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Dryopithecini

Dryopithecini is an extinct tribe of great apes within the subfamily (family ) that inhabited during the Middle and epochs, approximately 12.5 to 9.5 million years ago. Fossils of these are primarily known from European localities, including the Vallès-Penedès Basin in northeastern , sites in , and Rudabánya in . The tribe comprises several genera and is regarded as phylogenetically close to the common ancestor of modern great apes ( and ) and humans, offering key evidence for early hominoid evolution. Key genera assigned to Dryopithecini include (from and ), Pierolapithecus (from ), Anoiapithecus (from ), Hispanopithecus (from ), and Rudapithecus (from ). These taxa are distinguished by morphological analyses of dental structures, such as the enamel-dentine junction, which support their separation as distinct genera rather than synonyms of a single lineage. Postcranial remains, including a from the Abocador de Can Mata site in dated to about 11.7 million years ago, indicate body sizes comparable to modern female orangutans (estimated at around 38 kg for larger individuals) and a mosaic of primitive and derived features in the foot. Locomotor adaptations in Dryopithecini suggest a versatile repertoire, combining (about 32%), vertical climbing and clambering (about 50%), and suspensory behaviors (about 11%), with strong hallucal grasping for arboreal navigation. Vestibular morphology in genera like Hispanopithecus and Rudapithecus further aligns them with apes, supporting their placement as stem hominines rather than close to pongines (orangutans). Ongoing research debates their exact role in great ape diversification, with evidence pointing to independent of suspensory traits in crown hominoids and implications for the dispersal of early hominids from to .

Overview

Definition and Etymology

Dryopithecini is a taxonomic tribe within the subfamily of the family , encompassing extinct great apes that lived during the epoch. This group represents early members of the hominid lineage, characterized by their adaptation to arboreal lifestyles in Eurasian woodlands. The name Dryopithecini derives from the type genus , which combines the Greek words drys (δρῦς), meaning "" or "oak," and pithekos (πίθηκος), meaning "," literally translating to "tree ape"; the "-ini" is the standard Linnaean ending denoting a in zoological . The tribe was formally established by paleontologists William K. Gregory and Milo Hellman in 1939 to classify ape fossils exhibiting generalized great ape features. As an exclusively , Dryopithecini lacks direct living descendants, though its members are considered stem hominids potentially ancestral to later great ape clades. Their temporal range spans the to , approximately 12.5 to 9.5 million years ago.

Temporal and Geographic Distribution

Dryopithecini s date to the to , with the earliest records from approximately 12.5 million years ago () and extending to around 9 . This temporal span corresponds to the MN 7+8 to MN 9 biozones in the mammal , encompassing the late and early Tortonian stages. During this interval, dryopithecins represent a key phase in great ape , coinciding with climatic optima that supported diverse hominoid radiations. The primary geographic distribution of Dryopithecini is centered in , where fossils have been recovered from multiple localities across the continent. Key regions include the (e.g., Spain's Vallès-Penedès Basin), (e.g., Saint-Gaudens), central (e.g., and Hungary's Rudabánya), and southeastern Europe (e.g., Greece's Ravin de la Pluie). Limited evidence suggests possible extensions into southwestern , such as the Çorakyerler locality in , indicating a broader Eurasian presence during peak diversification. No confirmed records exist from further east in , such as , though related hominoids like occupied contemporaneous niches there. Paleoenvironmental reconstructions place Dryopithecini in subtropical, forested habitats characterized by closed-canopy woodlands with seasonal humidity. These settings, prevalent during the Climatic Optimum's tail end, featured abundant soft fruits and leaves, aligning with the folivorous-frugivorous diets inferred from dental . Such environments facilitated orthograde suspensory locomotion and contributed to hominoid diversification amid shifting continental climates and faunal dispersals between and .

