Thresholds for impaired species recovery

Studies on small and declining populations dominate research in conservation biology. This emphasis reflects two overarching frameworks: the small-population paradigm focuses on correlates of increased extinction probability; the declining-population paradigm directs attention to the causes and consequences of depletion. Neither, however, particularly informs research on the determinants, rate or uncertainty of population increase. By contrast, Allee effects (positive associations between population size and realized per capita population growth rate, r realized , a metric of average individual fitness) offer a theoretical and empirical basis for identifying numerical and temporal thresholds at which recovery is unlikely or uncertain. Following a critique of studies on Allee effects, I quantify population-size minima and subsequent trajectories of marine fishes that have and have not recovered following threat mitigation. The data suggest that threat amelioration, albeit necessary, can be insufficient to effect recovery for populations depleted to less than 10% of maximum abundance ( N max ), especially when they remain depleted for lengthy periods of time. Comparing terrestrial and aquatic vertebrates, life-history analyses suggest that population-size thresholds for impaired recovery are likely to be comparatively low for marine fishes but high for marine mammals. Articulation of a ‘recovering population paradigm’ would seem warranted. It might stimulate concerted efforts to identify generic impaired recovery thresholds across species. It might also serve to reduce the confusion of terminology, and the conflation of causes and consequences with patterns currently evident in the literature on Allee effects, thus strengthening communication among researchers and enhancing the practical utility of recovery-oriented research to conservation practitioners and resource managers.

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Breeding biology and population increase of the Endangered Bermuda Petrel Pterodroma cahow

Bird Conservation International ◽

10.1017/s0959270911000396 ◽

2012 ◽

Vol 22 (1) ◽

pp. 35-45 ◽

Cited By ~ 12

Author(s):

JEREMY MADEIROS ◽

NICHOLAS CARLILE ◽

DAVID PRIDDEL

Keyword(s):

Climate Change ◽

Population Size ◽

Breeding Success ◽

Reproductive Output ◽

Small Population ◽

Population Increase ◽

Storm Damage ◽

Breeding Phenology ◽

North East ◽

Rate Of Increase

SummaryThe Bermuda Petrel Pterodroma cahow was thought to have become extinct early in the 17th century due to a combination of hunting by human colonists and predation by introduced rats, cats, dogs and pigs. However, single individuals were found on four occasions during the first half of the 20th century, and in 1951 a small population was discovered breeding on several rocky islets in north-east Bermuda. Recovery actions began in 1962 when the population numbered just 18 pairs, dispersed among five small islets. Although rats extirpated one of these five colonies in 1967, the population has grown steadily to 56 breeding pairs in 2000. We investigated the breeding phenology, productivity and population size of the Bermuda Petrel between 2000/2001 and 2007/2008. Each year, the birds began arriving in Bermuda around mid-October. They departed on a pre-breeding exodus between 19 November and 14 December, returning after 32–56 days to lay a single egg between 31 December and 31 January. Eggs hatched from 16 February to 26 March after a mean (± SD) incubation period of 53 ± 2 days, and young fledged from 15 May to 25 June after a mean fledging period of 91 ± 5 days. Between 2000/2001 and 2007/2008, reproductive output ranged from 29 to 40 fledglings per annum. Mean annual breeding success (62%) was reasonably high relative to other Procellariiformes, largely due to the provision of artificial (concrete) nesting burrows. In 2008, the population numbered 85 breeding pairs. Monitoring since 1961 indicates the population has been increasing exponentially, doubling approximately every 22 years. This rate of increase, together with the increased incidence of storm damage, is making it progressively more impracticable to construct sufficient concrete burrows on the current nesting islets to accommodate all breeding pairs. The vulnerability of these sites to accelerating storm damage and erosion as a result of anthropomorphic climate change is now the greatest threat to the Bermuda Petrel.

