Factors limiting kererū (Hemiphaga novaeseelandiae) populations across New Zealand

Carpenter, Joanna K.; Walker, Susan; Monks, Adrian; Innes, John; Binny, Rachelle N.; Schlesselmann, Ann-Kathrin

doi:10.20417/nzjecol.45.30

Cited by 3 publications

(5 citation statements)

References 25 publications

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“…Although some columbid species flourish in landscapes modified by humans, such as the widespread Feral Pigeon, Columba livia domestica (Carlen et al, 2021), the Zenaida Dove, Zenaida aurita (Wolff et al, 2018), or the invasive Eurasian Collared-Dove, Streptopelia decaocto (Luna et al, 2018), most species rely on their natural habitats to persist. For instance, the occupancy of the Kereru, Hemiphaga novaeseelandiae, an endemic New Zealand Pigeon, has been affected by habitat loss resulting from European settlement in New Zealand (Carpenter et al, 2021). Following Walker (2007), the present study confirms that the loss of natural habitat is the greatest cause of extinction and populations decline in columbid species.…”

Section: Anthropogenic Driverssupporting

confidence: 65%

Identifying global research and conservation priorities for Columbidae: a quantitative approach using random forest models

Cambrone¹,

Jean-Pierre²,

Bezault³

et al. 2023

Front. Ecol. Evol.

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The family of Columbidae, including pigeons and doves, remains understudied despite their patrimonial value and high ecological and conservation relevance. Currently, 353 extant columbid species are listed in the IUCN red list, with about 20% of them being threatened with extinction. However, there has been little effort so far to synthetize the available information on factors influencing extinction risk and the allocation of research effort among columbid species. In this context, using random forest models, the present study aims at quantitatively assessing to what extent environmental, life history and socio-political factors may drive the extinction risk of pigeons and doves and explain differences in scientific attention among species. We found that high risk of extinction in columbids is associated with small historical range, exposure to invasive alien mammals and living in isolated islands and/or at low altitudes, while the probability of population decline is associated with species body size, surrounding human density and narrow habitat breadth. We also evidenced a large disparity between species or population extinction risk and scientific interest. Indeed, most of the studies on columbids have been conducted by scientists from North America and Western Europe on their local species, whereas species from biodiversity hotspots, which are more at risk of extinction, have comparatively received little attention. This unequal acquisition of knowledge creates gaps that deserve to be filled in order to have a good appreciation of extinction risk in columbids and associated threats, through fair transnational cooperation, academic training and regional coordination in conservation-oriented research on columbids.

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Section: Anthropogenic Driverssupporting

confidence: 65%

Identifying global research and conservation priorities for Columbidae: a quantitative approach using random forest models

Cambrone¹,

Jean-Pierre²,

Bezault³

et al. 2023

Front. Ecol. Evol.

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“…For some prey species, any degree of predator reduction may have some benefit (i.e., linear relationships), while for some vulnerable prey species there may be no response unless predator densities are reduced to very low levels. The empirical evidence for most secondary prey species supports the latter (Figure 2)-positive responses generally occur below threshold predator densities, but note that some prey populations show little or no response even at low predator densities (see Figure 2 in Binny et al, 2020;Figure 5 in Carpenter et al, 2021; Figure 2 to Figure 5 in Norbury et al, 2022;Figure 3 in Spencer et al, 2017). There are many explanations for this (see Doherty & Ritchie, 2017), including compensatory effects of other pest predators (e.g., Courchamp et al, 1999a;Norbury et al, 2013), or persistence of factors that are more limiting than predation, such as inadequate food supply or shelter (e.g., Fischer et al, 2020;Lavers et al, 2010).…”

Section: Introductionmentioning

confidence: 81%

“…In these cases, prey can potentially increase to density "c" or "c*" but note that densities below "b" or "b*" can still decline to extinction (in the case of Figure 3g) or to a low-density domain "a" (in the case of Figure 3i). These predictions are evident in the empirical predator density-impact functions for birds, lizards, and invertebrates in Figure 2-positive prey outcomes occur only when predator densities are reduced below a low critical level, but below this level some prey populations still fail to respond (as shown in Binny et al, 2020;Carpenter et al, 2021;Norbury et al, 2022;Spencer et al, 2017). While there are many potential mechanisms for this type of response (outlined earlier), the models in Figure 3 offer an alternative explanation based on total response predation theory.…”

Section: Total Response Models Predict Predator Density-impact Functi...mentioning

confidence: 92%

“…Examples of empirically derived predator density‐impact functions for vulnerable secondary prey species, showing relationships between: percentage trap catch of brushtail possums ( Trichosurus vulpecula ) and percentage of pairs of North Island kōkako ( Callaeas cinerea ) fledging young (a) (modified from Innes et al, 1999); mouse printing rates of tracking tunnels and numbers of southern grass skinks ( Oligosoma polychroma ) (b) and ground wētā ( Hemiandrus spp.) (c) in pitfall traps (modified from Norbury et al, 2022); ship rat ( Rattus rattus ) tracking index and number of kererū in 5 min bird counts (d) (reproduced from Carpenter et al, 2021); and residual ship rat tracking index (RTI) and predicted rat control effect size on recovery rates of deeply endemic New Zealand bird species for each endemicity level 7 years after the onset of control (e) (solid lines, predicted mean effect size; marker sizes depict relative weight each study contributed to overall effect size; shading, 95% confidence band; dotted lines, 95% prediction interval upper and lower bounds) (reproduced from Binny et al, 2020, with permission from Wiley). Approximate predator thresholds are apparent where prey recruitment or population size rapidly increase where predator density indices are less than about 10%.…”

