First fossil frog from Antarctica: implications for Eocene high latitude climate conditions and Gondwanan cosmopolitanism of Australobatrachia
Author
Mörs, Thomas
Department of Palaeobiology, Swedish Museum of Natural History, P. O. Box 50007, SE- 104 05, Stockholm, Sweden
thomas.moers@nrm.se
Author
Reguero, Marcelo
Instituto Antártico Argentino, Campus Miguelete, 25 de Mayo 1151, 3 ° piso B 1650 HMK, San Martín, Buenos Aires, Argentina
Author
Vasilyan, Davit
Department of Geosciences, University of Fribourg, Chemin du musée 6, 1700, Fribourg, Switzerland
text
Scientific Reports
2020
2020-04-25
10
5051
1
11
journal article
10.1038/s41598-020-61973-5
b42c7378-ff6d-40fc-98da-c1f2ea5649a3
PMC7181706
32327670
3766727
Calyptocephalella
sp.
Figures 2
and
3
Referred specimens.
Swedish Museum of Natural History
NRM-PZ B282
, right ilium (
Fig. 2
),
NRM-PZ
B281
, skull bone (
Fig. 3
).
Locality, horizon and age.
IAA 2/95, Marsupial site, Seymour Island, Antarctic Peninsula
(
64°13′58″S
;
56°39′06″W
). ‘
Natica
horizon’ within the
Cucullaea I Allomember
(Telm 5) of the La Meseta Formation, Bartonian (40Ma), Eocene
23
,
24
(
Fig. 1
).
Figure 2.
Ilium (NRM-PZ B282) of
Calyptocephalella
sp. from Seymour Island, Antarctica. Ilium in lateral (
a
), medial (
b
), ventral (
c
) and dorsal (
d
) views. Magnified region of the dorsal protuberance in lateral (
e –
dashed rectangle in orange color) and dorsal (
f –
dashed rectangle in yellow color) view. The dashed line in black on (
a
) indicates the probable outline of the posterior extension of the ventral acetabular expansion. The asterisk (
*
) on (
a
,
c
) indicates the shallow and broad depression of the ventral acetabular expansion. The double asterisk (
**
) indicates the notch caudally from the dorsal protuberance. The dashed red lines on (
e
,
f
) outline the intact bone surface. Abbreviations: ac, acetabulum; ar, acetabular rim; dae, dorsal acetabular expansion; is, iliac shaft; paf, preacetabular fossa; spf, supraacetabular fossa; vae, ventral acetabular expansion; vd, ventral depression.
Measurements.
The preserved part of the ilium measures 3.9 mm in length, the distance from the tip of the dorsal acetabular expansion to the (preserved) tip of the ventral acetabular expansion measures 3.3mm, the highest height of the acetabular fossa equals 2.5 mm. The skull bone measures 2.7 mm at its both broadest and longest parts.
Ilium.
The fragmentary right ilium (NRM-PZ B282) lacks the caudal portion of the acetabulum and most of the iliac shaft. The dorsal acetabular expansion has a smooth lateral surface and is higher than the preserved part of the ventral acetabular expansion (
Fig. 2a
). A large and deep supraacetabular fossa is present at its base (
Fig. 2a,d
). The preserved portion of the acetabulum is concave and its shape allows concluding a (semi-)circular outline. The acetabular rim is most prominent at its anterior part (
Fig. 2a,c
). The barely-developed ventral acetabular expansion projects ventrally. The posterior-most portion of the ventral acetabular expansion is broken off. However, the anterior portion of the ventral acetabular expansion is higher than the preserved posterior portion. In ventral view (
Fig. 2a,c
), the lateral surface of the ventral acetabular expansion is convex. The ventral acetabular expansion possesses a shallow and broad depression. In the preacetabular zone, a small and shallow preacetabular fossa is present (
Fig. 2c
). The preserved portion of the iliac shaft is damaged and precludes a confident statement whether the dorsal protuberance is present or absent. A narrow and shallow longitudinal groove is observable in the lateral surface of the iliac shaft, which probably corresponds to the posterior extension of the ventral depression (sensu
10
) (
Fig. 2a
). However, intact parts of bone surface are preserved slightly ventral to the dorsal margin on both lateral and medial surfaces (
Fig. 2e,f
). The one on the lateral surface is a curved shallow groove and runs posteroventrally (
Fig. 2e
). This feature anteroventrally demarcates the slightly elevated roughened scar interpreted above as the dorsal protuberance. The area between the dorsal acetabular expansion and iliac shaft is slightly projected dorsally. This area corresponds to the position of the dorsal protuberance. In fact, no clear evidence of a dorsal protuberance can be found on the ilium, only a slightly roughened area with minimal elevation that corresponds to the dorsal protuberance and the scar for the insertion of the musculus gluteus magnus can be observed. At the caudal side of the dorsal protuberance, a distinct notch is visible (
Fig. 2a
) which we consider as a further evidence of our interpretation. The area corresponding to the dorsal protuberance is located anteriorly to the anterior margin of the acetabular rim. Medially, the entire surface opposing the acetabulum is lost and the area preserved more anteriorly is slightly convex medially and smooth. Anteriorly and dorsally, just adjacent to the anterior end of the dorsal protuberance a foramen is present (
Fig. 2b
).
