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Equus capensis
Equus capensis
Equus capensis
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Equus capensis
Temporal range: Pleistocene
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Perissodactyla
Family: Equidae
Genus: Equus
Subgenus: Hippotigris
Species:
E. capensis
Binomial name
Equus capensis
Broom, 1909

Equus capensis (E. capensis), the Giant Cape zebra, is an extinct species of zebra[1] that lived during the Pleistocene of South Africa. E. capensis was first described from the Cape Town region of South Africa in 1909.[2] E. capensis can be estimated to have grown to about 150 cm (59 in) at the withers and 400 kg (880 lb) in body mass.[1]

A 2009 DNA study analyzed several museum specimens identified as Cape zebras and concluded that all specimens tested clustered within the plains zebra, Equus quagga, with E. q. quagga and E. q. burchelli, rather than belonging to a distinct species.[3]

References

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Equus capensis

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from Grokipedia
Equus capensis, commonly known as the giant zebra, is an extinct species of zebra that lived during the Pleistocene epoch in , particularly on the Cape south coast. It represents the largest equid from the period in , characterized by a robust build exceeding that of modern , with an estimated body mass of approximately 450 kg and a shoulder height of 144–156 cm at the . Phylogenetic analyses of ancient DNA place E. capensis within the zebra , forming a distinct lineage closely related to the modern (Equus quagga), distinguishing it from asses or horses. This species was adapted to open and wetland environments, such as those on the now-submerged Palaeo-Agulhas Plain, where it likely grazed alongside other . evidence, including skeletal remains from sites like Elandsfontein and deposits at Elands Bay and Wonderwerk, indicates its presence from at least 161,000 years ago until its extinction around 10,000–12,000 years . The extinction of E. capensis coincided with broader megafaunal losses in , potentially driven by habitat alterations from post-glacial sea-level rise that flooded expansive coastal plains, alongside possible influences during the . Recent paleontological discoveries have enhanced understanding of its and distribution; notably, 26 tracksites spanning a 350 km coastal stretch have yielded fossilized footprints, with 13 attributed to E. capensis based on track sizes exceeding 12 cm in length, dated between 161,000 and 43,000 years ago via optically stimulated . Among these, the Driefontein site preserves a rare 320 cm trackway comprising 12 consecutive prints, offering insights into its locomotion and proximity to ancient water sources like wetlands. These findings underscore E. capensis as a key species in reconstructing Pleistocene ecosystems and interactions with in the region.

Taxonomy and classification

Etymology and naming

The binomial name Equus capensis was proposed by the South African paleontologist Robert Broom in 1909, based on fossil remains recovered from the Cape region of South Africa. The generic name Equus derives from the Latin word for "horse," originating from Proto-Indo-European h₁éḱwos meaning the same. The specific epithet capensis refers to the Cape of Good Hope area, where the type specimen was discovered on the South African coast. Broom's initial description appeared in a short note in the Annals of the South African Museum, where he identified the species as a large, extinct equid from Pleistocene coastal deposits near Cape Town, based primarily on a partial mandible containing four teeth found in 1907. He characterized it as more robust than modern horses and suggested it represented a recently extinct form distinct from extant African equids.

Phylogenetic position

Equus capensis is classified within the Equus, Hippotigris, which encompasses the zebras, and is recognized as the largest equid known from the record of . Morphological analyses, including cranial and postcranial features, indicate a close phylogenetic relationship between E. capensis and the (Equus quagga), particularly the subspecies E. q. burchellii, while distinguishing it from other equids such as (E. grevyi) through traits like shorter facial proportions and dental morphology consistent with the Hippotigris clade. These morphological studies support the recognition of E. capensis as a distinct . Ancient DNA analyses further corroborate this affinity, with mitochondrial sequences from E. capensis specimens forming a nested within the diversity of modern plains zebras (E. quagga), including southern populations like E. q. burchellii. However, the genetic distances observed fall within the intraspecific variation of plains zebras, leading to suggestions that E. capensis may represent a large-bodied ecophenotype or variant of E. quagga rather than a fully separate . This debate highlights ongoing taxonomic uncertainties informed by both morphological and molecular evidence.

