One of the notable features of penguin evolution is the occurrence of very large species in the early Cenozoic, whose body size greatly exceeded that of the largest extant penguins. Here we describe a new giant species from the late Paleocene of New Zealand that documents the very early evolution of large body size in penguins. Kumimanu biceae, n. gen. et sp. is larger than all other fossil penguins that have substantial skeletal portions preserved. Several plesiomorphic features place the new species outside a clade including all post-Paleocene giant penguins. It is phylogenetically separated from giant Eocene and Oligocene penguin species by various smaller taxa, which indicates multiple origins of giant size in penguin evolution. That a penguin rivaling the largest previously known species existed in the Paleocene suggests that gigantism in penguins arose shortly after these birds became flightless divers. Our study therefore strengthens previous suggestions that the absence of very large penguins today is likely due to the Oligo-Miocene radiation of marine mammals.
New Zealand has yielded several fossils of Paleocene Sphenisciformes, which shed considerable light on the early evolution of penguins. All of the described specimens come from exposures of the Waipara Greensand in the Canterbury region and the two named species, Waimanu manneringi and W. tuatahi, are the oldest and phylogenetically most basal Sphenisciformes reported so far1,2,3.
Recently, remains of a very large penguin have also been found in the Waipara Greensand4. These fossils, an incomplete tarsometatarsus and associated pedal phalanges, belong to an unnamed species that is phylogenetically closer to the crown group (the clade including the extant species) than Waimanu. A definitive taxonomic assignment of the fragmentary fossils is, however, not possible and this is also true for Crossvallia unienwillia, an equally large stem group penguin from the late Paleocene of Antarctica5, 6.
Gigantism, that is, the evolution of a size exceeding that of the extant Emperor Penguin (Aptenodytes forsteri), is much better documented in post-Paleocene penguins, and the Eocene Anthropornis nordenskjoeldi and Pachydyptes ponderosus were for a long time considered to be the largest known penguin species7, 8. Pachydyptes ponderosus, from the late Eocene of New Zealand, is known only from a few wing and pectoral girdle bones7; however, numerous isolated skeletal elements as well as a few partial skeletons have been reported for A. nordenskjoeldi, from the late Eocene and early Oligocene of Antarctica9, 10. Recently, it was hypothesised that the well-preserved Kairuku grebneffi from the late Oligocene of New Zealand may have been taller, although less massive than P. ponderosus; for the largest individual of K. grebneffi, a total body length of about 1.5 m was estimated8. Based on isolated limb bones, lengths of 1.6 and 1.5 m were also calculated for Anthropornis nordenskjoeldi and the very large Palaeeudyptes klekowskii from the Eocene and Oligocene of Antarctica11. While partial skeletons of P. klekowskii indicate a somewhat shorter body length of about 1.4 m12, 13, a recently described humerus fragment and a tarsometatarsus may come from individuals with an estimated length of about 2.0 m14. A large size is reached by other Palaeeudyptes species from the Eocene and Oligocene of Antarctica and New Zealand2, 15, 16, and further, very large Sphenisciformes occurred in the late Eocene of Australia17 and the late Eocene of Peru18, 19.
Some authors assumed that penguins achieved a giant size multiple times6, but the giant taxa Anthropornis, Palaeeudyptes, Kairuku, Icadyptes, and Inkayacu were recovered as parts of subsequently branching clades and it was therefore considered more likely that extremely large size evolved only once18. Definitive conclusions about size evolution in fossil Sphenisciformes are, however, impeded by the fact that even in more recent analyses the exact interrelationships between giant sphenisciform taxa are poorly resolved8, 19, 20.
Here we report a partial skeleton of a giant stem penguin from the Paleocene Moeraki Formation at Hampden Beach in the Otago region of New Zealand, some 300 km southwest of the exposures of the Waipara Greensand in the Canterbury region. A few fragmentary bird remains from the Moeraki Formation were previously mentioned21 and the age of the Moeraki Formation has been constrained to the late Paleocene based on foraminiferal biostratigraphy22, 23. The new fossil is one of the oldest giant penguins found so far and is clearly outside a clade including the giant Eocene and Oligocene Sphenisciformes, substantiating multiple origins of gigantism in fossil penguins.
