Linking individuals with ecosystems: Experimentally identifying the relevant organizational scale for predicting trophic abundances

Ovadia, Ofer; Schmitz, Oswald J.

doi:10.1073/pnas.192245499

Cited by 63 publications

(82 citation statements)

References 23 publications

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“…As with grasshoppers preyed upon by spiders, vertebrate prey face different risks from predators with different tactics, and their antipredator responses vary accordingly (e.g., antelope responding to stalkers vs. coursers, or solitary vs. pack hunters; Fitzgibbon and Fanshawe 1989, Scheel 1993, Creel and Creel 2002, Caro 2005, Stankowich and Coss 2006, 2007. Because the strength and type of antipredator responses ultimately determine the importance of risk effects, these studies support the argument that consideration of hunting mode will help to frame theory about the strength of risk (Elgar 1989, Hunter andSkinner 1998), age and sex (Childress andLung 2003, Winnie and, body condition (Ovadia andSchmitz 2002, Heithaus et al 2007), position within the group (Hamilton 1971, Keys and Dugatkin 1990, Hunter and Skinner 1998, Stankowich 2003, habitat type (Lima 1987, Scheel 1993, time of day (Elgar 1989, Scheel 1993, and local environmental conditions (Elgar 1989, Lima andDill 1990). These studies clearly demonstrate that animals adjust their level of vigilance in response to their own condition, the size and composition of the group that they occupy, and in response to the local environment.…”

Section: Introductionmentioning

confidence: 57%

Toward a predictive theory of risk effects: hypotheses for prey attributes and compensatory mortality

Creel

2011

Ecology

109

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Abstract. Risk effects, or the costs of antipredator behavior, can comprise a large proportion of the total effect of predators on their prey. While empirical studies are accumulating to demonstrate the importance of risk effects, there is no general theory that predicts the relative importance of risk effects and direct predation. Working toward this general theory, it has been shown that functional traits of predators (e.g., hunting modes) help to predict the importance of risk effects for ecosystem function. Here, I note that attributes of the predator, the prey, and the environment are all important in determining the strength of antipredator responses, and I develop hypotheses for the ways that prey functional traits might influence the magnitude of risk effects. In particular, I consider the following attributes of prey: group size and dilution of direct predation risk, the degree of foraging specialization, body mass, and the degree to which direct predation is additive vs. compensatory. Strong tests of these hypotheses will require continued development of methods to identify and quantify the fitness costs of antipredator responses in wild populations.

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Section: Introductionmentioning

confidence: 57%

Toward a predictive theory of risk effects: hypotheses for prey attributes and compensatory mortality

Creel

2011

Ecology

109

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“…We calibrated the model based on field observations and experiments performed in an old-field system, in which the generalist grasshopper Melanoplus femurrubrum is a dominant consumer (e.g., Schmitz et al 1997;Schmitz and Suttle 2001). Using data on density-and size-dependent survival and growth (Beckerman 2000(Beckerman , 2002Ovadia and Schmitz 2002;appendix) we quantified the effects of size variation on M. femurrubrum population dynamics. We found that in the case of deterministic dynamics (i.e., a fixed season length), size variation tends to destabilize population dynamics, that is, causes slower return to equilibrium density after a perturbation ( fig.…”

Section: Discussionmentioning

confidence: 99%

“…Body size is a fundamental physiological trait that structures populations and influences all facets of an individual's function and performance, such as foraging (e.g., Belovsky 1997), growth rate (e.g., Pfister and Stevens 2002), and survival (e.g., Ovadia and Schmitz 2002). Invariably, besides variation linked to ontogenetic stage, phenotypic variation in body size exists within any natural population (e.g., Uchmanski 1985).…”

mentioning

confidence: 99%

“…Such variation has important consequences for grasshopper population dynamics (Joern and Gaines 1990). Ovadia and Schmitz (2002) found that the survival rates of the grasshopper Melanoplus femurrubrum change as a function of body size. In addition, theoretical work at the community level showed that size variation markedly influences the strengths of trophic interactions as mediated through mean herbivore survival (Ovadia et al 2007).…”

mentioning

confidence: 99%

“…A major issue in our study is the effect of size variation on the stability properties of population dynamics. We calibrate our analytical model with results of field observations and experiments on the generalist grasshopper M. femurrubrum inhabiting old fields in Connecticut (e.g., Schmitz et al 1997;Schmitz and Suttle 2001;Ovadia and Schmitz 2002).…”