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Breeding population increase and range expansion of the Great Crested Grebe Podiceps cristatus in southeastern Norway

Ornis Norvegica ◽

10.15845/on.v43i0.2982 ◽

2020 ◽

Vol 43 ◽

pp. 4-16

Author(s):

Svein Dale

Keyword(s):

Population Size ◽

Range Expansion ◽

Breeding Population ◽

Small Population ◽

Population Increase ◽

Strong Increase ◽

Breeding Sites ◽

Population Size Estimate ◽

Podiceps Cristatus ◽

Great Crested Grebe

The Great Crested Grebe Podiceps cristatus is listed as near-threatened on the Norwegian red list due to small population size, estimated in 2015 at 220–380 pairs. Population size is considered to be stable. Approximately one quarter of the population (50–100 pairs) is thought to occur in Oslo and Akershus, but this estimate is not based on detailed data, and the only previous systematic estimate was 90–100 pairs in 13 sites in 1982. In 2018, I conducted a comprehensive survey of all known and potential breeding sites to assess current population size in Oslo and Akershus. I recorded 233 pairs in 34 sites, suggesting a large increase in population size. To analyse the population increase in more detail, I collected all known records of Great Crested Grebes during the breeding season for the period 1995–2018. Analyses confirmed that there has been a strong increase, at a yearly rate of 4.2%. The increase was both due to increases in already established populations (69% of total increase), and establishment of new sites (31%). New sites were colonised in particular the last 10–15 years, and new sites were located gradually further away from the sites that were already used in 1982, indicating continuous range expansion. New sites were also located in smaller, less nutrient-rich lakes at higher elevations, perhaps indicating occupation of lower quality sites that could limit further population increase. Similar population increases have also occurred in other parts of the distribution range of Great Crested Grebes in Norway, and I present a new population size estimate for Norway at 531–634 pairs. Hence, the species no longer qualifies for red listing, and one may consider to downlist the species to least concern.

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The genetic Allee effect: A unified framework for the genetics and demography of small populations

10.1101/038125 ◽

2016 ◽

Cited By ~ 1

Author(s):

Gloria M. Lucque ◽

Chloé Vayssade ◽

Benoît Facon ◽

Thomas Guillemaud ◽

Franck Courchamp ◽

...

Keyword(s):

Genetic Structure ◽

Population Size ◽

Allee Effect ◽

Small Populations ◽

Allee Effects ◽

Unified Framework ◽

Fitness Components ◽

Individual Fitness ◽

Heated Debate ◽

Underlying Mechanisms

AbstractThe Allee effect is a theoretical model predicting low growth rates and the possible extinction of small populations. Historically, studies of the Allee effect have focused on demography. As a result, underlying processes other than the direct effect of population density on fitness components are not generally taken into account. There has been heated debate about the potential of genetic processes to drive small populations to extinction, but recent studies have shown that such processes clearly impact small populations over short time scales, and some may generate Allee effects. However, as opposed to the ecological Allee effect, which is underpinned by cooperative interactions between individuals, genetically driven Allee effects require a change in genetic structure to link the decline in population size with a decrease in fitness components. We therefore define the genetic Allee effect as a two-step process whereby a decrease in population size leads to a change in population genetic structure, and in turn, to a decrease in individual fitness. We describe potential underlying mechanisms, and review the evidence for this original type of component Allee effect, using published examples from both plants and animals. The possibility of considering demogenetic feedback in light of genetic Allee effects clarifies the analysis and interpretation of demographic and genetic processes, and the interplay between them, in small populations.

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Evolutionary genetics of small populations

10.1093/oso/9780198783398.003.0002 ◽

2017 ◽

Author(s):

Richard Frankham ◽

Jonathan D. Ballou ◽

Katherine Ralls ◽

Mark D. B. Eldridge ◽

Michele R. Dudash ◽

...

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Evolutionary Genetics ◽

Small Population ◽

Small Populations ◽

Effective Population ◽

Genetic Management ◽

Evolutionary Genetic ◽

Loss Of Genetic Diversity ◽

Number Of Individuals

Genetic management of fragmented populations involves the application of evolutionary genetic theory and knowledge to alleviate problems due to inbreeding and loss of genetic diversity in small population fragments. Populations evolve through the effects of mutation, natural selection, chance (genetic drift) and gene flow (migration). Large outbreeding, sexually reproducing populations typically contain substantial genetic diversity, while small populations typically contain reduced levels. Genetic impacts of small population size on inbreeding, loss of genetic diversity and population differentiation are determined by the genetically effective population size, which is usually much smaller than the number of individuals.

