Acta Palaeontol. Pol. 64 (X): xxx–xxx, 2019 https://doi.org/10.4202/app.00544.2018

A new capybara from the late Miocene of San Juan 
Province, Argentina, and its phylogenetic implications
ESPERANZA CERDEÑO, MARÍA E. PÉREZ, CECILIA M. DESCHAMPS, 
and VÍCTOR H. CONTRERAS

Cerdeño, E., Pérez, M.E., Deschamps, C.M., and Contreras, V.H. 2019. A new capybara from the late Miocene of San 
Juan Province, Argentina, and its phylogenetic implications. Acta Palaeontologica Polonica 64 (x): xxx–xxx.

A new hydrochoerine rodent, Cardiatherium calingastaense sp. nov. (Caviidae), is described based on the specimen 
INGEO-PV 87. It was recovered from the late Miocene Las Flores Formation, cropping out at the Puchuzum locality, 
San Juan Province, Argentina. The new species is based on a particular combination of characters, among which the 
following can be highlighted: p4 with internal fissures equally deep as in Cardiatherium paranense, secondary external 
fissure as in Cardiatherium patagonicum, and lacking the fifth internal fissure and supernumerary internal fissure, as in 
C. paranense; m3 with a conspicuous labial column in the posterior ramus of the second prism; very deep primary and 
secondary external fissures in upper cheek teeth, the former producing a labial strong step-shaped profile in M2; sagittal 
crest on the parietals; bullae small in ventral view; scars of the origin of the masseter medialis muscle with an anterior 
projection up to the level of the incisive foramen and the maxilla-premaxilla suture. The phylogenetic analysis supports 
the taxonomic proposal of creating a new species of Cardiatherium and shows C. calingastaense sp. nov. as the sister 
group of the other species of the genus. The lineage leading to the clade Cardiatherium + largest capybaras would have 
originated at least during the Chasicoan SALMA (early late Miocene). Cardiatherium calingastaense sp. nov. adds to 
the previous record of Cardiatherium chasicoense and Cardiatherium paranense in the late Miocene of San Juan and 
Mendoza provinces, respectively, thus increasing the diversity of capybaras in central-west Argentina.

Key words:  Mammalia, Rodentia, Caviidae, Cardiatherium, systematics, phylogeny, late Miocene, Argentina.

Esperanza Cerdeño [espe@mendoza-conicet.gob-ar], Instituto Argentino de Nivología, Glaciología y Ciencias Ambi-
entales (IANIGLA), Centro Científico Tecnológico, CONICET Mendoza, Av. Ruiz Leal s/n, 5500, Mendoza, Argentina.
María E. Pérez [mperez@mef.org.ar], Museo Paleontológico Egidio Feruglio, Av. Fontana 140, U9100GYO, Trelew, 
Argentina.
Cecilia M. Deschamps [ceci@fcnym.unlp.edu.ar], Comisión de Investigaciones Científicas de la provincia de Buenos 
Aires, Argentina; División Paleontología Vertebrados, Unidades de Investigación Anexo Museo de La Plata, Facultad 
de Ciencias Naturales y Museo, Universidad Nacional de La Plata, 122 y 60, 1900, La Plata, Argentina.
Víctor H. Contreras [vcontre@unsj-cuim.edu.ar], Instituto de Geología Dr. Emiliano P. Aparicio (INGEO) y Depar-
tamento Geología, FCEFN, Universidad Nacional de San Juan, Ignacio de la Roza y Meglioli, 5400 Rivadavia, San 
Juan, Argentina.

Received 5 September 2018, accepted 19 October 2018, available online 26 November 2018.

Copyright © 2018 E. Cerdeño et al. This is an open-access article distributed under the terms of the Creative Commons 
Attribution License (for details please see http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, 
distribution, and reproduction in any medium, provided the original author and source are credited.

Introduction
The Neogene continental outcrops in the San Juan Province, 
central-west Argentina (Fig. 1), encompass two localities 
that have yielded important late Miocene vertebrate remains. 
These localities are Puchuzum (Calingasta Valley), whose 
faunal assemblage is assigned to the Huayquerian SALMA 
(late Tortonian–Messinian; see Deschamps et al. 2013, for 
further details in bio- and chronostratigraphic equivalences), 
and Loma de Las Tapias, where two different levels are 
recognized as corresponding to the Chasicoan (Tortonian) 

and the Huayquerian South American Land Mammal Ages 
(SALMAs; Contreras et al. 1995; Peralta et al. 1995; Contreras 
1996; Cerdeño and Contreras 2000; Ciancio et al. 2006; León 
and Bracco 2008; Bracco et al. 2011; Contreras and Baraldo 
2011; Suvires and Contreras 2011).

Concerning the fossils from Puchuzum, different lev-
els of the section (distinct architectural elements) have 
provided remains of molluscs, ostracods, insects, fishes, 
and palynomorphs (found within lacustrine sediments), 
on the one hand, and mammals and birds (derived from 
flood plain sediments), together with footprint tracks, on 



2 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

the other hand (Contreras 1996; Contreras and Peralta 1998; 
Prámparo et al. 1998; Contreras and Cerdeño 2010; Bracco 
et al. 2011). Among mammal remains, only the specimens 
of a Hegetotheriidae (Notoungulata) were studied in de-
tail (Cerdeño and Contreras 2000). However, the faunal 
assemblage also includes xenarthrans, litopterns and ro-
dents (Contreras and Cerdeño 2010; Bracco et al. 2011). 
The hegetotheriid Hemihegetotherium achataleptum indi-
cated a Huayquerian SALMA for this fauna (Cerdeño and 
Contreras 2000), but no absolute age has been obtained for 
the unit. Herein we present the study of a well-preserved 
skull and mandible of a capybara, associated with some 
fragments of postcranial bones.

Capybaras are the largest living rodents, represented by 
the single genus Hydrochoerus, reaching a body length of 
100–130 cm, and adult males weighting up to 91 kg (Mones 
and Ojasti 1986). They have semiaquatic habits, and live 
in groups usually ranging in size from two to 30 individ-
uals (Dunnum 2015). They have characteristic euhypsod-
ont, multilaminated cheek teeth (Novak 1991; Deschamps et 
al. 2007). The phylogenetic relationships of capybaras with 
other cavioid rodents and the status of hydrochoerids have 
been revised during the last years (Rowe and Honeycutt 
2002; Vucetich and Pérez 2011; Upham and Patterson 2015; 
Pérez et al. 2018, and references therein). After these au-
thors, capybaras would be within the Family Caviidae as a 
subfamily, Hydrochoerinae, together with the extinct car-
diomyines and the small Kerodon (rock-dwelling mocos), 
the other living genus of the subfamily (Rowe and Honeycutt 
2002; Pérez and Pol 2012; Pérez et al. 2018).

The fossil record of capybaras (that is, hydrochoerines 
excluding ‘cardiomyines’) goes back to the late Miocene, and 
many taxa were described since the 19th century (Ameghino 

1883a, b; Rovereto 1914; Kraglievich 1930; Rusconi 1933, 
1935, 1944; Pascual and Bondesio 1963; Francis and Mones 
1965a, b; Bondesio 1985a, b; Mones 1991; among others), 
but revisions such as those by Mones (1984) and, more 
recently, Vucetich et al. (2005, 2012, 2014a, b, 2015) and 
Deschamps et al. (2007, 2009) have evidenced a great taxo-
nomic overestimation due to ontogenetic variation that had 
not been previously evaluated; consequently, these authors 
drastically reduced the known diversity of hydrochoerines, 
especially for the late Miocene–Pliocene interval.