Physical Characteristics

Cranial and Dental Features

The cranial morphology of Dryopithecini is characterized by a relatively small braincase, with endocranial volumes estimated at 230–330 cc based on specimens of Rudapithecus and , placing it within the lower range of modern great ape brain sizes. The face exhibits moderate overall, though this varies by genus: Pierolapithecus retains a plesiomorphic prognathic profile, while Anoiapithecus shows a derived orthognathous configuration with reduced subnasal projection. A robust supraorbital is a diagnostic feature, evident in and Rudapithecus, forming a continuous that contributes to the clade's derived hominine cranial architecture. Dentally, Dryopithecini display the Y-5 molar pattern characteristic of crown catarrhines, featuring five main cusps on lower molars arranged in a Y-shaped configuration, with subrectangular occlusal outlines and moderate crown heights. thickness is relatively thin across the , particularly in (mean relative enamel thickness of 10.6–12.7), akin to that in modern African apes and suggestive of adaptations for a , though Pierolapithecus and Anoiapithecus exhibit moderately thicker enamel (RET ~14.8–19.5). are large and sexually dimorphic, with males possessing robust, tusk-like upper canines (root heights up to 12.7 mm) for display and shearing. are sectorial, especially the lower third , which hones against the upper canine , further indicating frugivorous habits with some folivory. In comparison to modern apes, the dental arcade of Dryopithecini is U-shaped and parallels that of orangutans, but retains more primitive traits such as reduced shearing crests and less wrinkled surfaces relative to great apes.

Postcranial

The postcranial of Dryopithecini exhibits a of primitive and derived features adapted for , particularly suspensory behaviors in forested environments. Forelimbs are elongated relative to hindlimbs, with long arms facilitating arm-swinging and hanging. The features a large, rounded head that enhances mobility, allowing extensive rotation and flexion essential for navigating three-dimensional arboreal substrates. Manual phalanges are notably long and curved, with robust flexor sheath ridges that support powerful grasping during and , as evidenced in specimens of Hispanopithecus laietanus and Rudapithecus hungaricus. Hindlimbs in Dryopithecini are shorter than forelimbs, reflecting a positional repertoire dominated by above-branch suspension rather than . The femur displays cortical bone distribution indicative of high mobility and load-bearing during vertical clinging and leaping, while the talus has a broad, shallow trochlear body and elongated neck, akin to that in modern orangutans, promoting ankle flexibility for arboreal propulsion; a recently described talus (IPS85037) from the Abocador de Can Mata site (dated to 11.7 million years ago) further supports these locomotor inferences with morphometric affinities to extant hominoids. The pelvis shows ilium flaring intermediate between cercopithecoids and extant great apes, as seen in Pierolapithecus catalaunicus, which supports an orthograde posture by broadening the attachment area for and stabilizing the torso during upright climbing. This configuration suggests early adaptations for vertical body positioning without full commitment to terrestrial bipedality. The of Dryopithecini is characterized by a broad, shallow , inferred from that indicates a mediolaterally expanded for orthograde stability and increased lung capacity during strenuous arboreal activities. exhibit dorsally positioned transverse processes and moderate wedging, contributing to a flexible yet stiff lower that facilitates torso rotation and balance while climbing or suspending from branches. These features collectively underscore a optimized for arboreal life, bridging primitive pronograde elements with derived hominoid orthogrady.

Taxonomy and Phylogeny

Historical Classification

The genus was initially described by Édouard Lartet in 1856 based on fragmentary mandibular remains from Saint-Gaudens in , marking the first recognition of a great and highlighting its affinities to modern higher . Lartet noted similarities to apes, a connection later emphasized by in 1871 as evidence for from such forms. The tribe Dryopithecini was formalized within the subfamily Dryopithecinae by W.K. Gregory and Milo Hellman in 1939, encompassing apes with thinly enameled teeth and features bridging early hominoids. Throughout the , classifications shifted significantly; early views often aligned with the (orangutan subfamily) due to shared dental traits like sectorial premolars, as proposed in various systematic revisions. By mid-century, however, it was reassigned to the Dryopithecinae as a distinct group potentially ancestral to great apes, reflecting growing fossil evidence from . Major revisions in the late 20th century, such as Peter Andrews' 1992 synthesis, reinstated affinities to Ponginae for many dryopithecines based on environmental and morphological correlations, emphasizing their role in Eurasian hominoid diversification rather than direct hominine ancestry. Ongoing debates center on the inclusion of African genera like Proconsul, which early taxonomists such as Simons and Pilbeam (1965) subsumed under Dryopithecus as a subgenus due to primitive postcranial features, though later analyses excluded it as a stem catarrhine outside the tribe. These discussions are further complicated by tensions between morphological phylogenies supporting a European origin for Dryopithecini and molecular data favoring African in situ evolution of hominines.