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confidence: 99%

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Individual Size Variation and Population Stability in a Seasonal Environment: A Discrete‐Time Model and Its Calibration Using Grasshoppers

Filin

Ovadia

2007

The American Naturalist

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Much recent literature is concerned with how variation among individuals (e.g., variability in their traits and fates) translates into higher-level (i.e., population and community) dynamics. Although several theoretical frameworks have been devised to deal with the effects of individual variation on population dynamics, there are very few reports of empirically based estimates of the sign and magnitude of these effects. Here we describe an analytical model for sizedependent, seasonal life cycles and evaluate the effect of individual size variation on population dynamics and stability. We demonstrate that the effect of size variation on the population net reproductive rate varies in both magnitude and sign, depending on season length. We calibrate our model with field data on size-and density-dependent growth and survival of the generalist grasshopper Melanoplus femurrubrum. Under deterministic dynamics (fixed season length), size variation impairs population stability, given naturally occurring densities. However, in the stochastic case, where season length exhibits yearly fluctuations, size variation reduces the variance in population growth rates, thus enhancing stability. This occurs because the effect of size variation on net reproductive rate is dependent on season length. We discuss several limitations of the current model and outline possible routes for future model development.Keywords: body size, individual variation, population stability, seasonal environment, univoltine lifecycle. Ecological entities are organized hierarchically into different levels of organization, such as the individual, the population, and the community (MacMahon et al. 1987;Allen and Hoekstra 1992;Pickett et al. 1994). The way in which these different organizational levels combine to influence the dynamics of natural systems remains a fundamental research topic in ecology (Lomnicki 1988;Nisbet et al. 1989; Abrams 1995;Levin et al. 1997;. Such research is motivated by the need to understand the level of mechanistic biological detail that must be included in ecological theory as well as how much can be safely abstracted while still achieving biologically faithful and quantitatively accurate descriptions of population and community dynamics.In the past 30 years, ecologists have become increasingly interested in linking individual phenotypic variation (in behavior, morphology, physiology, and life history) to population and community dynamics (e.g., Lomnicki 1978;Metz and Diekmann 1986;Begon and Wall 1987;Ebenman and Persson 1988;Nisbet et al. 1989;Bjørnstad and Hansen 1994;Uchmanski 1999;Schmitz 2000;de Roos et al. 2003). Specifically, many theoretical studies have demonstrated how age, stage, and size structure; cohort effects; and other forms of individual variation (e.g., in developmental and growth rates or in competitive ability) have important consequences for population dynamics, stability, and persistence (e.g., Bellows 1986aBellows , 1986bLomnicki 1988;Bjørnstad and Hansen 1994;de Roos 1997;Uchmanski 2000;Kendall ...

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Florivory indirectly decreases the plant reproductive output through changes in pollinator attraction

Tsuji

Ohgushi

2018

Ecology and Evolution

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Species often interact indirectly with each other via their traits. There is increasing appreciation of trait‐mediated indirect effects linking multiple interactions. Flowers interact with both pollinators and floral herbivores, and the flower‐pollinator interaction may be modified by indirect effects of floral herbivores (i.e., florivores) on flower traits such as flower size attracting pollinators. To explore whether flower size affects the flower‐pollinator interaction, we used Eurya japonica flowers. We examined whether artificial florivory decreased fruit and seed production, and also whether flower size affected florivory and the number of floral visitors. The petal removal treatment (i.e., artificial florivory) showed approximately 50% reduction in both fruit and seed set in natural pollination but not in artificial pollination. Furthermore, flower size increased the number of floral visitors, although it did not affect the frequency of florivory. Our results demonstrate that petal removal indirectly decreased 75% of female reproductive output via decreased flower visits by pollinators and that flower size mediated indirect interactions between florivory and floral visitors.

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Linking individuals with ecosystems: Experimentally identifying the relevant organizational scale for predicting trophic abundances

Cited by 63 publications

References 23 publications

Toward a predictive theory of risk effects: hypotheses for prey attributes and compensatory mortality

Toward a predictive theory of risk effects: hypotheses for prey attributes and compensatory mortality

Individual Size Variation and Population Stability in a Seasonal Environment: A Discrete‐Time Model and Its Calibration Using Grasshoppers

Florivory indirectly decreases the plant reproductive output through changes in pollinator attraction

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