Introduction

The rise of the Tibetan Plateau is generally held responsible for the climatic cooling and monsoon intensification during the Cenozoic1,2,3. However, the history of the plateau has been fiercely debated, with conflicting uplift models proposed4. Some recent palaeoaltimetry studies, including those isotope-based ones5,6,7, suggest the establishment of near-present high elevations and harsh environment in the Tibetan interior since the Eocene or late Oligocene (~50–26 Ma)5,6,7,8,9 or some high and east-west trending mountain ranges in southern and northern plateau since Palaeocene10. Other tectonic models propose much younger uniform11 or northward stepwise uplift events since late Eocene12. Compared to the prevailing abiotic (tectonic, geophysical and geochemical, etc.) data, palaeobiological evidence bearing on timelines for uplift is scant, especially for the vast interior plateau5,6,7,8,9. Among the biotic proxies, plant megafossils, fishes and other vertebrates are environmentally sensitive and thus promising candidates for constraining the uplift of the plateau13,14,15,16,17,18,19,20,21,22. In addition to a fragmentary forelimb bone of an early Miocene fossil rhino20, only two late Oligocene to early Miocene fossil cyprinid (carps) species have been reported to date from the vast central area of the plateau. One is a primitive snow carp, Plesioschizothorax macrocephalus Wu et Chen16, 19, which has living relatives endemic to the plateau and its periphery17, 18. The other, Tchunglinius tchangii Wang et Wu, is a barbine carp, related to a lineage otherwise currently distributed in South Asia and Africa21. Both of these fishes were probably inhabitants of comparatively low altitudes16,17,18,19, 21. The plant megafossils from the interior of the plateau are even less common; there is but one barberry species formally reported from the Miocene Hox Xil basin in the northern plateau that possibly suggests an elevation ~2–3 km lower than modern-day levels14. Our recent discovery of a dozen well-preserved skeletons of a fossil climbing perch (Perciformes: Anabantidae) (Figs 1 and 2, Supplementary Figs 35) together with fifty exquisitely-preserved plant megafossils (Fig. 3) from the upper Oligocene (ca. 26~23.5 Ma) of the Nima and Lunpola basins in central Tibet (Supplementary Figs 1 and 2, and see Supplementary Information) is an important addition to the fossil record of the Tibetan Plateau. These fossils represent a biota that comprises ideal environmental indicators of warm and humid environment at low elevations.

Figure 1
figure 1

A new fossil climbing perch, Eoanabas thibetana gen. et sp. nov. from the upper Oligocene of central Tibet. It resembles its extant tropical relatives in having a labyrinth organ for air breathing and postocular contact organ in male fishes for stimulating the female during a mating clasp. (a) Photograph and (b) line drawing of holotype (IVPP V22782a), image horizontally rotated. (c) Photograph and (d) line drawing of the head of IVPP V18412a, red area in (d) representing muscular attachment facet. Abbreviations: alm, attachment facet of levator operculi muscle; Cbr1, ceratobranchial of first gill arch; op.st, V-shaped struts on inner side of opercles.

Figure 2
figure 2

Fossil climbing perch, Eoanabas thibetana gen. et sp. nov. from the upper Oligocene of central Tibet. (a) Line drawing of the head of IVPP V18414a. (b) Photograph of IVPP V18414a. (c) Photograph of IVPP V18581a. (d) Scanning Electron Microscope (SEM) images of relics of labyrinth organ in (c), arrows pointing the pores on the lamellae. (e) Computerized tomography of labyrinth organ (lateral view) of Anabas testudineus (OP 435). (f) Cleared and stained head showing the labyrinth organ and associated structures of Anabas testudineus (collection no. OP 432). (g) Cleared and stained specimen of Anabas testudineus (collection no. OP 433). (h) Osteological restoration of Eoanabas, purported male; not to scale. Images in (c), (d) are horizontally rotated. Abbreviations: br, branchiostegal rays; hp1, hypural 1; m., muscle; php, parhypural.

