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Rooting Around the Eutherian Family Tree: the Origin and Relations of the Taeniodonta

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An Erratum to this article was published on 03 October 2013

Abstract

Placing early groups into the overall phylogeny of eutherian mammals can be challenging, particularly when the group does not have extant members. We investigated the relationships of the Taeniodonta, an extinct group from the Late Cretaceous through Paleogene of North America. This group has a few purported close relatives, including Cimolestes, Procerberus, and Alveugena, that may form a sequence of ancestors and descendants. The leading hypothesis is that Procerberus gave rise to taeniodonts through Alveugena. We test this hypothesis and analyze relations to known stem and crown Eutheria to determine the place of taeniodonts in eutherian phylogeny. Cladistic analyses were performed using previously published characters and datasets, namely a taeniodont/cimolestid specific dataset and a reanalysis of Wible and colleagues (2009), with added taxa for both. Our studies suggest that taeniodonts arose from Cimolestes through Alveugena, that Procerberus is more distantly related to taeniodonts, and that taeniodonts and their relatives are stem eutherians. We diagnose the Taeniodonta based on these analyses. Other Paleogene groups, especially those allied with Cimolestes such as tillodonts and pantolestans, merit further study. Our findings indicate that stem eutherians such as the Taeniodonta, in addition to crown eutherians, continued to diversify during the Paleogene.

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Acknowledgments

This work was submitted by D. Rook, formerly D. Weinstein, in partial fulfillment of the degree Master of Science at The Ohio State University under the supervision of J. P. Hunter. We thank J. W. Wenzel for help on cladistic analyses. We also thank J. Galkin of the American Museum of Natural History and M. Brett-Surman of the National Museum of Natural History for access to collections. We thank R. Asher and especially J. Wible for extensive discussion of their character matrix and cladistic analyses. We thank two anonymous reviewers for their comments on our manuscript. The Ohio State University, Department of Evolution, Ecology and Organismal Biology, supported this work through a University Fellowship and a Graduate Teaching Assistantship.

Author information

Author notes

  1. Deborah L. Rook

    Present address: Department of Geoscience, University of Wisconsin-Madison, Madison, WI, 53706, USA

Authors and Affiliations

  1. Department of Evolution, Ecology, and Organismal Biology, Ohio State University, Columbus, OH, 43210, USA

    Deborah L. Rook

  2. Department of Evolution, Ecology and Organismal Biology, Ohio State University- Newark, Newark, OH, 43055, USA

    John P. Hunter

Authors
  1. Deborah L. Rook
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  2. John P. Hunter
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Corresponding author

Correspondence to Deborah L. Rook.

Additional information

A recently published study of eutherian relationships (O’Leary et al. 2013) reported a single most parsimonious tree in which Protungulatum donnae occurs within the eutherian crown group and an assumption that Purgatorius does as well. Using the character matrix of Wible et al. (2009), we recovered Protungulatum and Purgatorius as part of the sister taxon to the crown group (Figs. 2 and 3; see also Wible et al. 2009). Enlarging the crown group in our tree to include Protungulatum and Purgatorius, but also to exclude taxa that O’Leary et al. (2013) found to be stem eutherians (Maelestes, Ukhaatherium and Zalambdalestes) would not change our main inference that cimolestids and taeniodonts are stem eutherians.

Appendices

Appendix 1: Cimolestid Versus Palaeoryctid Analysis- Characters and Matrix from Analysis

Characters

These characters are the same as those used in Rook et al. (2010) and Rook and Hunter (2011). The characters appeared originally either in Schoch (1986) as uncoded lists or in Eberle (1999) coded for Cimolestes, Procerberus formicarum, P. grandis, Alveugena, and Onychodectes only. We cite below the source for each character. All taxa were coded by the senior author for characters modified from Schoch (1986). Similarly, all taxa, other than those listed above, were coded by the senior author for the characters from Eberle (1999). Additive characters are marked below with an asterix (*) and follow Eberle (1999), Rook et al. (2010), and Rook and Hunter (2011) in treating these characters as additive, based on the character states needing to progress through the central state (for instance, “medium”) before being either extreme. Premolars again are numbered assuming an ancestral count of five (e.g., Wible et al. 2009).