Within the late Miocene, the oldest species is Cardia-
therium chasicoense Pascual and Bondesio, 1968 from the 
Chasicoan SALMA, which is known from the type locality 
Arroyo Chasicó (Buenos Aires Province) as well as from 
the lower levels of the Loma de Las Tapias Formation in 
San Juan Province (Contreras 2000; Contreras et al. 2001; 
Deschamps et al. 2007, 2009; Contreras and Baraldo 2011). 
In turn, the Huayquerian SALMA localities with hydro-
choerines are more abundant and the material was re-eval-
uated by Vucetich et al. (2005). These authors described 
Cardiatherium patagonicum as the southernmost record, 
from the Puerto Madryn Formation (Chubut Province). 
At the same time, they proposed that all material from 
the Ituzaingó Formation (Entre Ríos Province, north-
east Argentina) would correspond to only one species, C. 
paranense, which was later confirmed by Vucetich et al. 
(2014b). These authors also recognized C. paranense in 
Tupungato, Mendoza Province (central-west Argentina), 
from levels of the Río de Los Pozos Formation, referred to 
the late Miocene (Yrigoyen 1993). Another species assigned 
to this genus, Cardiatherium orientalis Francis and Mones, 
1965b, was recorded in the late Miocene of Uruguay, and 
tentatively recognized later in the Cerro Azul Formation, La 

Fig. 1. Geographical map showing position of studied area within San Juan Province, central-west Argentina (A) and location of outcrops of the Las Flores 
Formation (striped area) near the village of Puchuzum (B). The asterisk indicates the fossil locality. 

500 km

W 69 33’

C
a
s
ta

o
v
ie

jo
R

iv
e
r

N

S 31 06’36’’

1 km

C
a
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d
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la

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PuchuzumPuchuzum

80 70 60

55

45

35

25

BA



CERDEÑO ET AL.—A NEW MIOCENE CAPYBARA FROM ARGENTINA 3

Pampa Province, Argentina, as C. aff. orientalis (Vucetich 
et al. 2014b). The genus Cardiatherium is also known in the 
late Miocene of Brazil, Peru and Venezuela (Deschamps et 
al. 2013 and literature therein).

The present contribution focuses on the description of 
a new species of Cardiatherium based on well-preserved 
cranial remains, previously mentioned as Cardiatherium sp. 
(Contreras and Cerdeño 2010), found in the province of San 
Juan. On the basis of a cladistic analysis, the phylogenetic 
position of the new species and the monophyly of the genus 
Cardiatherium within Caviidae were tested.

Institutional abbreviations.—GHUNLPam, Cátedra de 
Geología Histórica, Universidad Nacional de La Pampa, 
Santa Rosa, Argentina; INGEO-PV, Vertebrate Palae onto-
logical collection, Instituto de Geología Dr. Emiliano P. 
Aparicio, Universidad Nacional de San Juan, San Juan, 
Argentina; MACN, Museo Argentino de Ciencias Naturales, 
“B. Rivadavia”, Buenos Aires, Argentina; MLP, Museo 
de La Plata, Argentina; MMH-CH, Museo Municipal de 
Cien cias Naturales de Monte Hermoso, Argentina; MMP, 
Museo Municipal de Ciencias Naturales “Lorenzo Scaglia”, 
Mar del Plata, Argentina; MNHN-AYO, Ayo-Ayo collec-
tion, Muséum national d’Histoire naturelle, Paris, France; 
MPEF-PV, Palaeontological collection, Museo Pale on to-
lógico “Egidio Feruglio”, Trelew, Argentina; PVSJ, Verte-
brate Palaeontological collection, Instituto y Museo de Cien-
cias Naturales, Universidad Nacional de San Juan, San Juan, 
Argentina; SPV-FHC, Sección Paleontología Verte brados, 
Departamento de Paleontología, Facultad de Humanidades 
y Ciencias, Montevideo, Uruguay.

Other abbreviations.—ch., character; he, external fissure; 
HFI, fundamental internal fissure; hfe, fundamental external 
fissure; hi, internal fissure; HPE, primary external fissure; 
hpi, primary internal fissure; HSE/hse, secondary external 
fissure; hsi, secondary internal fissure; hsni, internal super-
numerary fissure; hti, tertiary internal fissure; M/m, upper/
lower molar; P/p, upper/lower premolar; pr, prism; prIIa/b, 
anterior and posterior lobes of prII; prsa, anterior secondary 
prism; SALMA, South American Land Mammal Age.

Material and methods
The studied material, INGEO-PV 87, includes a single spec-
imen composed of a well-preserved skull with associated 
mandible, and some fragmentary postcranial remains of the 
same individual, housed at the Vertebrate Palaeontological 
Collection of the INGEO. It was compared with the ho-
lotypes and referred materials of Cardiatherium chasico-
ense, C. paranense, C. orientalis, and C. rosendoi, housed 
in the following Argentinean museums: IMUSJ, MACN, 
MLP, MMH, MMP, and MPEF. The specimens of C. pata-
gonicum used for comparisons and the phylogenetic analy-
sis were taken from Vucetich et al. (2005) and Dozo et al. 
(2010). Cardiatherium aff. orientalis from the Cerro Azul 
Formation in La Pampa Province was also used in this study. 
The detailed list of revised remains is in Appendix 1.

Dental nomenclature is given in Fig. 2A–E (flexus/flexid 
were originally named as fissures by Mones 1991, and are 
here indistinctly used) and follows partially Vucetich et al. 
(2005) and modifications according to Pérez et al. (2018). 
However, some modifications have been introduced in this 
paper, in order to fit with a new character observed in the 
p4 of Cardiatherium patagonicum and the new species here 
described. This new feature is the external flexid of the pos-
terior lobe of prII of p4 (Fig. 2A), here referred to as hse or 
h2e according to the nomenclature of m1–m3 (h.s.e. sensu 
Mones 1991; Fig. 2B–D). Hence, the external fissure of the 
anterior supernumerary prism of p4 (prsa) is named here 
h3e (h.s.e. or h.2e sensu Mones 1991; Fig. 2A, D). Lobes of 
caviids are referred to as prisms in hydrochoerines. Cranial 
nomenclature follows Vucetich et al. (2014b) and Pérez et 
al. (2018).

Skull measurements follow Vucetich et al. (2014b): (i) 
posterior width of the incisive foramen; (ii) rostral width at 
the anterior margin of the anterior root of the zygomatic arch 
(complete or up to the midline in incomplete specimens); (iii) 
width between the anteriormost points of the scars marking 
the origin of the masseter medialis muscle; (iv) rostral width 
at the level of P4, measured at the alveolar margin of prism 
I; (v) rostral width at the posterior margin of the anterior 
root of the zygomatic arch (complete or up to the midline 

A B C D E

5 mm

Fig. 2. Dental nomenclature (occlusal view). A–C, E. Cardiatherium calingastaense sp. nov. A. Right p4. B. Right m1. C. Right m3. E. Right M1. 
D. Cardiatherium patagonicum, right p4. Abbreviations: c, column; he, external fissure (or flexid); HFI, fundamental internal fissure (hypoflexus); hfe, 
fundamental external fissure; hi, internal fissure; HPE, primary external fissure; hpi, primary internal fissure; HSE/hse, secondary external fissure; hsi, 
secondary internal fissure; hsni, internal supernumerary fissure; hti, tertiary internal fissure; pr, prism; prIIa/b, anterior and posterior lobes of pr II; prsa, 
anterior secondary prism.