Figure 3
figure 3

Plant megafossils associated with Eoanabas, showing the taxonomic and morphological diversity of the plant assemblage. (a) Palmate leaf of palm, IVPP B 2505. (b) Capsular valve of Koelreuteria sp., a golden rain tree, IVPP B 2506. (c) Leaflet of Pistacia sp., IVPP B 2508. (d) Winged fruit of Cedrelospermum sp., IVPP B 2510. (e) Undetermined toothed leaf, IVPP B 2519. (f) Undetermined entire-margined leaf, IVPP B 2518. (g) Undetermined toothed leaf, IVPP B 2527. (h) Infructescence of probable Araceae, IVPP B 2535. (i) Leaf of Araliaceae, IVPP B 2515. (j) Palmately compound leaf of Handeliodendron sp., with six leaflets, IVPP B 2513. (k) Leaf fragment of Limnobiophyllum sp., IVPP B 2514. (l) Leaf of Exbucklandia sp., IVPP B 2516. (m) Leaf of Magnoliales, IVPP B 2526. (n) Undetermined entire-margined leaf, IVPP B 2525. (o) Populus sp., IVPP B 2523. (p) Undetermined entire-margined leaf, IVPP B 2517. (q) Leaf fragment of Typha sp., IVPP B 2529.

The climbing perches (anabantid fishes) are closely related to kissing gouramies and fighting fishes23,24,25 in the perciform suborder Anabantoidei (labyrinth fishes)25. They are common in freshwaters in tropical Asia and sub-Saharan Africa23, 24. Their labyrinth organs are so large that they occupy a large portion of the gill chamber. In fact, their tissues are not sufficient to meet the respiratory needs, and they are therefore obligatory air-breathers24. The capability of accessary air breathing allows some of anabantids to move onto land under moist conditions, or even reputedly climb trees, thus earning the common name “climbing perch”23.

Results

Systematic Palaeontology of Fossil Climbing Perch

Teleostei Müller, 1845

Anabantiformes sensu Wiley and Johnson, 2010

Anabantoidei sensu Lauder and Liem, 1983

Anabantidae Bonaparte, 1839

Eoanabas thibetana gen. et sp. nov.

Etymology. The generic name combines ‘Eo-’ (Greek, early/primeval) with ‘Anabas’, the type genus of Anabantidae from tropical Asia. The specific name refers to Tibet, China.

Holotype. IVPP V 22782, a complete skeleton, part and counterpart (Fig. 1a,b).

Paratypes. Sixteen specimens are designated as paratypes (Supplementary Information).

Locality and Horizon. Jiangnongtangga (type locality) and Songwori in south Nima Basin and Dayu in Lunpola Basin in central Tibet (Supplementary Figs 1 and 2). Middle-upper part of Dingqing Formation, late Oligocene (Chattian) (ca. 26~23.5 Ma)6, 20, 26.

Diagnosis. A labyrinth fish displaying anabantid characteristics including a posterior notch of the opercle bounded by spines, a V-shaped strut on inner side of opercle and six to nine anal-fin spines. It shares with Asian anabantids the following derived characters: broad infraorbitals 3–5 completely covering the cheek, a sensory canal pore just behind sphenotic/pterotic junction and pelvic plate lying flat; and it shares with African anabantids some derived characters, e.g., sensory canal opening in between the infraorbitals, supraorbital commissure of the sensory canal absent and male postocular contact organ present.

Description

The body is oblong with long-based dorsal and anal fins comprising anterior spinous and posterior soft-ray sections, a thoracic pelvic fin anteceded by a spine, and a truncated caudal fin (Figs 1a,b and 2b,c,h, Supplementary Figs 3a,b,i,j, 4a–e, j–m and 5a,b,d–f).

