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Ameghiniana

versión On-line ISSN 1851-8044

Ameghiniana v.42 n.1 Buenos Aires ene./mar. 2005

 

A new tritheledontid (Therapsida, Eucynodontia) from the Late Triassic of Rio Grande do Sul (Brazil) and its phylogenetic relationships among carnivorous non-mammalian eucynodonts

Agustín G. Martinelli 1 , José F. Bonaparte 1-2 , Cesar L. Schultz 2 and Rogerio Rubert 3

1 Sección Paleontología de Vertebrados, Museo Argentino de Ciencias Naturales "Bernardino Rivadavia". Av. Angel Gallardo 470, 1405 Buenos Aires, Argentina. agusmart01@hotmail.com
2 Instituto de Geociências, Departamento de Paleontología y Estratigrafía, UFRGS, Av. Bento Gonçalves 9500, Porto Alegre (91501- 970), RS, Brazil. jose.bonaparte@ufrgs.br / cesar.schultz@ufrgs.br
3 Departamento de Geología, UFMT, Cuiabá, Mato Grosso, Brazil. rogrubert@yahoo.com.br

Abstract. A new tritheledontid, Irajatherium hernandezi gen. et sp. nov., from the Late Triassic Caturrita Formation of Brazil is described. The specimen consists of a left maxilla bearing the canine, five postcanines, and the alveolus of another one, two fragments of lower jaw, a humerus, and a femur. The association of the following features is unique for this taxon: 1) anterior upper postcanines transversely narrow bearing a higher cusp A and smaller cusp C; 2) last upper postcanines with higher, bulbous cusp A and smaller lingual cusps B and C, differing from Pachygenelus in lacking a buccal cingulum; 3) middle lower postcanines bearing a higher anterior cusp and three consecutively smaller posterior cusps, differing from Pachygenelus in lacking a lingual cingulum; 4) lower postcanines with sharp wear facets; 5) humerus with two thick osseous processes for the teres major muscle; and 6) femur with the greater trochanter at the head level and the lesser trochanter on the medial surface of the shaft. Our phylogenetic analysis placed I. hernandezi together with Riograndia guaibensis Bonaparte et al. , Chaliminia musteloides Bonaparte, Pachygenelus monus Watson and Diarthrognathus broomi Crompton. These taxa represent the family Tritheledontidae. The presence of two kinds of upper postcanines in different replacement waves in Irajatherium could be a useful feature for inference of possible mechanism of dental differentiation among non-mammalian cynodonts. Possible fossorial adaptations are documented in the humerus of Irajatherium .

Resumen. Un nuevo Tritheledóntido (Therapsida, Eucynodontia) del Triásico Tardío de Río Grande do Sul, (Brasil) y su posición filogenénetica entre eucinodontes carnívoros no mamalianos. Se describe un nuevo tritheledóntido, Irajatherium hernandezi gen. et sp. nov., de la Formación Caturrita del Triásico Tardío de Brasil. El especimen consiste en un maxillar izquierdo con el canino, cinco postcaninos y el alvéolo para uno más, dos fragmentos de mandíbula, un húmero y un fémur. La asociación de los siguientes caracteres es única para este taxón: 1) postcaninos superiores anteriores transversalmente angostos, con la cúspide A prominente y la cúspide C de pequeño tamaño; 2) último postcanino con la cúspide A prominente y bulbosa, y las cúspides B y C pequeñas desplazadas lingualmente, diferente a Pachygenelus por la ausencia de un cíngulo bucal; 3) dientes inferiores medios con una cúspide anterior alta y tres cúspides consecutivamente menores, diferentes de Pachygenelus por la ausencia de un cíngulo lingual; 4) facetas de desgaste en los postcaninos inferiores; 5) húmero con dos robustas tuberosidades para el músculo teres major; y 6) fémur con el trocánter mayor ubicado al nivel de la cabeza y trocánter menor proyectado medialmente. Nuestro análisis filogenético ubica a I. hernandezi junto con Riograndia guaibensis Bonaparte et al. , Chaliminia musteloides Bonaparte, Pachygenelus monus Watson, and Diarthrognathus broomi Crompton. Estos taxones representan la familia Tritheledontidae. La presencia de dos tipos distintos de morfologías de postcaninos superiores involucrados en el recambio dentario de Irajatherium podría ser un rasgo importante para inferir sobre posibles mecanismos de diferenciación dentaria entre cinodontes. Se documentan posibles adaptaciones fosoriales en el húmero de Irajatherium .

Key words. Eucynodontia. Tritheledontidae. Irajatherium hernandezi . Late Triassic. Brazil.
Palabras clave. Eucynodontia. Tritheledontidae. Irajatherium hernandezi . Triásico Tardío. Brasil.

Introduction

The family Tritheledontidae was established by Broom (1912) to include an extremely rare cynodont, Trithelodon riconoi Broom, from the Lower Jurassic Red Beds Stormberg Series of South Africa, based on some cranial and dental elements. Later, Watson (1913) described a new species, Pachygenelus monus , based on a fragment of a lower jaw from the same region. In 1929, Broom published two new specimens of cynodonts, one based on an almost complete skull (Ictidosaurian A) and the other based on a partial skull and fairly complete postcranial remains (Ictidosaurian B). All these taxa were included together in the Suborder Ictidosauria (Broom, 1929). Furthermore, Crompton (1958) studied the Ictidosaurian B, named it Diarthrognathus broomi , and proposed the family Diarthrognathidae for this taxon principally because of its peculiar temporomandibular joint formed by the articularquadrate and dentary-squamosal articulations.
In a more recent review of the group, Hopson and Kitching (1972) proposed to abandon the infraordinal rank Ictidosauria to include the ictidosaurian species within the infraorder Cynodontia. They used the familiar rank Tritheledontidae to include Trithelodon and Pachygenelus . Furthermore, they considered Diarthrognatidae and Diarthrognathus as a synonym of the family Tritheledontidae and the genus Pachygenelus respectively because the only known specimen of the genus Diarthrognathus was referred as a juvenile. Nevertheless, based on several new remains, Gow (1980) made an extensive description of the dentition of the Tritheledontidae and showed sufficient differences to merit separation of the three genera.
In 1980, Bonaparte described the first South American "ictidosaur", Chaliminia musteloides , from the Upper Triassic Los Colorados Formation of Argentina.
He proposed the family Pachygenelidae to include the new taxon and Pachygenelus , and at the same time, he referred Diarthrognathus and Trithelodon to the Tritheledontidae based on their specialized dental morphology (Bonaparte, 1980). Recently, another "ictidosaur", Riograndia guaibensis from the Upper Triassic of southern Brazil, was described and assigned to the new family Riograndidae (Bonaparte et al. , 2001).
The knowledge about the tritheledontids has improved in recent years ( e.g . Shubin et al. , 1991; Gow, 1994). This family was considered a group of small advanced non-mammalian cynodonts implicated in the origin of the early mammaliaforms ( e.g . Hopson and Barghusen, 1986; Shubin et al. , 1991; Crompton and Luo, 1993; Luo and Crompton, 1994; Luo, 1994; Sidor and Hopson, 1998; Hopson and Kitching, 2001; Luo et al. , 2001, 2002; however see Bonaparte and Barberena, 1975, 2001; Bonaparte et al. , 2003). Nevertheless, the phylogenetic relationships among the taxa within tritheledontids are not clear.
Thus, the aim of this paper is to describe a new tritheledontid cynodont discovered in 2000 during fieldworks organized by the Museo Argentino de Ciencias Naturales "Bernardino Rivadavia" (Argentina) and the Universidade Federal of Rio Grande do Sul (Brazil) in outcrops of the Upper Triassic Caturrita Formation ( sensu Andreis et al. , 1980; Montardo, 1982) in southern Brazil. Morover, a cladistic analysis was conducted to clarify the relationships of tritheledontids among eucynodonts.
Abbreviation. Institutional abbreviations used in this paper are as follows: MACN: Museo Argentino de Ciencias Naturales "Bernardino Rivadavia" (Buenos Aires) (N, Colección Neuquén; PV, Paleontología de Vertebrados); MCN: Museu de Ciências Naturais, Fundação Zoobotânica (Porto Alegre); MCZ: Museum of Comparative Zoology, Harvard University (Massachusetts); PVL: Instituto Miguel Lillo, Universidad Nacional de Tucumán (Tucumán), Vertebrate Paleontology Collection; SAM: South African Museum (Cape Town); UFRGS: Universidade Federal do Rio Grande do Sul (Porto Alegre) (PV, Vertebrate Paleontology; T, Triassic collection).

