DNA Barcoding Reveals Generalization and Host Overlap in Hummingbird Flower Mites: Implications for the Mating Rendezvous Hypothesis.

AbstractHummingbird flower mites are assumed to monopolize single host plant species owing to sexual selection for unique mating rendezvous sites. We tested the main assumption of the mating rendezvous hypothesis-extreme host specialization-by reconstructing interactions among tropical hummingbird flower mites and their host plants using DNA barcoding and taxonomic identifications. We collected 10,654 mites from 489 flowers. We extracted DNA from 1,928 mite specimens and amplified the cytochrome c oxidase I (CO1) DNA barcode. We analyzed the network structure to assess the degree of generalization or specialization of mites to their host plants. We recorded 18 species of hummingbird flower mites from three genera (Proctolaelaps, Rhinoseius, and Tropicoseius) interacting with 14 species of plants. We found that generalist mites are common, and congeneric mite species often share host plants. Our results challenge the assumption of strict specialization that supports this system as an example of mating rendezvous evolution.

Demographic Attritions, Elevational Refugia, and the Resilience of Insect Populations to Projected Global Warming.

AbstractTropical mountains might protect species from global warming by facilitating biotic migrations upslope. Current predictions of tropical biotic responses to global warming are based on correlations between species elevational distributions and temperatures. Because biotic attritions, range shifts, and mountaintop extinctions result from complex demographic processes, predictive models must be based on mechanistic associations between temperature and fitness. Our study combines long-term temperature records with experimental demography to determine the contribution of local adaptation to organismal resilience in a warming world. On the Barva volcano in Costa Rica, Cephaloleia belti (Coleoptera: Chrysomelidae) displays high-elevation (960-2,100 m asl) and low-elevation (50-960 m asl) mitochondrial haplotypes. We reared haplotype cohorts at temperatures prevalent along the elevational gradient (i.e., 10°-30°C). Based on ambient temperatures recorded every half hour for 4 years, we projected average instantaneous population growth rates ([Formula: see text]) at current and future temperatures (i.e., +1° to 6°C) for each beetle haplotype. Haplotypes are adapted to local temperatures, but with a temperature increase beyond 2°C, both haplotypes will face lower-elevation demographic attritions and extinctions. Upper distribution limits serve as potential elevational refugia from global warming. This study shows how species resilience to global warming emerges from complex fitness responses of locally adapted phenotypes facing novel environments.

Positive genetic covariance and limited thermal tolerance constrain tropical insect responses to global warming.

Tropical ectotherms are particularly vulnerable to global warming because their physiologies are assumed to be adapted to narrow temperature ranges. This study explores three mechanisms potentially constraining thermal adaptation to global warming in tropical insects: (a) Trade-offs in genotypic performance at different temperatures (the jack-of-all-trades hypothesis), (b) positive genetic covariance in performance, with some genotypes performing better than others at viable temperatures (the 'winner' and 'loser' genotypes hypothesis), or (c) limited genetic variation as the potential result of relaxed selection and the loss of genes associated with responses to extreme temperatures (the gene decay hypothesis). We estimated changes in growth and survival rates at multiple temperatures for three tropical rain forest insect herbivores (Cephaloleia rolled-leaf beetles, Chrysomelidae). We reared 2,746 individuals in a full sibling experimental design, at temperatures known to be experienced by this genus of beetles in nature (i.e. 10-35°C). Significant genetic covariance was positive for 16 traits, supporting the 'winner' and 'loser' genotypes hypothesis. Only two traits displayed negative cross-temperature performance correlations. We detected a substantial contribution of genetic variance in traits associated with size and mass (0%-44%), but low heritability in plastic traits such as development time (0%-6%) or survival (0%-4%). Lowland insect populations will most likely decline if current temperatures increase between 2 and 5°C. It is concerning that local adaption is already lagging behind current temperatures. The consequences of maintaining the current global warming trajectory would be devastating for tropical insects. However, if humans can limit or slow warming, many tropical ectotherms might persist in their current locations and potentially adapt to warmer temperatures.

Native leaf-tying caterpillars influence host plant use by the invasive Asiatic oak weevil through ecosystem engineering.

We tested the effect of leaf-tying caterpillars, native ecosystem engineers, on the abundance and host feeding of an invasive insect, the Asiatic oak weevil, Cyrtepistomus castaneus (Roelofs). Leaf quality was previously thought to be the sole factor determining host use by C. castaneus, but adult weevils congregate in leaf ties made by lepidopteran larvae (caterpillars). Adult weevil abundance was naturally higher on Quercus alba and Q. velutina compared to four other tree species tested (Acer rubrum, Carya ovata, Cornus florida, and Sassafras albidum). These differences were associated with more natural leaf ties on the two Quercus species. In the laboratory, weevils fed on all six species but again preferred Q. alba and Q. velutina. When artificial ties were added to all six tree species, controlling for differences in leaf-tie density, adult weevil density increased on all six tree species, damage increased on all species but A. rubrum, and host ranking changed based on both abundance and damage. We conclude that leaf ties increase the local abundance of C. castaneus adults and their feeding. Thus, these native leaf-tying caterpillars engender the success of an invasive species via structural modification of potential host plants, the first described example of this phenomenon.

Both host plant and ecosystem engineer identity influence leaf-tie impacts on the arthropod community of Quercus.

Many insect herbivores build shelters on plants, which are then colonized by other arthropod species. To understand the impacts of such ecosystem engineering on associated species, the contributions of ecosystem engineer and host-plant identities must be understood. We investigated these contingencies at the patch scale using two species of leaf-tying caterpillars, which vary in size and tie construction mode, on eight species of oak (Quercus) trees, which vary in leaf size and leaf chemistry. We created three types of artificial leaf ties by clipping together pairs of adjacent leaves using metal hair clips. We left the first type of leaf tie empty while adding individuals of the leaf-tying caterpillars of either Pseudotelphusa quercinigracella or Psilocorsis cryptolechiella to the other two. We also created a control treatment of untied leaves by affixing clips to single leaves. Leaf ties increased occupancy in the early season and arthropod alpha diversity throughout the experiment, on average fourfold. Furthermore, the presence of leaf ties increased arthropod species density on average three times and abundance 10-35 times, depending on the plant species. The mean phenolic content of the leaves of each oak species was positively correlated with the leaf-tie effect on abundance and negatively correlated with the leaf-tie effect on species diversity. Species diversity, but not abundance, was affected by the identity of the tie-maker. Arthropod species composition differed between untied leaves and artificial leaf ties, and between ties made by the two leaf-tier species. Our results demonstrate that the presence of leaf ties adds to habitat diversity within the oak-herbivore system, not only by creating a new kind of microhabitat (the leaf tie) within trees, but also by exacerbating differences among the eight oak species in apparent habitat quality. The identity of the leaf-tying caterpillar adds to this heterogeneity by creating leaf ties of different size, thus influencing subsequent colonization by other leaf-tying caterpillars of different sizes.