4 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

in incomplete specimens); (vi) rostral width at the level of 
M2, measured at the alveolar margin of prII; (vii) distance 
between the posterior margin of the incisive foramen and 
P4; (viii) P4–M1 anteroposterior length; and (ix) angle of 
the beginning of the ventral anterior zygomatic arch and the 
alveolar series, in lateral view. In order to explore the phy-
logenetic relationships of the taxon studied, we scored the 
new anatomical information throughout the last version of 
the combined Cavioidea matrix (Madozzo Jaén et al. 2018), 
originally published by Pérez and Pol (2012). The combined 
dataset of morphological and molecular characters (SOM 1 
and 2; Supplementary Online Material available at http://app.
pan.pl/SOM/app64-Cerdeno_etal_SOM.pdf) was modified. 
Some multistate characters are ordered, nine characters have 
been modified and eight characters are new (see SOM 2). 
The new dataset was analysed under equally weighted par-
simony in TNT (Goloboff and Catalano 2015), using a heu-
ristic search of 1000 replicates of Wagner trees, followed 
by tree bisection and reconnection branch swapping. Node 
supports were calculated using absolute GC bootstrap fre-
quencies calculated after 1000 pseudoreplicates. The modi-
fied Stratigraphic Manhattan Measure (Pol and Norell 2001) 
was used to calibrate the most parsimonious phylogenetic 
trees and the chronostratigraphic information for fossil taxa 
using TNT.

Geological setting
The specimen herein studied was collected in 2006 in levels 
of the Las Flores Formation, in the area of Puchuzum in 
the Calingasta Valley (Fig. 1). This unit is widely developed 
both geographically and in thickness in the Iglesia valley, 
where its type locality has been recognized (Wetten 1975; 
Contreras et al. 2013 and references therein). The strati-
graphic section at Puchuzum was previously described by 
Peralta et al. (1995) (see also Bracco et al. 2011), and corre-
sponds to the Neogene sediments cropping out at both mar-
gins of the Candelaria Creek, in the piedmont of the Manrique 
Mountains, Cordillera Frontal. According to geological and 
palaeontological studies at Puchuzum (Peralta et al. 1995; 
Contreras et al. 1995; Contreras 1996; Contreras and Peralta 
1998; Cerdeño and Contreras 2000; Bracco et al. 2011; Bogan 
et al. 2018), the bony remains recorded in this locality, which 
come from the middle of the exposed section, were assigned 
to the latest Miocene. This mid-section is characterized by 
brown-reddish to greyish psammo-pelitic deposits, reddish 
silty to silty-sandy beds, with some carbonaceous and con-
glomeratic levels, and with cut and fill structures. Three man-
tiform interbeddings of bentonitic clay, 3 to 10 m thick, are 
distinguished by their yellowish coloration. These bentonitic 
packages clearly correspond to sedimentary events that orig-
inated in lakes, evidenced by the recorded fossils: bivalves, 
gastropods, insects, and fish (Peralta et al. 1995; Contreras 
1996; Contreras and Peralta 1998; Bracco et al. 2011; Bogan 
et al. 2018). In turn, the mammals from this mid-section at 

Puchuzum represent a Huayquerian faunal association within 
the late Miocene (Peralta et al. 1995; Contreras 1996; Cerdeño 
and Contreras 2000).

The general palaeoenvironment of the mid-section of 
Puchuzum is interpreted as a fluvial system with great devel-
opment of flood plains and rivers, more or less channelled and 
strongly sinuous. The lacustrine interbeddings correspond to 
increasing and decreasing events of the lacustrine basin, in-
fluenced by tectonic and hydrologic activity. A similar situa-
tion has been interpreted for the Las Flores Formation in the 
Iglesia Basin (Milana 1994; Jordan et al. 1997).

Systematic palaeontology
Rodentia Bowdich, 1821
Hystricognathi Tullberg, 1899
Cavioidea (Fischer, 1817) sensu Kraglievich 1930
Caviidae (Fischer, 1817) sensu Waterhouse 1839
Hydrochoerinae (Gray, 1825) Gill, 1872
Genus Cardiatherium Ameghino, 1883b
Type species: Cardiatherium doeringi Ameghino, 1883b (= Cardiathe-
rium paranense [Ameghino, 1883a] in Vucetich et al. 2014b); Paraná 
River cliffs, Entre Ríos, Argentina, Ituzaingó Formation, Late Miocene.
Species included: Cardiatherium patagonicum Vucetich, Deschamps, 
Olivares, and Dozo, 2005, Cardiatherium orientalis (Francis and Mo-
nes, 1965b), Cardiatherium chasicoense (Pascual and Bondesio, 1968), 
Cardiatherium rosendoi Bondesio, 1985b, Cardiatherium talicei Fran-
cis and Mones, 1965a, and Cardiatherium isseli Rovereto, 1914.

Stratigraphic and geographic range.—Late Miocene (Chasi-
coan and Huayquerian SALMAs) of Argentina, Brazil, Peru, 
Uruguay, and Venezuela.

Cardiatherium calingastaense sp. nov.
Figs. 3, 4.
2010 Cardiatherium sp.; Contreras and Cerdeño 2010: 8R.
Etymology: After the Calingasta Valley, where the locality of Puchu-
zum is located.
Holotype: INGEO-PV 87, skull and mandible of an adult individual, 
together with associated fragments of vertebrae and long bones.
Type locality: Right side of the Candelaria Creek, Puchuzum area, Cal-
ingasta Valley, San Juan Province, central-west Argentina.
Type horizon: Mid stratigraphic section of Las Flores Formation, late 
Miocene.

Diagnosis.—Cavioid diagnosed by the following unique 
combination of characters (autapomorphies marked with an 
asterisk): euhypsodont cheek teeth; p4 with three prisms 
and P4 with two-lobed prisms as in other Hydrochoerinae; 
p4 with hfe, h3e, hpi, h2i, and h3i as in Hydrochoeropsis, 
Phugatherium, Neochoerus, and Hydrochoerus; h2i and 
h3i equally deep as in Cardiatherium paranense, Hydro-
choero psis dasseni, but differing from Hydrochoerus and 
Neochoerus in which h2i is shallower than h3i and its apex 
is behind the hfe; p4 with hse (h2e) as in C. patagonicum; 



CERDEÑO ET AL.—A NEW MIOCENE CAPYBARA FROM ARGENTINA 5

Fig. 3. Holotype (INGEO-PV 87) of the hydrochoerine rodent Cardiatherium calingastaense sp. nov., late Miocene, Puchuzum, San Juan Province, 
Argentina. A. Skull in dorsal (A1) and ventral (A2) views, and detail of the scars for masseter medialis muscle (A3); correspondence indicated by lines. 
B. Mandible in occlusal (B1) and left lateral (B2) views. 