Geological setting

The Upper Triassic Caturrita Formation (Andreis et al. , 1980) consists of a coarsening-upward succession that transitionally replaces the transgressive mudstones of the upper layers of the Santa Maria Formation. The faunal content of the Caturrita Formation, dominated by rhynchosaurs (mainly Hyperodapedon ), indicates a Carnian to Norian age.
This Formation constitutes the highstand systems tract of the Santa Maria two-third-order sequence (Zerfass et al. , 2003).
The Caturrita Formation contains isolated, smallscale trough cross-bedded sandstone lenses (St facies sensu Miall, 1996) that are interpreted as ribbon fluvial channels.
Rhytmites and sigmoidal, massive to climbing cross-laminated sandstone bodies are also present. This facies association is interpreted as a lacustrine- deltaic depositional system.
Upwards, the mudstone content decreases and the sandstone amalgamation increases. Sandstones occur as narrow, massive or stratified (horizontal and trough cross bedding) lenses (Sm, Sh and St facies sensu Miall, 1996) interpreted as amalgamated sandstone bodies related to high width/depth ratio channels. The described succession reveals a progressive reduction of accommodation space, shallowing of the lacustrine basin and its progressive replacement by a fluvial system.
In the outcrop where Irajatherium hernandezi was A new tritheledontid from the Late Triassic of Brazil 193 collected (figure 1) the massive sandstones (Sm facies sensu Miall, 1996) are predominant (figure 2). The fossil-bearing sandstones occupy the basal portion of the outcroup. Towards the top of the sequence occur tabular and intercalated layers of siltstone and fine sandstone (Fl facies sensu Miall, 1996).

 
Figure 1. Location map of Candelaria, State of Rio Grande do Sul, Brazil. The arrow indicates the type fossil locality of Irajatherium hernandezi . / Mapa de ubicación de Candelaria, Estado de Río Grande do Sul, Brasil. La flecha indica la localidad tipo de Irajatherium hernandezi.

 
Figure 2. Stratigraphical section of the middle-upper portion of the Caturrita Formation, near Candelaria, Rio Grande do Sul. / Perfil estratigráfico de la porción media-superior de la Formación Caturrita, cerca de Candelaria, Río Grande do Sul.

This succession is considered to represent the middle-upper portion of the Caturrita Formation. Equivalent levels in other localities have yielded a rich vertebrate assemblage composed by the probainognathians Riograndia guaibensis (Bonaparte et al. , 2001), Brasilodon quadrangularis (Bonaparte et al. , 2003) and Brasilitherium riograndensis (Bonaparte et al. , 2003); a primitive dinosaur, Guaibasaurus candelariensis (Bonaparte et al. , 1999); a leptopleuronin procolophonid, Soturnia caliodon (Cisneros and Schultz, 2003); a tuskless dicynodont, Jachaleria candelariensis (Araújo and Gonzaga, 1980); an indeterminated phytosaur (Kischlat and Lucas, 2003); and an unnamed sphenodont (Ferigolo, 2000).
The vertebrate association of the middle-upper portion of the Caturrita Formation suggests an early Coloradian age ( sensu Bonaparte, 1973, approximately Early Norian, Late Triassic).

Systematic paleontology

Therapsida Broom, 1905

Cynodontia Owen, 1861

Epicynodontia Hopson and Kitching, 2001

Eucynodontia Kemp, 1982

Probainognathia Hopson, 1990

Tritheledontidae Broom, 1912

Definition. The clade including the more recent common ancestor of Riograndia and Pachygenelus , and all its decendents.

Irajatherium gen. nov.

Type and only know species. Irajatherium hernandezi sp. nov.

Diagnosis. Small tritheledontid with anterior upper postcanines transversely narrow bearing a high cusp A and a small cusp C; posterior upper postcanines with high bulbous cusp A, and small lingual cusps B and C, differing from Pachygenelus in lacking a buccal cingulum; middle lower postcanines bearing a high anterior cusp and three consecutively smaller posterior cusps, with mesial accessory cusps in posteriormost postcanines, differing from Pachygenelus in a lacking lingual cingulum. Irajatherium differs from most eucynodonts with lower sectorial teeth in having sharp wear facets on the buccal side that indicates unilateral occlusion. The humerus has a deep and narrow biccipital groove in the proximal area and two thick osseous processes on the medial side below the lesser tuberosity, near the half of the humeral length. The femur is similar to that of Therioherpeton with the greater trochanter located at the level of the head and the lesser trochanter placed on the medial surface of the femoral shaft. This femur differs from that of Pachygenelus and Morganucodon in lacking the notch between the head and the greater trochanter.
Etymology. In honor to Professor Irajá Damiani Pintos, outstanding invertebrate paleontologist of the Universidade Federal do Rio Grande do Sul, Brazil.

Irajatherium hernandezi sp. nov.
Figures 3-6, 8, 10

Holotype. UFRGS-PV 0599T, incomplete left maxilla bearing the canine, five postcanines, and the alveolus of another one, both canine and the last postcanine are erupting (figure 3); natural cast of the incomplete left dentary bearing an anterior postcanine (figure 4), and a fragment of the left lower jaw with two postcanines (figure 5); left humerus (figure 8); left femur (figure 10); and other indeterminated fragments.

Diagnosis. As for genus.
Etymology. Named after the technician Daniel Henández (Museo Municipal "Carmen Funes", Neuquén, Argentina) who discovered the type specimen.
Locality and horizon. From an outcrop of the Caturrita Formation located 8 kilometers west of Candelaria, in a roadcut on the route (BR 287) to Santa Maria, Rio Grande do Sul State, Brazil (figure 1), possibly of Early Coloradian age ( sensu Bonaparte, 1973) (approximately Early Norian, Late Triassic).

Description and comparisons

Maxilla ( figure 3 )

 
Figure 3. Left maxilla of Irajatherium hernandezi (UFRGS-PV 599T holotype) in lateral (A), ventral (B) and medial (C) views. Scale bar equals 5 mm. Abbreviations in Appendix 3 / Maxilar izquierdo de Irajatherium hernandezi en vista lateral (A), ventral (B) y medial (C). La escala representa 5 mm. Abreviaturas en Apéndice 3.

The only cranial material available is a fairly complete left maxilla with a canine, five postcanines and the alveolus of another tooth. The lateral aspect of the maxilla shows two antero-posteriorly concave regions, one above the postcanine diastema and the second near the beginning of the zygomatic arch. The lateral wall of the canine alveolus is convex and bears small pits. There are two large infraorbital foramina for the maxillary branch of the trigeminal nerve (V2), one placed behind the thick alveolar process of the canine and the other above the fourth postcanine. The latter is smaller and both face anteriorly. In the posterior portion, the maxilla forms part of the root of the zygomatic arch. The contacts with the jugal and other bones are not preserved.
In ventral view, the anteriormost medial edge of the maxilla projects ventrally, possibly due to deformation. The posterior border of the paracanine fossa reaches the level of the canine alveolus. Medially and backwards from the third postcanine there is a deep narrow groove which accommodate the lower sectorial postcanines (figure 3.B).
Comparison. The distribution of the maxillary branch of the trigeminal nerve in the snout is similar to that found in Pachygenelus , Diarthrognathus , and Morganucodon (Kermack et al. , 1981) in which the anteriormost opening is located behind the canine root and the middle opening above the tooth row (Kemp, 1982). The posterior foramen near or in the contact between the lachrymal and the maxilla is not preserved in Irajatherium . In Lumkuia , Ecteninion , Probainognathus , Probelesodon , Chiniquodon , Therioherpeton , and Prozostrodon these foramina are smaller, lack a regular distribution, and their number is variable (Romer, 1969a, 1969b, 1970; Teixeira, 1982; Martinez and Forster, 1996; Martinez et al. , 1996; Hopson and Kitching, 2001; Bonaparte and Barberena, 2001).
As in cynognathians ( Cynognathus plus Gomphodonthia) (Hopson and Kitching, 2001), basal probainognathians and some mammaliaforms ( e.g . Sinoconodon ; Crompton and Luo, 1993) there is a fossa for the lower canine. Gow (1980) observed that in tritheledontids the fossa was not present due to the reduction of the lower canine. The deep groove parallel to the posterior half of the tooth row is a feature also present in carnivorous non-mammalian probainognathians and also in Cynognathus ( e.g . Abdala, 1996).

