Flexible responses to visual and olfactory stimuli by foraging Manduca sexta: larval nutrition affects adult behaviour

Here, we show that the consequences of deficient micronutrient (β-carotene) intake during larval stages of Manduca sexta are carried across metamorphosis, affecting adult behaviour. Our manipulation of larval diet allowed us to examine how developmental plasticity impacts the interplay between visual and olfactory inputs on adult foraging behaviour. Larvae of M. sexta were reared on natural (Nicotiana tabacum) and artificial laboratory diets containing different concentrations of β-carotene (standard diet, low β-carotene, high β-carotene and cornmeal). This vitamin-A precursor has been shown to be crucial for photoreception sensitivity in the retina of M. sexta. After completing development, post-metamorphosis, starved adults were presented with artificial feeders that could be either scented or unscented. Regardless of their larval diet, adult moths fed with relatively high probabilities on scented feeders. When feeders were unscented, moths reared on tobacco were more responsive than moths reared on β-carotene-deficient artificial diets. Strikingly, moths reared on artificial diets supplemented with increasing amounts of β-carotene (low β and high β) showed increasing probabilities of response to scentless feeders. We discuss these results in relationship to the use of complex, multi-modal sensory information by foraging animals.     

The subtlety of simple eyes: the tuning of visual fields to perceptual challenges in birds

Birds show interspecific variation both in the size of the fields of individual eyes and in the ways that these fields are brought together to produce the total visual field. Variation is found in the dimensions of all main parameters: binocular region, cyclopean field and blind areas. There is a phylogenetic signal with respect to maximum width of the binocular field in that passerine species have significantly broader field widths than non-passerines; broadest fields are found among crows (Corvidae). Among non-passerines, visual fields show considerable variation within families and even within some genera. It is argued that (i) the main drivers of differences in visual fields are associated with perceptual challenges that arise through different modes of foraging, and (ii) the primary function of binocularity in birds lies in the control of bill position rather than in the control of locomotion. The informational function of binocular vision does not lie in binocularity per se (two eyes receiving slightly different information simultaneously about the same objects from which higher-order depth information is extracted), but in the contralateral projection of the visual field of each eye. Contralateral projection ensures that each eye receives information from a symmetrically expanding optic flow-field from which direction of travel and time to contact targets can be extracted, particularly with respect to the control of bill position.     

Relative availability of nitrogen in host plants of invertebrate herbivores: three possible nutritional and physiological definitions

Summary It has been postulated that free amino acids in the diet of herbivores are a more readily available source of nitrogen than are amino acids in intact proteins. When plants are subjected to any of a number of stress factors the concentration of free amino acids in their tissues may increase relative to the protein content. It has been further postulated that such changes in available nitrogen can increase the survivorship of very young herbivores feeding on the tissues of stressed plants. In this paper, the concept of readily available nitrogen is given more specific definitions in the effort to uncover an underlying nutritional or physiological mechanism responsible for such changes in larval survivorship. The first hypothesis considered is that amino acids are more readily available than proteins in the sense that, as they occur in plant tissue, they are a more nutritious source of needed nitrogenous compounds. The second hypothesis considered is that amino acids are absorbed into the insect gut free from interference by proteinase inhibitors, and thus are more chemically available than are proteins. Finally, free amino acids, because of their solubility and greater mobility, may be more available to herbivores because of physical factors restricting the movement and digestion of proteins from plant tissue into the insect gut. The applicability of each hypothesis to certain types of insects feeding on particular plant tissues is discussed.The investigation reported in this paper (No. 86-7-224) is in connection with a project of the Kentucky Agricultural Experiment Station and is published with the approval of the Director     

Zebrafish Differentially Process Color across Visual Space to Match Natural Scenes

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Induction of defenses and within-alga variation of palatability in two brown algae from the northern-central coast of Chile: Effects of mesograzers and UV radiation

Macroalgae possess different defense mechanisms in response to herbivory. Some species produce anti-herbivore secondary metabolites, but production of these substances can be costly. Therefore, algae may produce defensive metabolites only in response to herbivory (inducible defense) or defend particular parts of the alga differentially (within-alga variation). In the present study, we examined whether two species of brown algae from the SE-Pacific show evidence of inducible chemical defense (non-polar compounds) or within-alga variation of defense, which we estimated in form of palatability of differently treated algae to amphipod grazers (with live algae and agar-based food containing non-polar algal extracts). In Glossophora kunthii (C. Agardh) J. Agardh, we observed an increase in palatability after algae were acclimated for 12 days without grazers. Subsequent addition of grazers for 12 days then resulted in a reduction of palatability indicating the existence of inducible defense. After removal of grazers for 12 days, these induced effects again disappeared. The reaction of G. kunthii was triggered even by the mere presence of grazers, which suggests that this alga can respond to waterborne cues by reducing palatability. Effects were only found for agar-based food containing non-polar extracts, but not for live algae, suggesting that some parts of the algae are undefended. Our second experiment on within-alga variation confirmed that only apical (growth region) and basal parts (near the holdfast region) of G. kunthii are defended against herbivores. For the second species, Macrocystis integrifolia Bory, the first experiment revealed no induction of defense, while the second experiment on within-alga variation showed that amphipods avoided basal parts and in particular stipes of M. integrifolia but only in live algae. Although both studied algal species differed substantially in their defensive strategies, their reaction was independent of the presence or absence of UV radiation. Thus, it appears that UV effects play only a minor role in anti-herbivore defense, which is in accordance with most previous studies.     