  1. 1.

    Upper molar protocone size (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = large

  2. 2.

    Upper molar conule size (Schoch 1986)

    • 0 = small

    • 1 = large

    • 2 = absent

  3. 3.

    Placement of conules on upper molars (modified from Eberle 1999)

    • 0 = labial

    • 1 = lingual

  4. 4.

    Upper molar paracone size (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = large

  5. 5.

    Stylar margin on upper molars (Eberle 1999) *

    • 0 = large, inflated stylar lobes; forward-projecting, parastylar lobe extends labially beyond, and often hooks around, metastylar lobe on tooth directly in front of it; stylar lobes appear largest on M2

    • 1 = para- and metastylar lobes relatively smaller than those of Cimolestes and Procerberus formicarum, but still relatively inflated; parastylar lobe is not hook-like, does not project anteriorly, and projects only slightly more labially (if at all) beyond metastylar lobe of tooth directly anterior to it

    • 2 = small, weak, uninflated stylar lobes; stylar shelves very narrow to absent; M2 stylar lobes subequal in size to those of other molars

  6. 6.

    Upper molar metacone size (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = large

  7. 7.

    Lingual cingula on upper molars (Eberle 1999)

    • 0 = present

    • 1 = absent

  8. 8.

    Lower molar trigonid height (modified from Eberle 1999) *

    • 0 = trigonid noticeably higher than talonid

    • 1 = trigonid only slightly higher than talonid

    • 2 = trigonid equal in height to talonid

  9. 9.

    Lower first molar trigonid width (modified from Eberle 1999)

    • 0 = trigonid wider than talonid

    • 1 = trigonid equal in width to talonid

    • 2 = width variable within taxon

  10. 10.

    Lower second molar trigonid width (modified from Eberle 1999)

    • 0 = trigonid wider than talonid

    • 1 = trigonid equal in width to talonid

    • 2 = width variable in taxon

  11. 11.

    Lower third molar trigonid width (modified from Eberle 1999)

    • 0 = trigonid wider than talonid

    • 1 = trigonid equal in width to talonid

    • 2 = width variable in taxon

  12. 12.

    Lower molar paraconids versus metaconids (Schoch 1986)

    • 0 = not equal

    • 1 = subequal

  13. 13.

    Molar hypsodonty (modified from Eberle 1999) *

    • 0 = absent

    • 1 = present

    • 2 = hypselodonty

  14. 14.

    P4 morphology (modified from Eberle 1999) *

    • 0 = triangular

    • 1 = submolariform

    • 2 = molariform

  15. 15.

    P5 morphology (modified from Eberle 1999) *

    • 0 = triangular

    • 1 = submolariform

    • 2 = molariform

  16. 16.

    p5 talonid heel (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = well developed

  17. 17.

    P5 parastyle (modified from Eberle 1999) *

    • 0 = absent

    • 1 = incipient

    • 2 = small

    • 3 = well developed

  18. 18.

    P5 stylocone (modified from Eberle 1999) *

    • 0 = absent

    • 1 = incipient

    • 2 = small

    • 3 = well developed

  19. 19.

    P5 metastyle (modified from Eberle 1999) *

    • 0 = absent

    • 1 = incipient

    • 2 = small

    • 3 = well developed

  20. 20.

    Lower molar paraconids (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = large

  21. 21.

    P1 (Schoch 1986)

    • 0 = present

    • 1 = absent

  22. 22.

    p5 morphology (Schoch 1986) *

    • 0 = nonmolariform

    • 1 = submolariform

    • 2 = molariform

  23. 23.

    M1 and M2 mesostyle (Schoch 1986)

    • 0 = absent

    • 1 = small

    • 2 = moderate

    • 3 = well developed

  24. 24.