Lower jaw (figures 4 and 5)

 
Figure 4. Cast of the left lower jaw of Irajatherium hernandezi (UFRGS-PV599T holotype) in lateral view. Tooth and white regions correspond to original bone. Scale bar equals 5 mm. Abbreviations in Appendix 3 / Molde de la mandíbula izquierda de Irajatherium hernandezi en vista lateral. El diente y las regiones blancas corresponden a hueso original. La escala representa 5 mm. Abreviaturas en Apéndice 3.

 
Figure 5. Fragment of left lower jaw with middle postcanines of Irajatherium hernandezi (UFRGS-PV599T holotype) in lateral (A) and medial (B) views. Schematic position of this fragment in the cast of the jaw in lateral view (C). Scale bar equals 5 mm. Abbreviations in Appendix 3 / Fragmento de la mandíbula izquierda con los postcaninos medios de Irajatherium hernandez i en vistas lateral (A) y medial (B). Posición esquemática del fragmento en el molde de la mandíbula en vista lateral (C). La escala representa 5 mm. Abreviaturas en Apéndice 3.

A natural cast of the lateral side of a portion of the left dentary is preserved. The coronoid process is high and bears a thick anterior edge. The masseteric fossa extends anteriorly in the horizontal ramus of the jaw near the level of the last preserved postcanine alveolus. The craniomandibular joint was probably located above the tooth row level as in Diarthrognathus and Pachygenelus (Crompton, 1958, 1963a; Luo, 1994).
In medial view, the dentary medial ridge of the postdentary trough is preserved. This ridge is a prominent crest and below it there is a broad and deep groove for the postdentary bones. The angular process of the dentary is not preserved.
In a fragment of the dentary cast bearing two teeth, part of the Meckelian groove is observed (figure 5.B). This groove is parallel and close to the ventral edge of the horizontal ramus of the dentary. Furthermore, the groove for the dental lamina (Crompton, 1963b) is evident near the alveolar border.
Comparison. The postdentary trough and the medial ridge are similar to that of most eucynodonts and Morganucodon (Kermark et al. , 1973; Luo, 1994) while the arrangement of the Meckelian groove is comparable to that of most non-mammalian cynodonts and Sinoconodon (Luo, 1994). Luo (1994) considered that a Meckelian groove parallel to the lower border of the horizontal ramus of the dentary is a plesiomorphic feature because it is present in most basal eucynodonts. In the probainognathian Prozostrodon braziliensis (Bonaparte and Barberena, 2001) this groove reaches the lower border of the dentary behind the symphysis at the level of the first postcanine. Among Mammaliaformes the arrangement of the Meckelian groove is variable. In docodonts ( e.g . Haldonodon and Docodon ) and in some triconodonts ( e.g . Priacodon , Triconodon and Triorachodon ) the Meckelian groove does not reach the inferior border while in morganucodontids ( e.g . Morganucodon and Megazostrodon ), Amphilestes , Amphiodon , Gobiconodon , Amphitherium and spalacotheriids, it does ( e.g . Rougier et al. , 2001).
The shape of the lower jaw cast resembles the jaw of tritheledontids (Crompton, 1963a) in which the horizontal ramus is high and the coronoid process has a deep masseteric fossa with a well-defined anterior edge. However, these features are also observed in some cynognathians ( e.g . Exaeretodon ; Bonaparte, 1962).

Upper dentition (figures 3 and 6).

The left maxilla bears the erupting canine and six postcanines of which the fifth is lost and the sixth is erupting. The upper postcanines increase their size posteriorly and a small diastema is present among them. The erupting canine is conical with a distal cutting edge; the size of the alveolus suggests it should be large. The postcanines are separated from the canine by a large diastema. The postcanines are transversely narrow and lack a lingual or buccal cingulum. The PC 1 is the smallest and has only one cusp. This postcanine is probably not fully erupted. The PC 2 has one low cusp with the crown thickened at the base. This tooth possibly was being replaced because its root is in a high position. The PC 3 bears two cusps. The mesial one is the biggest and slightly curved, while the distal cusp is smaller and located in a higher position. The main cusp has the mesial edge more convex than the distal one. Both cusps are in line and separated by a shallow furrow. On the buccal side the root is slightly constricted bucco-lingually as in the PC 4 . The PC 4 is badly preserved but seems to be similar in morphology than the PC 3 . Behind the PC 4 there is an empty alveolus and then the last postcanine, PC 6 . This erupting tooth bears a high bulbous central cusp A with the tip in a buccal position, and two smaller cusps, one on the mesiolingual edge (cusp B) and the other on the disto-lingual edge (cusp C), slightly tricker than cusp B (figure 6). The cusp A has mesial and distal cutting edges where the enamel is observed. There is no buccal cingulum. The root is not preserved but the beginning of a dividing groove is present on the lingual aspect on the base of the crown. The outline in occlusal view is almost triangular, being as wide as long, while the remaining postcanines are narrow transversely.

 
Figure 6. Sixth upper left postcanine of Irajatherium hernandezi (UFRGS-PV599T holotype) in lingual and occlusal views. Scale bar equal 1 mm. Abbreviations in Appendix 3 / Sexto postcanino superior izquierdo de Irajatherium hernandezi en vistas lingual y oclusal. La escala representa 1 mm. Abreviaturas en Apéndice 3.

Comparison (figure 7). In Irajatherium the four anterior upper postcanines, despite being not well preserved, are different from the last erupting tooth, lacking the mesial cusp B and being transversely narrow. In Pachygenelus and Diarthrognathus the tooth row shows an unique model, being the teeth more complex backwards where the buccal cingulum is thick and in some cases crenulate (Gow, 1980). The anterior upper postcanines of Irajatherium resemble those of Probelesodon lewisi (Romer, 1969b) and Chiniquodon theotonicus (Romer, 1969a), although in them the main cusp is curved backwards and they lack a constricted root.

 
Figure 7. Comparison of upper and lower postcanines among probainognathian cynodonts. A, left teeth in buccal view of Probelesodon (after Romer, 1969b); B, left teeth in buccal view of Probainognathus (after Romer, 1970); C, left teeth in buccal view of Riograndia (after Bonaparte et al. , 2001); D, left teeth in lingual view of Irajatherium ; E, right teeth in buccal and lingual views of Pachygenelus (after Gow, 1980); F, left teeth in lingual and buccal views of Diarthrognathus (after Gow, 1980); and G, right teeth in lingual view of Morganucodon (after Crompton and Jenkins, 1968). Not to scale / Comparación de los postcaninos superiores e inferiores entre cinodontes probainognatios. A, dientes izquierdos en vista bucal de Probelesodon (modificado de Romer, 1969b); B, dientes izquierdos en vista bucal de Probainognathus (modificado de Romer, 1970); C, dientes izquierdos en vista bucal de Riograndia (modificado de Bonaparte et al., 2001); D, diente izquierdo en vista lingual de Irajatherium; E, dientes derechos en vistas lingual y bucal de Pachygenelus (modificado de Gow, 1980); F, dientes izquierdos en vista lingual y bucal de Diarthrognathus (modificado de Gow, 1980); and G, dientes derechos en vista lingual de Morganucodon (modificado de Crompton and Jenkins, 1968). No están a escala.

The last erupting upper tooth is similar to the cheek teeth of Pachygenelus and this condition is one of the main features to consider Irajatherium as a Tritheledontidae. However, a buccal cingulum is absent in this postcanine such as in Chaliminia , Riograndia and most cynodonts, but is it well developed in Pachygenelus (Gow, 1980). The buccal cingulum is interpreted a derived character ( e.g . Crompton and Jenkins, 1968; Hopson and Kitching, 2001), also present in the postcanines of young individuals of Thrinaxodon (Crompton and Jenkins, 1968) and in morganucodontids ( e.g . Crompton, 1963b, 1974; Parrington, 1973). There are strong differences with Diarthrognathus in which the postcanines are closely packed, bulbous, bearing a prominent main cusp, and a posterior accessory cusp. The anterior cusp is lost and a mesial cingulum is present in this African genus (Gow, 1980). The available upper postcanines of Chaliminia are not well preserved (Bonaparte, 1980), but share with Irajatherium the shape of the main cusp and the plesiomorphic condition of the lack of a cingulum. Riograndia (Bonaparte et al. , 2001) differs from Irajatherium because the former has narrower upper postcanines with numerous smaller cusps aligned mesiodistally (figure 7).