Physical description

Morphology

Equus capensis exhibited a robust skeletal structure, characterized by strong and sturdy limb bones that supported its large body mass and facilitated movement across open landscapes. Fossil limb elements from sites such as Elandsfontein reveal proportions akin to those of modern draft horses (Equus caballus), indicating a powerfully built frame adapted for stability in varied terrains. The dental morphology of Equus capensis featured high-crowned () molars with expansive occlusal surfaces, enabling efficient grinding of tough, abrasive vegetation. These teeth, consistently larger than those of the extant (Equus quagga), displayed occlusal patterns similar to modern grazing equids, optimized for processing fibrous plant material over extended wear periods. Fossil track impressions attributed to Equus capensis show broad, rounded hooves with a curved anterior wall and prominent central frog structure, suggesting enhanced stability on soft, sandy, or grassy substrates. Cranially, the species possessed an elongated skull resembling that of the extinct Cape quagga.

Size and comparisons

Equus capensis was a notably large equid, with an estimated shoulder height of 144–156 cm at the and a body mass of approximately 450 kg. This made it the largest known Pleistocene equid in . In comparisons to modern relatives, E. capensis was 1.5–2 times heavier than the (Equus quagga, 250–300 kg body mass) and the Cape mountain zebra (Equus zebra zebra, 230–260 kg body mass). Fossil trackways further highlight these size differences, with E. capensis tracks measuring ≥12 cm in length (mean 13.6 cm), compared to 9–11 cm for tracks of modern zebras. The species' larger body size likely influenced its lower mass-specific metabolic rates, a common trait among Pleistocene megaherbivores, and favored habitat preferences in expansive grasslands suitable for .

Distribution and habitat

Geographic range

Equus capensis primarily inhabited the Province of , with its core range centered on the Cape south coast from Still Bay to along a 350 km stretch that includes sites from Arniston to the Robberg Peninsula. tracks and remains indicate a concentration on the now-submerged Palaeo-Agulhas Plain, where evidence spans the period from 161,000 ± 12,000 to 43,000 ± 4,000 years ago based on optically stimulated of 26 equid tracksites, over half attributed to this species. The species' distribution extended more broadly across during the Pleistocene, with scattered fossils documenting presence in the and regions of , a single locality in , and the Zimbabwe highlands. Additional records from the in further support this expanded range, though remains are less abundant beyond the coastal core. Evidence from trackways near wetlands, such as those within 12 km of the Rietvlei water source, indicates proximity to reliable water in corridors. This species exhibited a preference for C4 grasslands as a primary .

Paleoenvironment

Equus capensis inhabited the Pleistocene landscapes of southern Africa, particularly during periods of glacial maxima when lowered sea levels exposed the Palaeo-Agulhas Plain, a vast now-submerged coastal shelf spanning approximately 85,000 km² along the Cape south coast. This plain featured cool and arid climatic conditions, with temperatures several degrees lower than today and reduced atmospheric CO₂ levels contributing to a winter-dominated rainfall regime that limited overall precipitation. These environmental settings were part of broader glacial-interglacial cycles, during which sea levels fluctuated by up to 130 m, alternately exposing expansive habitats for megafauna and inundating them during interglacials, thereby influencing species distributions through changes in available land and water resources. Vegetation on the Palaeo-Agulhas Plain during the Last Glacial Maximum (approximately 26,000–19,000 years ago) was characterized by extensive C4-dominated grasslands, particularly in shale-dominated areas, interspersed with open savanna-woodland mosaics along floodplains and alluvial soils. Pollen records and stable isotope analyses indicate a landscape of dry, low-biomass grasses adapted to arid conditions, with nutrient-rich C4 species supporting bulk grazing by large herbivores, while fynbos and thicket elements occurred in more sheltered or coastal zones. Water availability, constrained by seasonal rivers and shallow floodplains, played a key role in limiting the range and mobility of species like Equus capensis, as glacial aridity reduced reliable freshwater sources across the plain. The paleoenvironment supported a diverse megafaunal community, with Equus capensis coexisting alongside other large herbivores such as the giant buffalo (Syncerus antiquus) and African elephant (Loxodonta africana), as evidenced by fossil tracksites from Marine Isotope Stage 5e (approximately 128,000–116,000 years ago) on the Cape south coast. This assemblage reflects a grassland ecosystem conducive to grazing megafauna, with predators likely including large carnivores adapted to open habitats, forming a complex food web sustained by the plain's productive yet arid vegetation during Pleistocene lowstands.

