. 2008) and an ungual phalanx (Novas et al. 2005b) attributed to Maniraptora, and still undescribed Enanthiornithes remains (Alvarenga and Nava 2005). Once proposed spinosaurid occurrences in the Bauru Group were not confirmed (Candeiro et al. 2006a). The abelisauroid fauna of the Bauru Group is coeval to abelisauroid faunas from other parts of Gondwana, i.e., Argentina, Indo-Pakistan, Madagascar, and continental Africa (Fig. 2, ^4c ) (Bonaparte 1991a, Sith and Laanna 2006, alkani 2006, rause et al. 2007, Canale et al. 2009), and alleged European records (^{Fig. 4c} ) (Le Loeuff and Buffetaut 1991, Carrano and Sampson 2002, Carrano et al. 2002). Late Cretaceous Enanthiornithes (Chiappe and Walker 2002) are widespread (^{Fig. 4c} ) in both Laurasia (North America, Eurasia) and Gondwana (South America and Madagascar). Campanian-Maastrichtian occurrences of carcharodontosaurids based on isolated teeth from both Argentinean and Brazilian strata (Martinelli and Forasiepi 2004, Candeiro et al. 2006a) have been considered dubious by some authors (Canale et al. 2009). However, a preliminary report (Porfiri et al. 2008) of a post-cranial skeleton from the Late Cretaceous of Neuquen Group, Argentina, confirms the presence of post-Cenomanian carcharodontosaurids in Gondwana. Contrasting with the diversified record of Laurasian deinonychosaurs (Norell and Makovicky 2004, Makovicky and Norell 2004), South American occurrences other than isolated teeth from Brazil include a few species from the Late Cretaceous of Argentina (Novas et al. 2008).

DISCUSSION

Paleogeographic reconstructions of the Middle-Late Triassic depict Pangaea as a nearly continuous supercontinent (^{Fig. 4a} , Scalera 2001, Scotese 2002). In this scenario, dispersal would not be hampered by oceanic barriers (Shubin and Sues 1991, Langer et al. 2010), although large-scale provincialism may result from the establishment of geologic barriers (Coney 1982). Indeed, terrestrial faunal endemism is not conspicuous across Pangaea in the Late Triassic (Benton 1993, Lucas 1998, Langer 2005a), and it is widely known that the tetrapod fauna of the Gondwana II Supersequence is correlated with those from Argentina, India, and southern Africa (Bonaparte 1969, 1973, 1982, Sill 1969, Barberena et al. 1985, Scherer et al. 1995, Lucas 1998, Ray and Chinsamy 2002, Langer 2005b, Kutty et al. 2007), sharing more inclusive but closely related taxa also with Europe and North America (Heckert and Lucas 1998, Langer 2005a).

Much has been argued on the record of the oldest and basal-most dinosauriforms in South America, hinting at the possible origin and early radiation of dinosaurs in southwestern Gondwana (Benton 1988, Langer 2004, Langer et al. 2010). esbitt et al. (2009) recently analyzed the premise of a South American protocontinent as the ancestral range for dinosaurs. Using distinct methodologies (Ronquist 1997, Ree and Smith 2008), this was the first objective study to test and corroborate the above mentioned hypothesis. The dataset of Nesbitt et al. (2009) lacks some dinosauriforms from Carnian strata of south Gondwana, as Guaibasaurus and Panphagia, but the inclusion of them probably would reinforce their conclusions (Fig. 2). However, as discussed by several authors (Parker et al. 2005, Nesbitt et al. 2009, Langer etal. 2010), the South American origin hypothesis may be biased by the worldwide record of Ladinian-Carnian terrestrial vertebrates, which mainly encompasses localities from Argentina and Brazil (Rogers et al. 1993, Langer 2005a, b, Langer et al. 2007a). Accordingly, both relative diversity and abundance of basal dinosaurs across Pangaea are probably underestimated.