Lower dentition (figures 4 and 5)

The number of lower postcanines is unknown due to the fragmentary condition of the dentary; only three postcanines are preserved in the holotype of Irajatherium . The first postcanine is in a natural cast of the left dentary (figure 4), and the following two (second and third postcanines) are implanted in a fragment of the dentary bone that fits well to this mold (figure 5.C). The first preserved postcanine (figure 4) is small and bears two cusps. The mesial cusp is high and the distal is very low, both curving backwards. The outline in lateral view of both cusps is rounded.
The remaining two teeth are transversely narrow with a well-defined wearing facet on the buccal side (figure 5). The second postcanine (figure 5) is smaller and has four cusps in line that decrease in size backwards; the cusps are separated by shallow furrows. The anterior and posterior edges of the tooth are convex and concave respectively. The third postcanine has the upper edge of the crown broken but the bases of the four cusps are observed. This tooth also has two tiny cingular cusps in line at the base of the mesiolingual edge. Both postcanines show incipient bifurcation of the root on the lingual side.
Comparison (figure 7). The lower postcanine crowns are similar to those of Pachygenelus (Gow, 1980). Nevertheless, on the lingual side, Pachygenelus has a pronounced cingulum (SAM K 1350) sometimes slightly crenulated (Gow, 1980; in figure 2 of Gow's paper the references are inverted) that becomes better developed on the posterior postcanines. This feature is absent in Irajatherium , however two tiny cingular cusps are present on the mesiolingual edge of the base of the crown in the last preserved lower postcanine. In buccal aspect, Diarthrognathus is similar to Pachygenelus and Irajatherium , except for the presence of a deep groove between the anterior high cusp and the remaining smaller cusps. Differing from Irajatherium , in Diarthrognathus the postcanines are as wide as long in occlusal view, the cusps are mesio-lingual to disto-buccal aligned, and the lingual cingulum is crenulated (Gow, 1980, 1994).
The lower teeth of Irajatherium resemble Chaliminia (Bonaparte, 1980) in having transversely narrow postcanines, with the same distribution of the cusps and without a fully developed lingual cingulum. In Riograndia , the lower postcanines have, as the upper ones, minuscule cusps in line (Bonaparte et al. , 2001).
In Probelesodon , the lower postcanines have more than three cusps, with the main central cusp strongly curved backwards (Romer, 1969b; PVL 4444). Probainognathus bears a prominent central cusp and accessory small cusps mesial and distally located (Romer, 1970; PVL 4445 and 4446). These morphologic patterns are different to that of Irajatherium .
The only lower postcanine preserved of Therioherpeton cargnini (Bonaparte and Barberena, 1975, 2001) and those of Charruodon tetracuspidatus (Abdala and Ribeiro, 2000) have the four cusps in line; the two central cusps are taller than the mesial and distal cusps. This pattern differs from that of Irajatherium , but it is closely similar to that of Probainognathus , however the latter taxon has until five cusps in line being the tallest the central one.

Humerus (figure 8)

 
Figure 8. Left humerus of Irajatherium hernandezi (UFRGS-PV599T holotype) in lateral ( A), ventral, ( B) and medial ( C) views. Scale bar equals 5 mm. Abbreviations in Appendix 3. / Húmero izquierdo de Irajatherium hernandezi en vistas lateral ( A) ; ventral ( B) y medial ( C) . La escala representa 5 mm. Abreviaturas en Apéndice 3.

An almost complete left humerus is preserved; the entepicondylar bridge, the capitulum, and the ulnar condyle are missing. The proximal and principally distal ends are expanded and twisted relative to one another.
The head is well defined and is mediodorsally projected. Proximally, the deltopectoral crest is prominent and it extends by more than half of the shaft length. Distally, the deltopectoral crest connects with the base preserved of the entepicondylar bridge. The proximal edge of the deltopectoral crest is at the level of the humeral head. The position of the deltopectoral crest is almost perpendicular to the main axis of the distal end. The angle between the plane of the head and the lesser tuberosity and the plane of the deltopectoral crest is approximately 90 degrees. The lesser tuberosity stands apart from the head as a medial projected prominence. It is bulbous and well developed medially bearing a striated medial surface possibly for insertion of the subcoracoscapularis muscle (Jenkins, 1971). The major tuberosity is low and almost continuous with the humeral head. The biccipital groove is wide, becoming deeper on the laterodistal side of the lesser tuberosity.
Medioventrally, in the proximal half of the humerus and near the mid portion of the bone there are two well-defined osseous processes (figures 8.B and C), possibly for the insertion of the teres major shoulder muscle (Jenkins, 1971; see also Discussion).
The distal width of the humerus is more than onehalf of the proximo-distal length. The ectepicondyle is dorsoventrally thin. The olecranon fossa is slightly concave; and the capitulum is not preserved. The ectepicondylar foramen is small and opens distally.
The entepicondyle is prominent, separated by a groove from the olecranon fossa. The entepicondyle is flat and lacks a medioproximal projection as in Thrinaxodon , ? Cynognathus , Pascualgnathus , Luangwa , and Probelesodon (Jenkins, 1971; Bonaparte, 1966a, 1966b; Kemp, 1980; Romer and Lewis, 1973). The ulnar condyle is not preserved. The entepicondylar foramen is large and oval, ventrally covered by the entepicondyle bridge which is partially broken.
Comparison (figure 9). The general aspect of the humerus of Irajatherium is comparable to that of several cynodonts and early mammals, which have expanded proximal and distal ends and a short shaft. The angle of the deltopectoral crest is similar to the small sized traversodontids Pascualgnathus , Andescynodon , and Massetognathus (Bonaparte, 1966b; Jenkins, 1970; Abdala, 1999).

 
Figure 9. Comparison of the left humerus among eucynodont and mammaliaforms in lateral and ventral views. A, the traversodontid Luangwa (after Kemp, 1980); B, the tritylodontid Oligokyphus (after Kühne, 1956); C, the probainognathian Probelesodon (after Romer and Lewis, 1973); D, the tritheledontid Irajatherium ; E, the morganucodontid Morganucodon (after Jenkins and Parrington, 1976); and F, the cladotherian Vincelestes (after Rougier, 1993). Not to scale / Comparación del húmero izquierdo entre eucinodontes y mamaliaformes en vistas lateral y ventral. A, el traversodóntido Luangwa (modificado de Kemp, 1980); B, el tritilodóntido Oligokyphus (modificado de Kühne, 1956); C, el probainognatia Probelesodon (modificado de Romer and Lewis, 1973); D, el triteledóntido Irajatherium; E, el morganucodóntido Morganucodon (modificado de Jenkins and Parrington, 1976); y F, el cladoterio Vincelestes (modificado de Rougier, 1993). No están a escala.

The shape of the lesser tuberosity as well as the biccipital groove of Irajatherium is similar to that of most cynodonts, morganucodontids (Jenkins and Parrington, 1976), and monotremes (Murray, 1978; Gambaryan and Kielan-Jaworowska, 1997). Nevertheless, Irajatherium has the biccipital groove deeper proximally as in the digging multituberculate ? Lambdopsalis bulla (Kielan-Jaworowska and Qi, 1990) and some fossorial therians ( e.g . Gambaryan and Kielan- Jaworowska, 1997).
In Irajatherium , the two processes for the teres major muscle are here considered a derived feature. Pascualgnathus polanski (Bonaparte, 1966b), Massetognathus pascuali (Jenkins, 1970), ? Cynognathus (Jenkins, 1971), Luangwa drysdalli (Kemp, 1980), and Morganucodon (Jenkins and Parrington, 1976) have a groove and a crest in the same position, which were considered to attach the teres major or the latissimus dorsi muscles ( e.g . Jenkins, 1971). This structure in Pascualgnathus was interpreted for the attachment of the triceps muscle (Bonaparte, 1966b), but probably this crest refers to the teres major or the latissimus dorsi muscles. The presence of an area for the attachment of the teres major muscle is a feature observed in most mammals. Thus, in the metatherians Didelphis (personal observation) and Mayulestes ferox (Muizon, 1998) there is a weak tuberosity located on the medial side below the lesser tuberosity for the teres major muscle, while in other recent mammals such as edentates (personal observation) there is a well-marked crest for both teres major and latissimus dorsi muscles.
The humerus of Irajatherium differs from that of Pachygenelus (Hopson, personal communication; Gow, 2001) and Morganucodon (Jenkins and Parrington, 1976) because the deltopectoral crest is not reduced, the shaft is thicker and more robust, and the entepicondyle is relatively flat (i.e. not strongly projected to the mediodistal side). Despite the similarities among the humerus of Pachygenelus , tritylodonts, Morganucodon , and Vincelestes , the three latter taxa lack an ectepicondylar foramen. Absence of this foramen in tritylodonts is probably convergent with mammaliaforms ( e.g . Hopson and Kitching, 2001).

