Herbivorous insects account for abo

Herbivorous insects account for about one quarter of all
extant organisms (Strong et al. 1984) and are essential
to ecosystem structure and functioning (Weisser and
Siemann 2004). Ecosystem process rates such as herbivory
may be altered significantly under climate change (Cornelissen
2011). The global mean surface air temperature is
expected to increase by 1.8–5.8°C (2090–2099 relative to
1980–1999), with additional changes in other climate
change drivers such as increasing CO2 levels or extreme
weather events (IPCC 2007). In recent studies, effects of
global change drivers on herbivorous insects have mostly
been studied in single-factor manipulative experiments
rather than multi-factorially (Rustad 2008). For example,
studies have shown that increases in CO2 (Stiling and
Cornelissen 2007), air temperature (Bale et al. 2002) or
altered water conditions (Jamieson et al. 2012) may affect
plant-insect herbivore interactions. However, important
interactive effects may be missed when global change
drivers are applied individually. Consequently, an increasing
number of studies now manipulate multiple climate
change drivers at once (e.g., Shaw et al. 2002; Pritchard
et al. 2007; Robinson et al. 2012; Stevnbak et al. 2012).
This “next generation” of global change experiments will
allow to test whether the effects of climate change drivers
add up or cancel out in combination (Larsen et al. 2011;
Leuzinger et al. 2011).
In this study, we independently manipulated atmospheric
CO2 concentration, near-surface air temperature
and summer drought in a replicated field experiment
(Mikkelsen et al. 2008). The experiments were conducted
in nutrient-poor heather vegetation dominated by Calluna
vulgaris (L.) and Deschampsia flexuosa (L.) TRIN. We
recorded weight and survival of larvae of an important
specialist herbivore, the heather beetle Lochmaea suturalis
THOMSON (Chrysomelidae). The heather beetle is a major
threat to heathlands worldwide, because its population
sizes periodically reach outbreak densities, causing severe
and large-scale defoliations to heather. Experimental studies
have suggested that warming may stimulate defoliation
by heather beetles (Pe~nuelas et al. 2004).
Here, we measured the response of insect individuals
on heather to multiple climate change effects under field
conditions. Responses to climate change may be direct or
plant-mediated (Cornelissen 2011; De Lucia et al. 2012).
In particular, elevated CO2 may alter the chemical composition
of plants (Pe~nuelas and Estiarte 1998; Awmack
and Leather 2002) and thus reduce the nutritive value for
herbivores (Cornelissen 2011). We therefore also assessed
climate change effects on plant chemistry, in addition to
our insect herbivore measurements. We tested the following
hypotheses:
(1) Elevated atmospheric CO2-concentrations negatively
affect growth and survival of L. suturalis larvae,
because plants contain more Carbon-based secondary
metabolites (De Lucia et al. 2012) and less nitrogen
(Stiling and Cornelissen 2007; Cornelissen 2011).
(2) Prolonged drought negatively affects plant quality
and hence reduces larval growth and survival (Huberty
and Denno 2004).
(3) Warming positively affects larval growth and survival
due to higher metabolic rates (Bale et al. 2002; Jamieson
et al. 2012).
(4) Climate change affects herbivores both directly via
physiological responses and indirectly via changes in
nitrogen content and plant secondary compounds
(De Lucia et al. 2012).
(5) With increasing number of climate change drivers,
the magnitudes of responses will decline (Leuzinger
et al. 2011), that is, growth and survival will be most
severely affected by single climate change drivers.