    Premolars set obliquely (Schoch 1986)

    • 0 = no

    • 1 = yes

  25. 25.

    Lower canines (Schoch 1986) *

    • 0 = small

    • 1 = moderate

    • 2 = large

  26. 26.

    Upper incisor number (Schoch 1986) *

    • 0 = 3

    • 1 = 2

    • 2 = 1

  27. 27.

    Lower incisor number (Schoch 1986) *

    • 0 = 3

    • 1 = 2

    • 2 = 1

  28. 28.

    p4 morphology (Schoch 1986) *

    • 0 = nonmolariform

    • 1 = submolariform

    • 2 = molariform

  29. 29.

    Lower canine root (Schoch 1986) *

    • 0 = shallow

    • 1 = deep

    • 2 = tending towards rootlessness

    • 3 = rootless

  30. 30.

    Bilophodont molars (Schoch 1986)

    • 0 = absent

    • 1 = present

  31. 31.

    Transverseness of upper molars (Eberle 1999) *

    Relative Transverse Width (RTW) = Maximum Transverse Width/Anteroposterior length

    • 0 = transverse (RTW of M1 > 1.30)

    • 1 = less transverse (1.30 > RTW of M1 > 1.20)

    • 2 = weakly to nontransverse (RTW of M1 < 1.20)

  32. 32.

    Development of molar ectoflexus (Eberle 1999) *

    • 0 = pronounced and deep, particularly on M2

    • 1 = small, shallow indentation

    • 2 = virtually absent, resulting in a relatively straight stylar shelf

  33. 33.

    Size of M2 relative to M1 (Eberle 1999) *

    • 0 = M2 noticeably larger than M1

    • 1 = M2 shorter but more transverse than M1

    • 2 = M2 subequal in size to, or slightly smaller than, M1

  34. 34.

    Upper molar lingual length (modified from Eberle 1999)

    • 0 = not pronounced

    • 1 = pronounced

  35. 35.

    Metacrista on upper molars (modified from Eberle 1999) *

    • 0 = well developed

    • 1 = reduced

    • 2 = absent

  36. 36.

    Lower molar cingulids (Eberle 1999)

    • 0 = present

    • 1 = absent

  37. 37.

    Wear pattern on upper molars and premolars (Eberle 1999)

    • 0 = not pronounced over entire occlusal surface

    • 1 = pronounced over entire occlusal surface

Matrix

Protictis

1102000000010111303101101000100111110

Cimolestes

?10000000000000133300000???0000000000

Acmeodon

0202101000000012???111101??0?00010000

Aaptoryctes

2110001000000011000011000?00000010100

Palaeoryctes

22?20010000001113300?0001?00000010000

Didelphodus

0202000000000011202101001001000000000

Procerberus formicarum

010000000000022?333?0000???0001000100

Procerberus grandis

01001001000?0222333200001??0001000101

Alveugena

0?01110000?000002320000011?0001111101

Schowalteria

????0?11100?1002232000?021?1000001?11

Onychodectes

0101211122011011121200001000002221111

Conoryctella

2202221122201011232201102000201121111

Conoryctes

2202221120001121232011202110100221111

Huerfanodon

02122211200111?2???111302??0102221011

Schochia

1102201?????102?010???01??????02211?1

Wortmania

10-2201000?11002111100012220010211111

Psittacotherium

2212201220001112010001012221210221111

Ectoganus

2212221220211222010002012222312221211

Stylinodon

????2?12111?2222010?02?12122312221?11

Appendix 2: Stem/Crown Analysis- Characters, Matrix, and Full Figure from Analysis

Characters

Dental and cranial characters used from Wible et al. (2007, 2009). As in the original study, there are 408 dental, cranial, and postcranial characters. Characters coded here for Alveugena (A) and Schowalteria (S); all others can be found in Wible et al. (2009).

  1. 1.

    Teeth (A, S)

    • 0 = present

    • 1 = absent

  2. 2.