Femur (figure 10)

 
Figure 10. Left femur of Irajatherium hernandezi (UFRGS-PV599T holotype) in lateral (A) , dorsal (B) and medial (C) views. Scale bar equal 5 mm. Abbreviations in Appendix 3 / Fémur izquierdo de Irajatherium hernandezi en vistas lateral (A) , dorsal (B) y medial (C) . La escala representa 5 mm. Abreviaturas en Apéndice 3.

Only the left femur of Irajatherium is preserved. The femoral head is convex, dorsomedially projected, and without a well defined neck. Distally to the femoral head, there is a smooth ridge defining a shallow lateral and a deep medial concave area, for the attachment of the pubio-ischio-femoralis internus muscle (Jenkins, 1971).
The greater trochanter is laterally projected at the same level of the femoral head, and is continuous with the latter. This trochanter is thin and less developed than in Exaeretodon (Bonaparte, 1963), Massetognathus (Jenkins, 1970), ? Cynognathus (Jenkins, 1971), and Luangwa (Kemp, 1980). The lesser trochanter has a more proximal position than in most eucynodonts ( e. g. Exaeretodon , Massetognathus and Probelesodon ; Bonaparte, 1963; Jenkins, 1970; Romer and Lewis, 1973). This trochanter is medially projected and separated from the femoral head.
The femoral shaft is thin, cylindrical in cross section, with the lateral border more concave than the medial one. The distal half is wider than the proximal. The lateral condyle is more prominent than the medial one, but the latter is more laterally projected. The supracondylar groove is shallow reaching the lateral condyle.
Comparison (figure 11). The femur of Irajatherium , as in Therioherpeton , has more derived features than that of Probelesodon , but it clearly presents more plesiomorphic traits than that of Pachygenelus , Oligokyphus and Morganucodon .

 
Figure 11. Comparison of the left femur among eucynodont and mammaliaforms in dorsal view. A, the traversodontid Exaeretodon (after Bonaparte, 1963); B, the tritylodont Oligokyphus (after Kühne, 1956); C, the probainognathian Probelesodon (after Romer and Lewis, 1973); D, the tritheledontid Irajatherium ; E, the probainognathian Therioherpeton (after Bonaparte and Barberena, 2001); F, the morganucodontid Morganucodon (after Jenkins and Parrington, 1976); and G, the cladotherian Vincelestes (after Rougier, 1993). Not to scale. / Comparación del fémur izquierdo entre eucinodontes y mamaliaformes en vista dorsal. A, el traversodóntido Exaeretodon (modificado de Bonaparte, 1963); B, el tritilodóntido Oligokyphus (modificado de Kühne, 1956); C, el probainognatia Probelesodon (modificado de Romer y Lewis, 1973); D, el triteledóntido Irajatherium; E, el probainognatia Therioherpeton (modificado de Bonaparte and Barberena, 2001); F, el morganucodóntido Morganucodon (modificado de Jenkins y Parrington, 1976); y G, el cladoterio Vincelestes (modificado de Rougier, 1993). No están a escala.

The projection of the head is similar to Therioherpeton , Pachygenelus , and Morganucodon (Bonaparte and Barberena, 2001; Jenkins and Parrington, 1976; Garbaryan and Averianov, 2001), while it is more medially projected in most cynodonts. The head of the femur of Irajatherium is bulbous as in Exaeretodon , Massetognathus , ? Cynognathus , and Luangwa (Bonaparte, 1963; Jenkins 1970, 1971; Kemp, 1980). In most non-mammalian cynodonts ( e.g . Probelesodon ; Romer and Lewis, 1973) the greater trochanter is more distally located than in Irajatherium . The location and projection of the lesser trochanter is similar to Therioherpeton (Bonaparte and Barberena, 2001), Pachygenelus , tritylodontids (Kühne, 1956; Sues, 1983) and Morganucodon (Jenkins and Parrington, 1976). The medial projection of the lesser trochanter in Therioherpeton was interpreted (Bonaparte and Barberena, 2001) as a local deformation, however its position on the medial surface of the femur is a derived feature and possibly related to the enlargement of the ventral fossa for the insertion of the adductor musculature and the pubo-ischio-femoralis internus muscle (Jenkins, 1971).
The proximal portion of the femur of Irajatherium is very similar to that of Therioherpeton , but the latter seems to have the head less developed. In Pachygenelus , tritylodontids, Morganucodon , and Vincelestes there is a distinctive notch between the head and the greater trochanter. In addition, the femoral head of Morganucodon and Vincelestes is globular with a fovea capitis, and a well defined femoral neck.
In Irajatherium the relative size and projection of both condyles seem to be similar to that of Morganucodon (Jenkins and Parrington, 1976); but in the latter the condyles are more convex. Jenkins and Parrington (1976) noted that when the supracondylar groove ends on the lateral condyle, the fibula participate in the knee joint, while when this groove ends between both distal condyles (condition present in most eutherians mammals), there is not articulation of the fibula with the femur. A lateral facet for articulation of the fibula is not observed in Irajatherium , nevertheless and according to Jenkins and Parrington (1976) it is most probable that the fibula contacted with the femur due to the lateral position of the supracondylar groove.

Discussion

Phylogenetic relationships of Irajatherium hernandezi . In the last years, the tritheledontids were considered to be the sister group of mammaliaforms ( e.g . Hopson and Barghusen, 1986; Shubin et al. , 1991; Crompton and Luo, 1993; Luo and Crompton, 1994; Luo, 1994; Luo et al. , 2002; Hopson and Kitching, 2001). Pachygenelus , the best known tritheledontid, shares with Mammaliaformes a large number of synapomorphies specially in basicranial and palatal regions, upper and lower dentitions, and postcranium as well ( e.g . Allin and Hopson, 1992; Hopson and Barghusen, 1986; Shubin et al. , 1991; Crompton and Luo, 1993; Luo, 1994; Luo and Crompton, 1994; Gow, 2001; Hopson and Kitching, 2001).
In most studies ( e.g . Hopson and Barghusen, 1986; Rowe, 1988; Sidor and Hopson, 1998; Crompton and Luo, 1993), the Tritheledontidae is treated as a natural group, but the phylogenetic relationships among their members are not clear. Bonaparte (1980) proposed the family Pachygenelidae to include Chaliminia musteloides and Pachygenelus monus , and Tritheledontidae to include Trithelodon riconoi and Diartrognathus broomi . Later authors did not follow this proposal. More recently, a new family Riograndidae was erected for the only species Riograndia guaibensis (Bonaparte et al. , 2001), based on the particular morphology of its dentition.
In the phylogenetic analysis of Hopson and Barghusen (1986), the diagnostic characters of tritheledontids were: three upper incisors, first lower incisor enlarged, upper postcanine teeth with lateral surface of the main cusp bulging laterally, and an extremely long bony secondary palate. Later, Crompton and Luo (1993) diagnosed the Tritheledontidae by: reduced number of incisors, bulbous upper postcanines, and a large descending process of the frontal.
Irajatherium hernandezi is here referred to the family Tritheledontidae due to the morphology of the upper last erupting postcanine and the lower postcanines which resemble those of Pachygenelus monus (Watson, 1913; Gow, 1980) and Chaliminia musteloides (Bonaparte, 1980).
A cladistic analysis was performed here in to test the position and relationships of Irajatherium hernandezi among eucynodonts. The taxa analyzed included 14 non-mammalian cynodonts and two mammaliaforms. Thrinaxodon was used as outgroup taxon and to root the tree. Ingroup taxa are represented by Cynognathus , Exaeretodon , Lumkuia , Chiniquodon , Probelesodon , Probainognathus , Prozostrodon , Therioherpeton , Riograndia , Chaliminia , Irajatherium , Pachygenelus , Diarthrognathus , and the early mammaliaforms Sinoconodon and Morganucodon . Tritylodontidae is excluded of this analysis because they have many derived features ( e.g . Kemp, 1982, 1983; Wible, 1991; Luo, 1994, 2001) possibly acquired in parallel to the Probainognathia clade ( e.g . Sues, 1985; Hopson and Barghusen, 1986; Hopson and Kitching, 2001). The ingroup taxa were selected following previous analyses ( e.g . Hopson and Barghusen, 1986; Crompton and Luo, 1993; Rowe, 1988; Luo and Crompton, 1994; Luo, 1994; Martinez et al. , 1996; Luo et al. , 2001, 2002; Hopson and Kitching, 2001).
The matrix (Apendix 1) is composed of 63 characters (character list in Appendix 2), most of which were taken from previously published studies, especially the analysis of Hopson and Kitching (2001) and Luo (1994). Modifications in some character-states and scored data were made and also new characters were added. All characters have the same weight and the multi-state characters were treated as unordered. The data matrix was analyzed under program NONA version 2.0 (Gologoff, 1993) using a heuristic search and edited with Winclada (Nixon, 1999).
In the analysis, four most parsimonious trees of 129 steps, a consistency index of 0.65 and a retention index of 0.73 were obtained. The strict con sensu s of these trees is shown in figure 12.

