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1 June 2014 The First Complete Leg of a Passerine Bird from the Early Oligocene of Poland
Zbigniew M. Bochenski, Teresa Tomek, Ewa Świdnicka
Author Affiliations +
Abstract

The leg bones of a small passeriform bird are described from the early Oligocene (29 Mya) of Poland. The specimen is the earliest complete passerine leg with elements in articulation described so far, and increases the known diversity of the very scanty records of the oldest European passeriforms. In general proportions the leg bones resemble those of Luscinia svecica and other species that live in shrubs. Assignment to a family within the passerines is not possible because of the incompleteness of the fossil.

Introduction

Marine Oligocene deposits of the Menilite Formation of the Outer Carpathians, southeastern Poland, are primarily known for their rich fauna of fishes (Kotlarczyk et al. 2006). Fossils of other taxa are very scarce; so far only four avian specimens have been described. They include a hummingbird, Eurotrochilus noniewiczi Bochenski and Bochenski, 2008, a passerine, Jamna szybiaki Bochenski, Tomek, Bujoczek, Wertz, 2011, a procellariiform, ?Diomedeoides lipsiensis known from an isolated bone (Elzanowski et al. 2012), and a bird of unknown affinities with a columbid-like foot (Bochenski et al. 2010).

Although passeriforms constitute more than a half of all extant avian species, their Paleogene fossil record is surprisingly limited (Mayr 2005, 2009). The oldest two fossils of possible passerine affinities are dated to the early Eocene of Australia (Boles 1995, 1997), but unquestionable remains of passeriforms come from the Oligocene of Europe. Two species based on relatively complete specimens have been described from the early Oligocene: Wieslochia weissi Mayr and Manegold, 2006 from Germany (Mayr and Manegold 2004, 2006b) and Jamna szybiaki from Poland (Bochenski et al. 2011). Other Oligocene remains in the literature include an articulated wing (Mayr andManegold 2006a) and several dozen isolated wing bones (Mourer-Chauviré et al. 1989; Manegold 2008). Leg bones are much more poorly preserved, and even those of Wieslochia weissi and Jamna szybiaki are incomplete. Apart from the latter, only two other fragments of the tarsometatarsus are known fromthe Oligocene of France (Mourer-Chauviré et al. 1989, 2004; Mourer-Chauviré 2006).

In this paper, we describe a nearly complete articulated specimen of a passerine leg found in southeastern Poland (Fig. 1). Although it is not perfectly preserved, it provides many new details that for the first time cast light on the osteology and external appearance of a Paleogene passeriform foot and leg.

Institutional abbreviations.—ISEA, Institute of Systematics and Evolution of Animals, Kraków, Poland; ZPALWr, Department of Palaeozoology, University of Wrocław, Wrocław, Poland.

Methods

Osteological terminology follows Baumel andWitmer (1993).Dimensions are given in millimetres and refer to the greatest length along the longitudinal axis of the bone. The fossil was compared with Recent specimens from the osteological collection of the ISEA. The fossiliferous horizon in the village of Przysietnica has been dated on the basis of the fish assemblage and correlated with the calcareous nannoplankton (Berggren et al. 1995; Kotlarczyk et al. 2006). The body mass of the fossilwas estimated fromthe relationship of femur dimensions to weight in birds (Campbell and Marcus 1992; Campbell and Bochenski 2010), using the formula for ordinary least-squares regression: log(y) = 2.418·log(x) 0.179, where y = mass in grams and x = least shaft circumference of femur in mm. The slope and intercept figures are specifically for the data subset “PS”, or passerine birds, of Campbell andMarcus (1992: table 3). The least shaft circumference was calculated from the minimum width of the femoral shaft, assuming that the cross-section of the shaft is circular.