Included Genera and Species

The tribe Dryopithecini encompasses a small number of extinct hominoid genera, primarily known from Eurasian sites, with body masses estimated between 20 and 45 kg based on postcranial and dental metrics. The type , Dryopithecus, includes the species D. fontani from Middle sites in (e.g., Saint-Gaudens), characterized by thin-enameled, low-crowned molars adapted for folivory, and D. brancoi from central European localities, now often reassigned to a separate genus but retaining similar dental features. Anoiapithecus brevirostris, from the Middle Miocene of northeastern (e.g., Els Casots), is distinguished by its orthognathic (relatively flat) profile, intermediate thickness (3D RET 11.40–14.26), and reduced morphology, suggesting a body mass around 30–40 kg. Pierolapithecus catalaunicus, also from Middle Miocene Spanish sites like Els Casots (dated 12.4–11.9 Ma), features intermediate thickness (3D RET 13.24–18.14) and mesiodistally compressed molars with complex -dentine shapes, indicative of a similar size range to Anoiapithecus. Hispanopithecus laietanus (including the junior synonym H. crusafonti), from deposits in (10.5–9.5 Ma, e.g., Can Llobateres), exhibits intermediate thickness, buccolingually broad molars, and more derived dental traits, with estimated masses of 35–44 kg based on dimensions. Rudapithecus hungaricus (formerly Dryopithecus brancoi), from the Late Miocene of Hungary (Rudabánya, ~10 Ma), is recognized as a distinct genus within Dryopithecini due to its robust postcrania and dental features like low-crowned premolars, with body mass estimates of 20–40 kg reflecting potential sexual dimorphism. Taxonomic debates persist regarding the distinctiveness of Pierolapithecus and Anoiapithecus, with some analyses proposing them as junior synonyms of Dryopithecus based on overlapping craniodental traits. Recent geometric morphometric analyses of the enamel-dentine junction (2023) and new dental remains of Anoiapithecus (2024) further support the distinctiveness of these genera from Dryopithecus, resolving some synonymy debates. Recent phylogenetic studies exclude genera like Nacholapithecus (African, Middle Miocene) and Sivapithecus (Asian, Late Miocene) from Dryopithecini, citing differences in inner ear morphology, enamel thickness, and biogeographic distributions that place them in separate clades (e.g., Equatorini or Ponginae).

Evolutionary Relationships

Dryopithecini occupies a pivotal position in the phylogeny of hominoids, generally recognized as a stem group within , the great ape and human . Cladistic analyses often recover Dryopithecini as basal hominids, predating the divergence between (including , the orangutan genus) and (African apes and humans). In some models, genera such as , Hispanopithecus, and Rudapithecus form a sister to within an expanded , based on shared derived features like thin on molars and adaptations for suspensory . Key evidence supporting this placement includes morphological synapomorphies observed in cranial, dental, and postcranial fossils from the Middle to Late Miocene (approximately 12–9 Ma), which align Dryopithecini more closely with great apes than with earlier stem hominoids like Proconsul. For instance, the reduced relative enamel thickness (RET) in dryopithecine dentition mirrors that of pongines, contrasting with the thicker enamel of hominines, while locomotor features suggest arboreal suspensory behaviors akin to those in extant great apes. Fossil evidence indicates a divergence of Dryopithecini from the lineage leading to African apes around 14–12 million years ago, contemporaneous with the initial radiation of crown Hominidae in Eurasia. Modern phylogenetic debates center on whether Dryopithecini represents a stem pongine, emphasizing Eurasian origins and pongine-like traits, or aligns more closely with stem , supported by inner ear morphology resembling that of and . Vestibular system analyses of taxa like Hispanopithecus laietanus and Rudapithecus hungaricus reveal hominid-grade proportions in , but with primitive configurations that do not conclusively favor one subfamily over the other, potentially indicating . These interpretations are integrated with estimates, which place the split between 13 and 10 million years ago, suggesting Dryopithecini captures an early phase of great ape diversification before the full separation of and African ape lineages.

