Paleocene emergence of elephant relatives and the rapid radiation of African ungulates
Edited by Elwyn L. Simons, Duke University Lemur Center, Durham, NC, and approved May 11, 2009
Abstract
Elephants are the only living representatives of the Proboscidea, a formerly diverse mammalian order whose history began with the 55-million years (mys) old Phosphatherium. Reported here is the discovery from the early late Paleocene of Morocco, ca. 60 mys, of the oldest and most primitive elephant relative, Eritherium azzouzorum n.g., n.sp., which is one of the earliest known representatives of modern placental orders. This well supported stem proboscidean is extraordinarily primitive and condylarth-like. It provides the first dental evidence of a resemblance between the proboscideans and African ungulates (paenungulates) on the one hand and the louisinines and early macroscelideans on the other. Eritherium illustrates the origin of the elephant order at a previously unknown primitive stage among paenungulates and “ungulates.” The primitive morphology of Eritherium suggests a recent and rapid paenungulate radiation after the Cretaceous-Tertiary boundary, probably favoured by early endemic African paleoecosystems. At a broader scale, Eritherium provides a new old calibration point of the placental tree and supports an explosive placental radiation. The Ouled Abdoun basin, which yields the oldest known African placentals, is a key locality for elucidating phylogeny and early evolution of paenungulates and other related endemic African lineages.
Acknowledgments.
The author thanks F. Escuillié and P. Dalous (Musée d'Histoire Naturelle de Toulouse) for providing material of Eritherium for study and/or for Muséum National d'Histoire Naturelle (MNHN) collection; P. Louis and C. Letenneur for drawings; P. Loubry and C. Lemzaouda for photographs; R. Vacant for preparation and casts; H. Cappetta for determination of the associated selachian fauna and for biostratigraphic comments; and useful comments on the manuscript were provided by E.K. Seiffert, P. Tassy, and an anonymous reviewer. The author also thanks the Geological Survey of the OCP mining centre of Khouribga for help with the field work, especially B. Bouya and M. Amaghzaz for logistic support, and our field collaborators O. Selloum and A. Mazzi, which helped to find and locate material of Eritherium. M. Bichara and S. Meslouh also helped with the field work. Field work was funded by the Centre National de la Recherche Scientifique (Unité Mixte de Recherche 5143) and MNHN (Bonus Qualite Recherche). This work was supported by the Collaboration Agreement with the Ministère de l'Energie et des Mines, the Office Chérifien des Phosphates (OCP) of Morocco, Universities Cadi Ayyad (Marrakech) and Chouaîb Doukkali (El Jadida).
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References
1
E Gheerbrant, P Tassy, Origin and evolution of proboscideans (Translated from French). C R Palevol 8, 281–294 (2009).
2
E Gheerbrant, J Sudre, H Cappetta, A Palaeocene proboscidean from Morocco. Nature 383, 68–71 (1996).
3
MJ Novacek, Mammalian phylogeny: Shaking the tree. Nature 356, 121–125 (1992).
4
JR Wible, GW Rougier, RJ Asher, Cretaceous eutherians and Laurasian origin for placental mammals near the K/T boundary. Nature 447, 1003–1006 (2007).
5
E Gheerbrant, J Sudre, H Cappetta, G Bignot, Phosphatherium escuilliei, from the Thanetian of the Ouled Abdoun basin (Morocco), oldest known Proboscidean (Mammalia) from Africa (Translated from French). Geobios 30, 247–269 (1998).
6
E Gheerbrant, et al., The mammal localities of Grand Daoui Quarries, Ouled Abdoun Basin, Morocco, Ypresian: A first survey (Translated from French). Bul Soc Géol Fr 174, 279–293 (2003).
7
E Gheerbrant, et al., New data on Phosphatherium escuilliei (Mammalia, Proboscidea) from the early Eocene of Morocco, and its impact on the phylogeny of Proboscidea and lophodont ungulates (Translated from French). Geodiversitas 27, 239–333 (2005).
8
F Solé, E Gheerbrant, M Iarochene, M Amaghzaz, B Bouya, Further evidence of the African antiquity of hyaenodontid (“Creodonta”, Mammalia) evolution. Zool J Lin Soc, in press. (2009).
9
JD Damuth Body Size in Mammalian Paleobiology, eds J Damuth, BJ MacFadden (Cambridge Univ Press), pp. 229–253 (1990).
10
CM Janis Body Size in Mammalian Paleobiology, eds J Damuth, BJ MacFadden (Cambridge Univ Press), pp. 255–300 (1990).
11
PA Goloboff, JS Farris, KC Nixon, TNT, a free program for phylogenetic analysis. Cladistics 24, 774–786 (2008).