Systematic palaeontology

Aves Linnaeus, 1758
Passeriformes Linnaeus, 1758
Family, genus, and species indeterminate

  • Material.—A slab (Fig. 2), found in 1985, with imprints of a complete right avian leg articulated to a poorly-preserved pelvis, and two pieces of a counter slab with fragments of the bones (ZPALWr. A/4004) from Przysietnica (site PS-5), one of eighteen exposures of marine deposits in the Menilite Formation of the Outer Carpathians, situated in the village of Przysietnica, about 8 km from Brzozów and 44 km southeast of Rzeszów, Podkarpackie Voivodeship, southeastern Poland (Fig. 1). Geographical coordinates of the site: 49°43.976′ N, 022°03.017′ E. ZPALWr. A/4004 was found in layer 40, together with 120 articulated fish imprints, and with the index fish species Carpathospinosus propheticus Tyler, Jerzmańska, Bannikov, and Świdnicki, 1993, Antigonia sp., and chaetodontid-like larva (Świdnicki 1988; Tyler et al. 1993; Micklich et al. 2009), all indicating the IPM4A Zone (Kotlarczyk et al. 2006: fig. 6). The fossiliferous horizon of Przysietnica (PS-5) has been dated to Rupelian, early Oligocene, circa 29 Mya, on the basis of the fish assemblage indicating the IPM4A Zone, and correlated with the calcareous nannoplankton of the NP24 Zone sensu Berggren et al. (1995). The fossil-bearing section at Przysietnica is currently referred to the Šitbořice Member of the Subsilesian Unit of the Menilite Formation of the Polish Outer Carpathians (Kotlarczyk et al. 2006: 16, 96).

  • Taxonomic remarks.—Small passerine which is distinguished from all other non-passerine taxa by the combination of the following characters: (1) all leg elements including the tarsometatarsus and tibiotarsus are long and slender; (2) the tibiotarsus bears the Crista cnemialis cranialis that projects far craniad and joins with the shaft almost at right angles; (3) the tarsometatarsus bears a relatively short, proximo-distally, hypotarsuswhose distal end joins abruptly with the shaft, (4) a distinct Crista plantaris lateralis, and (5) has the small trochleae of the second, third, and fourth pedal digits arranged in a line and reaching approximately equally far distally; (6) the specimen shows an anisodactyl foot; (7) the proximal phalanx of the hallux is greatly elongated; (8) the claws show relatively little curvature and their Tubercula flexoria areweakly developed. Character (5) is unique to passerines and is often used to discriminate them from all other non-passerine taxa (e.g., Cohen and Serjeantson 1996; Gilbert et al. 1996; Bochenski and Tomek 2009); the remaining characters are shared with one or more non-passerine orders but their combination is unique to passerines.

  • Fig. 1.

    Location of the village of Przysietnica in southeastern Poland, where the specimen ZPALWr. A/4004 was found.

    f01_281.jpg

    Description and comparison

    Size and weight.—Measurements (maximum length in mm): femur, 17.1; tibiotarsus, 36.3; tarsometatarsus, 25.7; hallux: proximal phalanx, 7.6; hallux: claw, 4.7; second phalanx of digit II, 4.5; claw of digit II, 3.2; second phalanx of digit III, 5.6; third phalanx of digit III, 5.5; claw of digit III, 3.9; second phalanx of digit IV, 3.0; third phalanx of digit IV, 3.1; fourth phalanx of digit IV, 3.4; claw of digit IV, 2.8. Minimum width of femoral shaft: 1.5 mm. Proportions of the leg bones: femur/tibiotarsus, 0.5; femur/tarsometatarsus, 0.7; tibiotarsus/ tarsometatarsus, 1.4.

    The estimated mass of the bird represented by ZPALWr. A/4004 was calculated to be 30.1 g.

    Pelvis.—The small fragment of the pelvis is too poorly preserved to allow meaningful comparisons. Only four incomplete caudal vertebrae are visible; the pygostyle is missing.

    Femur.—The femur is visible in cranial view. The Caput femoris is imprinted in the main slab only; the outlines of the Condyli medialis and Condyli lateralis are too poorly preserved to allow meaningful comparisons. The bone is similar in length to that of Wieslochia weissi (Mayr andManegold 2006b) andmuch shorter than in Jamna szybiaki (Bochenski et al. 2011).

    Tibiotarsus.—The tibiotarsus is visible in medial view, but the medial surface of the bone is missing. As in extant passeriforms, but in contrast to most “higher land-birds”, the tibiotarsus is slender and long. It is longer than the tibiotarsus in Wieslochia weissi (Mayr andManegold 2004) and Jamna szybiaki (Bochenski et al. 2011). The Crista cnemialis cranialis, which is better preserved on the counterslab, projects considerably craniad and it joins with the shaft distally almost at right angles; its shape and size is typical of that in passerine birds. The Crista fibularis extends far laterad; its distal end is missing. As in extant passeriforms, the Condyli medialis and Condyli lateralis are of similar size.