The distribution patterns of post-Carnian dinosaur faunas across Pangaea, including Laurasia (e.g., Rauhut and Hungerbuhler 1998, Irmis 2005, Nesbitt et al. 2007), and their driven biogeographic processes, also remain elusive (Nesbitt et al. 2009), as the detection of vicariance or dispersal depends on distribution data for a wellsampled set of taxa. This is the case of the possible Norian herrerasaurids from North America, which are younger than South American members of this clade. The alleged coeval record of the group in South Africa (Galton 1985) has been refuted (Galton and Van Heerden 1998, Langer 2004, Yates 2007a). Thus, the unambiguous record of herrerasaurid suggests that this clade is restricted to western Pangaea, regardless their phylogenetic position within dinosaurs. Some records from India (Novas et al. 2009a), if confirmed, may expand the known distribution of this clade across south Pangaea. The recent reclassification of the herrerasaurids as basal theropods (Fig. 2, Nesbitt et al. 2009) overcomes the ghost-lineage problem of Theropoda, since sauropodomorphs are recorded since Carnian (Langer et al. 1999, Martinez and Alcober 2009). However, the phylogeny of basal Saurischia is far from consensual (Langer et al. 2010).

Possible Jurassic dinosaurs in Brazil are limited to footprints and trackways from: 1 - Areado Group, in western Minas Gerais, allegedly of Late Jurassic/Early Cretaceous age (Carvalho and Kattah 1998); 2 - Botucatu Formation, Paraná Basin (Leonardi 1980, Leonardi and Oliveira 1990), a massive aeolian sequence of possible Late Jurassic-Early Cretaceous age (Assine et al. 2004) that crops out in an extensive area in east-central South America (Scherer 2000). The ichnofaunas includes possible theropod and ornithopod footprints recovered mainly in São Paulo State (Leonardi 1994, Leonardi et al. 2007, Fernandes and Carvalho 2007). Some authors have noted that the dinosaur fauna from Botucatu Formation is restricted both ecologically, as it is mainly composed of small to medium-sized animals, and taxonomically, with the virtual absence of sauropods (Leonardi 1989, Novas 2007, 2009). The interpretation of the Botucatu Formation as a paleodesert (Assine et al. 2004) suggests that environmental stress could be responsible for this pattern (Novas 2007, 2009). Late Jurassic dinosaur-bearing rocks in Gondwana are rare, with significant records only from the Tendaguru beds, Tanzania, which includes several sauropods, theropods, stegosaurs, and basal iguanodonts (Janensch 1914, Bonaparte et al. 2000, Tykoski and Rowe 2004, Upchurch et al. 2004, Rauhut 2005, Remes 2006, 2007), and the Canadon Calcareo Formation, Argentina, with sauropod records (Rauhut et al. 2005, Rauhut and Lopez-Arbarello 2008). Other records (see Novas 2009 for review) include the Lower or Middle Jurassic strata of the La Quinta Formation, Venezuela, with ornithischians and saurischian incomplete specimens (Barrett et al. 2008), La Matilde Formation from Middle or Late Jurassic of Argentina (Leonardi 1989), with theropod footprints (Novas 2009), and Banos del Flaco Formation, Tithonian of Chile (Moreno and Benton 2005), with sauropod tracks. The paucity of Jurassic dinosaurs in Brazil has been discussed under a paleoecological framework (Novas 2007, 2009), and it adds few information from a historical biogeography point of view. Indeed, the same can be said about the ornithischian record, which includes the above-mentioned and additional footprints from the Early Cretaceous of Sousa and Uirauna-Brejo das Freiras basins, northern Brazil (Leonardi and Carvalho 2002, 2007), and a preliminarily described vertebra from Itapecuru beds (see above) attributed to Hadrosauridae (Avilla et al. 2003). The ornithischian record from Argentina is much richer, consisting of stegosaurids and euornithopods, including hadrosauroid taxa (oria and abiaso 2007, ovas 2007, 2009). These clades, along with those registered in the Jurassic-Cretaceous of Africa (Galton and Upchurch 2004b, Norman 2004, Norman et al. 2004, Weishampel et al. 2004), probably ranged throughout South America, and could possibly be found in Mesozoic strata of Brazil. Explanations for their paucity include insufficient fieldwork, scarcity of available outcrops due to extensive vegetal covering, and a possible ecological constraint, as ornithischians are rarer herbivorous components in the known Mesozoic Gondwanan terrestrial ecosystems compared to sauropods (Bonaparte 1996, Upchurch and Barrett 2005).