Figure 3.
Skull bone fragment (NRM-PZ B281) of
Calyptocephalella
sp. from Seymour Island, Antarctica in dorsal (
a
), ventral (
b
) and lateral (
c
) views.
|
species
|
locality
|
coll nr.
|
SVL (in mm)
|
HT (in mm)
|
RHS (in %)
|
Reference
|
|
C. pichileufensis
|
Río Pichileufú locality |
BAR 85b |
107 |
6 |
5.6 |
48
: Figs.2 and 4
|
|
C. gayi
|
unknown |
M13105/cas:sua:10082
*
|
54.7 |
2.9 |
5.3 |
65
, see Fig.S3
|
| range |
5.3–5.6 |
| mean ± SD |
5.45 ± 0.21 |
|
C
. sp.
|
IAA 2/95, Marsupial site |
NRM-PZ B282 |
38.4 ± 3.8
|
2.1
|
Present work |
Table 1.
Measurements of the snout-vent length (SVL) and height of the transition from the iliac shaft and ilial body (HT) of some
Calyptocephalella
spp. and Antarctic ilia (Fig. S3), with the value of the ratio between HT and SVL (RHS = HT/SVL
*
100%) with the value of the standard deviation (SD). The reconstructed value of the snout-vent length of the studied ilium is highlighted in bold.
The fragmentary right ilium can be referred to an anuran based on the following characters
30
(the numbers before the characters correspond to the feature numbers of Appendix 1 in Gardner
et al
.
30
):
7
. (semi-) circular acetabulum;
9
. acetabulum with distinct margins;
10
. acetabular surface concave;
13
. at least dorsal acetabular expansion is strongly divergent;
18
. the dorsal protuberance present. Thus, the ilium derives from a small-sized frog (3.8 ± 0.4 cm snout-vent length, see methods,
Table 1
). The specimen is partly eroded and rather poorly preserved; however, it can be compared with all South American and Australian frog families (
Figs. 4
, S
1
and S
2
,
Table S1
). The families
Ranidae
,
Bufonidae
and
Hylidae
have not been illustrated in the present work, since their morphology is well known
31
(
Table S1
). The comparison has been done at family level, since the ilia display diagnostic features characteristic for identification of the family (dimensions of the dorsal and ventral acetabular expansions; location of the dorsal protuberance relative to the anterior margin of the acetabular rim etc.