    Tarsometatarsus.—The tarsometatarsus (seen only on the main slab) is oriented with the medial side up, but what is preserved is mainly the imprint of its lateral side with remnants of bone. It is long and slender, being much longer than in Wieslochia weissi (Mayr and Manegold 2006b). As in all extant passeriforms, the hypotarsus is relatively short proximo-distally and its distal end joins abruptly with the shaft. No details of hypotarsal canals and/or furrows are visible. The shaft bears a crista plantaris lateralis, which is present only in passerines and cuckoos (Manegold et al. 2004). The distal end with the trochleae of the second, third, and fourth pedal digits small and arranged in a line is highly characteristic for all passeriforms. The well-imprinted Trochlea metatarsi IV is narrow, the Trochlea metatarsi III is broader, grooved, and it reaches only a little farther distally. The Trochlea metatarsi II is only marked by a poorly visible imprint.

    Toes.—As in all passeriforms, the foot has an anisodactyl arrangement of toes,with three digits directed forward and one digit directed backward.All pedal digits have the usual number of phalanges, and they are thin and relatively short. TheOsmetatarsale I is detached from the rest of the hallux; as in all other passeriforms it exhibits a cylindrical Trochlea metatarsi I. Also as in all extant passeriforms and the early Oligocene Wieslochia weissi (Mayr and Manegold 2006b), the proximal phalanx of the hallux is greatly elongated. The proximal-most phalanges of digits II, III, and IV are damaged and/or visible only at an angle because they penetrate into the matrix; other phalanges are well preserved. The third digit seems to be the longest, the second and the fourth are about the same length. The claws show relatively little curvature, their Tubercula flexoria are weakly developed and they bear a groove along their length. The second and the third phalanges of digit III are approximately of the same length. In digit IV, the fourth phalanx is longer than the second and the third phalanges, which are similar in length.

    Fig. 2.

    An unidentified passerine bird leg from SE Poland, Przysietnica, early Oligocene, circa 29 Mya (ZPALWr. A/4004). A. Main slab. B. Counter slab. C. Interpretative drawing of slab and counter slab (enlarged fragments are indicated by arrows). D. Enlarged proximal tarsometatarsus from main slab. E. Enlarged distal tarsometatarsus from main slab. F. Enlarged proximal tibiotarsus from counter slab.

    f02_281.jpg

    Discussion

    Owing to the fragmentary preservation of the fossil and the un-known pattern of its hypotarsal canals in particular (Manegold et al. 2004), its assignment to a family within the passerines is not possible.

    The estimated mass of ZPALWr. A/4004 (∼30 g) is within the range of body masses of various small passerines. As a test, we measured the minimum width of the femur of a number of passerine species from our comparative collection, calculated the least shaft circumference and used the equation described in the Methods to estimate the mass of the comparative specimens. The two comparative species whose femur shaft minimum widths were most similar to ZPALWr. A/4004 (1.5 mm) were Alauda arvensis (1.6 mm) and Lanius collurio (1.5 mm). The estimated masses of these two comparative species fall within the range of recorded masses for these species (Alauda arvensis: estimated mass ∼31 g, range from Cramp 1988: 24.4–44.9 g; Lanius collurio: estimated mass ∼26 g, range from Cramp and Perrins 1993: 21.7–36.3 g), which indicates that the procedure is reliable and the estimate for the fossil specimen is most probably correct.

    In general proportions, the femur, tibiotarsus and tarsometatarsus are similar to those of extant passeriforms, particularly members of the Alaudidae (Larks), Motacillidae (Pipits and Wagtails), Prunellidae (Accentors), Sylviidae (Old World warblers), Troglodytidae (Wrens), and Turdidae (Thrushes) families. The most similar, yet not identical, extant species is Luscinia svecica of the family Muscicapidae (Old World Flycatchers). The size and proportions of the leg elements, as well as the relatively short pedal digits, correspond best with extant species that live in shrubs, trees or on the ground (Zeffer et al. 2003; TT and ZMB personal observations). Also the slight curvature of the claws suggests that ZPALWr. A/4004 was a bird that Glen and Bennett (2007) would include in ground or arboreal foragers.