Bonaparte (1986) proposed that the Cretaceous dinosaur faunas from Gondwana and Laurasia might be differentiated by their endemism following the separation of both landmasses in the Jurassic. In general, Laurasia would be dominated by ornithischians and some theropod taxa such as tyrannosauroids, ornithomimids, therizinosaurs and dromaeosaurids, while Gondwana would be inhabited by sauropods, specially titanosaurs (e.g., Bonaparte and Kielan-Jaworowska 1987), and other theropod taxa such as abelisaurids and alvarezsaurids (Bonaparte 1991b, 1996). This proposition has been weakened by novel findings that expand the distribution of several dinosaur clades (Fig. 2). Non-tyrannosaurid tyrannosauroids, possibly including Santanaraptor, are recorded in southern landmasses (Benson et al. 2010), and dromaeosaurids have been recovered in several localities from Gondwana (see above). On the other hand, theropod clades once thought to be endemic of Gondwana were more recently recovered from Laurasian terrains, including carcharodontosaurids from the Early Cretaceous of North America and Europe (Holtz et al. 2004, Sereno and Brusatte 2008), Late Cretaceous of Asia (Brusatte et al. 2010), and alvarezsaurids from the Late Cretaceous of Mongolia and North America (Chiappe et al. 2002). Abelisaurid remains from Laurasia are dubious (e.g., Le Loeuff and Buffetaut 1991, Sampson et al. 1998, but see Pereda-Suberbiola 2009), and titanosaur sauropods have representatives in both landmasses (Taylor and Naish 2007), although they are more common in Gondwanan (Fig. 2, ^4b-c ) (Upchurch et al. 2004). Naish et al. (2004) suggested the occurrence of some faunal interchange between Europe and South America via Africa in the Early Cretaceous (see also Sereno et al. 1998). Indeed, several dinosaur clades recovered in northeastern Brazil in Albian-Cenomanian strata, e.g., Rebbachisauridae, Spinosauridae, Carcharodontosauridae, and Compsognathidae, have older Laurasian records (see above). However, strata ofthe lowest Cretaceous are rare in northern Gondwana.

Several authors suggested that the similarities between the dinosaur fauna of northeastern Brazil and North Africa (Novas 2007, 2009) in this period may be explained by continuous land connections until the Cenomanian (Calvo and Salgado 1995, Sereno et al. 2003, 2004, Sereno and Brusatte 2008). Evidences supporting this hypothesis (named 'Pan-Gondwana'), include paleogeographic reconstructions (Smith et al. 1994) and shared Cretaceous taxa as the crocodyliforms Araripesuchus (Turner 2006, Sereno and Larsson 2009), Sarcosuchus (Buffetaut and Taquet 1977, 1979, Sereno et al. 2001), and notosuchians (Sereno et al. 2003, Turner 2006); araripemydid turtles (Fuente and Broin 1997, Gaffney et al. 2006); the coelacanthiform Mawsonia (Maisey 1991, Yabumoto and Uyeno 2005); abelisaurid (Sereno et al. 2004, Sereno and Brusatte 2008) and diplodocoid (Calvo and Salgado 1995, Medeiros and Schultz 2004) dinosaurs. However, the separation between Africa and South America is often considered older (Hay et al. 1999, Sampson et al. 1998, Scotese 2002, Krause et al. 2006, 2007), and geologic data from northeastern Brazil point towards the existence of openly marine deposits in Albian times (Petri 1987, Mohriak 2003). In this scenario ('Africafirst' hypothesis), the closer similarity of the turtle and crocodyliform faunas could be explained by the possibility for semi-aquatic forms to disperse across restrict oceanic barriers. Whatever separation date between these landmasses is correct, Upchurch et al. (2002) objectively suggested that vicariance rather than dispersal played a major role in the biogeographic evolution of dinosaurs at least for Middle Jurassic to mid-Cretaceous times. Turner (2004) performed an analysis of crocodyliform biogeography during the Cretaceous and also concluded that vicariance driven by the fragmentation of Gondwana was a major factor affecting the distribution of this clade during mid to Late Cretaceous.

