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Takahē

The Takahē (Porphyrio hochstetteri), also known as the takahē, is a large, flightless endemic to and the world's largest living member of the family Rallidae. Measuring approximately 63 cm in length and weighing up to 2.7 kg, it features vibrant cobalt-blue plumage on the head, neck, and underparts, olive-green upperparts, a massive scarlet bill and legs, and reduced wings unfit for flight. Adapted to and subalpine environments, the takahē inhabits tussock grasslands, wetlands, and shrublands, where it grazes on snow tussock (Chionochloa spp.), sedges, ferns, and grasses, using its strong bill to dig for roots and shoots in a low-nutrient diet that requires extensive foraging. Once widespread across New Zealand's lowlands, it was driven to apparent by and loss in the late , only to be rediscovered in 1948 in the remote Murchison Mountains of . Highly territorial and monogamous, takahē pairs defend territories of 10–40 hectares, breeding annually in and raising typically one per season in ground nests lined with vegetation. Their behavior includes social displays like and mutual , and they exhibit remarkable adaptability in but face challenges in the wild due to slow rates and vulnerability to introduced predators. Classified as Endangered by the IUCN, the species' global population stands at more than 500 individuals as of 2025, with more than half in managed wild sites and the rest in predator-proof islands or programs. The Takahē Recovery Programme, led by New Zealand's Department of Conservation since 1984, has been pivotal in averting extinction through captive rearing, genetic management to combat inbreeding, and strategic releases into safe habitats like offshore islands and mainland sanctuaries. Key threats include predation by stoats, rats, and cats; competition from introduced deer and chamois for tussock food sources; and habitat degradation from grazing. Recent efforts, such as the 2024 establishment of a new wild population in Ōtākou and the February 2025 release of 18 birds in the Rees Valley, aim to boost numbers to sustainable levels exceeding 1,000 birds, fostering genetic diversity and wild breeding success. As a cultural taonga (treasure) to Māori and a symbol of conservation triumph, the takahē underscores the impacts of human-induced biodiversity loss and the potential for restoration in Aotearoa New Zealand.

Taxonomy and nomenclature

Classification and systematics

The takahē belongs to the family Rallidae, which encompasses rails, crakes, and coots, and is classified within the genus Porphyrio as Porphyrio hochstetteri, the . This species is distinguished from the extinct , formerly known as Notornis mantelli but now recognized as Porphyrio mantelli, which represents a separate lineage within the same genus. The scientific name Porphyrio hochstetteri was formally described by A.B. Meyer in 1883, honoring the Austrian geologist Ferdinand von Hochstetter. As a flightless member of the Rallidae, the takahē exemplifies evolutionary adaptations to 's long isolation from mainland continents, where the absence of mammalian predators allowed rails to evolve into large, terrestrial forms. Its closest living relative is the pukeko (Porphyrio porphyrio), a smaller, flight-capable swamp hen that shares a common ancestor with the takahē but retained the ability to fly due to more recent colonization of New Zealand. Other relatives within the Porphyrio genus include various swamphens across the , highlighting the group's diversification in island environments. Genetic analyses of ancient and modern have confirmed that the takahē diverged from the (moho) approximately 1.5 million years ago, driven by Pleistocene glacial cycles that isolated populations across New Zealand's emerging landmasses. This divergence coincided with the joining of the North and South Islands around the same period, leading to distinct evolutionary trajectories for the two amid fluctuating climates and habitats. The takahē is considered monotypic, with no recognized , reflecting its uniform genetic profile across current populations despite historical range contractions.

Etymology and naming

The Māori name takahē derives from the term takahea, meaning "to stand up tall and stamp one's feet on the ground," which describes the bird's characteristic stamping behavior while foraging. This name was first documented by European explorers in the mid-19th century, following early encounters with live specimens in remote Fiordland regions, such as the 1849 sighting by sealers in Dusky Bay who followed the bird's tracks. The scientific binomial Porphyrio hochstetteri was assigned by German ornithologist Adolf Bernhard Meyer in 1883, with the specific epithet honoring Austrian geologist Ferdinand von Hochstetter, who traveled through from 1858 to 1859 and facilitated the collection of early bird specimens during geological surveys. Prior to this classification, specimens were often lumped with fossils under the Notornis, established by in 1848 for subfossil bones initially thought to represent a single extinct species. Historical naming confusion arose because the extinct North Island takahē, known to Māori as moho or mohoau (meaning "lonely"), was described from 1840s fossils as Notornis mantelli, leading early scientists to assume South Island live birds were the same taxon. Modern taxonomy, informed by morphological and genetic analyses, distinguishes the two as separate species—P. mantelli for the North Island form and P. hochstetteri for the South Island—resolving the earlier conflation. In English, the bird is commonly referred to as the South Island takahē to differentiate it from its northern relative, or as the mountain takahē, emphasizing its preference for tussock grasslands above the treeline.