    ZPALWr. A/4004 also differs considerably in general proportions from the other two Oligocene passerines known, Wieslochia weissi (Mayr and Manegold 2004, 2006b) and Jamna szybiaki (Bochenski et al. 2011), which might mean that it represents a different taxon. The two other fragments of proximal tarsometatarsi from the upper Oligocene of France (the Coderet specimen FSL 330802 and the Créchy specimen FSL 367057) are hard to compare because of their poor state of preservation. Although ZPALWr. A/4004 is not well preserved, it represents the first complete specimen of an Oligocene passerine with all the leg elements in articulation. It also increases the known diversity of the very scanty records of the oldest European passerines.

    Acknowledgements.

    We thank Andrea Pereswiet-Soltan (ISEA, Poland) and Piotr Wojtal (ISEA, Poland) for taking the photographs and Krzysztof Wertz (ISEA, Poland) for making the drawings. Kenneth E. Campbell Jr. (Natural History Museum of Los Angeles County, USA) and Gareth J. Dyke (University of Southampton, UK) provided helpful comments on the manuscript.

    References

    1.

    J.J. Baumel and L.M. Witmer 1993. Osteologia. In : J.J. Baumel , A.S. King , J.E. Breazile , H.E. Evans , and J.C. Vanden Berge (eds.), Handbook of Avian Anatomy: Nomina Anatomica Avium. Publications of the Nuttall Ornithological Club 23: 45–132. Google Scholar

    2.

    W.A. Berggren , D.V. Kent , C.C. Swisher , and M.P. Aubry 1995. A revised Cenozoic geochronology and chronostratigraphy. In : W.A. Berggren , D.V. Kent , M.P. Aubry , and J. Hardenbol (eds.), Geochronology, Time Scales and Stratigraphic Correlation. Society for Sedimentary Geology (SEPM) Special Publication 54: 129–212. Google Scholar

    3.

    Z. Bochenski and Z.M. Bochenski 2008. An Old World hummingbird from the Oligocene: a new fossil from Polish Carpathians. Journal of Ornithology 149: 211–216. Google Scholar

    4.

    Z.M. Bochenski and T. Tomek 2009. A Key for the Identification of Domestic Bird Bones in Europe: Preliminary Determination. 101 pp. Institute of Systematics and Evolution of Animals, Kraków. Google Scholar

    5.

    Z.M. Bochenski , T. Tomek , M. Bujoczek , and K. Wertz 2011. A new passerine bird from the early Oligocene of Poland. Journal of Ornithology 152: 1045–1053. Google Scholar

    6.

    Z.M. Bochenski , T. Tomek , and E. Świdnicka 2010. A columbid-like avian foot from the Oligocene of Poland. Acta Ornithologica 45: 233–236. Google Scholar

    7.

    W.E. Boles 1995. The world's oldest songbird. Nature 374: 21–22. Google Scholar

    8.

    W.E. Boles 1997. Fossil songbirds (Passeriformes) from the Eocene of Australia. Emu 97: 43–50. Google Scholar

    9.

    K.E. Campbell Jr. and Z.M. Bochenski 2010. A new genus for the extinct Late Pleistocene owl Strix brea Howard (Aves: Strigiformes) from Rancho La Brea, California. In : W.E. Boles and T.H. Worthy (eds.), Proceedings of the VII International Meeting of the Society of Avian Paleontology and Evolution. Records of the Australian Museum 62: 123–144. Google Scholar

    10.

    K.E. Campbell Jr. and L. Marcus 1992. The relationship of hindlimb bone dimensions to body weight in birds. Natural History Museum of Los Angeles County, Science Series 36: 395–412. Google Scholar

    11.

    A. Cohen and D. Serjeantson 1996. A Manual for the Identification of Bird Bones from Archaeological Sites. 115 pp. Archetype Publications, London. Google Scholar

    12.

    S. Cramp 1988. The Birds of the Western Palearctic , Vol. 5. 1063 pp. Oxford University Press, Oxford. Google Scholar

    13.

    S. Cramp and C.M. Perrins 1993. The Birds of the Western Palearctic , Vol. 7. 577 pp. Oxford University Press, Oxford. Google Scholar

    14.

    A. Elzanowski , M. Bieńkowska-Wasiluk , R. Chodyń , and W. Bogdanowicz 2012. Anatomy of the coracoid and diversity of the Procellariiformes (Aves) in the Oligocene of Europe. Palaeontology 55: 1199–1221. Google Scholar

    15.

