Seed predation increases from the Arctic to the Equator and from high to low elevations

Hargreaves, Anna L.; Suárez, Esteban; Mehltreter, Klaus; Myers‐Smith, Isla H.; Vanderplank, Sula E.; Slinn, Heather L.; Vargas-Rodriguez, Yalma L.; Haeussler, Sybille; David, Santiago; Muñoz, Jenny; Almazan-Nunoz, R. Carlos; Loughnan, Deirdre; Benning, John W.; Moeller, David A.; Brodie, Jededian F; Thomas, Haydn J. D.; M, Paula A Morales

doi:10.1101/304634

Cited by 24 publications

(47 citation statements)

References 59 publications

(85 reference statements)

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“…Warmer temperatures can also increase parasite overwintering success (Burdon & Elmqvist 1996; Pfender & Vollmer 1999) or allow parasites to produce more generations during a longer growing season (Garrett et al 2006). These results corroborate past studies suggesting that environmental gradients can directly alter the strength of biotic interactions (Schemske et al 2009; Pellissier et al 2014; Descombes et al 2017; Roslin et al 2017; Hargreaves et al 2019), including host-parasite interactions (Nunn et al 2005; Abbate & Antonovics 2014; LaManna et al 2017; Allen et al 2020).…”

Section: Discussionsupporting

confidence: 91%

Environmental drivers of disease depend on host community context

Halliday

Jalo

Laine

2021

Preprint

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Predicting disease risk in an era of unprecedented biodiversity and climate change is more challenging than ever, largely because when and where hosts are at greatest risk of becoming infected depends on complex relationships between hosts, parasites, and the environment. Theory predicts that host species characterized by fast-paced life-history strategies are more susceptible to infection and contribute more to transmission than their slow-paced counterparts. Hence, disease risk should increase as host community structure becomes increasingly dominated by fast-paced hosts. Theory also suggests that environmental gradients can alter disease risk, both directly, due to abiotic constraints on parasite replication and growth, and indirectly, by changing host community structure. What is more poorly understood, however, is whether environmental gradients can also alter the effect of host community structure on disease risk. We addressed these questions using a detailed survey of host communities and infection severity along a 1100m elevational gradient in southeastern Switzerland. Consistent with prior studies, increasing elevation directly reduced infection severity, which we attribute to abiotic constraints, and indirectly reduced infection severity via changes in host richness, which we attribute to encounter reduction. Communities dominated by fast pace-of-life hosts also experienced more disease. Finally, although elevation did not directly influence host community pace-of-life, the relationship between pace-of-life and disease was sensitive to elevation: increasing elevation weakened the relationship between host community pace-of-life and infection severity. This result provides the first field evidence, to our knowledge, that an environmental gradient can alter the effect of host community structure on infection severity.

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Section: Discussionsupporting

confidence: 91%

Environmental drivers of disease depend on host community context

Halliday

Jalo

Laine

2021

Preprint

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“…The LBIH, which was originally developed for among‐biome comparisons (Dobzhansky, 1950; Schemske et al., 2009), has been supported by several macroecological studies of predation (Hargreaves et al., 2019; Jeanne, 1979; Roslin et al., 2017). A few studies found a poleward decrease in predation rates within the temperate biome (DeGregorio et al., 2016; Thompson & Ribic, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…(DeGregorio et al., 2016; Roslin et al., 2017; Thompson & Ribic, 2012; Zvereva et al., 2019). These latitudinal changes in predation are frequently associated with changes in the abundance of invertebrate predators (Hargreaves et al., 2019; Roslin et al., 2017). We suggest that the decline in ant predation in our latitudinal gradient was also driven mainly by a decline in ant abundance: analysis of the soil macrofauna in the same gradient showed a substantial poleward decrease in the density of predatory ants (M. Kozlov, unpubl.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, natural enemies have been suggested as a factor driving latitudinal patterns in insect herbivory (Björkman et al., 2011). However, latitudinal studies of predator–prey interactions focused mostly on seed predation (Hargreaves et al., 2019; Moles & Westoby, 2003; Peco et al., 2014) and bird nest predation (Kubelka et al., 2018; McKinnon et al., 2010). Only a few studies tested the LBIH with data on the natural enemy impact on herbivores, and these studies demonstrated specific responses of different groups of enemies.…”

