Resource variability, aggregation and direct density dependence in an open context: the local regulation of an African elephant population

Chamaillé‐Jammes, Simon; Fritz, Hervé; Valeix, Marion; Murindagomo, Felix; Clobert, Jean

doi:10.1111/j.1365-2656.2007.01307.x

Cited by 559 publications

(173 citation statements)

References 67 publications

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“…Variation in K may provide insights into mechanisms underlying population regulation, especially if variation in K accounts for a substantial portion of the variation in N, as it did here (j K was at least three times the variation in N from all other sources). Previous models that have implicitly incorporated variation in K have done so by making resource levels a function of one or more climatic variables, often rainfall, usually with good success (e.g., Illius and O'Connor 2000;Davis et al 2002;Owen-Smith 2002;Georgiadis et al 2003;Lima et al 2006Lima et al , 2008Hone and Clutton-Brock 2007;Chamaillé-Jammes et al 2008;Yang et al 2008). Bouteloua rigidiseta readily adds tillers in response to rain and dies back in response to drought (N. L. Fowler, personal observation).…”

Section: Discussionmentioning

confidence: 99%

“…Rainfall, mediated through total plant biomass, is also an obvious limiting factor for large herbivores in arid climates. The majority of models that have implicitly incorporated variation in equilibrium population size have done so by incorporating the effects of rainfall into population models of large herbivores (e.g., Illius and O'Connor 2000;Davis et al 2002;Owen-Smith 2002;Georgiadis et al 2003;Chamaillé-Jammes et al 2008). In most cases, the inclusion of rainfall-dependent variation in resource levels has improved the prediction of herbivore population sizes.…”

Section: Introductionmentioning

confidence: 99%

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Temporal Variation in the Carrying Capacity of a Perennial Grass Population

Pease¹

2010

The American Naturalist

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JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. abstract: Density dependence and, therefore, K (carrying capacity, equilibrium population size) are central to understanding and predicting changes in population size (N). Although resource levels certainly fluctuate, K has almost always been treated as constant in both theoretical and empirical studies. We quantified temporal variation in K by fitting extensions of standard population dynamic models to 16 annual censuses of a population of the perennial bunchgrass Bouteloua rigidiseta. Variable-K models provided substantially better fits to the data than did models that varied the potential rate of population increase. The distribution of estimated values of K was skewed, with a long right tail (i.e., a few "jackpot" years). The population did not track K closely. Relatively slow responses to changes in K combined with large, rapid changes in K sometimes caused N to be far from K. In 13%-20% of annual intervals, K was so much larger than N that the population's dynamics were best described by geometric growth and the population was, in effect, unregulated. Explicitly incorporating temporal variation in K substantially improved the realism of models with little increase in model complexity and provided novel information about this population's dynamics. Similar methods would be applicable to many other data sets.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Temporal Variation in the Carrying Capacity of a Perennial Grass Population

Pease¹

2010

The American Naturalist

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“…Furthermore, the Gompertz-logistic model has performed robustly in describing the general dynamics of populations of birds and mammals over a wide range of body sizes (e.g., Saitoh et al 1997, 2008, Wang et al 2002, White et al 2007, Seavy et al 2009, Pasinelli et al 2011, is present in multi-model inference scenarios where competing models are contrasted (Saitoh et al 1997, Zeng et al 1998, Fryxell et al 2005, Chamaille´-Jammes et al 2008, McMahon et al 2009), is the top-ranked model in meta-analyses of hundreds of species in which various alternatives have also been evaluated (e.g., Brook and Bradshaw 2006), and has been a model used in theoretical development about density feedback (e.g., Dennis et al 2006). We avoided fitting the fully parameterized h-logistic model, due to recent caveats of application to analyses of time series (Clark et al 2010), or other highly parameterized analogues (e.g., hyperbolic growth).…”

Section: Methodsmentioning

confidence: 99%

Decoupling of component and ensemble density feedbacks in birds and mammals

Herrando‐Pérez

Delean

Brook

et al. 2012

Ecology

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Abstract. A component density feedback represents the effect of change in population size on single demographic rates, whereas an ensemble density feedback captures that effect on the overall growth rate of a population. Given that a population's growth rate is a synthesis of the interplay of all demographic rates operating in a population, we test the hypothesis that the strength of ensemble density feedback must augment with increasing strength of component density feedback, using long-term censuses of population size, fertility, and survival rates of 109 bird and mammal populations (97 species). We found that compensatory and depensatory component feedbacks were common (each detected in ;50% of the demographic rates). However, component feedback strength only explained ,10% of the variation in ensemble feedback strength. To explain why, we illustrate the different sources of decoupling between component and ensemble feedbacks. We argue that the management of anthropogenic impacts on populations using component feedbacks alone is ill-advised, just as managing on the basis of ensemble feedbacks without a mechanistic understanding of the contributions made by its components and environmental variability can lead to suboptimal decisions.

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“…Studies of wild African elephants' ranging behavior certainly reveal clustering around important resources like water [Chamaille´-Jammes et al, 2008], and the avoidance of potential threats or wastes of energy. Thus, they show avoidance of roads [e.g.…”

Section: Preference and Avoidancementioning

confidence: 99%

How should the psychological well‐being of zoo elephants be objectively investigated?

2010

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Animal welfare (sometimes termed ''well-being'') is about feelings -states such as ''suffering'' or ''contentment'' that we can infer but cannot measure directly. Welfare indices have been developed from two main sources: studies of suffering humans, and of research animals deliberately subjected to challenges known to affect emotional state. We briefly review the resulting indices here, and discuss how well they are understood for elephants, since objective welfare assessment should play a central role in evidence-based elephant management. We cover behavioral and cognitive responses (approach/avoidance; intention, redirected and displacement activities; vigilance/startle; warning signals; cognitive biases, apathy and depression-like changes; stereotypic behavior); physiological responses (sympathetic responses; corticosteroid output -often assayed noninvasively via urine, feces or even hair; other aspects of HPA function, e.g. adrenal hypertrophy); and the potential negative effects of prolonged stress on reproduction (e.g. reduced gametogenesis; low libido; elevated still-birth rates; poor maternal care) and health (e.g. poor wound-healing; enhanced disease rates; shortened lifespans). The best validated, most used welfare indices for elephants are corticosteroid outputs and stereotypic behavior. Indices suggested as valid, partially validated, and/or validated but not yet applied within zoos include: measures of preference/avoidance; displacement movements; vocal/postural signals of affective (emotional) state; startle/vigilance; apathy; salivary and urinary epinephrine; female acyclity; infant mortality rates; skin/foot infections; cardio-vascular disease; and premature adult death. Potentially useful indices that have not yet attracted any validation work in elephants include: operant responding and place preference tests; intention and vacuum movements; fear/ stress pheromone release; cognitive biases; heart rate, pupil dilation and blood pressure; corticosteroid assay from hair, especially tail-hairs (to access endocrine events up to a year ago); adrenal hypertrophy; male infertility; prolactinemia; and immunological changes. Zoo Biol 29:237-255,

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Resource variability, aggregation and direct density dependence in an open context: the local regulation of an African elephant population

Cited by 559 publications

References 67 publications

Temporal Variation in the Carrying Capacity of a Perennial Grass Population

Temporal Variation in the Carrying Capacity of a Perennial Grass Population

Decoupling of component and ensemble density feedbacks in birds and mammals

How should the psychological well‐being of zoo elephants be objectively investigated?

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