nasals

dorsal projection
of premaxilla

frontals
temporal
fossae

sagittal crest
suture

suture

anterior root of the
zygomatic arch

jugal

squamosal

incisive foramen

palatal foramen

mesopterygoid
fossa

tympanic bulla

mental foramen

bottom of
incisor alveolus

B1 2B

A1

2A

3A

3 mm

30 mm

30 mm



6 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

p4 lacks h5i and hsni, as in C. paranense; hpi, hti, HFI, and 
hfe of m1/M1–m2/M2 not splitting the teeth, as in other 
Cardiatherium and differing from Hydrochoeropsis, Phuga-
therium, Neochoerus, and Hydrochoerus, in which those 
flexi/ids completely cross the tooth; *m3 with a conspicuous 
labial column in the posterior ramus of prIIa in contrast to 
other species; HPE and HSE very deep, the latter shorter 
than the former but deeper than in other species and oriented 
backwards; M3 with nine prisms; sagittal crest on the pari-
etals, unlike Hydrochoeropsis, Phugatherium, Neochoerus, 
and Hydrochoerus, in which the area between both temporal 
fossae is plane, without forming the sagittal crest; bullae 
small in ventral view as in Neochoerus and Hydrochoerus; 
*scars marking the origin of the masseter medialis muscle on 
the beginning of the anterior zygomatic arch (ventral face), 
with an anterior projection up to the level of the incisive fora-
men and the maxilla-premaxilla suture.
Description.—As it is reflected in the diagnosis of the 
new proposed taxon, the specimen INGEO-PV 87 (Figs. 
3, 4) may be referred to the genus Cardiatherium, discard-
ing its assignment to other genera of capybaras such as 
Phugatherium, Hydrochoeropsis or the modern lineages 
represented by Hydrochoerus and Neochoerus (see also 
Phylogenetic analysis and Discussion). Therefore, the fol-
lowing description is focused on the comparison of the stud-
ied material with the known species of Cardiatherium.

Skull: It is somewhat mediolaterally deformed and lacks 
the left zygomatic arch, the left parietal-occipital area, and 
the left M3 (Fig. 3A1, A2).

In dorsal view (Fig. 3A1), the nasal is anterolaterally 
broken but the preserved portion indicates that this bone 
is long. The nasal is a little longer than the frontal in the 
new species as in C. paranense and the biggest capybaras 
(Phugatherium, Hydrochoeropsis, Hydrochoerus). Laterally, 
the nasal is in contact with the dorsal projection of the pre-
maxilla and posteriorly with the frontal. The nasal is dorsally 
slightly convex, differing from the strongly bulging condi-

tion of C. paranense and from Hydrochoerus, in which the 
nasal is slightly bulky in the middle portion. The posterior 
border of the nasal is anteriorly slightly concave, differing 
from the strongly concave border of C. paranense. The nasal 
and frontal (Fig. 3A1) are proportionately narrower than in C. 
paranense, Phugatherium, and Hydrochoerus. The frontal 
and the anterior portion of the parietal are dorsally flat as in 
most Hydrochoerinae. The posterior portion of the parietal 
has a temporal fossa posterolaterally concave and the tempo-
ral lines join, although not completely fusing, in a short sag-
ittal crest that diverges again posteriorly at the nuchal crest. 
This condition contrasts with that of the largest capybaras, 
which present an interposed area between the temporal fos-
sae (which are shallower than in C. calingastaense sp. nov.) 
instead of the sagittal crest. The postorbital apophyses are 
incomplete and would have been short.

In right lateral view, the ventral portion of the zygo-
matic arch is preserved and is similar to the condition of 
Hydrochoerus. The maxillary anterior root of the arch is 
dorso-ventrally flattened and narrows posteriorly, be-
ing dorso-ventrally elongated like the jugal, which is an-
tero-posteriorly short. The squamosal forms the posterior 
portion of the arch and is posteriorly extended above the 
tympanic bulla. The external auditory meatus is above the 
level of the molar series. The angle formed by the anterior 
root of the zygomatic arch and the alveolar plane in Lateral 
view is <20°, similar to C. paranense, but different from C. 
aff. orientalis from the Cerro Azul Formation, in which it is 
24–26° (Vucetich et al. 2014b).

In ventral view (Fig. 3A2), the diastema is longer than 
the molariform series (Table 1), like in C. paranense, C. 
patagonicum, H. dasseni, and P. novum. The scars for the 
insertion of the masseter superficialis muscle are anteriorly 
convergent as in the other species of Cardiatherium; how-
ever, in INGEO-PV 87 there is an additional scar in this area. 
One is oval, transversely concave, placed between the root 
of the zygomatic arch and the P4, but extended anteriorly 

Table 1. Comparison of skull dimensions (in mm, except for 9, 12) of Cardiatherium calingastaense sp. nov. following Vucetich et al. (2014b) with 
other late Miocene Cardiatherium and Recent Hydrochoerus hydrochaeris. Abbreviations: 1, posterior width of the incisive  foramen; 2, rostral 
width at the anterior margin of the anterior root of the zygomatic arch (complete or up to the midline in incomplete specimens); 3, width between 
the anteriormost points of the scars marking the origin of the masseter medialis muscle; 4, rostral width at the level of P4, measured at the alveolar 
margin of prism I; 5, rostral width at the posterior margin of the anterior root of the zygomatic arch (complete or up to the midline in incomplete 
specimens); 6, rostral width at the level of M2, measured at the alveolar margin of prII; 7, distance between the posterior margin of the incisive 
foramen and P4; 8, P4–M1 anteroposterior length; 9, angle of the beginning of the ventral anterior zygomatic arch and the alveolar series, in 
lateral view; 10, length of upper diastema; 11, length of P4–M3; 12, relationship (%) between dimensions 10 and 11; 1 holotype of C. paranense 
and MLP 71-VI-16-1; 2 GHUNLPam 27389 (the smallest) and GHUNLPam 5274 (the largest).

Skull dimension 1 2 3 4 5 6 7 8 9 10 11 12
Cardiatherium calingastaense sp. nov. (INGEO-PV 87) 5.8 29.0 13.5/21.8 18.1/25.1 29.9 32.6 19.0 19.3 18 71.1 56.6 75.3

Cardiatherium paranense  (N = 12)
minimum 3.2 22.6 –/16.0 10.7/– 21.4 24.0 9.0 12.5 18 132.0 131.0 196.8
maximum 8.0 32.4 –/28.0 19.4/– 37.7 43.9 22.5 22.5 19 175.0 159.0 178.6

Cardiatherium aff. orientalis (N = 5)
minimum 2.5 21.8 –/16.0 12.9/– 22.1 30.5 15.1 10.2 24 244.2 241.5 293.8
maximum 3.0 29.0 –/27.0 17.4/– 28.2 36.8 18.8 18.8 26 258.0 253.0 291.3

Cardiatherium patagonicum (MPEF-PV 2521) – – – – – – – – – 75.0 57.0 76

Hydrochoerus hydrochaeris (N = 8)
minimum 5.0 16.2 26.2 11.0 20.2 23.6 9.2 11.6 13 25.1 37.2 148.2
maximum 10.2 40.0 34.1 24.6 43.2 52.0 24.2 27.2 17 67.9 79.3 116.8