Aves Linnaeus, 1758
Sphenisciformes Sharpe, 1891
Kumimanu biceae, n. gen. et sp.
Holotype. NMNZ S.45877: partial skeleton of a single individual including cranial end of left scapula, incomplete right coracoid, cranialmost portion of sternum, partial left humerus, incomplete proximal end of left ulna, right femur, right tibiotarsus lacking proximal end, partial synsacrum, three vertebrae, and various bone fragments.
Etymology. From kumi (Maori), a large mythological monster, and manu (Maori), bird. The species epithet honors Beatrice (“Bice”) A. Tennyson, the mother of AJDT, who fostered his interest in natural history (pronounced “bee-chee-ae”).
Type locality and horizon. Hampden Beach, Otago, New Zealand (NZ Fossil Record Number J42/f0956; precise locality information is recorded at NMNZ); Moeraki Formation, late Paleocene (late Teurian, local stratigraphic level NZP522, which has an absolute age of 55.5.-59.5 million years23; a matrix sample taken from the fossil (GNS Science sample L29126) contained a specimen of the dinoflagellate Palaeocystodinium australinum and an unnamed dinoflagellate taxon that support a Teurian age for this sample; C. Clowes, pers. comm.).
Diagnosis. A very large-sized sphenisciform species, which is characterized by proximodistally low and widely spaced condyles of the tibiotarsus. Distinguished from the late Paleocene Crossvallia and all post-Paleocene Sphenisciformes of which humeri are known in the dorsoventrally narrower humerus shaft, with ratio of maximum width of proximal end of humerus to minimum width of shaft being 2.4 (less than this value in Crossvallia and all post-Paleocene Sphenisciformes of which the humerus is known). Distinguished from Waimanu tuatahi in having the bicipital crest of humerus not forming a distally directed bulge. Distinguished from Waimanu manneringi (the humerus of which is unknown) in having the tibiotarsus with proximodistally lower and more widely spaced condyles.
Dimensions (in mm). Coracoid, maximum length as preserved, 141.8; humerus, maximum length as preserved, 149.6; dorsoventral width of proximal end, 75.0; Tibiotarsus, length from distal margin of condylus lateralis to preserved proximal end, 151.3; width of distal end across condyles as preserved, 51.9; estimated actual width of distal end, ~48. Femur, maximum length along longitudinal axis, 161 mm.
Description and comparisons
The bones were densely packed in a very hard concretion (Fig. 1a). The humerus (Fig. 1i‒l) lacks most of the caput humeri and the distal end, with the latter having already been broken and lost before the bone was embedded in sediment. The attachment scar for the supracoracoideus muscle is slightly raised and dorsoventrally narrower than in Pachydyptes (Fig. 1n), Anthropornis, and Icadyptes. The fossa pneumotricipitalis is single and deeply excavated. The humerus shaft is proportionally narrower than in all post-Paleocene Sphenisciformes, and this is especially true if the bone is compared to the humeri of the giant taxa Pachydyptes, Anthropornis, and Icadyptes. An estimation of the total length of the humerus of Kumimanu biceae depends on the assumed proportions. If the proximal end had a similar relative size to that of Waimanu tuatahi, less than two thirds of the bone would be preserved and the estimated total length would have been about 228 mm (Fig. 1l). Our most conservative length estimate, by contrast, is based on comparisons with the short (albeit much stouter) humerus of Anthropornis—in this case only a small portion of the distal end would be missing and the humerus of Kumimanu biceae would have had a length of about 185 mm (Fig. 1k). If the bone was indeed that short, it would have had a proportionally much wider proximal end than the humeri of other Paleocene penguins (Table 1) and would have had an unusually slender shaft relative to the massive proximal end of the bone, so we consider our longer length estimate to be more likely.
The fragment of the proximal end of the ulna exhibits half of the ventral cotyla, next to which there is a distinct, flange-like projection (Fig. 1d‒f). The ulna of W. tuatahi and that of a phylogenetically basal penguin from the Waipara Greensand (CM 2016.6.1), whose description is pending24, has two such flanges on the caudal and cranial surfaces of the bones, respectively: the olecranon and the dorsal cotylar process (Fig. 1g, h). Based on comparisons with the ulnae of the Sphenisciformes from the Waipara Greensand, we consider the flange on the ulna of the K. biceae holotype to be the dorsal cotylar process, because the olecranon has a more convex margin in Paleocene Sphenisciformes and is much more prominent in post-Paleocene taxa. A well-developed dorsal cotylar process is a plesiomorphic feature24, which is absent in post-Paleocene Sphenisciformes.