Section: Introductionmentioning

confidence: 99%

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Total response models as a conceptual management framework for conserving vulnerable secondary prey

Norbury

Reardon²

2023

Conservat Sci and Prac

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Many of the world's native fauna suffer unsustainable losses from invasive mammalian predators. Conservation managers control predators on the premise that if large numbers are removed, prey will respond. This is sometimes true, but not always. Empirical relationships between predator densities and responses of vulnerable prey in Oceania often show little or no response across a broad range of predator reductions, with positive responses only at low threshold predator densities. Even then, some prey populations fail to respond.More research is required to identify predator thresholds across a range of prey taxa. This uncertainty of outcomes, coupled with the considerable cost of mammalian pest control, risks little or no return from limited conservation funds. A unifying theory is required to help understand why conservation outcomes from predator control are so variable despite the best efforts of conservation managers, and to expedite the right kind of management for a given prey species. We argue that a modern synthesis of numerical and functional response theory, in the form of total response models, provides such a theory. Stochastic consumer-resource models are recommended for dynamic systems, but they are difficult to parameterize. Total response models, on the other hand, present a simple conceptual framework that managers can use as a heuristic to understand predator-prey systems, help explain some of the variability in predator control outcomes and stimulate thinking about other management options that can be integrated with predator control to improve conservation outcomes. Five rules of thumb are suggested to assist conservation managers.

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“…Thus, failure of tawa to produce large fruit crops is especially problematic for kererū population recovery due to the absence of complementary podocarp fruit. Combined with this resource scarcity, losses of kererū nests and adults to mammalian predation (Carpenter et al, 2021) could result in reproduction slipping below levels necessary to achieve population stability or growth. The once thriving presence of kererū, particularly the autumn mega-flocks of 100-500 birds per flock, has significantly declined in the Tuawhenua forests (Lyver et al, 2008).…”

Section: Implications For Tuawhenuamentioning

confidence: 99%

Global change explains reduced seeding in a widespread New Zealand tree: indigenous Tūhoe knowledge informs mechanistic analysis

Yukich Clendon,

Carpenter,

Kelly

et al. 2023

Front. For. Glob. Change

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IntroductionClimate change is expected to exacerbate the pressures faced by already fragile ecosystems. Negative impacts on the localized and culturally significant plant and animal species within these ecosystems will have cascading effects for the indigenous communities that interact with those species. Understanding how climate change affects culturally important seed crops may be particularly important, as seeds are critical for forest regeneration as well as providing sustenance for wildlife and people. In the central North Island/Te Ika-a-Māui of Aotearoa-New Zealand, Tūhoe elders of the Tuawhenua region have observed declines in seed production by the large-fruited locally dominant forest tree Beilschmiedia tawa (tawa, Lauraceae) over the last half century, which could be related to climate change.MethodsWe used seed trap data from six sites throughout the geographic range of tawa to measure trends in seed crop size from 1986 to 2020 and to determine which weather factors affect seed crops. We then used these weather predictors to hindcast how tawa seeding may have changed in Tuawhenua forests from 1910–2019, based on historic weather data.ResultsSeed trap data showed a decline in seeding through time across tawa’s range, and that seeding was lower at more northerly sites. Seed crops were synchronous among trees within sites, but were strongly asynchronous among sites. High seed crops were associated with cooler summer and winter temperatures, and with high rainfall. In the Tuawhenua region, increases in summer and winter temperatures appear to have contributed to the declines in tawa seed crops observed by elders, with the model predicting that years with heavy fruiting have become less frequent after 1940.DiscussionOur study provides strong evidence that tawa is undergoing changing seedfall patterns in response to changing climate. The biggest weather drivers of seeding that we identified in tawa were winter and summer temperature, both of which were negatively associated with crop size. Both winter and summer temperatures have increased in Tuawhenua in the last 100 years suggesting a possible mechanism to explain observations of long-term declines in tawa seedfall observed by Tūhoe elders of the Tuawhenua region, with ecological and cultural implications.

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Factors limiting kererū (Hemiphaga novaeseelandiae) populations across New Zealand

Cited by 3 publications

References 25 publications

Identifying global research and conservation priorities for Columbidae: a quantitative approach using random forest models

Identifying global research and conservation priorities for Columbidae: a quantitative approach using random forest models

Total response models as a conceptual management framework for conserving vulnerable secondary prey

Global change explains reduced seeding in a widespread New Zealand tree: indigenous Tūhoe knowledge informs mechanistic analysis

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