CERDEÑO ET AL.—A NEW MIOCENE CAPYBARA FROM ARGENTINA 7

beyond this tooth, as observed in the other species of the 
genus; and the other one is another smooth surface at an ob-
tuse angle with the first scar, which is directed to the sagittal 
plane, reaching the border of the incisive foramen, where the 
premaxilla-maxilla suture is located (Fig. 3A2, A3). The inci-
sive foramen is ovoid and broad as in C. paranense whereas 
it is narrow in C. aff. orientalis (Table 1). The base of P4 does 
not project laterally and therefore does not form the bulge ob-
servable in ventral view in C. paranense. The ratio between 
the distance from the base of the incisive foramen up to the 
middle point between both P4s and the upper tooth series 
length is close to the minimum values of Cardiatherium, 
but different from the large capybaras (Phugatherium) and 
the modern lineages (Hydrochoerus–Neochoerus), in which 
the tooth series is proportionally longer (Table 1). The palate 
is rather shallow; from the level of M1 to that of the third 
prism of M3, there is a medium, narrow crest with a long 
and narrow palatal foramen at each side (M2–M3 level). The 
mesopterygoid fossa is narrow in outline, with a rounded 
anterior margin at the level of the posterior portion of the 
M3, as in C. paranense and C. pata gonicum. The tooth rows 
are divergent, but with a smooth curvature with M3 aligned 
with P4–M2, as in C. paranense. In C. patagonicum and C. 
aff. orientalis, the M3 are nearly parallel. The basicranium 
is badly preserved, although part of the basisphenoid and the 
right tympanic bulla are preserved. The bulla is relatively 
small. The occipital face is incomplete and displaced; the 
right paraoccipital apophysis is distally incomplete, but it 
would have been relatively long (Fig. 3A1).

Mandible: The mandible preserves the symphysis, with 
the incisors, most of the left horizontal ramus, with p4–m3, 

and the anterior part of the right ramus (Fig. 3B). The right 
cheek teeth were recovered separately, but complete. The 
symphysis is narrow and procumbent, with a smooth me-
dian keel on the labial side; the posterior end of the symphy-
sis does not reach the premolar level. The horizontal rami 
are well divergent; they are wide and vertically convex; 
ventrally, the area from the level below m1 to the base of 
the symphysis is flattened. The mental foramen is located 
anteriorly to p4 and at the dorso-ventral midpoint of the 
lateral surface of the dentary. The bottom of the i1 alveolus 
reaches internally the anterior half of the m2 and widens the 
lingual side of the ramus (clearly visible on the left side). 
The posterior border of the symphysis in C. calingastaense 
sp. nov. is below p4; according to Vucetich et al. (2005) and 
Deschamps et al. (2007), its position depends on the age of 
individuals, located anterior of p4 in juveniles and below the 
midpoint of p4 in larger (older) individuals. Main mandibu-
lar measurements are provided in Table 2.

Dentition: Both upper and lower incisors are narrow 
(I1, 8.1 mm; i1, 7.4 mm and 7.6 mm) and strongly curved, 

Fig. 4. Occlusal dental details of the holotype (INGEO-PV 87) of the hydrochoerine rodent Cardiatherium calingastaense sp. nov., late Miocene, 
Puchuzum, San Juan Province, Argentina. A. Right P4–M3. B. Left P4–M1. C. Left M1–M2. D. Posterior part of right M3. E. Left p4–m3. F. Right m1. 
G. Left m3. H. Left p4. I. Right p4.

Table 2. Mandibular dimensions (in mm) of Cardiatherium calin-
gastaense sp. nov. (INGEO-PV 87).

Symphysis length 51.5
Anterior transversal diameter of symphysis 23.6
Transversal diameter symphysis at foramen level 31.9
Anterior height of symphysis c. 23.4
Height symphysis at foramen level 24.0
Transversal diameter between p4s, anterior to alveolus 30.6
Height horizontal ramus ahead left p4 20.3
Maximum width anterior to lateral crest 67.1

B C D

F G H I

A

E

10 mm

5 mm



8 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

with bevelled occlusal surface and enamel only on the la-
bial side (Fig. 3B).

Among upper cheek teeth (Fig. 4A–D; Table 3), P4, M1, 
and M2 are formed by two heart-shaped prisms, joined by 
a short isthmus. As in all species of Cardiatherium, HPE is 
deeper than HSE, unlike Phugatherium in which these flexi 
are almost similar in depth (Fig. 5A–E). In INGEO-PV 87, 
the HPE is very deep and curved backward, in such a way 
that in M2 it reaches the labial side and produces a defor-
mation of this wall resulting in a strong step-shaped profile 
(Figs. 4B, C, 5A). The HSE is shorter than HPE, but is 
deeper than in the other species and oriented slightly back-
ward (Fig. 5A–C); only the largest specimen of C. patagon-
icum has an HSE similar in depth to C. calingastaense sp. 
nov., but anteriorly concave. P4 has undulated walls of HPE. 
The HFI is so deep that it almost splits prI from prII. M3 
has nine prisms; prI is bilobed with a deep HPE similar to 
those of the other upper cheek teeth; the other eight prisms 
are laminar with a shallow, open V-shaped labial fissure 
in prII to prVII whereas in prVIII there is a barely marked 
labial concavity; as usual in capybaras, prIX is transversally 
shorter with a convex posterior margin and no labial fissure 
(Figs. 4D, 5A).

Among lower cheek teeth (Figs. 4E–I, 6A; Table 4), p4 
has a deep h3e, bifurcated at the end, and anteriorly directed. 
C. calingastaense sp. nov. lacks h4i and h5i as C. paranense 
(Fig. 6C), whereas h5i is extended up to 25% of the occlusal 
surface in C. patagonicum (Fig. 6B), C. orientalis (Fig. 6D) 
and C. chasicoense (Fig. 6E). C. calingastaense sp. nov. and 
C. aff. orientalis have no supernumerary internal flexid 
(hsni) typical of C. orientalis and C. patagonicum (Fig. 
6B, D). The hfe is also deep, wide and transversely di-
rected whereas in other species it is oblique. Lingually, the 
hpi is transversely directed and very deep, reaching almost 
the labial side, producing a deformation on this margin; at 
the same time, the third external flexid (h2e) is markedly 
concave (Figs. 4H, I, 6A) whereas in C. patagonicum (also 
with very deep hpi) the h2e is only incipient (Fig. 6B). The 
h2i and h3i are long and also bifurcated at the end, and 
both delimit a conspicuous internal column (c3). In C. pa-
tagonicum, h2i is much shallower than h3i; in C. paranense 
(Fig. 6C) and C. chasicoense (Fig. 6E), these flexids are 
shallower and similar in depth, those of the latter being the 
shallowest.

The m1–m2 are similar in morphology (Figs. 4F, 6A). 
The hsi penetrates less than 50% of the width of prI as in 

Table 3. Comparison of upper tooth dimensions (in mm) of Cardiatherium. a minimum and maximum values after Vucetich et al. (2014b); * M1 and 
M2 not differentiated; AW, anterior width, L, length; PW, posterior width; W, width; approximate values in parentheses.