The skull roof is smooth. The frontals carry paired coronal pores on the supraorbital sensory canals (Fig. 1a,b and Supplementary Fig. 3a,b) and, as in the species of African Microctenopoma 24, lack the supraorbital commissure. The circumorbital bones include a ventrally serrated lacrimal and broad infraorbitals 3–5 covering the cheek completely (Figs 1 and 2a, Supplementary Fig. 5a,b). Similarly large infraorbitals are only seen in Anabas (Fig. 2g); however, the sensory pores are open between these elements, a character known only in African anabantids24. Just posterior to the sphenotic/pterotic junction, the pterotic bears a sensory opening (Fig. 1 and Supplementary Fig. 5a,b), which is present in Anabas but not in African forms24. More posteriorly, it has a depressed attachment facet for the levator operculi muscle (Fig. 1c,d and Supplementary Fig. 5a,b) as in living anabantids24. Immediately ventral to this facet is the suprabranchial chamber (Fig. 1c,d) housing the labyrinth organ referred to below. The parasphenoid shaft is straight without oral or orbital processes (Supplementary Figs 3a,b,g and 4j–m), and the transverse process is likely present (Supplementary Fig. 3h).

The opercle has a round posterior notch bounded by two large spines or spine patches (Figs 1c,d and 2a,b, Supplementary Figs 3a,b and 5a,b) and a V-shaped strut on the inner side emerging from the articular socket with the hyomandibular (Figs 1a,b and 2c, Supplementary Figs 3a,b, 4k and 5a,b).

The maxilla is relatively short and stout with a clubbed posterior end (Figs 1 and 2a,b). Stout and recurved teeth occur on the anterior oral edges of the premaxilla and dentary (Figs 1a,b and 2a, Supplementary Figs 3f and 4k).

The ventral postcleithrum directly contacts the flat lying pelvic plate (Fig. 1a,b and Supplementary Fig. 3g), which resembles that of Anabas, but differs from the dorsally angled one in African forms24.

The long-based dorsal and anal fins show relatively low numbers of anal spines (7–9) and soft rays (7–9) in both fins (Figs 1a,b and 2b,c, Supplementary Figs 3a,b,i,j, 4a–e, j–m and 5a,b,d–f, and Supplementary Table 1). The truncated caudal fin has a principal fin-ray formula of I-7/7-I (Figs 1a,b and 2b,c, Supplementary Figs 3a,b,i,j, 4j–m and 5d,e and Supplementary Table 1). The parhypural firmly attaches to the compound vertebra (Fig. 1a,b and Supplementary Fig. 3a,b,i,j), whereas in living anabantids, it is detached and widely separated from the vertebra24 (Fig. 2g).

In one specimen of Eoanabas, layers of bony lamellae just above the branchial chamber (Fig. 2c and Supplementary Fig. 3g,h) show a cribrate structure (Fig. 2d) almost identical to that of the expanded plates of the labyrinth organ (modified first epibranchial)24 in living anabantids (Fig. 2e,f), suggesting the presence of a labyrinth organ also in the fossil fish (Fig. 2h).

Sexual dimorphism is exemplified by the postocular contact organ located immediately posteroventral to the orbit, a patch of scales with large ctenii (Fig. 2a,b and Supplementary Figs 3a,b,d and 5c) that are much larger than those of flank scales (Supplementary Fig. 3a,c,e). This organ is rare among perciform fishes24 and is seen in all African anabantids except for the species of Microctenopoma and Sandelia capensis 24, 27.

The Plant Megafossils Assemblage Associated with Eoanabas

Eoanabas was found in the lacustrine depositional environments with several aquatic herbs (Fig. 3 and Supplementary Information) such as duckweed (Limnobiophyllum, Lemnoideae, Araceae) (Fig. 3k) and bulrush (Typha) (Fig. 3q), associated with a diverse lowland vegetation (Fig. 3 and Supplementary Information) including palms (Fig. 3a), golden rain trees (Koelreuteria) (Fig. 3b), Pistacia (Fig. 3c), Ulmaceae (Fig. 3d), Araliaceae (Fig. 3i), Handeliodendron (Fig. 3j), Exbucklandia (Fig. 3l) and aspens (Populus) (Fig. 3o). Among the 15 types of woody dicot leaves in this plant assemblage, only five types have a toothed leaf margin, whereas the remaining 10 types all have an entire margin (Supplementary Table 2). Regarding the leaf size28, microphyll leaves are dominant in the assemblage, with at least 10 morphotypes.