Fossil Record

Discovery History

The initial discovery of Dryopithecini fossils occurred in 1856 when French paleontologist Édouard Lartet described a from Saint-Gaudens in the French as belonging to a new genus, , representing the first recognized fossil great and sparking early debates on primate evolution in Europe. This find, later attributed to Dryopithecus fontani, was followed by additional 19th-century discoveries in , such as at La Grive-Saint-Alban, which provided more dental and postcranial material, reinforcing the perception of Dryopithecus as a Miocene with affinities to modern hominoids. In Germany, contemporaneous excavations at sites like Eppelsheim and Höwenegg yielded further Dryopithecus remains, including teeth and limb bones, which expanded the known morphological diversity and geographic range of the tribe during the late 19th century, influencing Charles Darwin's discussions on ape ancestry in The Descent of Man. The saw sporadic finds but accelerated in the early with Spanish discoveries that revitalized interest in Dryopithecini as potential stem great apes. In 2004, a nearly complete skeleton from Barranc de Can Vila near was described as Pierolapithecus catalaunicus, a 12.5–13 million-year-old exhibiting orthogrady and reduced tail vertebrae, which positioned it as a key transitional form between earlier hominoids and the great -human clade. This discovery shifted phylogenetic interpretations toward a European origin for great adaptations, challenging African-centric models of hominoid . In 2004, excavations at Abocador de Can Mata in uncovered a partial face and of Anoiapithecus brevirostris, formally described in 2009 as a Middle (~11.9 million years old) species with a short, broad palate and thin-enameled teeth, highlighting dental specializations that suggested closer ties to the lineage and further diversified the tribe's inferred ecological roles in Eurasian forests. Excavations at Rudabánya in , ongoing since the 1960s with significant finds in 1965–1967, yielded fossils described in 1993 as Rudapithecus hungaricus, a late (~9.8 million years old) with features aligning it closely to stem hominines. Post-2020 reanalyses have extended the temporal and spatial understanding of Dryopithecini, particularly through Turkish fossils. In , a new partial cranium from the 8.7-million-year-old Çorakyerler site in central was described as Anadoluvius turkae, a dryopithecine with arboreal adaptations that potentially links European and Asian hominoid radiations, thereby broadening the tribe's eastern range and supporting migration hypotheses from to . Ongoing taxonomic debates, including synonymy proposals for like Dryopithecus fontani and D. laietanus based on new comparative analyses, continue to refine the group's alpha , emphasizing the need for integrated morphometric and phylogenetic studies to resolve historical classifications.

Key Fossil Sites and Specimens

The Dryopithecini fossils are primarily known from localities in , with significant discoveries concentrated in karstic fissure fillings that preserve fragmentary skeletal elements through biostratigraphic to the MN6–MN9 zones (approximately 12.5–9.5 million years ago). These sites yield dentognathic and postcranial remains, often disarticulated due to taphonomic processes involving collapse into caves and subsequent mineralization. In , the Rudabánya locality has produced key specimens of Rudapithecus hungaricus, including the (Rud-1), a recovered from (MN9) deposits around 9.8 million years old. Additional dental and postcranial remains from this site, such as isolated molars, premolars, and a partial pelvis (Rud-285/P), exhibit features typical of early dryopithecins and provide insights into locomotor adaptations. The fossils were excavated from mine spoil heaps overlying karstic fissures, preserving a mix of cranial and postcranial fragments alongside other like Anapithecus. Spain hosts several pivotal sites, including Barranc de Can Vila in the Els Hostalets de Pierola area of the Vallès-Penedès Basin, where the partial skeleton of Pierolapithecus catalaunicus (holotype IPS21350) was discovered in 2002 and described in 2004. This Middle Miocene (MN6, ~12.4 million years old) specimen includes over 50 elements, such as vertebrae, ribs, a sacrum, and limb bones, providing rare insights into postcranial anatomy; it was recovered from a fissure infill with excellent three-dimensional preservation despite some compression. Nearby, Abocador de Can Mata yielded the holotype of Anoiapithecus brevirostris (IPS43000), a partial cranium and mandible from Middle Miocene deposits (~11.9 million years old, MN6), featuring a short broad palate and thin-enameled teeth, recovered from a stratigraphic series with good preservation. Can Ponsic yielded fossils of Dryopithecus crusafonti, notably upper molars and incisors forming the basis of the species description in 1992, dated to the late Middle Miocene (MN7+8, ~11.9–11.2 million years ago) and characterized by robust dental morphology in karstic sediments. Further Spanish contributions include the type locality of Hispanopithecus laietanus at La Tarumba (MN9, ~9.9 million years old), where the mandible (IP1-1) and associated lower teeth were found in 1944, featuring thin-enameled molars and a robust corpus. This fragmentary dentognathic material from fissure deposits has been supplemented by later finds at nearby sites like Can Llobateres, enhancing the sample of this taxon. Overall, these European assemblages, dated via micromammal , underscore the patchy but informative fossil record of Dryopithecini.