12
PG Cox, Character evolution in the orbital region of the Afrotheria. J Zool 269, 514–526 (2006).
13
J Sudre, J-J Jaeger, B Sigé, M Vianey-Liaud, New data on the condylarths from the Thanetian and Ypresian of the Ouarzazate Basin (Morocco) (Translated from French). Geobios 26, 609–615 (1993).
14
R Tabuce, B Coiffait-Martin, PE Coiffait, M Mahboubi, JJ Jaeger, A new genus of Macroscelidea (Mammalia) from the Eocene of Algeria: A possible origin for elephant-shrews. J Vert Pal 21, 535–546 (2001).
15
R Tabuce, et al., Early Tertiary mammals from North Africa reinforce the molecular Afrotheria clade. Proc Roy Soc B 274, 1159–1166 (2007).
16
ER Seiffert, A new estimate of Afrotherian phylogeny based on simultaneous analysis of genomic, morphological, and fossil evidence. BMC Evol Biol 7, 1–13 (2007).
17
RJ Asher, TM Lehman, Dental eruption in afrotherian mammals. BMC Evol Biol 6, 14 (2008).
18
SP Zack, TA Penkrot, JI Bloch, KD Rose, Affinities of ‘hyopsodontids’ to elephant shrews and a Holarctic origin of Afrotheria. Nature 434, 497–501 (2005).
19
WJ Murphy, et al., Resolution of the early placental mammal radiation using Bayesian Phylogenetics. Science 294, 2348–2351 (2001).
20
O Madsen, et al., Parallel adaptive radiations in two major clades of placental mammals. Nature 409, 610–614 (2001).
21
TJ Robinson, ER Seiffert, Afrotherian origins and interrelationships: New views and future prospects. Curr Top Dev Biol 63, 37–60 (2004).
22
E Gheerbrant, et al., A new large mammal from the Ypresian of Morocco: Evidence of a surprising diversity of early proboscideans. Act Pal Pol 47, 493–506 (2002).
23
PD Gingerich, Environment and evolution through the Paleocene-Eocene thermal maximum. Trend Ecol Evo 21, 246–253 (2006).
24
JD Archibald, KD Rose The Rise of Placental Mammals, eds KD Rose, JD Archibald (Johns Hopkins Univ Press, Baltimore, 2005).
25
KD Rose The Beginning of the Age of Mammals (Johns Hopkins Univ Press, Baltimore, 2006).
26
A Rokas, SB Carroll, Bushes in the tree of life. PLOS 4, 1899–1904 (2006).
27
MS Springer, WJ Murphy, E Eizirik, SJ O'Brien, Placental mammal diversification and the Cretaceous-Tertiary boundary. Proc Nat Acad Sci USA 100, 1056–1061 (2003).
28
AT Pardini, et al., Chromosome painting among Proboscidea, Hyracoidea, and Sirenia: Support for Paenungulata (Afrotheria, Mammalia), but not Tethytheria. Proc Roy Soc B 274, 1333–1340 (2007).
29
E Gheerbrant, J-C Rage, Paleobiogeography of Africa: How distinct from Gondwana and Laurasia? Palaeogeo, Palaeocl, Palaeoecol 241, 224–246 (2006).
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Received: January 14, 2009
Published online: June 30, 2009
Published in issue: June 30, 2009
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Acknowledgments
The author thanks F. Escuillié and P. Dalous (Musée d'Histoire Naturelle de Toulouse) for providing material of Eritherium for study and/or for Muséum National d'Histoire Naturelle (MNHN) collection; P. Louis and C. Letenneur for drawings; P. Loubry and C. Lemzaouda for photographs; R. Vacant for preparation and casts; H. Cappetta for determination of the associated selachian fauna and for biostratigraphic comments; and useful comments on the manuscript were provided by E.K. Seiffert, P. Tassy, and an anonymous reviewer. The author also thanks the Geological Survey of the OCP mining centre of Khouribga for help with the field work, especially B. Bouya and M. Amaghzaz for logistic support, and our field collaborators O. Selloum and A. Mazzi, which helped to find and locate material of Eritherium. M. Bichara and S. Meslouh also helped with the field work. Field work was funded by the Centre National de la Recherche Scientifique (Unité Mixte de Recherche 5143) and MNHN (Bonus Qualite Recherche). This work was supported by the Collaboration Agreement with the Ministère de l'Energie et des Mines, the Office Chérifien des Phosphates (OCP) of Morocco, Universities Cadi Ayyad (Marrakech) and Chouaîb Doukkali (El Jadida).
Notes
This article is a PNAS Direct Submission.
This article contains supporting information online at www.pnas.org/cgi/content/full/0900251106/DCSupplemental.
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The author declares no conflict of interest.
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