The BsmI vitamin D receptor gene polymorphism is associated with ulcerative colitis in Jewish Ashkenazi patients

Susceptibility to inflammatory bowel disease (IBD) has a strong genetic component. The vitamin D receptor (VDR) gene maps to a region on chromosome 12 shown to be associated with IBD in some studies. In this case-control study we determined the association between the BsmI VDR gene polymorphism and IBD in patients with Crohn's disease (CD) and ulcerative colits (UC). Three hundred seventy-nine Jewish Israeli patients with IBD, 228 with CD (129 Ashkenazi and 99 non-Ashkenazi), and 151 patients with UC (72 Ashkenazi, 79 non-Ashkenazi) were studied. The control group included 495 healthy blood donors (352 non-Ashkenazi and 143 Ashkenazi). All subjects were genotyped for the BsmI VDR gene polymorphism. The frequency of the BB genotype was higher in Ashkenazi patients with UC compared to Ashkenazi controls (0.21 vs. 0.11, p = 0.042, odds ratio 2.27, 95% confidence interval [CI] 1.06-4.9). There were no differences in the prevalence of the BB genotype or the B allele between ethnically matched patients with CD and UC. Nor were there differences in the BB genotype or B allele frequencies between CD patients and ethnically matched controls. The BsmI VDR gene polymorphism is associated with increased susceptibility to UC in Israeli Ashkenazi patients with UC.     

Non‐trophic effects of litter reduce ant predation and determine caterpillar survival and distribution

The tritrophic model featuring plants consumed by herbivores consumed by parasitoids or predators has become the primary paradigm used to describe herbivore dynamics. However, interactions involving herbivores can be habitat‐ specific and plants often provide habitat, as well as food. Structural complexity of the habitat may favor predators or may allow herbivore prey to escape detection and capture. This study considered the spatial and temporal dynamics of an arctiid caterpillar, Platyprepia virginalis. The tritrophic model that includes only a tachinid parasitoid that attacks P. virginalis and the caterpillars’ primary host‐plant, Lupinus arboreus, has failed to provide much insight into this system. Instead, we found that ants killed and removed many small caterpillars. Protecting caterpillars from ants increased their survival three‐fold and five‐fold in assays conducted during two years. Caterpillars were more likely to survive in short‐term assays at sites that naturally had a deeper cover of dead and living plant material. Experiments with baits showed that ant recruitment declined as litter depth increased on average. These survey results indicated that ant predation was an important source of mortality for young caterpillars and that the presence of thick litter reduced this mortality. These results were corroborated in an experiment that manipulated litter depth and ant access to caterpillars. Previous findings that other defoliating caterpillars increased litter depth and benefitted P. virginalis are also consistent with this hypothesis. Litter acts as an important non‐trophic resource, allowing caterpillars to avoid predation by ants such that wet sites with deep litter act as source populations for caterpillars. Our results show strong effects of both trophic and non‐trophic interactions since plants indirectly provided limiting habitat and this heterogeneous habitat strongly affected risk of predation and ultimately caterpillar abundance and distribution.     

Caterpillar Basking Behavior and Nonlethal Parasitism by Tachinid Flies

Insects that become parasitized may behave differently than unparasitized individuals. For instance, some parasitized caterpillars bask at the top of vegetation. Caterpillars of Platyprepia virginalis that had previously been infected by the tachinid parasitoid, Thelaira americana, were more likely to bask on dead vegetation than were unparasitized caterpillars. This behavior was associated with elevated body temperatures compared to individuals that were not basking. This is the first report of behavioral fever by a caterpillar, by any insect in the field, and by any insect caused by a macroparasite rather than a pathogen. The results are consistent with the hypothesis that parasitized caterpillars are induced to develop behavioral fever by basking and this may help them recover from their parasitoids; other interpretations are also possible.     

Plant structural complexity and mechanical defenses mediate predator–prey interactions in an odonate–bird system

Habitat‐forming species provide refuges for a variety of associating species; these refuges may mediate interactions between species differently depending on the functional traits of the habitat‐forming species. We investigated refuge provisioning by plants with different functional traits for dragonfly and damselfly (Odonata: Anisoptera and Zygoptera) nymphs emerging from water bodies to molt into their adult stage. During this period, nymphs experience high levels of predation by birds. On the shores of a small pond, plants with mechanical defenses (e.g., thorns and prickles) and high structural complexity had higher abundances of odonate exuviae than nearby plants which lacked mechanical defenses and exhibited low structural complexity. To disentangle the relative effects of these two potentially important functional traits on nymph emergence‐site preference and survival, we conducted two fully crossed factorial field experiments using artificial plants. Nymphs showed a strong preference for artificial plants with high structural complexity and to a lesser extent, mechanical defenses. Both functional traits increased nymph survival but through different mechanisms. We suggest that future investigations attempt to experimentally separate the elements contributing to structural complexity to elucidate the mechanistic underpinnings of refuge provisioning.     