 
Figure 12. Strict consensus of the four most parsimonious trees obtained under NONA program and edited with Winclada. Clades: 1, Eucynodontia; 2, Cynognathia; 3, Probainognathia; 4, Tritheledontidae; 5, Mammaliaformes. / Consenso estricto de los cuatro árboles más parsimoniosos obtenido por el programa NONA y editados con Winclada.

In all the trees Cynognathus and Exaeretodon , representing the Cynognathia clade (Hopson and Barghusen, 1986), share the presence of posterodorsal mandibular movement during the occlusion (Ch. 2); sequential addition posteriorly of postcanine replacement (Ch. 8); unfused parietals (Ch. 27); zygomatic arch dorsally extended above the middle of the orbit (Ch. 34); presence of jugal suborbital process (Ch. 36); very deep squamosal groove for the external auditory meatus (Ch. 37); absence of the internal carotid foramina in the basisphenoid (Ch. 40); and greatest width of the zygomatic arch at the posterior end (Ch. 44). Lumkuia fuzzi , the most plesiomorphic taxon of the Probainognathia clade ( sensu Hopson and Kitching, 2001), is unresolved in this analysis, forming a trichotomy with Cynognathia and Probainognathia (figure 12). The clade Probainognathia is supported by two unequivocal and one equivocal synapomorphies: the premaxilla forms the posterior border of the incisive foramen (Ch. 24); the frontal contacts the palatine in the orbit (Ch. 38); and the fenestra rotunda and jugular foramen are partially separated by a fingerlike projection from the posterolateral wall of the jugular foramen (Ch. 47). Probelesodon and Chiniquodon are sister taxa of Prozostrodon and the most inclusive clade. Both chiniquodontid genera are not resolved in this analysis. The clade including Prozostrodon , Therioherpeton , Tritheledontidae, and Mammaliaformes is supported by five unequivocal and one equivocal synapomorphies: unilateral occlusion (Ch. 1); dorsomedial mandibular movement during occlusion (Ch. 2); presence of constricted root on the postcanines (Ch. 9); presence of wear facets on the postcanines (Ch. 18, absent in Sinoconodon ) (Ch. 19); and presence of an unfused symphysis (Ch. 21). The postorbital bone was described in Prozostrodon (Bonaparte and Barberena, 2001), but it possibly corresponds to the anterolateral projection of the parietal, similar to Therioherpeton (Bonaparte and Barberena, 1975, 2001). Therioherpeton , Tritheledontidae, and Mammaliaformes share the absence of prefrontal (Ch. 32) and postorbital bones (Ch. 33). In addition, the sutures of the prefrontal bone, if present, are not clear in the holotype of Prozostrodon . However, until new studies of this material are done, we will follow the interpretation of Bonaparte and Barberena (2001). Sinoconodon and Morganucodon share two unequivocal features: squamosal glenoid cavity facing ventrally and separated from the cranial moiety by a neck (Ch. 22), and the presence of the stapedial muscle fossa (Ch. 48). In addition, they share four equivocal synapomorphies: characters 11(1); 24(0); 41(1) and 42(2). The tritheledontid group is supported by one unequivocal and two equivocal synapomorphies: presence of three upper incisors (Ch. 3); some incisor enlarged (unequivocal, Ch. 5); and the presence of an interpterygoid vacuity (Ch. 29). Riograndia is considered the most plesiomorphic taxon within the Tritheledontidae. Chaliminia , Irajatherium , Pachygenelus , and Diarthrognathus share one unequivocal and three equivocal synapomorphies: presence of middle and posterior lower postcanines with four cusps aligned that decreasing in size backward (unequivocal, Ch. 14); posterior portion of the maxillary tooth row that extends medial to the temporal fossa (Ch.16); axis of the posterior part of the maxillary tooth row directed toward the medial rim of the temporal fossa (Ch. 17); and the tooth row oriented parallel or subparallel to the axial plane of the cranium (Ch. 20). Irajatherium , Pachygenelus , and Diarthrognathus form an unresolved trichotomy. These taxa share five unequivocal synapomorphies: two upper (Ch. 3) and two lower incisors (Ch. 4); presence of a dominant central bulbous main cusp on upper postcanines (Ch. 12); presence of lower teeth much larger than the uppers ones (Ch. 15); and the squamosal formed a broad and anteroventrally facing glenoid cavity (Ch. 22). The characters 3, 4 and 22 are unknown in Irajatherium . This analysis supports that Tritheledontidae are the sister taxon of Mammaliaformes without considering the two newly described Brasilodon quadrangularis and Brasilitherium riograndensis from Caturrita Formation (Rio Grande do Sul, Brazil). Nevertheless, these latter taxa are depicted as more closely related to Mammaliaformes than are the tritheledontids as can be seen in the analysis of Bonaparte et al. (2003).
Dental features. Gow (1980) noted that Pachygenelus has the most generalized dentition among tritheledontids. However, Riograndia , Chaliminia , and Irajatherium are still more plesiomorphic, due to the lack of a cingulum in the upper and lower postcanines. Among these taxa Riograndia shows a plesiomorphic tooth morphology directly related with the more derived type of the tritheledontid's postcanines (Bonaparte et al. , 2001).
The strong wear facets present on the buccal side of the lower postcanines of Irajatherium indicated dorsomedial movements of the lower jaw during mastication, similar to Pachygenelus (Gow, 1980; Shubin et al. , 1991), Diarthrognathus (Gow, 1980), and Riograndia (Bonaparte et al. , 2001). Despite the sharp wear facets, no other precise pattern of occlusion between upper and lower postcanines were observed. Patterns of occlusion are present in mammaliaforms ( e.g . Morganucodon and Megazostrodon ; Mills, 1971; Crompton, 1974; Gow, 1986), however in Sinoconodon , despite having a well-developed mandibular condyle, wear facets are not observed (Crompton and Sun, 1985; Crompton and Luo, 1993).
In Irajatherium , the mesiodistal length of the upper postcanines is almost one-half the length of the lower postcanines, similar to Pachygenelus and Diarthrognathus (Gow, 1980). This condition could represented a carnassial specialization in which the lower postcanines become narrower and elongated mesiodistally.
The pattern of canine and postcanines replacement in Irajatherium is alternate as in most carnivorous non-mammalian cynodonts ( e.g . Crompton, 1963b). This replacement is evidenced by the fact that the eruption of the first upper postcanine occurred long after the eruption of the second upper postcanine.
In Irajatherium there are at least two variants of crown morphology in the upper postcanines: one present in the anterior postcanines and the other in the last tooth, which resembles the postcanines of Pachygenelus . Possibly, the new generation of the posteriormost postcanines has a crown morphology more complex than the older teeth. However, this kind of replacement is not documented in the anteriormost postcanines because the erupting first tooth (a new generation) is similar to the second tooth that represents an older generation. Pachygenelus has also an alternate replacement, with different waves of replacement resulting in the same morphological type of tooth (Gow, 1980). In Thrinaxodon , the Early Triassic sister taxon of all Eucynodontia ( e.g . Hopson and Kitching, 2001), an inverse replacement pattern has been noted ( e.g . Crompton and Jenkins, 1968). The upper and lower postcanines of young individuals of Thrinaxodon have a crown morphology similar to that of Morganucodon that are replaced in older specimens with more simple postcanines (Parrington, 1936; Crompton, 1963b; Crompton and Jenkins, 1968). Gomphodont eucynodonts, which loose the anterior postcanines and add new larger postcanines at the end of the tooth row, also have different crown morphologies involved in the dental replacement ( e.g . Fourie, 1963; Hopson, 1971; Crompton, 1972; Goñi, 1986). The Early-Middle Triassic gomphodont Andescynodon mendozensis (Bonaparte, 1969) shows in its juvenile stage posterior sectorial postcanines that are replaced by gomphodont teeth (Goñi, 1986; Goñi and Goin, 1987). In non-mammalian cynodonts the types of postcanines are classified following their morphology and placement on the dentary, but not according to their ontogenetic patterns as in mammals (the premolars are the only postcanine with replacement; e.g . Owen, 1845). In many mammals, the deciduous teeth are morphologically more complex than the permanent ones or quite similar ( e.g . in Morganucodon the last deciduous premolar is molarized and in marsupials the only replacement, the dP3, is a molariform which is replaced by P 3 similar to the other premolars). The new posterior tooth of Irajatherium is more complex than the remaining postcanine as in gomphodonts but differing from Thrinaxodon and many mammals. This probably indicates that new types of teeth in a later stage of the ontogeny are a consequence of a different type of diet. In addition, the replacement waves of Irajatherium could be a useful reference to infer a possible mechanism of dental differentiation among non-mammalian cynodonts.
Irajatherium has a constricted root on the lingual side of the upper postcanines and on the buccal side of the lower ones. The incipient bifurcation of some roots on upper and lower teeth occurs in tritheledontids (except Chaliminia ; Bonaparte, 1980), Therioherpeton (Bonaparte and Barberena, 1975, 2001), and Microconodon (Sues, 2001). An incomplete separation of the roots occurs in some postcanines of Sinoconodon (Crompton and Luo, 1993; Luo, 1994). A fully division occurs in the ?chiniquodontid Mitredon cromptoni (Shapiro and Jenkins, 2001) and in Mammaliaformes. In Morganucodon this feature varies in the tooth row, some postcanine roots are completely separated whereas others are not. Shapiro and Jenkins (2001) claimed that tooth root bifurcation was developed more than once in the evolution of the nonmammalian cynodonts and early mammals, an interpretation that we follow here.
Postcranial features and adaptations. The knowledge of postcranial remains in tritheledontids was only based on Pachygenelus (Gow, 2001; Hopson and Kitching, 2001). The humerus and the femur of this taxon closely resemble that of Morganucodon (unpublished remains, Hopson, personal communication).
Some features observed in the humerus of Irajatherium might suggest burrowing adaptation. The presence of robust, short, heavily muscled, and large-clawed forelimbs represent a type of fossorial adaptations to digging (Dubost, 1968). These features are observed in the digging insectivorous moles Talpidae (Dubost, 1968) and the golden moles Chrysochloridae (Hickman, 1990), among others. Kielan-Jaworowska and Qi (1990) expressed that "it seems possible that adaptations for digging were more common among early mammals...". We think that this interpretation may also apply to several non-mammalian cynodonts (Sues, 1983). As the only forelimb bone preserved of Irajatherium is the humerus (figure 7), it is difficult to make unequivocal interpretations about functionality and behavior. Nevertheless, the combination of some features would indicate adaptations to dig or eventually to burrow: 1) the humerus of Irajatherium has a proximally deep biccipital groove as in the presumably digging multituberculate ? Lambdopsalis bulla (Kielan-Jaworowska y Qi, 1990) and some fossorial therians; 2) the lesser tuberosity is prominent representing a plesiomorphic feature among cynodonts, but may also indicate a burrow adaptation because a large lesser tuberosity is present in burrowing mammals with sprawling forelimbs increasing the function of the subscapularis and scapulohumerus muscles (homologous to subcoracoscapularis muscle of non-mammalian cynodonts; Jenkins, 1971) (Gambaryan and Kielan-Jaworowska, 1997); 3) the presence of well developed osseous processes for the teres major muscle is also evident in some non-mammalian cynodonts, early mammals, and in current fossorial mammals such as edentates ( e.g . Dasypus , personal observation). The teres major muscle, jointly with other muscles, is a medial rotator and adductor of the humerus (Jenkins and Weijs, 1979; Argot, 2001). Based on the great development of the processes for the teres major in Irajatherium it is probable that in concordace this muscle was also well developed, increasing its functionality; 4) the deltopectoral crest is well developed in the humerus of Irajatherium . The position of this crest is similar to that of small traversodontids and some chiniquodontids, but the angle between the plane of the head and the lesser tuberosity and the plane of the deltopectoral crest is more reduced than in large sized nonmammalian cynodonts (Abdala, 1999). Finally, Groenewald et al. (2001) described burrow complexes in outcrops of the Early Triassic of South Africa in which the gomphodont cynodont Trirachodon was found inside. No functional studies were done in this taxon but probably it represents an example of fossorial behavior in cynodonts. However, further studies and new materials are needed to clarify these paleobiological inferences.