The coracoid lacks the sternal end (Fig. 1b) and the acrocoracoid process is damaged, with its medial portion being broken. The scapular cotyla is of circular outline and more deeply excavated than in post-Paleocene Sphenisciformes including Pachydyptes ponderosus. The well-developed procoracoid process projects perpendicular to the longitudinal axis of the bone and has a ventrally deflected tip. As in W. tuatahi (Fig. 1c), there is no coracoidal fenestra, with this fenestra being present in all Eocene and Oligocene Sphenisciformes of which well-preserved coracoids are known (in P. ponderosus, the corresponding area is damaged, although the remaining medial section of the shaft suggests the former presence of a fenestra).
The cranial extremity of the scapula (Fig. 2a, b) resembles that of Waimanu tuatahi (Fig. 2c) and differs from the known scapulae of post-Paleocene penguins in that the humeral articulation facet is craniocaudally more extensive. Unlike in W. tuatahi, however, the scapular blade widens caudally, as it does in phylogenetically more crownward Sphenisciformes, and the articulation facet of the humerus is craniocaudally narrower, with a more pointed ventral tip.
Of the sternum, the cranial margins of the carina and the corpus are preserved (Fig. 2g), but only a few osteological details can be discerned. As in Platydyptes marplesi 8 but unlike in extant penguins, the articular sulci for the coracoid meet each other at the midline of the bone. Compared to extant Sphenisciformes, the external lip of the articulation sulcus for the coracoid (labrum externum) is furthermore situated in a very lateral position. The sternal keel appears to have been unusually thick, but is too incompletely preserved to determine its original shape.
A thoracic vertebra (Fig. 2d, e) has a slightly concave caudal articulation facet and an essentially flat cranial one, whereas in extant Sphenisciformes, the vertebrae are opisthocoelous, that is, with a distinctly convex cranial articulation facet and a distinctly concave caudal one. Unlike in W. tuatahi, the lateral surfaces of the corpus do not exhibit well-delimited fossae.
The new species has a longer femur than all other fossil penguins, for which this skeletal element is known (Table 1). The bone is partially embedded in matrix (Fig. 2f) and is stouter than the femur of W. tuatahi, but less stout than the femora of Kairuku and Inkayacu. On the distal end, the fibular trochlea is strongly developed and there is a projecting tubercle for the gastrocnemialis lateralis muscle.
The tibiotarsus lacks the proximal end, but preserves the distalmost portion of the fibular crest (Fig. 2h). The distal end exhibits a crack, which disrupted the medial part of the bone, so that the condylus medialis appears to be unusually splayed. However, even when the bone is digitally restored (Fig. 2i), the shape of the distal end is highly characteristic in that the condyles are more widely spaced and proximodistally lower than in all other stem group Sphenisciformes, of which the tibiotarsus is known. The distal opening of the extensor sulcus is more medially positioned than in post-Paleocene Sphenisciformes, in which it is in a central position along the midline of the long axis of the tibiotarsus, but it is situated less medially than in Waimanu manneringi (Fig. 2j). The width of the distal end of the tibiotarsus is only exceeded by the very large Antarctic P. klekowskii specimens14 (these consist of a humerus fragment and a tarsometatarsus, but an estimate of the distal width of the tibiotarsus is possible, because this value corresponds to the proximal width of the tarsometatarsus; Table 1).
Results of the phylogenetic analysis
Our initial phylogenetic analysis based on the complete data set of ref. 8 resulted in a placement of Kumimanu in a clade including all other Sphenisciformes except W. manneringi and W. tuatahi, where it was recovered in a polytomy together with the much smaller Eocene taxa Perudyptes, Delphinornis, Marambiornis, and Mesetaornis (Supplementary Fig. 1). Analysis of the reduced and emended data set (Methods section) supports a position of K. biceae outside a clade including all post-Paleocene Sphenisciformes, and recovers the new species as sister taxon of a clade including all other Sphenisciformes except W. manneringi and W. tuatahi (Fig. 3).