    Teeth (A, S)

    • 0 = differentiated into classes (incisors, canines, premolars, and molars) with enamel

    • 1 = simple peg-like without enamel

  3. 3.

    Number of postcanine tooth loci (A, S)

    • 0 = eight or more

    • 1 = seven

    • 2 = six

    • 3 = five or less

  4. 4.

    Upper diastema (A)

    • 0 = small, between incisors and canine

    • 1 = small, between canine and premolars

    • 2 = enlarged

    • 3 = absent

  5. 5.

    Lower diastema behind incisors (S)

    • 0 = absent or small

    • 1 = enlarged

    • Dentition – Incisors

  6. 6.

    Incisor shape (A)

    • 0 = root and crown are straight and continuous in length

    • 1 = a continuous curve

  7. 7.

    Number of upper incisors (A)

    • 0 = five

    • 1 = four

    • 2 = three

    • 3 = two

    • 4 = one

    • 5 = none

  8. 8.

    Number of lower incisors (S)

    • 0 = four

    • 1 = three

    • 2 = two, anterior position

    • 3 = one

    • 4 = none or posterior position(s) only

  9. 10.

    Anteriormost upper incisor size (S)

    • 0 = small, subequal to subsequent

    • 1 = enlarged

    • 2 = smaller than subsequent

  10. 14.

    Ultimate upper incisor (A, S)

    • 0 = in premaxilla

    • 1 = between maxilla and premaxilla

    • 2 = in maxilla

  11. 15.

    Anteriormost lower incisor size (S)

    • 0 = small, subequal to subsequent incisors

    • 1 = greatly enlarged

    • 2 = or tiny, smaller than subsequent

  12. 17.

    Procumbent anteriormost lower incisor (S)

    • 0 = absent

    • 1 = present

  13. 18.

    Anteriormost lower incisor root (S)

    • 0 = closed

    • 1 = open

  14. 21.

    Procumbent posterior lower incisor(s) (S)

    • 0 = absent

    • 1 = present

  15. 22.

    Staggered lower incisor (S)

    • 0 = absent

    • 1 = present

    • Dentition – Canine

  16. 23.

    Upper canine (A, S)

    • 0 = present, large

    • 1 = present, small

    • 2 = absent

  17. 24.

    Number of upper canine roots (A, S)

    • 0 = two

    • 1 = one

  18. 25.

    Lower canine (A, S)

    • 0 = present, large

    • 1 = present, small

    • 2 = absent

  19. 26.

    Number of lower canine roots (A, S)

    • 0 = two

    • 1 = one

  20. 27.

    Procumbent lower canine (A, S)

    • 0 = absent

    • 1 = present

    Dentition – Premolars

  21. 29.

    Number of premolars (A, S)

    • 0 = five or more

    • 1 = four

    • 2 = three

    • 3 = two

  22. 31.

    Tall, trenchant premolar (A, S)

    • 0 = ultimate premolar

    • 1 = penultimate premolar

    • 2 = absent

  23. 32.

    Procumbent first upper premolar (A, S)

    • 0 = absent

    • 1 = present

  24. 33.

    First upper premolar roots (A, S)

    • 0 = two

    • 1 = one

    • 2 = three

  25. 34.

    Diastema posterior to first upper premolar (S)

    • 0 = absent

    • 1 = present

  26. 36.

    Penultimate upper premolar protocone (A)

    • 0 = absent

    • 1 = small lingual bulge

    • 2 = with an enlarged basin

  27. 37.

    Penultimate upper premolar metacone (A)

    • 0 = absent

    • 1 = swelling

    • 2 = large

  28. 38.

    Penultimate upper premolar parastylar lobe (A, S)

    • 0 = absent or small

    • 1 = well developed

  29. 39.

    Penultimate upper premolar roots (A, S)

    • 0 = two

    • 1 = three

    • 2 = one

    • 3 = four

  30. 40.