Paleoecology and behavior

Diet and locomotion

Equus capensis was a bulk grazer specialized in consuming low-quality, dry grasses, as evidenced by its highly adapted for processing abrasive vegetation. Mesowear analysis of molar teeth further supports an strategy, with consistently high and rounded cusps indicating a diet dominated by grasses rather than browse. Stable carbon isotope ratios (δ¹³C) in dental enamel, ranging from -10.5‰ to -17.8‰, confirm substantial consumption of C₄ grasses, consistent with open, arid-adapted habitats. Locomotion in E. capensis was quadrupedal, with tracks preserving evidence of walking and trotting gaits characterized by alternating manus-pes sequences and moderate overstepping. Prominent wall impressions in these tracks, often 12–17 cm in length, suggest adaptations for efficient movement across soft aeolianites and grassy substrates, minimizing slippage in unconsolidated sediments. Track distributions indicate a strong water dependency, with equid impressions concentrated near paleo-river channels, implying routine access to sources within approximately 12 km. Foraging behavior likely involved herd-based in open areas to exploit sparse , enabling coverage of large distances; the species' large body size further supported endurance during these extended movements.

Social and predatory interactions

Equus capensis, as a large-bodied equid closely related to modern zebras, is inferred to have exhibited gregarious , living in herds that provided anti-predator advantages through collective vigilance and dilution of individual risk. trackways from Pleistocene sites on the Cape south coast, including intersecting paths at Driefontein and Goukamma, suggest patterns of group travel, consistent with the dynamics observed in extant Equus species. The species' substantial body size, estimated at up to 450 kg, likely enhanced these benefits by deterring solitary attacks from predators and facilitating coordinated defensive responses within the herd. Predatory interactions involving Equus capensis are evidenced by bone modifications at key Pleistocene sites in , indicating scavenging and hunting by large . Tooth marks and fragmentation patterns on equid remains from Cooper's D and similar localities point to spotted hyenas (Crocuta crocuta) as primary accumulators and consumers, often transporting and breaking bones in dens. Additionally, saber-toothed felids such as , present at sites like and , are implicated in direct predation on equids, with their robust suited for tackling large prey like the Cape horse. These interactions highlight Equus capensis's role as a key prey item in the Pleistocene , contributing to taphonomic assemblages dominated by activity. As a specialized in , Equus capensis occupied an that shaped Pleistocene grassland dynamics through intensive pressure, promoting short-grass lawns and suppressing woody encroachment in open habitats. This influence likely competed with sympatric equids, such as Equus quagga, for resources in shared ranges across , where both species co-occurred in Middle to deposits. Furthermore, symbiotic relationships may have included associations with other ungulates in mixed-species groups, enhancing overall herd vigilance against predators in environments.

Extinction

Timeline and last occurrences

The oldest dated tracks of Equus capensis are from the Driefontein site on South Africa's south coast, dated to approximately 161,000 years ago () via optically stimulated luminescence (OSL). The originated in the based on earlier skeletal remains. This persisted through much of the Pleistocene, as evidenced by additional track sites spanning the , including the youngest dated tracks at Robberg, calibrated to around 43,000 years ago via OSL methods. These ichnofossil records provide a robust chronological framework for the ' temporal range in , highlighting its long-term presence as a large-bodied grazer in coastal paleoenvironments. The final evidence of E. capensis survival comes from radiocarbon-dated skeletal remains in terminal Pleistocene archaeological contexts. At Boomplaas Cave in the , remains associated with the species are from layers dated to approximately 10,650–12,100 calibrated years (cal yr ), based on Bayesian modeling of multiple samples from relevant stratigraphic layers. Comparable late occurrences are documented at Elands Bay Cave (10,650–11,180 cal yr ) and (10,120–12,100 cal yr ), confirming the species' persistence until the onset of the . Post-Last Glacial Maximum (~20,000 years ago), E. capensis underwent a gradual population reduction, reflected in diminishing abundances within large assemblages from sites like Boomplaas Cave, where grazer taxa including this equid decline sharply after ~18,000 cal yr BP. No fossil records exist for the species, indicating its in by ~10,000 cal yr BP. This timeline aligns with a regional megafaunal turnover in during the late , where E. capensis paralleled the loss of other specialized grazing around the Pleistocene-Holocene transition.