Physical description

Morphology and size

The takahē (Porphyrio hochstetteri) is a robust, flightless recognized as the largest living member of the family Rallidae, with an overall body length of approximately 63 cm and a standing height of up to 50 cm at the shoulder. takahē exhibit a stocky build, with males averaging 2.67 kg (range 2.25–3.25 kg) and females averaging 2.27 kg (range 1.85–2.6 kg), though overall weights reported in conservation records span 2.3–3.8 kg depending on condition and age. Flightlessness is evident in several anatomical adaptations that prioritize terrestrial mobility over aerial capability. The wings are greatly reduced in size and incapable of sustaining flight, serving instead limited roles in displays. In contrast, the legs are strong and stout, colored red with orange thighs, supporting rapid running and climbing on steep terrain; the feet are broad and equipped with long toes, facilitating navigation through dense tussock vegetation without sinking. The bill represents a key morphological feature suited to the takahē's herbivorous lifestyle, forming a large, conical structure that is bright red and reinforced by a prominent red frontal shield extending across the forehead. This robust beak enables the bird to grasp and shear fibrous plant material, such as snow tussock. Sexual dimorphism in the takahē is subtle, primarily manifested in body size where males are slightly larger and heavier than females on average, with no notable differences in bill structure, leg proportions, or other external features.

Plumage and coloration

The adult takahē displays vibrant, iridescent plumage characterized by a dark royal blue head, neck, and breast, transitioning to peacock blue on the shoulders and iridescent turquoise with olive-green shades on the back and rump. The undertail coverts are strikingly white, contrasting with the overall dark tones. The bird features a massive, bright red bill that is paler towards the tip, topped by a scarlet frontal shield extending from the base of the culmen to the rear of the eye. The legs are stout and red with an orange tinge on the undersides, while the iris is a vivid red. There is minimal sexual dimorphism in coloration, with males and females exhibiting nearly identical plumage patterns. Juveniles hatch covered in deep blue to black down, which is soon replaced by juvenile feathers starting around one month of age. Their plumage is duller and less iridescent than that of adults, with muted olive-green tones dominating the upperparts and a general lack of the vibrant blue sheen; the bill appears blackish-orange, and the legs are dull pink-brown. Immatures resemble adults but retain slightly subdued colors, with the iris reaching full red by 5–6 months. Full adult plumage is achieved after the first complete moult, typically by around six months. The takahē's plumage exhibits no significant seasonal variations, maintaining consistent coloration year-round. This blue-green serves a camouflage function, blending with the tussock and subalpine in their habitats.

History and rediscovery

Pre-20th century records

The takahē held a place in oral traditions, particularly among of Southland and , where it was recognized as a inhabiting the remote high country and occasionally hunted as a food source. These accounts describe the takahē in subalpine tussock grasslands, reflecting its elusive nature in rugged terrains that limited frequent encounters. The first recorded European encounter with a live South Island takahē occurred in 1849, when Walter Mantell captured a specimen on Resolution Island in Foveaux Strait, . Mantell shipped the live to the London Zoological Society, but it perished during the voyage, with its skin later preserved and described in a notice by G.A. Mantell. This event marked the initial scientific recognition of a living representative of the , previously known only from bones. In 1859, members of the Austrian expedition, led by geologist Ferdinand von Hochstetter, collected two takahē skins during explorations in Dusky Sound, . These specimens provided key material for later taxonomic study, contributing to the formal description of the [South Island](/page/South Island) takahē as a distinct species, Porphyrio hochstetteri, in 1883. Throughout the , takahē were reported as relatively abundant in 's remote valleys and grasslands by early explorers and settlers, though sightings remained sporadic due to the bird's habitat in inaccessible areas. The last confirmed mainland sighting before a prolonged absence occurred on 7 1898, near the Middle Arm of , where a mustering named Rough captured a specimen on the lakeshore. This event, documented by local resident Jack Ross, represented the fourth and final pre-20th century collection from the region.