    Ultimate upper premolar protocone (A)

    • 0 = absent or narrow cingulum

    • 1 = shorter than paracone

    • 2 = approaches paracone in height

  31. 41.

    Ultimate upper premolar metacone (A)

    • 0 = absent

    • 1 = swelling

    • 2 = large

  32. 42.

    Ultimate upper premolar para- and metastylar lobes (A, S)

    • 0 = absent or insignificant

    • 1 = subequal

    • 2 = parastylar lobe larger

    • 3 = metastylar lobe larger

  33. 43.

    Ultimate upper premolar precingulum (A)

    • 0 = absent

    • 1 = present

  34. 44.

    Ultimate upper premolar postcingulum (A)

    • 0 = absent

    • 1 = present, lower than protocone

    • 2 = present, level with protocone

  35. 46.

    Ultimate upper premolar size (occlusal surface) relative to first upper molar (A, S)

    • 0 = smaller or subequal

    • 1 = larger

  36. 47.

    First lower premolar orientation (A, S)

    • 0 = in line with jaw axis

    • 1 = oblique

  37. 48.

    First lower premolar roots (A, S)

    • 0 = two

    • 1 = one

  38. 49.

    Diastema separating first and second lower premolars (A, S)

    • 0 = absent (gap less than one tooth root for whichever is smaller of adjacent teeth)

      1 = present, subequal to one tooth-root diameter or more

  39. 52.

    Penultimate lower premolar paraconid (A, S)

    • 0 = indistinctive or absent

    • 1 = present and distinctive

  40. 53.

    Penultimate lower premolar metaconids (A, S)

    • 0 = absent

    • 1 = swelling

    • 2 = separate from protoconid

  41. 54.

    Penultimate lower premolar talonid cusps (A, S)

    • 0 = one

    • 1 = two

    • 2 = three

  42. 55.

    Ultimate lower premolar paraconid (A, S)

    • 0 = indistinctive or absent

    • 1 = distinctive but low

    • 2 = distinctive and high

  43. 56.

    Ultimate lower premolar metaconids (A, S)

    • 0 = absent

    • 1 = swelling

    • 2 = large

  44. 57.

    Ultimate lower premolar talonid (A, S)

    • 0 = narrower than anterior portion of crown

    • 1 = as wide as anterior portion of crown

  45. 59.

    Length of ultimate lower premolar to penultimate (A, S)

    • 0 = longer

    • 1 = equal to or less

  46. 60.

    Ultimate lower premolar anterolingual cingulid (S)

    • 0 = absent

    • 1 = present

    Dentition – Molars

  47. 61.

    Number of molars (A, S)

    • 0 = four or more

    • 1 = three

    • 2 = two

  48. 62.

    Size of molar series (A, S)

    • 0 = subequal

    • 1 = posterior increase

    • 2 = posterior decrease

  49. 63.

    Molar cusp form (A, S)

    • 0 = sharp, gracile

    • 1 = inflated, robust

    • 2 = crest-like

  50. 64.

    Upper molar shape (A, S)

    • 0 = as long as wide, or longer

    • 1 = wider than long (length more than 75 % but less than 99 % of width)

    • 2 = much wider than long (length less than 75 % of width)

  51. 65.

    Size (labiolingual width) of upper molar labial stylar shelf at maximum (A, S)

    • 0 = 50 % or more of total transverse width

    • 1 = less than 50 % but more than 25 %

    • 2 = less than 25 %

    • 2 = absent

  52. 66.

    Labial extent of parastylar and metastylar lobes (A, S)

    • 0 = parastylar lobe more labial

    • 1 = subequal

    • 2 = metastylar lobe more labial

    • 3 = lobes absent

  53. 67.

    M1 parastylar lobe relative to paracone (A, S)

    • 0 = parastylar lobe is anterolabial to paracone

    • 1 = parastylar lobe is anterior to paracone

  54. 68.