32
,
33
). The studied ilium (NRM-PZ B282) differs in: (1) Reduced anterior portion of the dorsal acetabular expansion from nearly all South American and Australian frog families and the genus
Telmatobufo
, which have moderately or strongly developed anterior portion of the dorsal acetabular expansion. Only the genus
Calyptocephalella
(
Fig. 4c,e
), the families
Ranidae
31
,
Pipidae
(
Fig. S1a
),
Rhinodermatidae
(
Fig. S1j
), and
Leptodactylidae
(
Fig. S2b
) have similar state/morphology of this character. (2) Dorsal protuberance located either at the level of or anteriorly from the anterior margin of the acetabular rim from nearly all families, besides
Brachycephalidae
(
Fig. S1a
),
Rhinodermatidae
(
Fig. S1j
),
Telmatobiidae
(
Fig. S1k
), Hyloididae (
Fig. S1m
),
Leptodactylidae
(
Fig. S2b
) and the genera
Calyptocephalella
(
Fig. 4
b–e) and
Telmatobufo
(
Fig. 4g,h
). (3) Developed dorsal acetabular expansion from the families
Ranidae
31
,
Hylidae
31
,
Bufonidae
31
,
Myobatrachidae
(
Fig. 4i
),
Pipidae
(
Fig. S1i
),
Microhylidae
(
Fig. S1b
),
Telmatobiidae
(
Fig. S1k
),
Leptodactylidae
(
Fig. S2b
),
Allophrynidae
(
Fig. S2c
),
Centrolenidae
(
Fig. S2d
) and the genus
Telmatobufo
(
Fig. 4g,h
). Other families have moderately or well-developed dorsal acetabular expansion, however, due to incomplete preservation of the Antarctic frog remain any further comparison is impossible. (4) Weakly developed dorsal protuberance and lack of dorsal tubercle from nearly all families (e.g.
Limnodynastidae
,
Fig. 4j
), besides
Calyptocephalellidae
(
Fig. 4
b–e,g,h),
Myobatrachidae
(
Fig. 4i
),
Craugastoridae
(
Fig. S1e
), and Dendrabatidae (
Fig. S2e
).
Figure 4.
3D models of some skeletal elements of Australobatrachia. (
a,f
) skull and (
b–e
,
g–j
) ilia of
Calyptocephalella gayi
(
a–e
);
Telmatobufo venustus
(
f–h
);
Myobatrachus gouldii
(
i
);
Limnodynastes convexiusculus
(
j
). Collection numbers of each specimen are listed in Table S1.
Among the compared forms, only the South American endemic genus
Calyptocephalella
resembles all mentioned four characters. In addition to this, a shallow and broad depression on the anterior portion of the ventral acetabular expansion is a unique character observable on our ilium (NRM-PZ B282) and Recent
Calyptocephalella gayi
(
Fig. 4
). Further, the fossil ilium displays a ventral depression on its lateral surface anteriorly to the acetabulum (
Fig. 2c
), a comparable structure can be observed also in the fossil species
Calyptocephalella canqueli
9
but not in the Recent species
C. gayi
(
Fig. 4
).
Skull element.
The second bone fragment (NRM-PZ B281) is flat and slightly curved. Both sides of the bone have different structures. One surface is covered by small to large circular or reniform in outline, rather deep pits, which sink in the planar surface of the bone (
Fig. 3a
). The diameters of pits vary from 0.1–0.7 mm and some of them are punctured by foramina. The opposite surface of the bone is in general smooth, slightly deepened and is pierced with some foramina, some of which are preceded by a groove (
Fig. 3b
). One side of the fragment preserves an unbroken margin of the original bone with a distinct process that is bent and that gives the bone a curved shape (
Fig. 3c
). The ornamented surface of the bone projects slightly over this process. Comparable ornamentation, build of pits of different size, is found on the dorsal surfaces of different cranial and postcranial bones of amphibians and reptiles
34
,
35
. Among them, the following groups can be excluded from consideration: (1)
Albanerpetontidae
(
Allocaudata
); albanerpetontids are a primary Laurasian lissamphibian group with a single occurrence in Northern Africa. So far no evidence of a Gondwanan radiation of albanerpetontids exists
36
. In addition to this, all their ornamented bones (e.g. frontal, premaxillae)
37
do not resemble the bone described here. (2)
Caudata
; salamanders are also considered as a Laurasian group, with a number of occurrences in Africa which need critical revision
38
. In salamanders, ornamented bones are found both among skull bones and on vertebrae (on plates located on the tip of the neural arch)
39
. Bone ornamentation here (e.g.
Tylototriton, Chelotriton, Echinotriton
39
,
40
) is represented by a network of pits, ridges and pointy spines that do not resemble the bone described here. (3) Crocodylia; in crocodyliforms, comparable patterns of ornamentation with well-developed pits appear only with growth during later ontogenetic stages
41
–
43
. On one hand, the bone dimensions indicate a small-sized animal (corresponding to a juvenile crocodilian without such developed ornamentation). On the other hand, crocodylian osteoderms are flat without any processes, unlike the studied bone. (4)
Testudines
; shell plates of several turtles, such as
Trionyx, Allaeochelys
etc
.