20th century extinction declaration and rediscovery

By the early , the takahē was widely regarded as , a status reinforced by ornithologist Walter Buller in his comprehensive works on birds, where he noted the absence of sightings following the capture of the last known specimen in 1898. This declaration stemmed from decades without verified observations, as the bird's habitat had been severely impacted by human activities and introduced species. After the 1898 specimen, there were no confirmed sightings until the rediscovery, underscoring the species' drastic decline. The takahē's rediscovery came on November 20, 1948, when ecologist Geoffrey Orbell, leading an expedition organized by the Wildlife Service, located a small population in the remote Murchison Mountains of . Orbell's team, motivated by reports of unusual bird tracks near , confirmed the presence of living birds after hearing distinctive calls and observing two adults with a chick in what became known as Takahē Valley; initial estimates placed the population at 250–300 individuals. In the 1950s, follow-up surveys by the Wildlife Service, including efforts led by G. R. Williams, refined the population estimate to around 250 birds and mapped their distribution within the isolated alpine tussock grasslands. These assessments highlighted the takahē's vulnerability to introduced predators like stoats, which preyed on eggs and chicks, and , which competed for food resources. The first live captures for occurred in the early 1960s, enabling closer examination of the birds' biology without immediate harm to the wild population. This rediscovery dramatically illustrated the severe impacts of invasive predators and herbivores on , prompting urgent protective measures that culminated in the designation of a 500 km² within soon after the rediscovery to safeguard the remaining and restrict human access.

Distribution and habitat

Historical range

Prior to the arrival of humans, the takahē (Porphyrio hochstetteri) was widely distributed across the of , occupying diverse habitats including lowland grasslands, forests, and wetlands from up to zones. Subfossil bones recovered from over 50 sites, such as swamps, caves, sand dunes, and middens, confirm its former presence in these environments, particularly in eastern lowland areas that supported grassy vegetation and forest edges. The arrival of around 1300 AD marked the beginning of significant range contraction for the takahē, driven by hunting pressure and habitat alterations like forest clearance for , which confined the species to isolated, remote refugia in the mountainous interior. By this period, populations had retreated from accessible lowlands, with evidence indicating a shift away from former strongholds in favor of higher-elevation grasslands. In the , the takahē's distribution had further narrowed, becoming primarily restricted to the Murchison Mountains and adjacent valleys within , where small remnant populations persisted in tussock grasslands. Scattered historical reports suggested occasional presence beyond this core area, including unconfirmed sightings in and the regions.

Current range and habitat preferences

The takahē's current range is confined to protected mainland sites in New Zealand's and several predator-free offshore islands, as a result of targeted translocation programs. The core wild population persists in the Murchison Mountains of , where birds occupy subalpine and plateaus. Additional mainland sites include Gouland Downs in Kahurangi National Park and the Rees in the Upper Whakatipu area of , with the latter receiving multiple releases totaling over 50 birds in 2025 (including 18 in February, 27 in March, and additional birds in September) to bolster wild numbers, aiming for 70-80 by year-end. Translocations have also established self-sustaining populations on offshore islands such as Kapiti, Maud, , Tiritiri Matangi, Codfish Island (Whenua Hou), and Motuihe Island, providing secure environments free from mammalian predators. Takahē exhibit a strong preference for subalpine tussock grasslands, particularly those dominated by snow tussock (Chionochloa spp.), at elevations ranging from 900 to 1,800 meters. These habitats offer snow-free foraging areas during the accessible summer period, consisting of open tussock meadows interspersed with sedges, rushes, and occasional fern bogs that support the birds' grazing lifestyle. In , they also utilize red tussock (Chionochloa rubra) flats along river valleys for seasonal movement. Within these grasslands, takahē select microhabitats with dense vegetative cover for nesting, often building raised ground nests from snow tussock leaves to shield eggs from moisture and cold. Preferred sites are those proximate to abundant snow tussock stands for efficient feeding access, while the flightless birds generally avoid steep slopes that hinder mobility and increase exposure risks.