    Length of parastylar lobe (measured to stylocone or stylocone position) relative to total length on penultimate molar (A, S)

    • 0 = more than 30 %

    • 1 = less than 30 % but more than 20 %

    • 2 = 20 % or less

  55. 69.

    Preparastyle (A, S)

    • 0 = absent

    • 1 = present

  56. 70.

    Stylar cusp A (A, S)

    • 0 = subequal to larger than B

    • 1 = distinct, but smaller than B

    • 2 = vestigial to absent

  57. 71.

    Stylar cusp B relative to paracone (A, S)

    • 0 = smaller but distinctive

    • 1 = vestigial to absent

    • 2 = subequal

  58. 72.

    Stylar cusp C, mesostyle (A, S)

    • 0 = absent

    • 1 = present

  59. 73.

    Stylar cusp D (A, S)

    • 0 = absent

    • 1 = smaller or subequal to B

    • 2 = larger than B

  60. 74.

    Stylar cusp E (A)

    • 0 = directly lingual to D or D-position

    • 1 = distal to D

    • 2 = small to indistinct

  61. 75.

    Preparacingulum (A, S)

    • 0 = absent

    • 1 = interrupted between stylar margin and paraconule or paraconule position

    • 2 = continuous

  62. 76.

    Deep ectoflexus (A, S)

    • 0 = present only on penultimate molar

    • 1 = on penultimate and preceding molars

    • 2 = strongly reduced or absent

  63. 77.

    Metacone size relative to paracone (S)

    • 0 = noticeably smaller

    • 1 = slightly smaller

    • 2 = subequal or larger

    • 3 = absent or merged with paracone.

  64. 78.

    Metacone position relative to paracone (A)

    • 0 = labial

    • 1 = approximately at same level

    • 2 = lingual

  65. 79.

    Metacone and paracone bases (A)

    • 0 = adjoined

    • 1 = separated

  66. 80.

    Preparacrista (A)

    • 0 = strong, from side of paracone to stylocone

    • 1 = weak, from base of paracone, or absent

  67. 81.

    Cuspate preparacrista (A)

    • 0 = present

    • 1 = absent

  68. 82.

    Centrocrista (A)

    • 0 = straight

    • 1 = V-shaped

    • 2 = absent

  69. 83.

    Postmetacrista (A)

    • 0 = prominent, from side of metacone to metastyle

    • 1 = salient

    • 2 = weak, from base of metacone, or absent

  70. 84.

    Cuspate postmetacrista (A)

    • 0 = present

    • 1 = absent

  71. 87.

    Development of postvallum shear (A, S)

    • 0 = present but only by the first rank: postmetacrista

    • 1 = present, with the addition of a second rank (postprotocrista below postmetacrista) but the second rank does not reach labially below the base of the metacone

    • 2 = present, with second rank extending to metastylar lobe: metacingulum

    • 3 = absent

  72. 88.

    Paraconule (A)

    • 0 = weak or absent

    • 1 = prominent, closer to protocone

    • 2 = prominent, midway or closer to paracone

  73. 89.

    Metaconule (A)

    • 0 = weak or absent

    • 1 = prominent, closer to protocone

    • 2 = prominent, midway or closer to metacone

  74. 92.

    Protocone (A)

    • 0 = lacking

    • 1 = small, without trigon basin

    • 2 = with distinct trigon basin

  75. 93.

    Protocone antero-posterior expansion (A)

    • 0 = none, subequal to paracone

    • 1 = expanded, larger than paracone

  76. 94.

    Protocone procumbency (A, S)

    • 0 = absent

    • 1 = present

  77. 95.

    Degree of labial shift of protocone (distance from protocone apex to lingual border vs. total tooth width, in %) (A)

    • 0 = no labial shift (10 %–20 %)

    • 1 = moderate labial shift (21 %–30 %)

    • 2 = substantial labial shift (≥ 31 %)

  78. 97.

    Precingulum (A, S)

    • 0 = absent or weak

    • 1 = present

    • 2 = present, reaching labially passed the paraconule or paraconule position

  79. 98.