35
, are also covered by ornamentation. The ornamentation is characterized by larger and closely arranged pits, which are not always clearly delimited from each other (see Scheyer
35
:
Fig. 1a
). (5) Lacertilia; lizards also have skull bones and osteoderms covered with ornamentation patterns
44
. They all are characterized by a network of spines, grooves, ridges
45
and protuberances
46
, which differs from the morphology on NRM-PZ B281.
The ornamentation pattern found in NRM-PZ B281 is comparable to that of some frog genera, i.e.
Thaumastosaurus
47
,
Beelzebufo
48
,
Calyptocephalella
9
and
Baurubatrachus
49
, but only the last three genera are Gondwanan forms and, thus, considered for comparison herein.
Beelzebufo
is a very large form and the ornamentation pattern is present both on skull bones and on vertebrae
50
.
Calyptocephalella
9
and
Baurubatrachus
49
have very similar ornamentation patterns on the surfaces of hyperossified skull bones, comparable to our specimen. A recent phylogenetic analysis
49
placed the Late Cretaceous
Baurubatrachus
within both Recent calyptocephalellid genera
Calyptocephalella
and
Telmatobufo
. Though Muzzopappa and Báez
10
mention that both
Calyptocephalella
and
Telmatobufo
are characterized by a heavily ossified neurocranium, we can confirm this only for the former genus (
Fig. 4a,f
). Within
Calyptocephalella
the ornamentation pattern on skull bones is variable. In
C. conquella
10
, it is built either by network of pits in small individuals, or tuberculated ornamentation in adults. In
C. satan
9
and
C. casamayorensis
51
, ornamented skull bones are slightly larger than NRM-PZ B281 but they have a similar pattern built of pits.
C. pichifleufensis
48
is known by larger individuals which show similar ornamentation patterns but with larger pits. In comparison to these species, the Antarctic frog displays an ornamentation most similar to that of
C. satan
9
and
C. casamayorensis
48
. Taking into account our comparison, we conclude that the ornamented bone fragment NRM-PZ B281 represents a skull bone (most probably a nasal) of a small-sized
Calyptocephalella
or
Baurubatrachus
. Given the presence of a small
Calyptocephalella
as indicated by the ilium in the same, only few m
2
measuring outcrop, it is most likely that specimen NRM-PZ B281 belongs to the same genus. A comparable record of an ilium and ornamented bones referable to the genus
Calyptocephalella
has been mentioned in Báez
52
.
Discussion
Among Recent amphibians, the frogs (
Anura
) have the widest distribution, covering all continents except Antarctica, where the conditions have been uninhabitable for over tens of millions of years. Contrary to all other continents, no traces of any extant amphibian group, all of which belong to the lissamphibian clade, have been documented from Antarctica. This paper presents the first record of a lissamphibian in Antarctica, with Eocene fossils referable to the order
Anura
, and most likely to the australobatrachian genus
Calyptocephalella
. The family
Calyptocephalellidae
belongs to neobatrachian frogs and is exclusively known from South America
53
,
54
. The five extant species, including the monospecific genus
Calyptocephalella
with hyperossified skull bones, are restricted to the Chilenean Andes
54
while most fossil representatives are known from Argentine Patagonia
9
,
48
,
53
. Today,
Calyptocephalella
inhabits lowland areas of central Chile (upper elevation limit 500 m) east of the Andes within temperate and humid climates, between latitudes 30–43°S. It has an aquatic or semiaquatic lifestyle and populates standing or slow flowing water bodies (lakes, ponds, streams) in the Valdivian temperate
Nothofagus
forests
54
–
56
.
The oldest fossils referable to
Calyptocephalella
are known from the Upper Cretaceous of Argentina
9
,
52
. During the Paleocene–terminal early Miocene, their geographic range was restricted to Patagonia east of the Andes
48
,
51
,
53
,
57
. Not until the late Pleistocene did they appear west of the Andes, where they have their endemic present-day distribution
54
–
57
.