Behavior and ecology

Diet and foraging

The takahē maintains a primarily herbivorous diet, centered on the starchy leaf bases, roots, and shoots of snow tussock grasses (Chionochloa spp.), which form the bulk of its nutritional intake in snow-free alpine grasslands. This core food source is supplemented by sedges (Uncinia spp., Carex coriacea), rushes (Juncus spp.), speargrass (Aciphylla spp.), and fern rhizomes, providing essential fibers and minerals. Opportunistic consumption of large insects such as moths, beetles, and wētā occurs seasonally, particularly in summer, to supplement protein needs. Foraging techniques rely on the bird's robust to grasp and strip tussock shoots downward or pull up by the base, often combined with digging using its feet to access underground rhizomes and roots. Takahē preferentially target new growth emerging after , selectively on nutrient-rich juvenile tissues while avoiding tougher, mature parts. Daily foraging bouts can extend up to 19 hours to meet energy demands from this low-nutrient, high-fiber vegetation. Seasonal shifts in diet reflect environmental constraints: in summer and autumn, open s allow sustained access to tussock and sedges, with increased for support; in winter, heavy limits grassland access, prompting relocation to forested valleys where rhizomes (Hypolepis millefolium) comprise 60–80% of intake, alongside smaller amounts of forest grasses and sedges. Reduced activity occurs under deep snow cover, with conserving by relying on stored fats and accessible subsurface foods. The takahē's nutritional adaptations enable efficient processing of its fibrous diet, including a digestive system augmented by an enlarged that hosts microbial to break down and extract nutrients from plant material otherwise indigestible to many . This supports survival on nutrient-poor , with the bird's larger ceca compared to related species like the pukeko facilitating higher fiber digestibility.

Social and reproductive behavior

Takahē exhibit a monogamous , with pairs forming long-term bonds that can last 12 years or more, potentially for life. These pairs vigorously defend breeding territories ranging from 15 to 40 hectares, depending on quality, against intruders through vocalizations and physical confrontations if necessary. Post-breeding, groups typically consist of 4 to 6 individuals, including the parental pair and their surviving , which remain with the adults for several months; however, takahē do not form large flocks or exhibit extensive social aggregation beyond these units. Breeding occurs primarily during the spring months of to December, aligning with optimal environmental conditions in their alpine habitats. Pairs produce a clutch of 1 to 3 eggs, with two-egg clutches being most common for initial attempts, laid in a bulky nest constructed under dense . lasts approximately 30 days and is shared equally by both parents, who take turns to ensure the eggs remain at a stable temperature. Chick rearing involves intensive biparental care, with both adults providing protection, warmth, and guidance to the precocial but dependent young. hatch covered in black down and remain under close parental supervision, fledging around 3 months of age when they can more independently. Full independence is achieved at about 1 year, though juvenile mortality is high, with approximately one-third of failing to survive to breeding age due to predation, weather, and nutritional challenges. Vocalizations play a key role in social and reproductive interactions, including a series of grunting or hooting calls used by pairs to advertise and defend territories, often in response to intruders. Chicks produce high-pitched peeping or contact calls to solicit food and maintain proximity to parents, facilitating family cohesion during the vulnerable rearing period.

Conservation and status

Threats and population decline

The takahē (Porphyrio hochstetteri) faced initial population declines following the arrival of Polynesian settlers in around the , primarily due to for and habitat modification through burning for agriculture. communities valued the bird as a substantial food source, contributing to its rarity by the mid-19th century. European colonization in the 1800s exacerbated these pressures through intensified , widespread for farming and , and the of invasive predators such as rats, stoats, and cats. Fires set for land clearance and by introduced livestock further fragmented the takahē's preferred tussock grasslands, reducing available foraging areas. By the late , these combined factors had drastically reduced takahē numbers to near , leading to its official declaration as extinct in 1898. Following its rediscovery in 1948 in the remote Murchison Mountains of , the population—initially around 250 birds—continued to plummet in the due to predation by and competition from introduced for snow tussock (Chionochloa spp.) vegetation. Stoat irruptions, often triggered by beech forest seeding events, decimated pairs and chicks, while deer depleted food resources, pushing numbers below 500 by the 1980s and reaching a low of 120 individuals in 1981. Ongoing risks to the remnant takahē population include predation by introduced mammals, which remains a primary driver of mortality, particularly in unmanaged areas. poses an emerging threat by altering alpine snow cover patterns, potentially reducing access to tussock foraging sites during winter and increasing vulnerability to cold snaps. Stochastic events such as avalanches and severe weather can cause sudden losses in the isolated habitat, where birds are concentrated in steep terrain. Additionally, the species' small population size has led to , evidenced by reduced hatching success and genetic bottlenecks that compromise long-term viability.