Determining the size of extinct penguins from fragmentary remains is not straightforward as different species may have different proportions8. That Kumimanu biceae, n. gen. et sp. was an exceptionally large bird is, however, clear from the fact that the major limb bones are distinctly larger than those of most known Sphenisciformes (Table 1). Even our conservative estimate of 185 mm for the minimum total length of the humerus of K. biceae exceeds the humerus length of almost all other giant penguin species. The maximum estimate of 228 mm, which is based on the humerus proportions of other Paleocene Sphenisciformes, is only surpassed by an estimate based on very large fossils from the late Eocene of Antarctica, which were assigned to Palaeeudyptes klekowskii 14 (Table 1).
Based on published allometric equations (Table 1 in ref. 11) and a femur length of 161 mm, we calculate a weight of 101 kg and a body length of 1.77 m for K. biceae. These values exceed the weight and length estimates of all other stem group Sphenisciformes except for the exceptionally large specimens of P. klekowskii, for which a body length of about 2.0 m was estimated14. There exists no overlap between the bones of the holotype of K. biceae and those of the recently described large penguin foot bones from the Waipara Greensand (CM 2016.158.19)4. However, the proximal end of the tarsometatarsus of the latter species has a width of about 40.5 mm, and with a width of about 46 mm for the restored distal end of the tibiotarsus (Fig. 2j), K. biceae represents a larger bird. We therefore conclude that K. biceae is among the largest fossil penguins reported so far and may have been exceeded only in size by the above-mentioned fragmentary P. klekowskii specimens from the Eocene of Antarctica14.
K. biceae differs from post-Paleocene Sphenisciformes in the plesiomorphic presence of a flange-like dorsal cotylar process of the ulna and in the plesiomorphic absence of a coracoidal fenestra. As in W. tuatahi but unlike in C. unienwillia and all post-Paleocene Sphenisciformes, the humerus of K. biceae has a slender shaft. The widening of the scapular blade, the more centrally positioned extensor sulcus of the tibiotarsus, and the absence of distinct fossae on the lateral surfaces of the thoracic vertebrae supports a closer relationship of K. biceae to phylogenetically more crownward post-Paleocene Sphenisciformes than to W. manneringi and W. tuatahi.
The tarsometatarsus of the unnamed giant penguin from the Waipara Greensand (CM 2016.158.1) has a more derived morphology than the tarsometatarsus of Waimanu manneringi and W. tuatahi 4, but as the tarsometatarsus is unknown for K. biceae, the affinities between the latter species and CM 2016.158.1 can not be assessed. The exact relationships between K. biceae and the slightly younger Crossvallia unienwillia are also uncertain due to the poor preservation of the holotype of the latter species. However, K. biceae was much larger than C. unienwillia and had a proportionally narrower humerus shaft (Fig. 1k‒m).
Irrespective of the exact affinities between the new species and other Paleocene stem group Sphenisciformes, our study corroborates the observation of earlier authors4, 6, 11 that some sphenisciform species achieved a large size very early in the evolution of penguins. What is unexpected, however, is how fast these birds reached even their maximum size in the earliest Paleogene. That a penguin rivaling the largest previously known fossil species existed in the Paleocene may indicate that gigantism in penguins arose shortly after these birds became flightless divers. Gigantism therefore may be an inherent feature of Paleogene penguins, which may have evolved soon after aerodynamic constraints ceased to exist.
Kumimanu furthermore documents that a very large size occurred in a phylogenetically basal penguin, which in its osteological features closely resembles the Sphenisciformes from the Waipara Greensand. Because the new taxon is phylogenetically separated from the giant Eocene and Oligocene species by various smaller taxa, such as Perudyptes, Delphinornis, Mesetaornis, and Marambiornis (Fig. 3), a giant size must have evolved independently several times in penguin evolution.
There exists no correlation between palaeotemperatures and body size in fossil Sphenisciformes, with most giant taxa having evolved in a ‘greenhouse world’6, 18. The presence of giant penguins in the Paleocene shortly after the end-Cretaceous mass extinction event may indicate that these birds entered ecological niches left vacant after the extinction of large predatory marine reptiles2. An increase in body size over time is known for many groups of organisms, with this evolutionary trend (‘Cope’s Rule’) being due to positive, directional selection on population level, which benefits survival and mating success25. In penguins, a size increase may have also constituted a selective advantage in competition for suitable breeding grounds. A correlation with improved diving capabilities has likewise been discussed2.
