%0 Generic %A MacDonald, Andrew %A Srivastava, Diane %A Romero, Gustavo %D 2016 %T Predator diversity and bromeliad communities: experimental results %U https://figshare.com/articles/dataset/Predator_diversity_and_bromeliad_communities_experimental_results/3983964 %R 10.6084/m9.figshare.3983964.v2 %2 https://ndownloader.figshare.com/files/6328959 %K food webs %K Bromeliads %K predation %K Freshwater Ecology %K Community Ecology (excl. Invasive Species Ecology) %K Invertebrate Biology %X

We tested effects of both single and multiple predator species on community responses with a manipulative experiment where identical prey communities were exposed to treatments of either a single predator, or pairs of predators representing increasing phylogenetic diversity. In this experiment we focused on the four most abundant large predators found in
the community: Leptagrion andromache and Leptagrion elongatum (Odonata:
Coenagrionidae), a predatory Tabanid fly (Diptera:Tabanidae:Stibasoma sp.) and
a predatory leech. We combined these species in eight treatments: predator-free
control (no predators), each of the four predator species alone (3a) and
pairs of predator species chosen to maximize variation in phylogenetic distance
(3b). Specifically, these pairs were: two congeneric damselflies
(Leptagrion andromache and Leptagrion elongatum), two insects (L.
elongatum
and Stibasoma), and two invertebrates (L. elongatum
and a predatory leech). We used five replicate bromeliads for each of these 8
treatments (8 treatments, n=5). This experiment, therefore, allows the estimation
of the effect of each predator species (single-species treatments), as well as the
detection of non-additive effects in predator combinations.

We created bromeliad communities that were as similar as possible to each other, and also to the average composition of a bromeliad. In February 2011 we collected bromeliads with a volume between 90 and 200ml,
thoroughly washed the plants to remove organisms and detritus, and soaked them for 12 hours in a
tub of water. We then hung all bromeliads for 48 hours to dry. This procedure was intended to remove all existing macroinvertebrates; one bromeliad dissected
afterwards contained no insects . We simulated natural detritus inputs from the canopy by adding a standard mass of dried leaves of the species Plinia cauliflora (Jabuticaba, Myrtaceae; a common Brazilian tree). In order to
track the effects of detrital decomposition on bromeliad N cycling, we enriched
these leaves with 15N by fertilizing five plants with 40ml pot-1 day-1 of 5g L-1 ammonium sulphate containing 10% atom excess of 15N. After 21 days we then collected P. cauliflora leaves,
air-dried until constant weight, and then soaked them for three days. This procedure removes excess nutrients from the artificial fertilization. Because some of our prey species consume fine detritus, not coarse, we also added a standard amount of dried fine detritus to our bromeliads. We separated coarse and fine detritus by passing water from bromeliads through two sieves (as above for observational work, 150 and 850 µm). We defined “coarse detritus” as anything retained on the 850 µm sieve, and “fine detritus” as anything found on the 150 µm sieve.

Each bromeliad was stocked with a representative insect community (See supplementary material). The densities
of each prey taxon were calculated from the observational dataset (Hypothesis 1), using
data from bromeliads of similar size to those in our experiment. We ran this experiment in two temporal blocks for logistical reasons: three complete replicates of all treatments were set up on 20 February 2011, and two on 08 March 2011. We first placed the prey species into the bromeliad, allowed two days for the prey to adjust, then added predators. After 26 days from the beginning of each block, we added the same prey community a second time to simulate the continuous
oviposition that characterizes the system. We concluded the experiment 43 days from the first addition of prey (20 April 2011). Throughout the experiment, all bromeliads were enclosed
with a mesh cage topped with a malaise trap and checked daily for emergence of
adults. At the end of the experiment we completely dissected our bromeliads, collecting all invertebrates and detritus remaining inside.

We used a substitutive design, maintaining the same predator
metabolic capacity in all replicates (see below). In a substitutive experiment, all experimental units receive the same “amount” of predators — usually standardized by abundance — and only species composition varies. However, when species differ substantially in body
size - as in this experiment - abundance does not standardize the their effects on the community. We chose to standardize using metabolic capacity instead. Metabolic capacity is equal to individual body
mass raised to the power of 0.69; this reflects the nonlinear relationship between feeding rate and body size across many invertebrate taxa.

To quantify the effect of predators on ecosystem function, at the end of the experiment we measured five
community and ecosystem response variables: decomposition of coarse detritus,
production of fine particulate organic matter (FPOM), bromeliad growth,
uptake of detrital nitrogen into bromeliad tissue, and survival of
invertebrate prey (emerged adults + surviving larvae). We measured decomposition by once again passing the bromeliad water through a 850 µm sieve, collecting the retained detritus and determining the mass of this detritus after oven-drying it at approximately 70C. We measured the
production of FPOM by taking the remaining liquid and filtering it on pre-weighed coffee filters, which were then dried and reweighed. We measured bromeliad growth as the average increase in length of five leaves per plant. We
tracked the uptake of labeled detrital nitrogen by analyzing three innermost
(closest to meristem) bromeliad leaves at the end of the experiment. Finally, we quantified the species
composition and survivorship of invertebrate prey by combining counts of
emerging adult insects and surviving larvae.

We measured decomposition by collecting all Plinia leaves from bromeliads; these
were oven-dried at 70C before their mass was determined. At the end of
experiment, we sampled three new bromeliad leaves for isotopic (15N) and
nitrogen concentration analyses. These analyses were performed at the Stable
Isotope Facility laboratory (UC Davis, CA, USA) using continuous flow isotope
ratio mass spectrometer (20-20 mass spectrometer; PDZ Europa, Sandbach,
England) after sample combustion to N~2~ at 1000C by an on-line elemental
analyzer (PDZ Europa ANCA-GSL).

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