Recovery programs and efforts

Following the rediscovery of the takahē in 1948, the New Zealand Department of Conservation established the Takahē Recovery Programme in the early 1980s to coordinate conservation efforts and prevent extinction, building on initial post-rediscovery surveys that identified a critically low population confined to the Murchison Mountains in . The programme's core strategies include at facilities such as Pūkaha Mount Bruce National Wildlife Centre and , where eggs are incubated artificially and chicks are reared using innovative techniques pioneered by ornithologist Elwyn Welch, who successfully used bantam hens as surrogate parents in the and to boost hatchling survival rates. To address predation threats, intensive predator control operations in focus on trapping stoats—the primary killer of takahē chicks—through networks of over 3,500 traps in managed areas, significantly reducing mortality during breeding seasons. Island translocations began in the mid-1980s to establish secure populations on predator-free offshore islands, with the first transfers of 20 breeding pairs to in 1985 providing a safe refuge and genetic reservoir for the species. Complementing this, an egg-swapping technique involves replacing infertile or addled eggs in wild nests with fertile ones from captive stock, allowing wild pairs to raise unrelated chicks while minimizing disturbance and enhancing recruitment without full removal from natural habitats. These efforts have driven population recovery, growing from approximately 140 birds in 1981 to over 500 by 2025, with recent wild releases—including 18 takahē into the Rees Valley near Queenstown in February 2025, 33 in April 2025, and additional birds in September 2025—aiming to establish self-sustaining mainland populations through ongoing translocations planned for up to 80 birds by year's end. International collaboration with the IUCN's Conservation Planning Specialist Group has informed genetic management strategies to maintain diversity across meta-populations, while community and involvement, including monitoring in sites like the Rees Valley, ensures culturally informed and sustainable programme implementation.

Current population and future prospects

As of late 2025, the takahē (Porphyrio hochstetteri) is classified as Nationally Vulnerable under the (NZTCS). The total population exceeds 500 individuals and is growing at approximately 5% annually, reflecting ongoing recovery efforts. More than half of these birds now live in wild sites, including the core population in the Murchison Mountains, translocations to offshore islands, and recent mainland releases. The population comprises an estimated 141 breeding pairs, with preserved at around 97.3% through regular transfers of individuals between subpopulations to optimize pairings and prevent . Juvenile survival rates in protected areas have improved due to enhanced predator control, though specific figures vary by site; overall, these measures support steady recruitment into the adult cohort. The recovery program has successfully increased wild occupancy, with over 50% of birds now outside captive or populations. Long-term prospects aim for self-sustaining populations across multiple sites, bolstered by New Zealand's Predator Free 2050 initiative, which targets eradication of key invasive predators to enable expansion beyond current strongholds. Monitoring advancements in 2025 include AI-driven tracking for behavioral insights and expanded genetic analyses to guide translocations and maintain diversity. A key milestone is the projected establishment of up to 80 birds in the Rees Valley site by year's end, indicating viable growth in new mainland habitats. However, challenges persist in sustaining this trajectory amid , such as altered habitat suitability and increased events that could exacerbate predation pressures.