To understand size evolution in penguins we therefore must not seek an explanation for the presence of giant species throughout the Paleogene, but one for the absence of equally large species in the Neogene and today. Earlier authors proposed that feeding competition with marine mammals played a role in the extinction of giant penguins and other very large wing-propelled diving birds7, 26, 27, and competition with gregarious pinnipeds for safe breeding was also considered28. The disappearance of giant penguins indeed coincides with the rise of marine mammals, that is, odontocete cetaceans and pinnipeds27, but the exact causes and mechanisms of a competitive replacement remain poorly understood. In any case, the evolution of penguins appears to have been strongly influenced by non-avian vertebrates: whereas the end-Cretaceous extinction of larger marine and terrestrial predators may have been the ecological driver for the loss of flight capabilities in the earliest Sphenisciformes, the radiation of pinnipeds and odontocetes towards the Oligocene27 seems to have terminated the existence of giant species towards the Miocene.
The fossils referred to here are in the collections of Canterbury Museum, Christchurch, New Zealand (CM); Museo de La Plata, La Plata, Argentina (MLP); Museum of New Zealand Te Papa Tongarewa, Wellington, New Zealand (NMNZ).
The phylogenetic analysis is based on a published morphological character matrix (245 characters, without nuclear sequence data)8. Character scoring for the new fossil is as follows: 122:1, 123:0, 129:0, 131:0, 136:1, 137:1, 139:0, 140:2, 141:0, 149:0, 150:0, 151:1, 154:2, 155:0, 156:1, 157:1, 159:0, 160:1, 161:0, 196:1, 199:1, 235:1; all other characters were scored as unknown (?). Based on our study of the published fossils and various new specimens24, character 140 (coracoidal fenestra) was scored as “2” (absent) for Waimanu tuatahi; the character was scored as “0” (complete) for Anthropornis nordenskjoeldi 29. Character 141 (foramen nervi supracoracoidei) was scored as “0” (absent) for W. tuatahi and A. nordenskjoeldi. Based on the referred tibiotarsi in ref. 10, character 199 (position of sulcus extensorius) was scored as “1” (close to midline of tibiotarsus) for Mesetaornis exilis, Marambiornis polaris, Delphinornis larseni, D. arctowskii, D. gracilis, D. wimani, Palaeeudyptes klekowskii, and P. gunnari. The nexus file used in the analysis can be found in the Supplementary Data 1. In a second analysis (Supplementary Data 2), we deleted most non-sphenisciform species from the data set and left only Phoebetria palpebrata (Diomedeidae, Procellariiformes) as an outgroup taxon. To improve the resolution of the resulting phylogeny, we furthermore restricted the coverage of crown group Sphenisciformes to six species and deleted fossil taxa, which are poorly represented or irrelevant for the present study (Palaeeudyptes antarcticus, Anthropornis sp. [UCMP 321023], Palaeospheniscus spp., Platydyptes spp., Duntroonornis, Archaeospheniscus spp., Eretiscus, Marplesornis, Madrynornis). For this second analysis, two characters were newly added: character 246 (dorsal supracondylar process of ulna) was scored as present (0) for P. palpebrata, W. tuatahi and the new taxon, absent (1) for Delphinornis larseni (based on a referred ulna in ref. 10), Anthropornis nordenskjoeldi, Palaeeudyptes klekowskii, Kairuku grebneffi, K. waitaki, Inkayacu paracasensis, Icadyptes salasi, and all extant sphenisciform species, and unknown (?) for all other species included in the analysis; character 247 (ratio of width of proximal end of humerus to width of shaft) was scored as 2.4 or more (0) for P. palpebrata, W. tuatahi and the new taxon, unknown (?) for Mesetaornis polaris, Marambiornis exilis, and Delphinornis spp., and < 2.4 (1) for all other species included in the analysis. All analyses were performed with the heuristic search modus of NONA 2.030 through the WINCLADA 1.00.08 interface31, using the commands hold 10,000, mult*1000, hold/10, and max*. Character ordering was as in ref. 8. Bootstrap support values were calculated with 200 replicates, ten searches holding ten trees per replicate, and TBR branch swapping without max*.