The clade Australobatrachia comprises Myobatrachoidea (families
Myobatrachidae
+
Limnodynastidae
sensu
27
), nowadays distributed in Australia and south of New Guinea, and the family
Calyptocephalellidae
(
Batrachophrynidae
sensu
27
). Australobatrachia are considered as a stem group of the Hyloidea. The earliest myobatrachoid from Australia is at least as old as early Eocene, based on fragmentary ilia that were referred to the basal extant
Lechriodus
58
. The split between
Calyptocephalellidae
and
Myobatrachidae
(
Calyptocephalellidae
+ Myobatrachoidea sensu
27
) occurred ~100 Ma (~Early-Late Cretaceous boundary)
59
. Considering the distributions of extant Australobatrachia (
Fig. 5
), the earliest fossil records
10
and the divergence age (from genetic data)
59
of both
Calyptocephalellidae
and Myobatrachoidea lineages, it is clear that Antarctica had played an important palaeobiogeographic role for Australobatrachia and their consequent dispersal. Because the most recent common ancestor of the clade, including Hyloidae and
Myobatrachidae
+
Calyptocephalellidae
, occurred in South America, their origin in South America and consequent dispersal from South America to Australia via Antarctica has been suggested
59
. Additionally, this suggests one more case of strong faunistic affinities of the continent with South America and Australia
4
,
6
,
16
,
60
. So far, Antarctica has been considered as a dispersal route, but not as a probable place of origin. The new fossil finds support the hypothesis
10
that Antarctica may have acted as a center of diversification for australobatrachians.
The Seymour Island frog reported herein is the first vertebrate indicative of freshwater habitats on the Eocene Antarctic Peninsula, following invertebrate and plant evidence
12
,
17
(
Fig. 6
). It is interesting to note that nearly all fossil localities where
Calyptocephalella
occurs (excepting those, for which fossil plant data are not available) contain evidence of the presence of
Nothofagus
, including Seymour Island
16
,
60
,
61
. The southern extant range of
Calyptocephalella
occurs sympatrically with the microbiotherian marsupial
Dromiciops gliroides
(
Fig. S4
), also known as “Monito del Monte” or “Colocolo Opossum”, a small mammal with an arboreal lifestyle and an endemic
Figure 5.
Eocene palaeogeography of the south polar region with a cladogram of australobatrachid frogs showing their occurrences on the southern continents. The grey color indicates the outlines of the continents during the Eocene, the black colored outline the present-day outlines of the continents. Map redrawn from an original generated using ArcGIS 10.17.1 (www.esri.com) software, based on the Satellite base map layer in google Maps (Map data ©2019 Google). Abbreviations: ANT, Antarctica; AUS, Australia and Tasmania; NG, New Guinea; NZ, New Zealand; SA, South America. The red star indicates the fossil locality on Seymour Island.
distribution in the dense Valdivian
Nothofagus
forests of highland Argentina and Chile
62
. The climate of this
Nothofagus
forest area with the sympatric occurrences of these two endemic animals shows humid and temperate conditions (for the numerical values, see Methods and
Table 2
,
Fig. S4
).
Dromiciops gliroides
is the only extant species of the order
Microbiotheria
and is considered as the only South American representative of the superor- der Australidelphia which otherwise comprises Australian marsupials
63
. From the same small shell-rich lens that produced the frog remains reported herein, the fossil microbiotherian
Woodburnodon casei
has been described
64
. Hence, we hypothesize that the climatic conditions for the Antarctic Peninsula during the Bartonian (late middle Eocene) should be comparable with the climate found today in the concurrent range of the
Calyptocephalella-
and
Dromiciops
-inhabited
Nothofagus
forests of South America.
The fossil finds of a frog and marsupial from Seymour Island, and their fossil and Recent distributions, represent outstanding examples of the role of global climate change on shifting biogeographic ranges. Despite global cooling and the disappearance of the habitats of these groups over large areas from Antarctica to Patagonia, they maintained their relictual occurrence in the
Nothofagus
forests of the central Chilean Andes. Thus, the Valdivian
Nothofagus
forest is a unique environment offering habitats not only for Eocene Antarctic refugees but also provides a modern analogue of the Antarctic climate just prior to the glaciation of the southern continent.