    B.M. Gilbert , L.D. Martin , and H.G. Savage 1996. Avian Osteology. 252 pp. Missouri Archaeological Society, Missouri. Google Scholar

    16.

    C.L. Glen and M.B. Bennett 2007. Foraging modes of Mesozoic birds and non-avian theropods. Current Biology 17 (21): R911–R912. Google Scholar

    17.

    J. Kotlarczyk , A. Jerzmańska , E. Świdnicka , and T. Wiszniowska 2006. A framework of ichthyofaunal ecostratigraphy of the Oligocene-Early Miocene strata of the Polish Outer Carpathian basin. Annales Societatis Geologorum Poloniae 76: 1–111. Google Scholar

    18.

    A. Manegold 2008. Passerine diversity in the late Oligocene of Germany: earliest evidence for the sympatric coexistence of Suboscines and Oscines. Ibis 150: 377–387. Google Scholar

    19.

    A. Manegold , G. Mayr , and C. Mourer-Chauviré 2004. Miocene songbirds and the composition of the European passeriform avifauna. Auk 121: 1155–1160. Google Scholar

    20.

    G. Mayr 2005. The Paleogene fossil record of birds in Europe. Biological Reviews 80: 515–542. Google Scholar

    21.

    G. Mayr 2009. Paleogene Fossil Birds. 262 pp. Springer, Berlin. Google Scholar

    22.

    G. Mayr and A. Manegold 2004. The oldest European fossil songbird from the early Oligocene of Germany. Naturwissenschaften 91: 173–177. Google Scholar

    23.

    G. Mayr and A. Manegold 2006a. A small suboscine-like passeriform bird from the early Oligocene of France. Condor 108: 717–720. Google Scholar

    24.

    G. Mayr and A. Manegold 2006b. New specimens of the earliest European passeriform bird. Acta Palaeontologica Polonica 51: 315–323. Google Scholar

    25.

    N.R. Micklich , J.C. Tyler , G.D. Johnson , E. Świdnicka , and A.F. Bannikov 2009. First fossil records of the tholichthys larval stage of butterfly fishes (Perciformes, Chaetodontidae) from the Oligocene of Europe. Paläontologische Zeitschrift 83: 479–497. Google Scholar

    26.

    C. Mourer-Chauviré 2006. The avifauna of the Eocene and Oligocene Phosphorites du Quercy (France): an updated list. Strata Série 1 13: 135–149. Google Scholar

    27.

    C. Mourer-Chauviré , D. Berthet , and M. Hugueny 2004. The late Oligocene birds of the Créchy quarry (Allier, France), with a description of two new genera (Aves: Pelecaniformes: Phalacrocoracidae, and Anseriformes: Anseranatidae). Senckenbergiana lethaea 84: 303–315. Google Scholar

    28.

    C. Mourer-Chauviré , H. Hugeney , and P. Jonet 1989. Découverte de passériformes dans l'Oligocène supérieur de France. Comptes Rendus de l'Académie des Sciences de Paris, Série II 309: 843–849.  Google Scholar

    29.

    J. Świdnicki 1988. Juveniles of some Oligocene Antigonia (Caproidae, Teleostei) from the Polish Carpathians. Acta Palaeontologica Polonica 33: 249–259. Google Scholar

    30.

    J.C. Tyler , A. Jerzmańska , A.F. Bannikov , and J. Świdnicki 1993. Two new genera and species of Oligocene Spikefishes (Tetraodontiformes: Triacanthodidae), the first fossils of the Hollardiinae and Triacantho−dinae. Smithsonian Contributions to Paleobiology 75: 1–27. Google Scholar

    31.

    A. Zeffer , L.C. Johansson , and Å Marmebro . 2003. Functional correlation between habitat use and leg morphology in birds (Aves). Biological Journal of the Linnean Society 79: 461–484. Google Scholar
    ©2013 Z.M. Bochenski et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
    Zbigniew M. Bochenski, Teresa Tomek, and Ewa Świdnicka "The First Complete Leg of a Passerine Bird from the Early Oligocene of Poland," Acta Palaeontologica Polonica 59(2), 281-285, (1 June 2014). https://doi.org/10.4202/app.2012.0021
    Received: 8 February 2012; Accepted: 23 March 2012; Published: 1 June 2014
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