References

  1. [1]
    South Island Takahe - Porphyrio hochstetteri - Birds of the World
    Diet and Foraging ... Eats predominantly leaf video bases of Chionochloa tussocks and other alpine grass species; leaf bases of Cyperaceae, grass seeds and fern ( ...<|control11|><|separator|>
  2. [2]
    Porphyrio hochstetteri (southern takahe) - Animal Diversity Web
    They occasionally take insects as well, especially when raising young. They also eat rhizomes of native ferns. Primary Diet; herbivore herbivore. folivore
  3. [3]
    The takahē's ecological niche - Science Learning Hub
    Feb 11, 2019 · Takahē get their food and shelter from alpine grassland species such as snow tussocks, sedges and rushes. The food is low in nutrients.
  4. [4]
    South Island takahe | Takahē - New Zealand Birds Online
    The South Island takahe is a rare relict of the flightless, vegetarian bird fauna which once ranged New Zealand.
  5. [5]
    Takahē: NZ native land birds - Department of Conservation
    The flightless takahē is a unique bird, a conservation icon and a survivor. Population: Around 500 as of October 2023. New Zealand status: Endemic.
  6. [6]
    South Island Takahe Porphyrio Hochstetteri Species Factsheet
    IUCN Red List assessment history ; 2008. Endangered. D1 ; 2006. Endangered. D ; 2004. Endangered. D ; 2000. Endangered. D.
  7. [7]
    Takahē thrive in new wild home on Ngāi Tahu whenua in Ōtākou ...
    Aug 15, 2024 · The national population now numbers around 500, with annual growth around 8% a year. The takahē recovery focus is now on establishing new wild ...
  8. [8]
    Takahē released to grow wild population
    Feb 12, 2025 · A further two takahē releases into the Rees Valley are planned for later this year, with the aim of establishing a population of up to 80 takahē ...
  9. [9]
    North Island Takahe - Porphyrio mantelli - Birds of the World
    Monotypic. Subspecies. Estimated year of extinction 1894. Demise attributed to anthropogenic modifications of habitat combined with hunting and predation ...
  10. [10]
    Species Details - NZTCS
    Species Type. Bird. Formal Name. Name and Authority. Porphyrio hochstetteri A.B. Meyer, 1883. Scientific Name. Porphyrio hochstetteri. Genus. Porphyrio. Species ...
  11. [11]
    The takahē's evolutionary history - Science Learning Hub
    Feb 11, 2019 · Once in New Zealand and free of land-based predators, the North Island and South Island takahē evolved to become large flightless birds.
  12. [12]
    A Tale of Two Rails: The Pūkeko and the Takahē - Island Conservation
    Sep 17, 2018 · The Pūkeko and the Takahē share a common ancestor. The difference is that the Takahē's ancestor arrived in New Zealand many thousands of years ...Missing: history isolation
  13. [13]
    Molecular Ecology | Molecular Genetics Journal | Wiley Online Library
    Nov 29, 2023 · The glacial/interglacial cycles of the Pleistocene are implicated in the divergence between takahē and moho ~1.5 Mya. This divergence date is ...
  14. [14]
    Evolution of takahē mapped for benefit of species | University of Otago
    Dec 4, 2023 · The two takahē species subsequently evolved when the North and South Island landmasses joined around 1.5 million years ago,” Dr Rawlence says.
  15. [15]
    Takahē – new genetic research - Science Learning Hub
    Dec 15, 2023 · Genetic analysis has also revealed that takahē are closely related to their extinct North Island cousin, the moho, contrary to previous research ...
  16. [16]
    Takahe - the bird that came back from the dead | New Zealand ...
    To understand, we need to first look at the takahe's closest relative, the pukeko. Charlie Douglas, the legendary West Coast explorer, described the pukeko thus ...
  17. [17]
    Minor on Porphyrio hochstetteri (Meyer, AB 1883) - BirdForum
    Sep 4, 2023 · Christian Gottlieb Ferdinand Ritter von Hochstetter was an Austrian geologist. He studied theology at Tübingen University (1847–1851), gaining a ...
  18. [18]
    Takahē – an introduction - Science Learning Hub
    Feb 11, 2019 · The takahē's scientific name is Porphyrio hochstetteri and it is also called the South Island takahē to distinguish it from its extinct ...
  19. [19]
    https://www.nzbirdsonline.org.nz/assets/95597/1691731837-180_south-20island-20takahe.pdf
  20. [20]
    South and North Island Takahē | DinoAnimals.com
    Length: averages 63 cm (24.8 in) ; Weight: males average 2.7 kg (5.95 lb); females average 2.3 kg (5.07 lb); ranging from 1.8–4.2 kg (3.97-9.26 lb) ; Lifespan: 18 ...
  21. [21]
    [PDF] 180_South Island Takahe - New Zealand Birds Online