Discussion

A phylogenetic analysis based on morphological data resolves Eoanabas as the earliest diverging lineage within the family Anabantidae, with its African relatives being monophyletic and sister to the Asian single genus Anabas (Supplementary Fig. 6). Eoanabas is also the oldest anabantid known so far, extending the geological record (previously represented only by three opercular bones from Pleistocene Java)29, 30 of this family for ca. 20 Ma and expanding the geographic distribution of this family to the middle Cenozoic central Tibet.

Living anabantids are confined mostly to the regions in Asia and Africa dominated by the tropical monsoon (Supplementary Fig. 7), with the greatest diversity in the rain forests of western and central Africa24, 31. They inhabit small bodies of water in lowlands in tropical Asia and sub-Saharan Africa23, 24, 31 (Supplementary Table 3), rarely higher than 1,000 m asl31. With few exceptions in the rivers of west Africa24, they prefer warm and periodically oxygen-poor stagnant waters, under the optimal temperature range of 18 to 30 °C (Supplementary Table 3). The key adaptations to such conditions are the labyrinth organ (Fig. 2f), a highly convoluted structure covered by richly vascularized epithelia24, and the resultant accessary air-breathing capability24, 32. Their air-breathing behaviour is facilitated by several muscles, including the levator operculi muscle32 that leaves a characteristic marked facet on the pterotics in living anabantids24. Interestingly, Eoanabas also has a labyrinth organ (Fig. 1d) and similar arrangement of the air-breathing muscle on the pterotics (Fig. 1c,d and Supplementray Fig. 5a,b). These strikingly similar characters appear physiologically specific and environmentally diagnostic31, and thus may indicate similar habitat conditions.

Eoanabas possesses a postocular contact organ in the males, which is unique to certain African anabantids24, 27. This structure indicates a typical anabantid spawning behavior. When the male embraces the female, it thrusts the spines of this organ into her abdomen to stimulate her to release eggs and ensure fertilization27. The similar reproductive behaviour strengthens the ecological similarities between Eoanabas and its living confamilial relatives.

The plant megafossil assemblage found with Eoanabas contains some taxa with living analogues (e.g., the palms and duckweed) commonly associated with the extant climbing perches (Supplementary Information), and hence reinforces the above palaeoenvironmental inference. Although the available material is insufficient to conduct a quantitative climatic reconstruction, the relatively high percentage (>60%) of the entire-margined types among the woody dicot leaves suggests a warm and humid climate (Supplementary Information). The dominance of microphyll leaves is consistent with this climatic inference, and appears to further suggest that the late Oligocene central Tibetan vegetation is more comparable to modern subtropical vegetation in Zhejiang, East China33. Based on the co-existing range of the living analogues of these fossil plants, this assemblage is assumed to grow most likely at an elevation of ca. 1,000 m asl (Supplementary Information).

Collectively, the ecological signal of Eoanabas and associated plant megafossils, as well as the co-existing fossil barbel fish Tchunglinius 21, suggests that warm and humid lowland habitats were present in the Tibetan interior ca. 26 Ma, probably at an elevation ~1,000 m asl, just like the environmental settings for modern climbing perches (Supplementary Fig. 8). Such a vibrant ecosystem represented by a spiny-rayed fish, barbel carp, and a diverse subtropical vegetation is in sharp contrast to that in the central Tibet today15, 17, 18. Yet the general lowland landscape might exhibit some topographic variation within the catchment area according to the contemporaneous pollen data of a mixed coniferous-broadleaved forest26.