P4 M1 M2 M3
L AW PW L AW PW L AW PW L W

Cardiatherium calingastaense sp. nov. 
(INGEO-PV-87)

right 10.0 6.3 7.6 8.8 (8.0) 8.5 8.5 7.7 7.9 28.5 11.0
left (9.5) (6.8) – 9.2 98.4 (8.4) (8.9) (7.4) (7.5) – –

Cardiatherium chasicoensea* minimum 8.0 7.2 7.5 8.1 6.7 7.6 12.7 5.1
maximum 8.6 7.2 7.6 9.2 7.6 8.3 20.1 8.0

Cardiatherium paranensea minimum 6.0 4.6 4.6 5.1 4.9 4.6 4.9 5.4 5.4 9.2 5.9
maximum 12.0 8.2 9.7 11.0 8.7 9.7 9.1 6.4 7.2 37.5 10.7

Cardiatherium aff. orientalisa minimum 4.8 3.0 3.6 4.0 3.33 4.3 5.6 5.9 5.9 6.8 3.0
maximum 9.7 5.2 6.7 8.9 7.2 7.0 8.1 7.5 7.6 21.5 7.7

Cardiatherium patagonicuma* minimum 6.8 4.8 6.1 4.4 3.8 4.3 14.1 3.6
maximum 9.2 6.5 8.0 9.9 7.0 8.5 25.6 8.5

Table 4. Comparison of lower tooth dimensions (in mm) of Cardiatherium. a minimum and maximum values after Vucetich et al. (2005); b values 
correspond to the holotype MLP 40-XI-15-1; c values after Deschamps et al. (2009), a very small m1/2 of Cardiatherium patagonicum was not 
here considered; * m1–m2 not differentiated; AW, anterior width; L, length; MW, medium width; PW, posterior width; approximate values in 
parentheses.

p4 m1 m2 m3
L AW MW PW L AW PW L AW PW L AW MW PW

Cardiatherium calingastaense 
sp. nov. (INGEO-PV-87)

left 14.4 5.3 7.0 6.8 11.7 7.6 7.0 12.2 7.9 8.2 16.3 10.7 11.4 9.7
right 13.8 5.3 6.7 6.9 11.5 7.3 7.0 12.6 (8.1) 8.0 17.0 10.9 11.7 –

Cardiatherium paranensea minimum 9.7 4.0 5.1 5.1 5.7 4.0 4.1 8.9 4.9 6.4 12.6 8.0 – –
maximumb 19.8 6.4 7.8 8.8 15.8 9.6 10.1 17.6 9.6 11.6 21.7 10.4 – –

Cardiatherium orientalis (holotype)a 11.2 4.6 5.2 5.9 9.6 5.6 6.1 0.3 6.0 7.0 13.4 7.0 – –

Cardiatherium aff. orientalisa minimum 9.9 3.8 4.8 4.9 8.0 4.5 5.1 >8 5.3 >5 13.6 8.2 – –
maximum 23.0 8.5 10.6 11.2 18.5 12.1 10.2 20.9 >11 12.4 15.2 9.1 – –

Cardiatherium patagonicuma,* minimum 7.2 2.8 3.3 3.8 5.6 3.3 3.2 – 7.2 – –
maximum 12.0 4.6 5.9 6.2 13.3 8.8 9.2 – 9.6 – –

Cardiatherium chasicoense* minimumc 6.3 2.1 3.2 3.6 6.1 3.4 5.3 9.7 4.8 6.1  5.8
maximumc 13.7 4.8 6.8 7.3 11.5 7.6 7.6 15.5 7.6 8.6 9.4



CERDEÑO ET AL.—A NEW MIOCENE CAPYBARA FROM ARGENTINA 9

the other species of Cardiatherium, whereas hti is deep 
(crossing the prism but not splitting as in C. patagonicum; 
Fig. 6B) and Phugatherium) and bifurcated at the end, pro-
ducing a deformation of the labial margin at this point. 
The hse is deep and wide. The m3 is the longest molar of 
the series, and flexids are not bifurcated. This molar has a 
conspicuous labial column in the posterior ramus of prIIa, 
delimited by two accessory fissures between hse and hfe 
(Figs. 4G, 6A).

The previous comparative description has been focused 
on the best-known species, but some comparison can also be 
provided for two other poorly known taxa. In C. isseli (holo-
type and only specimen MACN 6354; middle Miocene, Río 
Negro Province; Rovereto 1914), the p4 is quite similar, but 
the m3 differs because the anterior margin of prI is straight 
and the hsi is very deep. In C. talicei (holotype SPV-FHC-
10-VIII-63-1; Pliocene, San Gregorio, Uruguay; Francis and 
Mones 1965a; Mones 1991, who adds two other specimens), 
the flexids are anteroposteriorly wider; the p4 has deeper 
h4i and no h2e; h2i and h3i are shallower, especially the for-
mer; and the m3 shows a deep hsi, more anteriorly directed 
than in C. calingastaense sp. nov., which is reflected in a 
longer and more triangular first prism.

Stratigraphic and geographic range.—Late Miocene, mid-
dle section of the Las Flores Formation. Right side of the 
Candelaria Creek, Puchuzum area, Calingasta Valley, San 
Juan Province, central-west Argentina..

Phylogenetic analysis
We assessed the phylogenetic affinities of C. calingastaense 
sp. nov. using the dataset and protocols presented in previ-
ous studies (Pérez et al. 2018; Madozzo Jaén et al. 2018; see 
SOM 1–3). The parsimony analysis of the combined dataset 
(including morphological and molecular partitions) resulted 
in 333 most parsimonious trees (MPTs) of 3364 steps. The 
strict consensus of all MPTs is shown in SOM 3. Figure 7 
displays the node Hydrochoerinae in the strict consensus.

Our phylogenetic analysis recovers the monophyly of 
Cardiatherium (Fig. 7: node B and SOM 3). At the same 
time, this clade is the sister group of the largest capyba-
ras (a clade including Hydrochoeropsis, Phugatherium, 
Neochoerus and Hydrochoerus; Fig. 7). Cardiatherium cal-
ingastaense sp. nov. is the sister group of the other species 

A B C D

E

P4

M1

M2

M3

Fig. 5. Schematic occlusal view of upper teeth of Cardiatherium (A–C) 
and Phugatherium (D–E). A. Cardiatherium calingastaense sp. nov. (late 
Miocene, Puchuzum, San Juan Province, Argentina), INGEO-PV 87, right 
P4–M3. B. Cardiatherium patagonicum (late Miocene, Estancia Rincón 
Chico, Chu but Province, Argentina), MPEF-PV 740/22, reversed left P4; 
MPEF-PV 740/23, reversed left M1 or M2; MPEF-PV 740/18, right M3. 
C. Cardiatherium paranense (late Miocene, Ituzaingó Formation, Entre 
Ríos Province, Argentina), MLP 87-XI-1-27, right P4–M3. D. Phugatherium 
novum (middle Pliocene, Chapadamalal Formation, Buenos Aires Province, 
Argentina), MMP 492-S, right P4–M1. E. Phugatherium cataclisticum 
(late Miocene–Early Pliocene, Monte Hermoso Formation, Buenos Aires 
Province, Argentina), MLP 15-231a, right M1.