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Genetic and Nongenetic Bases for the L-Shaped Distribution of Quantitative Trait Loci Effects

Genetics ◽

10.1093/genetics/157.4.1773 ◽

2001 ◽

Vol 157 (4) ◽

pp. 1773-1787 ◽

Cited By ~ 8

Author(s):

Bruno Bost ◽

Dominique de Vienne ◽

Frédéric Hospital ◽

Laurence Moreau ◽

Christine Dillmann

Keyword(s):

Linkage Disequilibrium ◽

Quantitative Trait Loci ◽

Population Size ◽

Quantitative Trait ◽

Metabolic Flux ◽

Genetic Model ◽

Small Population ◽

Additive Genetic Model ◽

Metabolic Mechanism ◽

Qtl Effects

Abstract The L-Shaped distribution of estimated QTL effects (R2) has long been reported. We recently showed that a metabolic mechanism could account for this phenomenon. But other nonexclusive genetic or nongenetic causes may contribute to generate such a distribution. Using analysis and simulations of an additive genetic model, we show that linkage disequilibrium between QTL, low heritability, and small population size may also be involved, regardless of the gene effect distribution. In addition, a comparison of the additive and metabolic genetic models revealed that estimates of the QTL effects for traits proportional to metabolic flux are far less robust than for additive traits. However, in both models the highest R2's repeatedly correspond to the same set of QTL.

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Population Density or Populations Size. Which Factor Determines Urban Traffic Congestion?

Sustainability ◽

10.3390/su13084280 ◽

2021 ◽

Vol 13 (8) ◽

pp. 4280

Author(s):

Yu Sang Chang ◽

Sung Jun Jo ◽

Yoo-Taek Lee ◽

Yoonji Lee

Keyword(s):

Population Density ◽

Population Size ◽

Traffic Congestion ◽

Critical Role ◽

Small Population ◽

High Density ◽

Urban Traffic ◽

Contradictory Result ◽

Low Density

A large number of articles have documented that as population density of cities increases, car use declines and public transit use rises. These articles had a significant impact of promoting high-density compact urban development to mitigate traffic congestion. Another approach followed by other researchers used the urban scaling model to indicate that traffic congestion increases as population size of cities increases, thus generating a possible contradictory result. Therefore, this study examines the role of both density and population size on traffic congestion in 164 global cities by the use of Stochastic Impacts by Regression on Population, Affluence and Technology model. We divide 164 cities into the two subgroups of 66 low density cities and 98 high density cities for analysis. The findings from the subgroups analysis indicated a clear-cut difference on the critical role of density in low-density cities and the exclusive role of population size in high-density cities. Furthermore, using threshold regression model, 164 cities are divided into the two regions of large and small population cities to determine population scale advantage of traffic congestion. Our findings highlight the importance of including analysis of subgroups based on density and/or population size in future studies of traffic congestion.

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Detection of Allee effects in marine fishes: analytical biases generated by data availability and model selection

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2017.1284 ◽

2017 ◽

Vol 284 (1861) ◽

pp. 20171284 ◽

Cited By ~ 12

Author(s):

Tommi Perälä ◽

Anna Kuparinen

Keyword(s):

Statistical Approach ◽

Positive Association ◽

Scientific Basis ◽

Marine Fishes ◽

Clupea Harengus ◽

Data Availability ◽

Allee Effects ◽

Methodological Issues ◽

Data Limitations ◽

Colonization Success

The demographic Allee effect, or depensation, implies positive association between per capita population growth rate and population size at low abundances, thereby lowering growth ability of sparse populations. This can have far-reaching consequences on population recovery ability and colonization success. In the context of marine fishes, there is a widespread perception that Allee effects are rare or non-existent. However, studies that have failed to detect Allee effects in marine fishes have suffered from several fundamental methodological and data limitations. In the present study, we challenge the prevailing perception about the rarity of Allee effects by analysing nine populations of Atlantic herring ( Clupea harengus ), using Bayesian statistical methods. We find that populations of the same species can show either strong evidence for Allee effects or compensation. We explicitly demonstrate how the evidence for Allee effects is strongly provisional on observations made at low population abundances. We contrast our statistical approach with previous attempts to detect Allee effects and illustrate methodological issues that can lead to erroneous conclusions about the nature of population dynamics at low abundance. The present study demonstrates that there is no substantive scientific basis to support the perception that Allee effects are rare or non-existent in marine fishes.