Conclusions

Irajatherium hernandezi is here considered a new tritheledontid closely related to the African and North American Pachygenelus monus and the African Diarthrognathus broomi . Five taxa, Riograndia , Chaliminia , Irajatherium , Pachygenelus , and Diarthrognathus , are included within the family Tritheledontidae.
The dentition of Irajatherium is clearly more complex than that of the South American Riograndia and Chaliminia , but less specialized than those of Pachygenelus and Diarthrognathus . The presence of two different kinds of upper postcanines in alternate replacement waves in Irajatherium could offer evidence for possible mechanism of dental differentiation among cynodonts taxa. However further studies and new specimens are needed to corroborate these inferences.
Possible fossorial adaptations are documented in the humerus of Irajatherium ; and these features, related to digging or burrowing, might be common in several small-bodied non-mammalian cynodonts.

Appendix 1. Data matrix

Distribution of the character-states for the 63 characters listed in Appendix 2 among 15 ingroup taxa and 1 outgroup taxon considered in this analysis. Coding for character-states: 0, primitive; 1 to 3, derived; ?, missing information or uncertain character-states; A, polimorphic condition 1+2. We studied the following specimens for comparison and character scorings: Exaeretodon frenguellii : MACNPV 15175, MACN-PV 18114, MACN-PV 18125, PVL 2079 and PVL 2162; Probainognathus jenseni : MACN-PV 18916, PVL 3857, PVL 4445, PVL 4446, PVL 4678, PVL 5442 and MCZ 4015; Probelesodon sp.: PVL 4444; Chaliminia musteloides : PVL 3857; Riograndia guaibensis : MCNPV 2264; MCN-PV 2265, MCN-PV 2271; Prozostrodon brasiliensis: UFRGS-PV 0248 T; Pachygenelus monus : SAM K 1350; Diarthrognathus broomi : MCZ without number; Vincelestes neuquenianus : MACN-PV N 38 and MACN-PV N 39. Other anatomical information was taken from the literature.

 

Appendix 2. Phylogenetic analysis

List of characters used in the phylogenetic analysis:

1. Mode of occlusion: bilateral (0) or unilateral (1) (Luo, 1994).
2. Direction of mandibular movement during occlusion: orthal (0), posterodorsal (1) or dorsomedial (2) (Luo, 1994).
3. Upper incisor number: 5 or more (0), 4 (1), 3 (2) or 2 (3) (modified from Hopson and Kitching, 2001).
4. Lower incisor number: 4 or more (0), 3 (1) or 2 (2) (modified from Hopson and Kitching, 2001).
5. Some incisor enlarged: absent (0) or present (1).
6. Upper incisor size: all small (0), incisor 1 enlarger and the others small (1) or incisor 2 enlarger and the others small (2).
7. Lower incisor size: all small (0) or incisor 1 enlarger and the others small (0).
8. Postcanine replacement: alternate (0), partial (1) or sequential addition posteriorly (2) (modified from Luo, 1994).
9. Roots of postcanines: single (0), contricted root (1), complete separation of roots (2) or multiple roots (3) (modified from Luo, 1994).
10. Upper postcanine buccal cingulum: absent (0) or present (1) (Hopson and Kitching, 2001).
11. Upper postcanine lingual cingulum: absent (0), narrow (1) or lingually expanded (2) (Hopson and Kitching, 2001).
12. A dominant central bulbous main cusp on upper postcanines: absent (0) or present (1).
13. Upper posterior postcanines with cusps B and C buccally displaced and bulbous, prominent cusp A: absent (0) or present (1).
14. Lower middle and posterior postcanines with four cusps aligned decresingin size backwards: absent (0) or present (1).
15. Lower teeth much larger than the uppers: absent (0) or present (1).
16. Posterior portion of the maxillary tooth row extends medial to the temporal fossa: absent (0) or present (1) (Hopson and Kitching, 2001).
17. Axis of posterior part of maxillary tooth row: directed lateral to temporal fossa (0), directed toward center fossa (1) or directed toward medial rim (2) (Hopson and Kitching, 2001).
18. Wear facets on postcanines: absent (0), absent at eruption but developed later by wear (1) or wear facets present at eruption (2) (Luo, 1994).
19. Relationships of wear facet to main cusps: absent (0), simple longitudinal in most of the length of crown (1), two distintive facets (2) or multiple cusp, with each cusp bearing one or two transverse facets (3) (modified from Luo, 1994).
20. Tooth row: divergent posteriorly (0) or parallel to subparallel from the axial plane of the cranium (1) (Martinez et al. , 1996).
21. Symphysis: fused (0) or unfused (1) (Luo, 1994).
22. Squamosal glenoid for the dentary: absent (0), formed by small and medially facing facet (1), formed by broad and anteroventrally facing glenoid (2) or glenoid facing ventrally and separated from cranial moiety by neck (3) (modified from Luo, 1994).
23. Anterolateral projection of the frontal contacting medially the nasal: absent (0) or present (1).
24. Premaxilla forms posterior border of the incisive foramen: absent (0) or present (1) (Hopson and Kitching, 2001).
25. Prefrontal: present (0) or absent (1) (Hopson and Kitching, 2001).
26. Postorbital: present (0) or absent (1) (Hopson and Kitching, 2001).
27. Parietals: fused (0) or unfused (1) (Martinez et al. , 1996).
28. Parietal foramen: present (0) or absent (1) (Hopson and Kitching, 2001).
29. Interpterygoid vacuity in adult between pterygoid flanges: absent (0) or present (1) (Hopson and Kitching, 2001).
30. Length secondary palate relative to toothrow: shorter (0), about equal (1) or longer (2) (Hopson and Kitching, 2001).
31. Length secondary palate relative to anterior border of orbit: shorter (0), about equal (1) or longer (2) (Hopson and Kitching, 2001).
32. Ventral surface of basisphenoid depressed below occipital condyles: less than 1/4 occipital height (0) or less than 1/4 occipital height (1) (Hopson and Kitching, 2001).
33. Zygomatic arch dorsoventral height: slender (0), moderaty deep (1) or very deep (2) (Hopson and Kitching, 2001). A.G. Martinelli, J.F. Bonaparte, C.L. Schultz and R. Rubert 208.
34. Zygomatic arch dorsal extent: below middle of orbit (0) or above middle of the orbit (1) (Hopson and Kitching, 2001).
35. Jugal depth in zygomathic arch relative to exposed squamosal depth: less than twice (0) or greater than twice (1) (Hopson and Kitching, 2001).
36. Jugal suborbital process: absent (0) or present (1) (Hopson and Kitching, 2001).
37. Squamosal groove for external auditory meatus: moderately deep (0), very deep (1) or shallow (2) (modified from Hopson and Kitching, 2001).
38. Frontal-palatine contact in the orbit: absent (0) or present (1) (Hopson and Kitching, 2001).
39. Descending flange of squamosal lateral to quadratojugal: present not contacting surangular (0), present contacting surangular (1) or absent (2) (modified from Hopson and Kitching, 2001).
40. Internal carotid foramina in basisphenoid: present (0) or absent (1) (Hopson and Kitching, 2001).
41. Groove on prootic extending from pterygoparoccipital foramen to trigeminal foramen: open (0) or enclosed as a canal (1) (modified from Hopson and Kitching, 2001).
42. Trigeminal nerve exit via foramen: between prootic and epipterygoid (0) or via two foramina (1) (modified from Hopson and Kitching, 2001).
43. Quadrate ramus of pterygoid: present (0) or absent (1) (Hopson and Kitching, 2001).
44. Greatest width of zygomatic arches: near middle of arch (0) or at posterior end of arch (1) (Hopson and Kitching, 2001).
45. Length of palatine relative to maxilla in secondary palate: shorter (0), about equal (1) or longer (2) (Hopson and Kitching, 2001).
46. Posterolateral end of maxilla: passes obliquely posterodorsally into suborbital bar 0) or forms right angle ventral to jugal contact (1) (Hopson and Kitching, 2001).
47. Fenestra rotunda separation from jugular foramen: confluent (0), partially separed by fingerlike projection from posterolateral wall of jugular foramen (1) or completely separated (2) (Luo, 1994).
48. Stapedial muscle fossa: absent (0) or present (1) (Luo, 1994).
49. Foramen and passage of prootic sinus: separate tympanic foramen for prootic sinus absent from the lateral trough of petrosal (0), foramen present in lateral trough, but vessel passed through cavum epiptericum (1) or foramen present in lateral trough, but vessel passed through cavum epiptericum (2) (modified from Luo, 1994).
50. Postorbital bar: present (0) or absent (1) (Luo, 1994).
51. Scapular elongation between acromion and glenoid: present (0) or absent (1) (Hopson and Kitching, 2001).
52. Procoracoid in glenoid: present (0) or barely present or absent (1) (Hopson and Kitching, 2001).
53. Procoracoid contact with scapula: greater than coracoid contact (0) or smaller than coracoid contact (1) (Hopson and Kitching, 2001).
54. Humerus ectepicondilar foramen: present (0) or absent (1) (Hopson and Kitching, 2001).
55. Ulna olecranon process: absent (unossified) (0) or present (1) (Hopson and Kitching, 2001).
56. Length of anterior process of ilium anterior to acetabulum (relative to diameter of acetabulum): less than 1.0 (0), 1.0-1.5 (1) or 1.0- 1.5 (2) (Hopson and Kitching, 2001).
57. Length of posterior process of ilium posterior to acetabulum (relative to diameter of acetabulum): greater than 1.0 (0) or less than 0.5 (1) (Hopson and Kitching, 2001).
58. Dorsal profile of ilium: strongly convex (0) or flat to concave (1) (Hopson and Kitching, 2001).
59. Greater trochanter separated from the femoral head by distinct notch: absent (0) or present (1) (Hopson and Kitching, 2001).
60. Lesser trochanter position: on the ventromedial surface of femoral shaft (0) or on medial surface of femoral shaft (1) (Hopson and Kitching, 2001).
61. Vertebral centra: amphicoelous (0) or platycoelous (1) (Hopson and Kitching, 2001).
62. Greater trochanter location at the level of the femoral head: absent (0) or present (1).
63. Lesser trochanter location near the level of the femoral head: absent (0) or present (1).

Appendix 3

List of abbreviations : big, biccipital groove; cr, constricted root; D, dentary; dc, deltopectoral crest; dl, dental lamina; e, enamel; ecf, ectepicondylar foramen; ect, ectepicondyle; enf, entepicondylar foramen; ent, entepicondyle; epc, erupting last postcanine; fc, fossa for lower canine; gt, greater trochanter; h, head; iof, infraorbital foramen; M, maxilla; maf, masseteric fossa; mc, medial condyle; meg, Meckelian groove; mt, major tuberosity; lc, lateral condyle; lt, lesser tuberosity; ltr, lesser trochanter; scg, supracondylar groove; ttm, tuberosities for insertion of the teres major muscle; wf, wear facet.

Lista de abreviaturas: big, canal bicipital; cr, raiz constrictida; D, dentario; dc, cresta deltopectoral; dl, lamina dental; e, esmalte; ecf, foramen ectepicóndilar; ect, ectepicóndilo; enf, foramen entepicóndilar; ent, entepicóndilo; epc, último postcanino en erupción; fc, fosa para el canino inferior; gt, trocánter mayor; h, cabeza; iof, foramen infraorbital; M, maxilar; maf, fosa masetérica; mc, cóndilo medial; meg, canal Meckeliano; mt, tuberosidad mayor; lc, cóndilo lateral; lt, tuberosidad menor; ltr, trocánter menor; scg, surco supracondilar; ttm, tuberosidades para la inserción del músculo teres major; wf, faceta de desgaste.

Acknowledgments

For comments and critical reading, we acknowledge J.A. Hopson, A.W. Crompton, Z. -X. Luo, G.W. Rougie, and A.M. Forasiepi. To the National Geographic Society for supports (grants 6716/00 and 7187/02) fieldworks in Brazil to J.F.B. We thank J. Powell, A.W. Crompton for the access to the collection under their care. We specially thank to C. Sidor, J.G. Cripps, and Y. Gurovich for their comments and assistance with English grammar corrections. We are also grateful to F. Abdala, Z. -X. Luo, and C. Marsicano who have provided helpful critiques on the last version of the manuscript.

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Recibido: 6 de noviembre de 2002.
Aceptado: 10 de junio de 2004.

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