A B C D E
p4

m1

m2

m3

Fig. 6. Schematic occlusal view of lower teeth of Cardiatherium. A. Car-
diatherium calin gastaense sp. nov. (late Miocene, Puchuzum, San Juan 
Province, Argentina), holotype, INGEO-PV 87, right p4–m2 and reversed 
left m3. B. Cardiatherium patagonicum (late Miocene, Estancia Rincón 
Chico, Chubut Province, Argentina), MPEF-PV 740/9, reversed left p4; 
MPEF-PV 740/24, right m1–m2; MPEF-PV 740/7, reversed left m3. 
C. Cardiatherium paranense (late Miocene, Ituzaingó Formation, Entre 
Ríos Province, Argentina), MLP 40-XI-15-1, right p4–m3. D. Cardia-
therium orientalis (late Miocene, Camacho Formation, San Gregorio, 
Uruguay), SPV-FHC-27-XI-64-20, right p4–m3. E. Cardia therium chasi-
coense (late Miocene, Arroyo Chasicó, Buenos Aires Province, Argentina), 
MMP 300-M, right p4–m2; MMH-CH 88-6-71, reversed left m3.



10 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

Global
scale

stage/age

South
American
stage/ageE

p
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“Ionian” Bonaerian

Calabrian

Ensena-
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12

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3

2

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Gelasian

Piacen-
zian

Zanclean

Messinian

Serra-
vallian Laventan

Mayoan

Chasi-
coan

Tortonian

M
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c
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P
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c
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Chapad-
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“cardiomyines”

largest capybaras

Cardiatherium

A
B

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Hydrochoerinae
52

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54
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Fig. 7. Stratigraphic adjustment of the strict consensus tree for the phylogenetic analysis of Hydrochoerinae (333 MPTs of 3364 steps). Upper case letters 
indicate the nodes within Hydrochoerinae, as described in the main text. Silhouettes reflect external aspect and relative size of representatives of the main 
clades within Hydrochoerinae.



CERDEÑO ET AL.—A NEW MIOCENE CAPYBARA FROM ARGENTINA 11

of the genus (Fig. 7: node B). Cardiatherium and the largest 
capybaras (Fig. 7: node A) share the following unambiguous 
synapomorphies: root of the lower incisors extending up to 
the level of the anterior lobe of m2 (ch. 20); concave palatal 
surface (ch. 55); presence of h2i on p4 (ch. 86); anterior lo-
cation of h3i (ch. 90); hpi deeper than h5i (ch. 96); c3 present 
on prI of p4 (ch. 98); oblique h3e (ch. 101); posterior prism 
of m1–m2 complex heart-shaped (ch. 106); presence of hti 
on m1–m2 (ch. 109); hsi shallower than hpi on m1 (ch. 114); 
hpi in m1–m2 reaching the labial end (ch. 115); presence 
of hse on m1–m2 (ch. 116); p4–m1 shorter than m2–m3 
(ch. 121); m1<m2<m3 (ch. 122); m3 complex (ch. 123); HPE 
deeper than HSE (ch. 138); laminar posterior prisms in M3 
with three or more prisms, in which the first prism is heart-
shaped (ch. 141); only the first prism is heart-shaped or lan-
ceolate-shaped and the others are laminar in M3 with three 
or more prisms (ch. 142).

On the other hand, the Cardiatherium clade (Fig. 7: node 
B) is supported by two unambiguous synapomorphies: an-
tero-posterior length of the posterior portion of the upper 
diastema more than 20% of the antero-posterior length of 
the maxilla (measured from the premaxilla-maxilla suture 
to the posterior border of maxilla at the level of the posterior 
projection of M3) (ch. 52), and hsi in m1–m2 is extended less 
than 50% of the occlusal surface (ch. 108). The other species 
of the genus (C. patagonicum, C. paranaense, C. aff. orien-
talis, and C. chasicoense; Fig. 7: node C) share a shallow 
h2i on the occlusal surface of p4 (ch. 88) and a normal de-
velopment of c3 on p4 (ch. 99), while C. calingastaense sp. 
nov. and the largest capybaras have a deep h2i on p4 and a 
long c3 on p4. The clade that includes C. paranaense, C. aff. 
orientalis and C. chasicoense (Fig. 7: node D) shares hti ex-
tended up to 50% of the prism on m1 (ch. 110) and m2 (ch. 
111), while in C. calingastaense sp. nov. and C. patagonicum 
the hti on m1–m2 is crossing the prism but not splitting as 
in Phugatherium and Hydrochoeropsis; in Neochoerus and 
Hydrochoerus, the hti on m2 is crossing and dividing the 
prism. Finally, the clade formed by C. aff. orientalis and C. 
chasicoense (Fig. 7: node E) is supported by a shallow hsi 
in complex m3 (ch. 125) and a laminar prI in complex m3 
(ch. 126). The other species of Cardiatherium present a deep 
hsi in complex m3.

The most parsimonious hypothesis places C. calinga-
staense sp. nov. as the sister group of a clade including all 
the other species of the genus because it shares some charac-
ters with the largest hydrochoerines (ch. 88[1], 99[2], 110[1], 
111[1]). When C. chasicoense is forced as the earliest branch-
ing species of the genus, the most parsimonious hypothesis 
costs three more steps.

The analysis with stratigraphic adjustment (Fig. 7) sug-
gests that the lineage leading to the clade Cardiatherium + 
largest capybaras (Hydrochoeropsis, Phugatherium, Neo-
choerus, and Hydrochoerus) would have originated at least 
during the Chasicoan SALMA, in view of the phylogenetic 
position of C. chasicoense. The evolutionary novelties such 
as the increasing complexity of molariforms (e.g., presence 

of h2.i, h5.i, h2.e, c3 on p4, presence of hse on m1–m2, ad-
dition of laminar prisms in M3) would have been achieved 
during the Chasicoan SALMA. In turn, the novel traits that 
characterize the clade including the largest capybaras (e.g., 
deepening of flexi/flexids splitting transversally the prisms) 
would have been acquired at some point in time between the 
Chasicoan and Montehermosan SALMAs, suggested by the 
presence of an extensive ghost lineage (Fig. 7; see Pérez et 
al. 2018 for discussion on basal forms of “cardiomyines”).

Concluding remarks
The specimen INGEO-PV 87 is included in the genus 
Cardiatherium on the basis of cranial and dental charac-
teristics, as detailed above, some of the latter being close to 
Cardiatherium patagonicum; however, this specimen shows 
an exclusive combination of both cranial and dental features 
that leads to propose the new taxon Cardiatherium calin-
gastaense sp. nov.

Concerning the skull, C. calingastaense sp. nov. is 
closer to C. paranense than to more derived capybaras, 
but differs from the former in: nasal dorsally slightly con-
vex (strongly bulging in C. paranense); posterior margin 
of the nasal slightly concave anteriorly (strongly concave 
in C. paranense); the scar for the insertion of the masse-
teric muscle with two differentiated areas (single scar in 
C. paranense and other species); and absence of bulge at the 
base of P4 (present in C. paranense).