Section: Introductionmentioning

confidence: 99%

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Predation and parasitism on herbivorous insects change in opposite directions in a latitudinal gradient crossing a boreal forest zone

Zvereva

Zverev

Kozlov

2020

Journal of Animal Ecology

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1. The latitudinal biotic interaction hypothesis (LBIH) predicts that the strength of various biotic interactions decreases from low to high latitudes. Inconsistency between studies testing this hypothesis may result from variations among different types of interactions and among study systems. Therefore, exploration of multiple interactions within one system would help to disentangle latitudinal patterns across individual interactions and to evaluate latitudinal changes in the overall impact of enemies on prey. 2. We tested the prediction based on the LBIH that the pressure of natural enemies on herbivorous insects decreases with increase in latitude across the boreal forest zone. We also asked whether the impacts of major groups of these enemies exhibit similar latitudinal patterns and whether these patterns are consistent across study years. 3. In 10 forest sites located from 60°N to 69°N in Northern Europe, each summer, from 2016 to 2019, we measured (a) mortality of three groups of leafmining insects caused by birds, ants, parasitoids and unknown factors, (b) bird attacks on caterpillar-shaped plasticine models and (c) birch foliar damage caused by defoliators and leafminers. 4. Latitudinal patterns in both insect herbivory on birch and top-down pressure on herbivorous insects varied considerably and inconsistently among the four study years, so that only some of the year-specific correlations with latitude were statistically significant. Nevertheless, meta-analysis combining correlations across years, preys and enemies revealed general decreases in predation by birds (on both natural and model prey) and ants, but an increase in parasitism rates, from low to high latitudes. 5. We found that the direction of latitudinal changes in the strength of biotic interactions was interaction-specific: predation and herbivory supported LBIH, whereas parasitism exhibited an opposite trend. Consequently, the overall impact of natural enemies on herbivorous insects did not change with latitude and was therefore an unlikely reason for the poleward decrease in herbivory observed in our gradient. Considerable among-year variation in the strength of the latitudinal | 2947

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“…2016; Moles & Ollerton 2016; Roslin et al . 2017; Baskett & Schemske 2018; Hargreaves et al . 2019; Freeman et al .…”

Section: Introductionmentioning

confidence: 99%

The latitudinal gradient in rates of evolution for bird beaks, a species interaction trait

Freeman

Schluter

Tobias

2020

Preprint

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Where is evolution fastest? The biotic interactions hypothesis proposes that greater species richness creates more ecological opportunity, driving faster evolution at low latitudes, whereas the “empty niches” hypothesis proposes that ecological opportunity is greater where diversity is low, spurring faster evolution at high latitudes. Here we test these contrasting predictions by analyzing rates of bird beak evolution for a global dataset of 1141 sister pairs of birds. We find that beak size evolves at similar rates across latitudes, while beak shape evolves faster in the temperate zone, consistent with the empty niches hypothesis. By comparing rates of evolution in sympatric versus allopatric sister lineages, we also find evidence that character displacement is similar between latitudes. Our analyses focusing on recent speciation events finds that drivers of evolutionary diversification are more potent at higher latitudes, thus calling into question multiple hypotheses invoking faster tropical evolution to explain the latitudinal diversity gradient.

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Seed predation increases from the Arctic to the Equator and from high to low elevations

Cited by 24 publications

References 59 publications

Environmental drivers of disease depend on host community context

Environmental drivers of disease depend on host community context

Predation and parasitism on herbivorous insects change in opposite directions in a latitudinal gradient crossing a boreal forest zone

The latitudinal gradient in rates of evolution for bird beaks, a species interaction trait

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