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Eumops floridanus (Chiroptera: Molossidae)

Mammalian Species ◽

10.1093/mspecies/seab012 ◽

2021 ◽

Vol 53 (1009) ◽

pp. 125-133

Author(s):

Jessica M Vannatta ◽

Jeffery A Gore ◽

Verity L Mathis ◽

Brian D Carver

Keyword(s):

United States ◽

Population Size ◽

The United States ◽

Small Population ◽

Species Level ◽

Small Population Size ◽

Restricted Distribution ◽

Dead Trees ◽

Fish And Wildlife Service

Abstract Eumops floridanus (Allen, 1932) is a molossid commonly called the Florida bonneted bat or the Florida mastiff bat. Eumops floridanus is the largest species of bat in Florida and is one of 16 species in the genus Eumops. With one of the smallest distributions of any bat in the United States, it is endemic to southern peninsular Florida where it roosts in cavities of live and dead trees and man-made structures. Eumops floridanus was formerly classified as a subspecies of E. glaucinus but has been elevated to species level based on morphology. Due primarily to its restricted distribution, small population size, and the continued loss of habitat, E. floridanus is federally listed as “Endangered” (EN) by the United States Fish and Wildlife Service.

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Clipperton Atoll as a model to study small marine populations: Endemism and the genomic consequences of small population size

PLoS ONE ◽

10.1371/journal.pone.0198901 ◽

2018 ◽

Vol 13 (6) ◽

pp. e0198901 ◽

Cited By ~ 4

Author(s):

Nicole L. Crane ◽

Juliette Tariel ◽

Jennifer E. Caselle ◽

Alan M. Friedlander ◽

D. Ross Robertson ◽

...

Keyword(s):

Population Size ◽

Small Population ◽

Small Population Size

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Epimeletic behaviour in a Southern Resident Killer Whale (Orcinus orca)

The Canadian Field-Naturalist ◽

10.22621/cfn.v134i4.2555 ◽

2021 ◽

Vol 134 (4) ◽

pp. 316-320

Author(s):

Taylor Shedd ◽

Allison Northey ◽

Shawn Larson

Keyword(s):

Marine Mammals ◽

Killer Whale ◽

The United States ◽

Small Population ◽

Orcinus Orca ◽

Salish Sea ◽

The People ◽

Species At Risk Act ◽

Prey Scarcity ◽

Vessel Noise

Southern Resident Killer Whale (SRKW, Orcinus orca) may be found year round in the Salish Sea. These orcas comprise three matrilineal pods (J, K, and L) and were listed as Endangered under the Canadian Species at Risk Act in 2003 and under the United States Endangered Species Act in 2005 because of prey scarcity, vessel noise and disturbance, small population size, and exposure to toxins. Since 1993, the Whale Museum has been operating Soundwatch, a boater education program for vessels. Soundwatch personnel are on the water in the central Salish Sea throughout the summer educating boaters on how to maneuver near marine mammals legally and documenting vessel regulation violations and marine mammal presence and behaviour. Starting on 24 July 2018, Soundwatch documented an adult female SRKW of J pod (J35) carrying a dead neonate calf. J35 continued to carry her dead calf for 17 consecutive days covering ~1600 km. Her story riveted the attention of the people of the Salish Sea as well as people around the world, evoking empathy for J35 and her loss as well as the plight of the Endangered SRKW population. Here, we tell her story and evaluate whether the behaviour J35 displayed toward her dead calf was an example of epimeletic behaviour, animal grief.

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