Such palaeoenvironmental and palaeotopographic inferences will help us reevaluate our current understanding of the rise of the plateau and its environmental and climatic consequences. A warm and humid central Tibet requires a palaeogeographic setting allowing sufficient warm moisture to reach as far as the plateau interior at least up to the late Oligocene. As such, the current high-standing topographic features in southern Tibet might not exist then to block the southerly moisture from the ocean. This is in conflict with the notions that high Gangdese range has already been in place since the Palaeocene10 or the plateau had undergone northward stepwise uplift from late Eocene time onward12, but is compatible with the predictions of the rise of the Himalaya until the Neogene34 and newly proposed hypothesis for the oceanic Greater Indian Basin that would have maintained a deep tropical water mass between Asia and India throughout most of the Palaeogene35. Given the intrinsic environmental signals of the fossil climbing perch and the highly diversified sub-tropical plants, the establishment of a central Tibet with near-present elevation and climatic condition since early to late Eocene5, 7,8,9 or late Oligocene6 also seems highly problematic. Therefore, we caution against simple links between the rather early uplift of the plateau and the global climatic cooling during the early Cenozoic era9. The generally low elevation in plateau interior and probably more southern areas around the Palaeogene/Neogene transition is an important condition to test the existing tectonic models of plateau uplift. It is compatible with the inferences of either a period of un-roofing2 or the cease of the uplift process and a Tibet no higher than 1,000 m during ca. 30–20 Ma11, but contradicts the models for the constantly thickened crust in central Tibet since at least as early as the late Oligocene6 or even earlier8, 9. Our estimation of a fairly low, warm and wet central Tibet implies that this area has been elevated ~4,000 m to attain its current conditions since latest Palaeogene. In light of our fossil discovery, the geological history of the Tibetan Plateau is in need of critical re-evaluation.

Methods

Fossils were prepared mechanically with sharp needles. The Recent material for comparison was cleared and stained according to the method of Bai36. Photographs of fossils were taken with Nikon except Fig. 2d and Supplementary Fig. 3f,h that were images produced using Hitachi S-3700N Scanning Electron Microscope (SEM) (working condition: Fig. 2d, 3 kV, 98 µA, Working Distance = 25.4 mm; Supplementary Fig. 3f, 5 kV, 99 µA, WD = 16.7 mm; Supplementary Fig. 3h, 3 kV, 101 µA, WD = 25.5 mm); and Fig. 2e that is an X-ray micro-computerized tomography. For the latter, the scanning was carried out at the Key Laboratory of Vertebrate Evolution and Human Origins, Chinese Academy of Sciences (CAS) using the 225 kV micro-computerized tomography (developed by the Institute of High Energy Physics, CAS. The specimen (partial labyrinth organ of Anabas) was scanned with beam energy of 90 kV and a flux of 100 μA at a detector resolution of 6.27 μm per pixel using a 360° rotation with a step size of 0.5° and an unfiltered aluminium reflection target. A total of 720 transmission images were reconstructed in a 2,048*2,048 matrix of 1,563 slices using a two-dimensional reconstruction software developed by the Institute of High Energy Physics, CAS. The three dimensional reconstructions were created in VG Studio Max (v2.0), and images of the reconstructions were exported from VG Studio and finalized in Adobe Photoshop and Adobe Illustrator. Line drawings were done under a Leica MZ8 microscope with a camera lucida attachment and further prepared using Adobe Photoshop CS4.

To conduct a phylogenetic analysis to assess the systematic position of Eoanabas within the family Anabantidae, we developed a data matrix including 165 soft tissue, behavioural, and skeletal morphological characters (Wu et al. 2016.nex, Wu et al. 2016.tnt). These morphological characters are updated from ref. 24 and include 33 newly defined and other characters adopted from references elsewhere (for details see Appendix section below). Of the total 21 taxa, Badis and kissing gouramy Helostoma were designated as outgroups. The ingroup comprises fossil Eoanabas thibetana and 18 living anabantid species and species assemblages according to ref. 24. The data matrix was edited in WinClada 1.00.0837 and saved in the NEXUS format (Wu et al. 2016.nex) and TNT format (Wu et al. 2016.tnt). Additionally, to further test the phylogenetic position of the fossil taxon, we also tried the backbone-constrained search with the relationships based on Rüber et al.’s gene matrix25 of the extant taxa involved in this study used as backbone (datamatix: Wu et al. 2016 backboned.tnt). Parsimony analysis was undertaken using TNT, Tree analysis using New Technology, a parsimony analysis program supported by the Willi Hennig Society38. The analyses were conducted using a traditional search strategy, with default settings except for the following: 10,000 maximum trees in memory and 100 replications. Bremer support values were generated in TNT by applying the ‘New Traditional Search’ using TBR and collecting suboptimal topologies with 100 replicates. All characters were treated as unordered, and weighted equally.