Proposed causes

The primary proposed cause for the extinction of Equus capensis is habitat loss resulting from post-glacial sea-level rise, which submerged much of the Palaeo-Agulhas Plain—a vast coastal that supported large herbivores—around 10,000 years ago. This inundation drastically reduced the extent of productive C4 grasslands essential for the species' survival as a specialized , leading to a contraction of suitable areas during the Pleistocene-Holocene transition. and ichnological indicates that E. capensis persisted until approximately 10,000–12,000 years ago, after which the loss of this refugium likely precipitated its demise. Secondary environmental factors include climate shifts toward greater aridification in at the Pleistocene-Holocene boundary, which diminished water availability and grass productivity across remaining . These changes, driven by broader global warming and altered precipitation patterns, would have compounded stress for grassland-dependent like E. capensis by favoring shrublands over open plains. Additionally, potential anthropogenic pressures from human populations, including increased hunting, may have contributed, as the timing of the species' disappearance aligns with the expansion of Homo sapiens in the region equipped with advanced technologies. In comparison to other regional megafaunal extinctions in , the submersion of the Palaeo-Agulhas Plain represents a unique driver for coastal species such as E. capensis, contrasting with more widespread climate-driven die-offs of interior grazers affected primarily by continental . There is no direct evidence supporting outbreaks or sudden catastrophic events as primary causes; instead, the appears multi-factorial, unfolding gradually over millennia through cumulative environmental and possibly human-induced pressures.

Fossil record

History of discovery

The extinct species Equus capensis, commonly known as the giant Cape zebra, was first described in the early 20th century based on fossils recovered from the Cape region of South Africa. In 1909, paleontologist Robert Broom formally named the species from a partial mandible containing four teeth, discovered in 1907 near Cape Town, which he interpreted as evidence of a large, recently extinct equid adapted to the local environment. This initial description highlighted the animal's robust dental morphology, suggesting it was larger than extant zebras, and sparked interest in Quaternary megafauna of southern Africa. Subsequent early works built on this foundation, with C. S. Churcher's 2006 review synthesizing the known distribution and historical records of E. capensis across African Quaternary sites, emphasizing its prevalence in coastal and inland deposits while noting the challenges of fragmentary remains. During the mid-20th century, research on E. capensis received limited attention, primarily due to the scarcity of well-preserved body fossils in the region's sandy and aeolian sediments, which often led to poor osseous preservation. Attention shifted toward morphological revisions, as exemplified by Véra Eisenmann's 2000 analysis of cranial material from the Elandsfontein site, which refined the species' diagnostic features—such as enlarged incisors and robust skull proportions—distinguishing it from related equids like Equus grevyi and underscoring its unique adaptations. These studies relied on comparative osteology to address taxonomic uncertainties, but the overall pace of discovery remained slow, constrained by the episodic nature of fossil exposures in coastal contexts. In the 21st century, advancements in molecular and trace fossil techniques revitalized investigations into E. capensis. A pivotal 2009 study by Ludovic Orlando and colleagues extracted ancient DNA from multiple specimens, including those from Wonderwerk Cave, revealing that E. capensis formed a distinct clade within the plains zebra (Equus quagga) lineage rather than representing a separate species or synonym of E. grevyi, thus challenging prior morphological classifications and integrating genetic evidence into equid phylogenetics. More recently, ichnological research has complemented these findings; in 2023, Adrian Helm and coauthors documented 26 Pleistocene tracksites along the Cape south coast, attributing elongated trackways in aeolianites to E. capensis based on stride length and pes morphology, providing direct behavioral evidence where body fossils are rare. This evolution in research methodology reflects a broader shift from reliance on body fossils—hindered by taphonomic biases in coastal sands—to trace fossils, which offer higher preservation potential and insights into locomotion and habitat use in southern Africa's dynamic paleoenvironments.