The dataset of Turner (2004) includes several taxa recorded in Brazil as Araripesuchus gomesi, from the Araripe Basin, baurusuchids (Baurusuchus) and peirosaurids fro the auru roup. The phylogenetic analysis presented by this author shows A. gomesi closer to A. patagonicus, from Argentina, than to A. wegeneri, from Africa. This is congruent with the presence of the sauropod Rayososaurus in mid-Cretaceous strata from both Argentina and Brazil. On the other hand, additional archosaurian records suggest a closer affinity of the northern fauna of the mid-Cretaceous of Brazil with African faunas (Medeiros and Schultz 2002, Novas 2009). This includes the spinosaurids from the Araripe Basin/Itapecuru Group, and the crocodyliform Candidodon itapecuruensis from the Itapecuru Group (Nobre 2004), which is closely related to the African Malawisuchus (Zaher et al. 2006). This conundrum alternatively suggests a closer similarity between eastern and western Gondwanan faunas than previously thought. Accordingly, the close relationship between the crocodyliforms from Itapecuru group with Gondwanan forms (i.e. notosuchians) (Zaher et al. 2006, Kellner et al. 2009), along with the occurrence of peirosaurids and baurusuchids in the Late Cretaceous, reinforces the existence of a vicariant pattern in crocodyliform distribution (Turner 2004). This scenario is also compatible with the distribution of dinosaurs in southern landmasses (Upchurch et al. 2002, Novas 2007, 2009).

The Brazilian fossil record of dinosaurs adds relevant data to the biogeographic comparison with Argentina. Early Cretaceous taxa shared between these areas include diplodocoids, carcharodontosaurids, and titanosaurs. On the contrary, clades recorded in the Araripe and São Luis-Grajau basins, such as Spinosauridae and Compsognathidae, were not found in chronostratigraphically equivalent strata in Argentina (Novas 2007, 2009), while abelisauroids, with a well-known record in that country, are not recorded in the Aptian-Cenomanian of Brazil. This pattern may reflect either the paucity of the fossil record, inaccessibleness to fossil specimens due to vegetal covering, insufficient fieldwork, or endemism, although evidence supporting the latter is weak. The Late Cretaceous from both areas exhibits a rather similar dinosaur fauna, including carcharodontosaurids and aeolosaurine titanosaurs, even at a generic level, i.e., Aeolosaurus (see below).