    Postcingulum (A, S)

    • 0 = absent or weak

    • 1 = present, lingual to metaconule or metaconule position

    • 2 = present, reaching labially passed metaconule or metaconule position

    • 3 = present, extending to labial margin

  80. 99.

    Hypocone on postcingulum (A, S)

    • 0 = absent

    • 1 = present, lower than protocone

    • 2 = present, subequal to protocone

  81. 100.

    Pre- and postcingulum (A, S)

    • 0 = separated

    • 1 = continuous lingually

  82. 101.

    Number of penultimate roots (A)

    • 0 = three

    • 1 = four

    • 2 = more

  83. 102.

    Number of roots on ultimate molar (A)

    • 0 = three

    • 1 = two

    • 2 = one

    • 4 = four or more

  84. 103.

    Lingual root position on upper molars (A)

    • 0 = supporting paracone

    • 1 = supporting trigon

  85. 104.

    Ultimate upper molar width relative to penultimate molar (A)

    • 0 = subequal

    • 1 = smaller

  86. 105.

    Metastylar lobe on ultimate molar (A)

    • 0 = absent

    • 1 = present

  87. 106.

    Paraconid (A, S)

    • 0 = present

    • 1 = absent

  88. 107.

    Paraconid height relative to metaconid (A, S)

    • 0 = shorter

    • 1 = subequal

    • 2 = taller

  89. 108.

    Paraconid on lingual margin (A, S)

    • 0 = absent

    • 1 = present

  90. 111.

    Trigonid configuration (A)

    • 0 = open, with paraconids anteromedial, paracristid-protocristid angle more than 50°

    • 1 = more acute, with paraconid more posteriorly placed, paracristid-protocristid angle between 36 and 49°

    • 2 = anteroposteriorly compressed, paracristid-protocristid angle 35° or less

  91. 112.

    Protoconid height (A, S)

    • 0 = tallest cusp on trigonid

    • 1 = subequal to para- and/or metaconids

    • 2 = smaller than para- and/or metaconid

  92. 114.

    Anterior and labial (mesio-buccal) cingular cuspule (f) (A)

    • 0 = present

    • 1 = present with a distinct cingular shelf posteroventrally directed from it

    • 2 = present with shelf continuing along buccal border

    • 3 = absent

  93. 115.

    Talonid (A, S)

    • 0 = small heel

    • 1 = multicusped basin

  94. 117.

    Trigonid height relative to talonid height (A, S)

    • 0 = twice or more

    • 1 = less than twice

    • 2 = subequal

  95. 118.

    Anteroposterior shortening at base of trigonid relative to talonid (A, S)

    • 0 = trigonid long (more than 75 % of tooth length)

    • 1 = some shortening (50-75 % of tooth length)

    • 2 = anteroposterior compression of trigonid (less than 50 % of tooth length)

  96. 119.

    Talonid width relative to trigonid (A, S)

    • 0 = very narrow, subequal to base of metaconids

    • 1 = narrower

    • 2 = subequal to wider

  97. 120.

    Hypoconulid (A)

    • 0 = absent

    • 1 = in posteromedial position (near the mid-point of transverse talonid width)

    • 2 = lingually placed with slight approximation to entoconid

    • 3 = close approximation to entoconid

  98. 122.

    Entoconid (A)

    • 0 = absent

    • 1 = smaller than

    • 2 = subequal to larger than hypoconid and/or hypoconulid

  99. 123.

    Postcristid (between entoconid and hypoconulid) taller than hypoconulid and nearly transverse (A)

    • 0 = absent

    • 1 = present

  100. 124.

    Mesoconid (A)

    • 0 = absent

    • 1 = present

  101. 125.

    Hypolophid (A, S)

    • 0 = absent

    • 1 = present

  102. 126.

    Labial postcingulid (A)

    • 0 = absent

    • 1 = present

  103. 127.