Paleobiology and Significance

Inferred Behavior and Ecology

The diet of Dryopithecini is reconstructed as primarily frugivorous, supplemented by folivory, based on their low-crowned molars adapted for processing soft fruits and dental microwear patterns indicating occasional consumption of tougher, foliage. Low molar crown heights and intermediate occlusal microwear textures align with a fruit-dominated diet similar to that of early Miocene hominoids, while buccal microwear on taxa like Dryopithecus laietanus reveals higher striation densities consistent with tough plant foods, as seen in folivorous extant great apes such as . Locomotion among Dryopithecini emphasized arboreal quadrupedalism and suspensory behaviors, inferred from postcranial features including elbow joint morphology that permitted extensive flexion for climbing and below-branch suspension. Distal humeral and proximal ulnar elements in species like Hispanopithecus laietanus exhibit mediolateral compression and a trochlear keel, facilitating stable pronation-supination during palmigrade quadrupedalism on slender branches, with additional capacity for arm-swinging and clambering. Some terrestrial proficiency is suggested by femoral neck cortical bone distribution in Dryopithecus, indicating a quadrupedal component alongside orthograde postures, though hindlimb proportions limited efficient ground travel. Sociality in Dryopithecini is inferred to involve small groups within habitats. These apes inhabited mixed forest-savanna mosaics with dense canopies and clearings, as evidenced by associated faunal dental wear patterns indicating humid, wooded environments with fruit availability and some open areas. Such settings supported fission-fusion grouping dynamics for foraging in arboreal niches, consistent with the ecological constraints of their Eurasian range.

Role in Hominoid Evolution

Dryopithecini represent a pivotal group in hominoid evolution, exhibiting a mosaic of primitive catarrhine features and derived traits characteristic of crown hominoids, thus serving as a morphological bridge between earlier Miocene apes and modern great apes. Fossils such as the partial skeleton of Dryopithecus laietanus from Spain, dated to approximately 9.5 million years ago (Ma), reveal evidence of orthograde posture and locomotion, including a short lumbar region, broad ilia, and a centrally positioned foramen magnum, which align closely with the body plan of extant hominoids and differ from the pronograde quadrupedalism of more primitive Miocene catarrhines like proconsulids. Similarly, Pierolapithecus catalaunicus from the Middle Miocene of Spain (around 12.4 Ma) displays a combination of suspensory adaptations in the forelimbs and orthograde indicators in the axial skeleton, such as a stiff vertebral column, supporting its role as an early representative of great ape positional behaviors. These traits suggest that Dryopithecini were among the first hominoids to transition toward the arboreal, orthograde lifestyles that define the great ape clade, predating the divergence of pongines and hominines. The European radiation of Dryopithecini underscores their significance in broader hominoid dispersal patterns, particularly as part of the Afro-European faunal exchanges during the Middle Miocene. Originating from stem catarrhines that dispersed northward around 15–14 Ma, Dryopithecini are exemplified by early taxa like Griphopithecus from , which marks the onset of this 's diversification in European forests amid fluctuating paleoenvironments. One suggests that these exchanges contributed to the evolution of the great ape in , with possible dispersals influencing hominoid lineages, though the exact origins remain debated. Such exchanges highlight how tectonic and climatic changes, including the closure of the Tethys Sea and forest fragmentation, drove hominoid adaptive radiations across continents. Despite these insights, significant gaps in the Dryopithecini fossil record hinder a complete resolution of their phylogenetic position relative to pongines and hominines, largely due to fragmentary postcrania and that obscure precise branching patterns. Current evidence places Dryopithecini as stem members of the great ape clade, potentially close to the hominine-pongine split around 14-12 , but debates persist on whether they represent stem hominines or a more basal position. Emerging Asian discoveries, such as the late Miocene hominid from (approximately 9-7 ), offer promise for clarifying pongine origins by filling voids in the Southeast Asian record, where potential ancestors like Lufengpithecus exhibit ambiguous affinities that could link back to Eurasian dryopithecins. Future finds in under-sampled regions may thus refine understandings of early great ape diversification beyond the Euro-African focus.