Due to its Gondwanan distribution (Fig. 3 c), abelisauroids played a major biogeographic role since their first discovery (Bonaparte and Novas 1985). The occurrence of ore derived for s of this clade (Carnotaurinae sensu Sereno et al. 2004, see also Carrano and Sampson 2008) in South America, Indo-Pakistan, and Madagascar leaded some authors (Sampson et al. 1998) to suggest that abelisaurids might have radiated across Gondwana after the separation of continental Africa in the Early Cretaceous (Krause et al. 2007). Yet, recent records of basal abelisauroids in the Early Cretaceous of Niger (Sereno et al. 2004, Sereno and Brusatte 2008), along with fragmentary material from the Aptian-Albian of Libya (Smith and Dalla Vecchia 2006), Cenomanian of Morocco (Mahler 2005), and Maastrichtian of Egypt (Smith and Lamanna 2006), indicate a wider distribution of this group in southern landmasses than previously thought. These findings suggest a later separation of continental Africa from Gondwana ('Pan-Gondwana' model), and the absence of carnotaurines in northern Africa in the Late Cretaceous could be explained by the incompleteness of the fossil record (Sereno and Brusatte 2008). However, recent findings suggest that carnotaurines are restricted to Gondwana and at least one clade within it (Brachyrostra) is endemic to South America (Canale et al. 2009). The recent discovery of a Megaraptor-like theropod in the Early Cretaceous of Australia is congruent with a connection between South America and Australia until the Late Cretaceous (Krause et al. 2006), but it is uncertain if the separation of Africa occurred earlier than this period (Sereno et al. 2004).

The sauropod fossil record in Brazil (Table I, ^II ) is also relevant for paleobiogeographic studies because of its rich titanosaur record. In the context of some phylogenetic hypotheses (Wilson 2002, Upchurch et al. 2004, Curry Rogers 2005), the Late Cretaceous cosmopolitanism of this clade (^{Fig. 4b-c} ) cannot be explained only by cladogenesis associated with the splitting of Pangaea. For some authors (e.g., Bonaparte 1984, Sullivan and Lucas 2000), the Maastrichtian record of the titanosaur Alamosaurus in North America (Montellano-Ballesteros 2003, Upchurch et al. 2004) is congruent with a land connection with South America in the Late Cretaceous (Simpson 1950, 1978), which would also be responsible for the presence of hadrosaurids and ankylosaurs in southern latitudes (Bonaparte et al. 1984, McCarthy 2005, Coria and Cambiaso 2007).

The Late Cretaceous tetrapod fauna of the Bauru Group has often been considered endemic, either at a generic level (ertini et al. 1993) or for sall-bodied animals relative to sauropod dinosaurs (e.g., crocodylomorphs and turtles, Santucci and Bertini 2001). These alleged taxonomic and/or ecological partitioning may be related to the formation of biogeographic barriers at the borders of the 'basin' originated with the lithostatic load of the basalt floods referred to as the Serra Geral Formation (Santucci and Bertini 2001). However, the existence of geologic barriers at the borders of Bauru Group is questionable (see Milani 2001). Besides, no tetrapod taxon is endemic to the Bauru Group at a suprageneric level, and even genera such as Aeolosaurus, Peirosaurus, Roxochelys, plus baurusuchids closely related to Brazilian forms are recorded in Argentinean strata (Gasparini 1972, Broin 1991, Gasparini et al. 1991, Riff and Kellner 2001, Franco-Rosas et al. 2004). In addition, taxa recorded only in the Bauru Group are closely related to forms recorded in widespread localities across southern landmasses (Franco-Rosas et al. 2004, Carvalho et al. 2004, Turner and Calvo 2005, Zaher et al. 2006, Franca and Langer 2006, Evans et al. 2008). Although less diverse and abundant than some faunas of equivalent age in South America (e.g., Neuquina Basin, Novas 2009), the dinosaur assemblages of the Bauru Group is rather similar to the Late Cretaceous assemblages from other parts of Gondwana, especially Argentina.

CONCLUSIONS

ACKNOWLEDGMENTS

The authors wish to thank Ricardo Weska and Manuel Alfredo de Medeiros for sharing information on some Cretaceous deposits from Brazil, and Alex Kellner for the invitation to contribute in this volume. This project was funded by Coordenacao de Aperfeicoamento de Pessoal de Nivel Superior (CAPES), with a doctorate fellowship to JSB, Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq), and Fundacao de Amparo a Pesquisa do Estado de São Paulo (FAPESP).

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Manuscript received on February 3, 2010; accepted for publication on September 14, 2010

Proceedings of the Third Gondwanan Dinosaur Symposium

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