This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the International Code of Zoological Nomenclature. The ZooBank Life Science Identifiers for the taxa in this publication are http://zoobank.org/urn:lsid:zoobank.org:act:3EF7C725-A115-4A80-8FA8-2461342AEDEE and http://zoobank.org/urn:lsid:zoo-bank.org:act:596D5C8A-052A-48A4-81E2-67F0183BBAAA.
The nexus files used in the phylogenetic analysis are available in the Supplementary Data 1 and 2. All other datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.
Slack, K. E. et al. Early penguin fossils, plus mitochondrial genomes, calibrate avian evolution. Mol. Biol. Evol. 23, 1144–1155 (2006).
Ksepka, D. T. & Ando, T. in Living Dinosaurs. The Evolutionary History of Modern Birds (eds Dyke, G. & Kaiser, G.) Ch 6 (John Wiley and Sons, 2011).
Mayr, G. Avian Evolution: The Fossil Record of Birds and its Paleobiological Significance (Wiley-Blackwell, Chichester, 2017).
Mayr, G., De Pietri, V. L. & Scofield, R. P. A new fossil from the mid-Paleocene of New Zealand reveals an unexpected diversity of world’s oldest penguins. Sci. Nat. 104, 9 (2017).
Jadwiszczak, P., Acosta Hospitaleche, C. & Reguero, M. Redescription of Crossvallia unienwillia: the only Paleocene Antarctic penguin. Ameghiniana 50, 545–553 (2013).
Tambussi, C. P., Reguero, M. A., Marenssi, S. A. & Santillana, S. N. Crossvallia unienwillia, a new Spheniscidae (Sphenisciformes, Aves) from the late Paleocene of Antarctica. Geobios 38, 667–675 (2005).
Simpson, G. G. in The Biology of Penguins (ed. Stonehouse, B.) Ch 2 (Macmillan Press, 1975).
Ksepka, D. T., Fordyce, R. E., Ando, T. & Jones, C. M. New fossil penguins (Aves, Sphenisciformes) from the Oligocene of New Zealand reveal the skeletal plan of stem penguins. J. Vertebr. Paleontol. 32, 235–254 (2012).
Jadwiszczak, P. Partial limb skeleton of a “giant penguin” Anthropornis from the Eocene of Antarctic Peninsula. Pol. Polar Res. 33, 259–274 (2012).
Jadwiszczak, P. Eocene penguins of Seymour Island, Antarctica: taxonomy. Pol. Polar Res. 27, 3–62 (2006).
Jadwiszczak, P. Body size of Eocene Antarctic penguins. Pol. Polar Res. 22, 147–158 (2001).
Acosta Hospitaleche, C. & Reguero, M. Palaeeudyptes klekowskii, the best-preserved penguin skeleton from the Eocene–Oligocene of Antarctica: Taxonomic and evolutionary remarks. Geobios 47, 77–85 (2014).
Acosta Hospitaleche, C. Paleobiological remarks on a new partial skeleton of the Eocene Antarctic penguin Palaeeudyptes klekowskii. Ameghiniana 53, 269–281 (2016).
Acosta Hospitaleche, C. New giant penguin bones from Antarctica: systematic and paleobiological significance. C. R. Palevol. 13, 555–560 (2014).
Acosta Hospitaleche, C. & Olivero, E. Re-evaluation of the fossil penguin Palaeeudyptes gunnari from the Eocene Leticia Formation, Argentina: additional material, systematics and palaeobiology. Alcheringa 40, 373–382 (2016).
Acosta Hospitaleche, C. & Reguero, M. First articulated skeleton of Palaeeudyptes gunnari from the late Eocene of Isla Marambio (Seymour Island), Antarctica. Antarct. Sci. 22, 289–298 (2010).
Jenkins, R. J. F. A new giant penguin from the Eocene of Australia. Palaeontol. 17, 291–310 (1974).
Clarke, J. A. et al. Paleogene equatorial penguins challenge the proposed relationship between penguin biogeography, diversity, and Cenozoic climate change. Proc. Natl Acad. Sci. USA 104, 11545–11550 (2007).
Clarke, J. A. et al. Fossil evidence for evolution of the shape and color of penguin feathers. Science 330, 954–957 (2010).