    Olson (1973b) recognized two sub-families: the monotypic Himantomithinae and the Rallinae, with Himantomithinae ... when birds meet each other in neutral area, ...
  22. [22]
    South Island Takahe - Creature Atlas
    Jun 9, 2025 · Grass Specialist. Its diet consists mainly of tussock grasses, especially the seeds and softer bases of these alpine plants.
  23. [23]
    Threats to takahē - Science Learning Hub
    Feb 11, 2019 · However, the only clear references to takahē in Māori oral histories come from Māori living in Southland and Fiordland. It is possible that ...Missing: traditional | Show results with:traditional
  24. [24]
    The scientific exertions of an enterprising colonial son: Walter BD ...
    Almost from the time of his arrival in New Zealand in 1840, Walter Baldock Durrant Mantell started collecting moa bones, sending them to his father, ...
  25. [25]
    [PDF] Takahe (Porphyrio hochstetteri) recovery plan: 2007-2012
    Twelve to eighteen Burwood-reared takahe yearlings are now released annually, and at least 38% of breeding pairs in the Murchison. Mountains consist of at least ...
  26. [26]
    Takahe, Porphyrio mantelli | New Zealand Birds
    Sep 7, 2023 · The discovery of the first specimen, in 1849, at Duck Cove, Resolution Island, is thus described by Dr Gideon Mantell when exhibiting the skin ...
  27. [27]
    [PDF] Takahe Recovery Plan (Porphyrio [Notornis] mantelli)
    Takahe on islands feed on a mixture of native and introduced grasses. Grasslands and swamps appear to be the highly preferred habitat on Kapiti, a largely ...Missing: behavior | Show results with:behavior
  28. [28]
    Back from extinction – the Takahe - envirohistory NZ
    Jan 24, 2010 · As figured in Sir Walter Buller's “Birds of New Zealand”, the notornis or takahe was a handsome bird, resembling in many respects the swamp hen.Missing: declaration 1898
  29. [29]
    (PDF) The takahe – a relict of the Pleistocene grassland avifauna of ...
    Aug 9, 2025 · The takahe (Notornis mantelli), an endangered rail once widely distributed through New Zealand, had become restricted to Fiordland, and possibly Nelson and the ...Missing: Caesar | Show results with:Caesar
  30. [30]
    [PDF] Demography of takahe (Porphyrio hochstetteri) in Fiordland
    Aug 30, 2011 · In pre-Polynesian times takahē were distributed across most lowland regions in the eastern part of the South Island (Trewick & Worthy 2001), and ...
  31. [31]
    A Holocene fossil South Island takahē (Porphyrio hochstetteri) in a ...
    Apr 4, 2019 · Takahē subfossils have been found in a variety of different habitats and altitudes across the South Island, including formerly forested ...
  32. [32]
    Takahē - Large forest birds - Te Ara Encyclopedia of New Zealand
    Takahē were thought to be extinct – but then, in 1948, Geoffrey Orbell rediscovered the South Island species (Porphyrio hochstetteri) in Fiordland's Murchison ...
  33. [33]
    Visit a takahē - Department of Conservation
    As of 2024, the population is estimated to be around 240 birds. Kahurangi ... As of 2024, there are up to 20 takahē in the park, with pairs living ...
  34. [34]
    [PDF] WINTER USE BY TAKAHE OF SUMMER-GREEN FERN
    In the beech forest the takahe diet consists of 60-80% Hypolepis millefolium rhizomes. Other winter foods eaten in smaller amounts include the leaf bases of ...
  35. [35]
    Organ weight and weight relationships in takahe and pukeko
    Aug 6, 2025 · The Takahe had significantly deeper beaks, shorter intestines and larger recta than the Pukeko. The pyloric caeca were longer but not ...
  36. [36]
    [PDF] Takahē and the Takahē Recovery Programme Fact Sheet 2018-2019
    Weird fact – because of their highly fibrous diet takahē can do up to 7m - 9m of poo a day! Breeding: reach sexual maturity 2-3 years, monogamous. (although ...
  37. [37]
    in New Zealand - jstor
    It is here that comparative studies with the Takahe's closest relative, the Pukeko, become relevant. History of Pukeko in New Zealand. The story of the Pukeko ...
  38. [38]
    Resurrecting the Takahe: A New Zealand Conservation Tale
    Feb 12, 2024 · The bird's unique appearance and behaviors made it a significant part of the indigenous Maori culture, featuring in folklore and traditions as a ...
  39. [39]
    The incredible takahē story - Department of Conservation
    Takahē were believed to be extinct, not once, but twice. The first in 1850, then in 1898 until they were rediscovered on 20 November 1948.
  40. [40]
    Takahē (Porphyrio hochstetteri) - Biology Online Tutorial