Key sites and specimens

The type specimen of Equus capensis, consisting of a partial with four teeth, was recovered in 1907 from a deposit near , . Additional body fossils include dental remains from Boomplaas Cave in the , dated to approximately 12,000 years ago. Post-cranial elements are sparse, with isolated bones reported from regions such as the and . Fossil track sites provide the majority of evidence for E. capensis, with 26 Pleistocene aeolianite localities documented along the Cape south coast of . These include prominent sites at Driefontein, Goukamma , Robberg , and the Garden Route National Park, of which 13 preserve large tracks measuring 12 cm or greater in length, consistent with the size of E. capensis. A notable trackway specimen, documented in 2023 near Still Bay, features 12 consecutive prints that were analyzed using 3D photogrammetry to reveal detailed hoof morphology. Preservation in aeolianites has favored the formation of tracks over body fossils due to the coarse dune sands and rapid cementation, resulting in a total of only dozens of skeletal fragments known across all sites.

References

  1. https://doi.org/10.1017/qua.2023.1
  2. https://vera-eisenmann.com/IMG/pdf/128.E.capensis.pdf
  3. https://www.pnas.org/doi/10.1073/pnas.0903672106
  4. https://theconversation.com/new-discovery-fossilised-giant-zebra-tracks-found-in-south-africa-201687
  5. https://www.researchgate.net/publication/368673637_Tracking_the_extinct_giant_Cape_zebra_Equus_capensis_on_the_Cape_south_coast_of_South_Africa
  6. https://www.cambridge.org/core/journals/quaternary-research/article/tracking-the-extinct-giant-cape-zebra-equus-capensis-on-the-cape-south-coast-of-south-africa/D410B4D755781DC0206CB810A35CC74E
  7. https://www.biodiversitylibrary.org/item/100427#page/303/mode/1up
  8. https://www.researchgate.net/publication/288729003_Equus_capensis_Mammalia_perissodactyla_from_Elandsfontein
  9. https://open.uct.ac.za/items/e7ac48a8-b73c-4ebf-b4f1-3dc6338c72d0
  10. https://www.researchgate.net/figure/Comparisons-of-teeth-measurements-of-Equus-capensis-from-Coopers-D-and-Equus-quagga-The_tbl3_333104697
  11. https://www.cambridge.org/core/services/aop-cambridge-core/content/view/BB99779E263B69092C6D58473706E96F/S0094837300008927a.pdf/pleistocene-extinctions-the-pivotal-role-of-megaherbivores.pdf
  12. https://doi.org/10.1016/j.quascirev.2019.106161
  13. https://www.researchgate.net/publication/340991923_The_Palaeo-Agulhas_Plain_A_lost_world_and_extinct_ecosystem
  14. https://www.researchgate.net/publication/330572684_The_Pleistocene_fauna_of_the_Cape_south_coast_revealed_through_ichnology_at_two_localities
  15. https://open.uct.ac.za/bitstream/handle/11427/32408/thesis_sci_2020_malherbe%20megan.pdf?sequence=1&isAllowed=y
  16. https://www.sciencedirect.com/science/article/abs/pii/S0033589408000914
  17. https://portals.iucn.org/library/efiles/documents/2002-043.pdf
  18. https://peerj.com/articles/6909/
  19. https://pmc.ncbi.nlm.nih.gov/articles/PMC6525595/
  20. https://www.sciencedirect.com/science/article/abs/pii/S004724840600162X
  21. https://pmc.ncbi.nlm.nih.gov/articles/PMC7126070/
  22. https://doi.org/10.1016/j.jhevol.2013.08.004
  23. https://doi.org/10.17159/sajs.2019/5135
  24. https://www.annualreviews.org/doi/10.1146/annurev-environ-102016-060653
  25. https://www.tandfonline.com/doi/abs/10.1080/00359190609519957
  26. https://www.researchgate.net/publication/233368144_Distribution_and_history_of_the_Cape_zebra_Equus_capensis_in_the_Quaternary_of_Africa
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