Volatile communication between plants that affects herbivory: a meta‐analysis

Volatile communication between plants causing enhanced defence has been controversial. Early studies were not replicated, and influential reviews questioned the validity of the phenomenon. We collected 48 well‐replicated studies and found overall support for the hypothesis that resistance increased for individuals with damaged neighbours. Laboratory or greenhouse studies and those conducted on agricultural crops showed stronger induced resistance than field studies on undomesticated species, presumably because other variation had been reduced. A cumulative analysis revealed that early, non‐replicated studies were more variable and showed less evidence for communication. Effects of habitat and plant growth form were undetectable. In most cases, the mechanisms of resistance and alternative hypotheses were not considered. There was no indication that some response variables were more likely to produce large effects. These results indicate that plants of diverse taxonomic affinities and ecological conditions become more resistant to herbivores when exposed to volatiles from damaged neighbours.     

How 17-year cicadas keep track of time

Seventeen-year periodical cicadas ( Magicicada spp.) require 17 years to develop underground and all individuals at any location emerge synchronously within several days. The mechanisms that animals use to keep track of time are poorly understood and nothing is known about how cicada nymphs emerge after precisely 17 years. We altered the seasonal cycles of trees supporting cicada nymphs and thereby induced premature metamorphosis of the associated cicadas. This indicates that cicadas accomplish a consistently accurate 17-year preadult development time by counting host seasonal cycles and not either by the passage of real time or by the accumulation of degree days.     

THE SIGNIFICANCE OF OUTCROSSING IN AN INTIMATE PLANT-HERBIVORE RELATIONSHIP. I. DOES OUTCROSSING PROVIDE AN ESCAPE FROM HERBIVORES ADAPTED TO THE PARENT PLANT?

Sexual reproduction may be advantageous for hosts that are preyed on or parasitized by enemies that are highly adapted to them. Sexual reproduction can create rare genotypes that may escape predation by virtue of rarity and can create variable progeny that may escape predation if enemies are specialized to only one genotype of host. Populations of the herbivorous thrips, Apterothrips apteris, have been shown to be adapted to individual Erigeron glaucus clones. Here, we show that thrips adapted to the parental clone could better use plant progeny of the “home” clone produced through selfing than progeny derived from selfing of other clones. Thus, despite recombination, progeny produced by selfing presented a resource that was similar to the parental phenotype with respect to use by adapted thrips. We also show that E. glaucus susceptibility to thrips has a genetic basis and then ask whether outcrossing provides a means for E. glaucus clones to escape attack by adapted thrips. When we compared the success of thrips on progeny produced by selfing or outcrossing of the home clone, we found that the merits or disadvantages associated with outcrossing were dependent on the susceptibility to infestation of the parental clones. Selfing by clones characterized by low infestations of thrips appeared to preserve resistant genotypes; all outcrossed progeny had, on average, higher infestation levels than selfed progeny. In contrast, outcrossed progeny of clones characterized by high infestations of thrips had either the same thrips density as progeny from selfing, when the pollen donor was a highly infested clone, or lower density, when the pollen donor was a low infestation clone. The advantages of outcrossing were caused by the alleles contributed to progeny rather than to progeny variability or rarity.     

Predicting novel herbivore–plant interactions

As human‐aided range expansions and climate change alter the distributions of plants and their herbivores, predicting and addressing novel species interactions will become increasingly pressing for community ecologists. In this context, a key, surprisingly understudied question is: when an exotic plant is introduced, which herbivores will adopt this new potential host? Whether the plant is a weed, an ornamental, or a crop, the development versus non‐development of a novel plant–insect interaction can have profound effects for both economic and conservation applications. In this paper, we sketch mechanistic and statistical frameworks for predicting these interactions, based on how plant and herbivore traits as well as shared evolutionary history can influence detection, recognition, and digestion of novel plants. By emphasizing mechanisms at each of these steps, we hope to clarify different aspects of novel interactions and why they may or may not occur. We also emphasize prediction and forecasting, as a major goal is to know in advance which interactions will develop from the many plant or insect introductions that occur in natural and man‐made systems.