    Ultimate lower molar size relative to penultimate lower molar (S)

    • 0 = subequal or larger

    • 1 = smaller

    Mandible

  104. 128.

    Number of mental foramina (A, S)

    • 0 = two or more

    • 1 = one

  105. 129.

    Anteriormost mental foramen (A, S)

    • 0 = below incisors (or anteriormost mandible)

    • 1 = below p1

    • 2 = below p2

    • 3 = more posterior

  106. 130.

    Posteriormost mental foramen (A, S)

    • 0 = in canine and anterior premolar (premolariform) region (in saddle behind canine eminence of mandible)

    • 1 = below penultimate premolar (under anterior end of functional postcanine row)

    • 2 = below ultimate premolar

    • 3 = at ultimate premolar and first molar junction or more posterior

  107. 131.

    Depth of mandibular body (A, S)

    • 0 = slender and long

    • 1 = deep and short

  108. 132.

    Space between ultimate molar and coronoid process (S)

    • 0 = absent

    • 1 = present

  109. 133.

    Coronoid process height (S)

    • 0 = higher than condyle

    • 1 = even with condyle

  110. 134.

    Coronoid process width (S)

    • 0 = broad, roughly two molar lengths

    • 1 = narrow, subequal to or less than one molar length

  111. 138.

    Anteroventral extension of masseteric fossa (S)

    • 0 = absent

    • 1 = extending anteriorly onto mandibular body

  112. 139.

    Labial mandibular foramen (S)

    • 0 = absent

    • 1 = present

  113. 152.

    Mandibular symphysis posterior extent (S)

    • 0 = p1 or more anterior

    • 1 = p2

    • 2 = p4 or more posterior

  114. 154.

    “Meckelian” groove (S)

    • 0 = present

    • 1 = absent

  115. 156.

    “Coronoid” facet (S)

    • 0 = present

    • 1 = absent

    Skull – Rostrum

  116. 164.

    Exit(s) of infraorbital canal (S)

    • 0 = multiple

    • 1 = single

    • 2 = canal absent

  117. 165.

    Infraorbital foramen position (S)

    • 0 = dorsal to ultimate premolar

    • 1 = dorsal to penultimate premolar or more anterior

    • 2 = dorsal to first molar or more posterior

    Skull – Zygoma

  118. 196.

    Posterior edge of anterior zygomatic root (S)

    • 0 = aligned with last molar

    • 1 = aligned with anterior molars

    • 2 = aligned with premolars

  119. 198.

    Jugal (S)

    • 0 = present

    • 1 = absent

  120. 199.

    Jugal (S)

    • 0 = contributes to anteroventral orbit and zygoma

    • 1 = contributes to zygoma

  121. 200.

    Maxillary-jugal contact bifurcated (S)

    • 0 = absent

    • 1 = present

  122. 201.

    Jugal-lacrimal contact (S)

    • 0 = present

    • 1 = absent

  123. 202.

    Zygomatic arch (S)

    • 0 = stout

    • 1 = delicate

    • 2 = incomplete

Matrix

Scored characters for Alvuegena and Schowalteria. All others can be found in Wible et al. (2009).

Alveugena

0010?13??????0????????11010?1?201?-100110100?0010---000000?0?100120020010020001001001??322??2101?210000110000?-00-31?0111?20000?0120????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ?

Schowalteria

001?0??2?1???01?00??0011010?1?2010-??00??2???0011--000001?011001200200100-00??????????3??????0??1100?????100???1??1?001?????0?10220100???10????????????2?1-1???????11??????????????????????????????1?00002??????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????

Complete Eutherian tree

Fig. 3
figure 3

External relations among Eutheria from cladistic analysis. Entirety of tree from Fig. 2, showing both crown and stem relationships

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Rook, D.L., Hunter, J.P. Rooting Around the Eutherian Family Tree: the Origin and Relations of the Taeniodonta. J Mammal Evol 21, 75–91 (2014). https://doi.org/10.1007/s10914-013-9230-9

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