    These birds are very colorful. The plumage from the head to the breast is deep blue to peacock-blue. The wings and back are olive-green and blue.
  41. [41]
    Climate change risks to conservation
    Climate change risks to conservation · Other threats to native species. How our native species and ecosystems respond to climate change is complicated by other ...<|control11|><|separator|>
  42. [42]
    Hatching failure increases with severity of population bottlenecks in ...
    Habitat destruction and exploitation are causing catastrophic population declines in many species around the world. Even if endangered populations recover ...
  43. [43]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC327186/
  44. [44]
    Advancing recovery strategies for the last wild takahē
    Oct 23, 2023 · The takahē is the rarest flightless rail in the world. This project will create genomic tools to assess takahē health and persistence.Missing: selection avoidance scree
  45. [45]
    Takahē conservation efforts - Science Learning Hub
    Feb 11, 2019 · It was officially declared extinct in 1898. It was thought to have experienced the same fate as the moa and the moho (North Island takahē). Ka ...Missing: confirmed | Show results with:confirmed
  46. [46]
    Elwyn Welch - a man, his bantams and a tale of takahē
    Mar 2, 2020 · Elwyn Welch, a farmer, used trained bantams to help incubate and raise takahē eggs, starting the first captive rearing program in NZ.Missing: Auckland zoos
  47. [47]
    Takahē released on Rotoroa island | Auckland Zoo News
    Aug 28, 2016 · DOC's partnership with Auckland Zoo and Rotoroa Island Trust (RIT) to have breeding takahē on pest-free Rotoroa is part of its Takahē Recovery ...Missing: collaboration | Show results with:collaboration
  48. [48]
    Takahē: the challenging road to recovery | Conservation blog
    Nov 20, 2021 · However, with a higher proportion of takahē in their natural habitat, periodic pressures, such as predator surges and environmental conditions, ...
  49. [49]
    Twenty Nine Takahē Successfully Released In Murchison Mountains
    Feb 22, 2025 · ... predator controlled areas, with 3500 traps in place! The breeding is so successful that the next challenge is to establish a new wild ...
  50. [50]
    Maud Island - Wikipedia
    ... Maud Island's kākāpō population was translocated to more forested islands. The takahē was also introduced there in 1985. Another rare species is the Maud Island ...Missing: 1980s | Show results with:1980s
  51. [51]
    Population data - Science Learning Hub
    Feb 7, 2019 · The worksheets as detailed in the article Takahē – a context for learning and in this interactive planning pathway, can be used for Biology ...
  52. [52]
    Managing the takahē population - Department of Conservation
    The Takahē Recovery Programme is in the business of making more takahē. Every transfer is planned and carried out with this aim in mind. The health, age and ...
  53. [53]
    Takahë | Conservation Planning Specialist Group
    The takahë is the largest living member of the rail family. It is flightless and occurs only in New Zealand. Two different species existed historically.<|separator|>
  54. [54]
    Takahē Recovery Programme - Department of Conservation
    The Takahē Recovery Programme brings together our DOC takahē team, tangata whenua, and communities across Aotearoa New Zealand.The incredible takahē story · How we're helping takahē · Get involved · Donate
  55. [55]
    Takahē spread their wings further afield | Fulton Hogan
    Mar 3, 2025 · 18 takahē were released in Rees Valley, with more planned. The goal is to establish a large population in the Upper Whakatipu, with over half ...
  56. [56]
    [PDF] Takahē Recovery Programme Annual Report 2022-23
    As of 31 September 2023, the end of the 2022 'takahē year', the takahē population was estimated at 493 birds (141 breeding aged pairs), consisting of 208 ...
  57. [57]
    How new tech could help save New Zealand's unique birds - NPR
    To save its unique and rare birds, New Zealand is turning to AI and genetic research. September 18, 20257:17 AM ET. Heard on All Things Considered.
  58. [58]
    Takahē released in the Rees Valley - a conservation milestone
    Feb 12, 2025 · The Rees Valley's alpine tussock grasslands provide an ideal habitat for takahē, whose diet includes the starchy bases of tussock leaves ...
  59. [59]
    Climate‐change impacts exacerbate conservation threats in island ...
    Feb 9, 2021 · Climate-change impacts exacerbate conservation threats in island systems: New Zealand as a case study. Cate Macinnis-Ng,. Corresponding Author.