With respect to the dentition, C. calingastaense sp. nov. 
is characterized by the great depth of flexi/flexids, which 
makes it different from most of the species of Cardiatherium. 
Vucetich et al. (2005) concluded that deeper flexi/ids cor-
relate with larger size, which, in turn, is directly related to 
age. The great depth observed in flexi/ids of INGEO-PV 87, 
resulting in a particular morphology with a step-shaped pro-
file, suggests that it would be an adult individual. In addition, 
the bifurcation of flexi/ids has been also observed in adult 
(large) specimens of Cardiatherium (e.g., p4, MPEF 740/34, 
C. patagonicum; m2, MLP 40-XI-15-1, C. paranense; m3, 
MMH-CH 88-6-41 and MLP 55-IV-28-15, C. chasicoense), 
as well as in other hydrochoerines (m3, MNHN-AYO 226, 
Phugatherium saavedrai; p4, MLP 15-232, P. cataclisticum) 
and some cardiomyines (Caviodon cuyano) (Vucetich et al. 
2011, 2014a, b).

Some characters observed in C. calingastaense sp. nov. 
resemble the molariforms of Pliocene capybaras (such as 
Phugatherium or Hydrochoeropsis), although the latter are 
different in many others (see above). One of those characters 
is the deep HSE slightly oriented backwards and another 
one is the c3; although this column is present in all the spe-
cies of Cardiatherium (see Deschamps et al. 2013: fig. 4), 
in C. calingastaense sp. nov. the c3 is very conspicuous, 
delimited by very deep h2i and h3i.

A particular character of the studied specimen is the con-
spicuous labial column in the posterior ramus of prIIa in m3, 



12 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

which is not known in the other species of Cardiatherium. 
Even though molariforms of hydrochoerines have strong 
individual variability (Mones 1991), this feature of m3 has 
not been previously described. Only more material from 
Puchuzum could reveal the existence of variation on this 
character within C. calingastaense sp. nov.

The phylogenetic analysis supports the taxonomic pro-
posal of a new species of Cardiatherium and places C. cal-
ingastaense sp. nov. as the sister group of a clade including 
all the other known species of the genus.

Cardiatherium calingastaense sp. nov. increases the 
known diversity of capybaras in the late Miocene of San 
Juan Province. Up to now, the only record of capybaras from 
this area was that of C. chasicoense (the oldest capybara) 
from the lower levels of Loma de Las Tapias Formation, 
corresponding to the Chasicoan SALMA. At the same time, 
the species C. paranense had been recognized in the near 
Mendoza Province, in levels of Huayquerian age. Therefore, 
the new taxon corresponds to the first record of capyba-
ras in the Huayquerian SALMA of San Juan Province and 
increases the general diversity of this group in the late 
Miocene of central-west Argentina.

Acknowledgements
The specimen INGEO-PV 87 was collected by Mariano Hidalgo (San 
Juan, Argentina) during a field season at Puchuzum within the proj-
ect CICIT-UNSJ 21E/649, Universidad Nacional de San Juan. Special 
thanks are due to Paula Villagra (Mendoza, Argentina) for taking pho-
tographs of the fossil; Natalia Mónaco (Centro Científico Tecnológico 
CONICET, Mendoza, Argentina) prepared Fig. 1, and Santiago 
Hernández Del Pino (Instituto Argentino de Nivología, Glaciología y 
Ciencias Ambientales, Mendoza, Argentina) helped with Figs. 3 and 4. 
The authors thank the editor, Olivier Lambert (Royal Belgian Institute 
of Natural Sciences, Brussels, Belgium) and reviewers, Álvaro Mones 
(Augsburg, Germany) and an anonymous reviewer, for their useful 
comments on the manuscript. This paper contributes to the Research 
Project CICITCA-UNSJ, Programación 2018–2019: Estudio bio-cron-
oestratigráfico y correlación regional de las unidades neógenas de 
Loma de La Dehesa, valle de Matagusano, San Juan, Argentina (V.H. 
Contreras).

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14 ACTA PALAEONTOLOGICA POLONICA 64 (X), 2019

Appendix 1 
List of revised material of Cardiatherium.

Cardiatherium chasicoense: MMP 300-M (holotype of Procardia-
therium chasicoense), fragment of right mandible with p4–m3; 
MMH-CH 85-4-40, almost complete right mandible with i1, p4, 
m1, and m3; Las Barrancas Member (= FSC facies) of the Arroyo 
Chasicó Formation, Buenos Aires Province, Argentina; PVSJ-537, 
palate fragment with right and left P4–M3 and associated mandi-
ble with p4–m3; Arenisca Albardón Member of the Loma de Las 
Tapias Formation, San Juan Province, Argentina.

Cardiatherium paranense: MLP 40-XI-15-1 (neotype), right man-
dibular fragment with p4–m3; MLP 87-XI-1-27 (holotype of Ana-
tochoerus inusitatus), incomplete skull with both P4–M3; and MLP 
78-II-27-1 (holotype of Kiyutherium scillatoyanei), right mandibu-
lar fragment with p4–m3. “Conglomerado osífero” of the Ituzaingó 
Formation (= “Mesopotamiense”), Entre Ríos Province, Argentina.

Cardiatherium orientalis: SPV-FHC 27-XI-64-20 (holotype of 
Kiyutherium orientalis), right mandible with p4–m3; San Pedro 
Member (or Kiyú Lithofacies) of the Camacho Formation (see 
Perea et al., 2013); Barrancas de San Gregorio, San José, Uruguay.

Cardiatherium aff. orientalis: GHUNLPam 139, damaged skull 
fragment with both M1–3; GHUNLPam 2009, skull fragment with 
both P4–M3; GHUNLPam 5236, anterior fragment of palate with 
anterior root of the zygomatic arch, both P4 and left M1; GHUNL-

Pam 5274; skull with both P4–M3, rostrum, right orbital area and 
damaged skull roof; GHUNLPam 8978, small fragment of palate 
with left M1–2; GHUNLPam 14452, palate with both P4–M3 and 
posterior portion of rostrum; GHUNLPam 14661, distorted skull 
with both P4–M3; GHUNLPam 14985, damaged rostrum with 
right incisor, right P4–M2 and left P4; GHUNLPam 27389, skull 
with both P4–M3, incisors, a left mandible fragment with p4–m3, 
and six cervical vertebrae articulated to skull; MLP 62-XII-4-17, 
left mandible fragment with p4–m3 and palatal fragment with left 
P4–M3 and right P4–M1 (the palatal fragment is currently lost).

Cardiatherium rosendoi: MLP 29-X-8-26 (holotype and single 
specimen of Kiyutherium rosendoi), left mandibular fragment with 
p4, m1 and part of m2; Puerta de Corral Quemado, Andalhuala 
Formation (“Araucanian”, late Miocene), Catamarca Province, Ar-
gentina.

Cardiatherium patagonicum: MPEF-PV 740/1, holotype, right 
mandibular fragment with m1–m2; MPEF-PV 740/2, isolated right 
m1 or m2; MPEF-PV 740/9, left p4; MPEF-PV 740/11, incomplete 
left p4; and MPEF-PV 740/24, isolated right m1 or m2; Estancia 
Rincón Chico, upper levels of the Puerto Madryn Formation, Penín-
sula Valdés, Chubut Province. MPEF-PV 2521, complete skull; 
La Pastosa, Puerto Madryn Formation, Península Valdés, Chubut 
Province (data after Dozo et al. 2010).