Chávez Hoffmeister, M. Phylogenetic characters in the humerus and tarsometatarsus of penguins. Pol. Polar Res. 35, 469–496 (2014).
Fordyce, R. E. in Vertebrate Palaeontology of Australasia (eds Vickers-Rich, P., Monaghan, J. M., Baird, R. F. & Rich, T. H.) Ch 26 (Pioneer Design Studio, 1991).
Morgans, H. E. G. Late paleocene to middle eocene foraminiferal biostratigraphy of the hampden beach section, eastern South Island, New Zealand. NZ J. Geol. Geophys. 52, 273–320 (2009).
Crouch, E. M. & Brinkhuis, H. Environmental change across the Paleocene–Eocene transition from eastern New Zealand: a marine palynological approach. Mar. Micropaleontol. 56, 138–160 (2005).
Mayr, G., De Pietri, V. L., Love, L., Mannering, A. A. & Scofield, R. P. A well-preserved new mid-Paleocene penguin (Aves, Sphenisciformes) from the Waipara Greensand in New Zealand. J. Vertebr. Paleontol. (in press, 2017).
Kingsolver, J. G. & Pfennig, D. W. Individual-level selection as a cause of Cope’s rule of phyletic size increase. Evolution. 58, 1608–1612 (2004).
Fordyce, R. E. & Jones, C. M. in Penguin Biology (eds Davis, L. S. & Darby, J. T.) Ch 18 (Academic Press, 1990).
Ando, T. & Fordyce, R. E. Evolutionary drivers for flightless, wing-propelled divers in the Northern and Southern Hemispheres. Palaeogeogr. Palaeoclimatol. Palaeoecol. 400, 50–61 (2014).
Warheit, K. I. & Lindberg, D. R. in Seabirds and Other Marine Vertebrates: Competition, Predation, and Other Interactions (ed. Burger, J.) Ch 9 (Columbia University Press, 1988).
Ksepka, D. T., Bertelli, S. & Giannini, N. P. The phylogeny of the living and fossil Sphenisciformes (penguins). Cladistics 22, 412–441 (2006).
Goloboff, P. A. NONA v. 2.0 (de Tucumán, S. M. 1993).
Nixon, K. C. WinClada, v.1.00.08 (Ithaca, NY, 2002).
Ksepka, D. T., Clarke, J. A., DeVries, T. J. & Urbina, M. Osteology of Icadyptes salasi, a giant penguin from the Eocene of Peru. J. Anat. 213, 131–147 (2008).
Stephan, B. Vergleichende Osteologie der Pinguine. Suppl. Ann. Ornithol. 3, 3–98 (1979).
We are indebted to Al Mannering for the preparation of the penguin fossil. Chris Clowes (GNS Science) provided data on the dinoflagellate fauna associated with the fossil. Jean-Claude Stahl (NMNZ) took the overview photos of the fossil before final preparation. We furthermore thank Carolina Acosta Hospitaleche, Martin de los Reyes, and Nadia Haidr (all MLP), and Ewan Fordyce and Marcus Richards (both Otago University) for access to fossil specimens. This research was supported by a grant from the Marsden Fund Council from New Zealand Government funding, managed by Royal Society Te Apārangi; the publication costs were covered by the RS Allan Fund.
The authors declare no competing financial interests.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Mayr, G., Scofield, R., De Pietri, V.L. et al. A Paleocene penguin from New Zealand substantiates multiple origins of gigantism in fossil Sphenisciformes. Nat Commun 8, 1927 (2017). https://doi.org/10.1038/s41467-017-01959-6
Oldest, smallest and phylogenetically most basal pelagornithid, from the early Paleocene of New Zealand, sheds light on the evolutionary history of the largest flying birds
Papers in Palaeontology (2021)
Early Plotopteridae Specimens (Aves) from the Itanoura and Kakinoura Formations (Latest Eocene to Early Oligocene), Saikai, Nagasaki Prefecture, Western Japan
Paleontological Research (2021)
Leg bones of a new penguin species from the Waipara Greensand add to the diversity of very large-sized Sphenisciformes in the Paleocene of New Zealand
Alcheringa: An Australasian Journal of Palaeontology (2020)
New mammalian and avian records from the late Eocene La Meseta and Submeseta formations of Seymour Island, Antarctica