Tiger moths and the threat of bats: decision-making based on the activity of a single sensory neuron

Echolocating bats and eared moths are a model system of predator–prey interaction within an almost exclusively auditory world. Through selective pressures from aerial-hawking bats, noctuoid moths have evolved simple ears that contain one to two auditory neurons and function to detect bat echolocation calls and initiate defensive flight behaviours. Among these moths, some chemically defended and mimetic tiger moths also produce ultrasonic clicks in response to bat echolocation calls; these defensive signals are effective warning signals and may interfere with bats'' ability to process echoic information. Here, we demonstrate that the activity of a single auditory neuron (the A1 cell) provides sufficient information for the toxic dogbane tiger moth, Cycnia tenera, to decide when to initiate defensive sound production in the face of bats. Thus, despite previous suggestions to the contrary, these moths'' only other auditory neuron, the less sensitive A2 cell, is not necessary for initiating sound production. However, we found a positive linear relationship between combined A1 and A2 activity and the number of clicks the dogbane tiger moth produces.     

Clonal plants in a spatially heterogeneous environment: effects of integration on Serengeti grassland response to defoliation and urine-hits from grazing mammals

It has been hypothesized that clonal integration between ramets inenvironments with spatially variable rates of herbivory and nutrientavailabilities leads to increased growth and fitness in the genet. An increasein genet growth could potentially influence ecosystem processes such as primaryproductivity and nutrient cycling. I tested the idea that clonal integrationwould lead to greater aboveground productivity, compensatory response todefoliation, and N re-distribution in a factorial experiment in fieldplots in the Serengeti Ecosystem, Tanzania. Each plot had either all stolonssevered or left intact, had repeated defoliation (to simulate grazing bythe African buffalo) or none, and was either located next to a plot thatreceived urea (to simulate a urine-hit) or next to a plot thatremained untreated. Plots that received stolon severing treatments had32% less peak biomass than did connected control plots, and this suggeststhat plants grew better when ramets remained connected. However, compensatoryresponse by plots to repeated defoliation was inconsistent with the hypothesizedbenefits of ramet integration at the ecosystem level: productivityresponse to defoliation was similar between plots with connected vs. severedramets (i.e. no stolon severing × defoliation interaction wasfound). When averaged across other treatments, defoliated plots hadincreased productivity compared to nondefoliated plots during the growingseason. Thus, ramet connection and defoliation did increase productivity whenthey were considered alone, but productivity response to defoliation wasunaffected by ramet connections. Urea additions, which led to a 78%increase in productivity in adjacent urine-hits, had noconsistent effect on productivity but did increase leaf percent N in adjoiningstudy plots. Thus, in the Serengeti, urine hits probably have very localizedeffects on productivity during the initial growing season.     

Habitat architecture and trophic interaction strength in a river: riffle-scale effects

Invertebrate algal grazer densities were manipulated in a temperate river to discover the impact of differences in riffle-scale architectural complexity on the strength of the trophic interaction between grazers and epilithic algae. Animal densities were manipulated by manual removal in architecturally complex boulder-cobble riffles and simpler bedrock riffles, with the complexity of smaller-scale architecture held constant. Responses in algal density were recorded before and after a month of manipulations, together with grazer colonization rate and body sizes. The experiment was carried out in winter and again in summer. The interaction between grazers and algae differed between habitats and seasons. In winter, when algae were growing, the more complex rifflescale architecture in the boulder-cobble riffles created a refuge from grazing for algae. This was probably the result of the movement abilities of the grazers interacting with habitat architecture, and potentially also due to the control of predatory fish densities by habitat architecture resulting in greater predation pressure on grazers in boulder-cobble riffles. Therefore the impact of highly complex riffle-scale architecture was to weaken the strength of the trophic interaction between algae and their grazers by reducing grazer densities, while potentially strengthening the trophic interaction between grazers and their fish predators.     

Sensory ecology of scyphomedusae

The sensory ecology of scyphomedusae is a subject ripe for investigation. There are sensory structures for which there is no experimental evidence of function, there are behavioral performances for which there are no demonstrated sense organs, and there are behaviors for which there are no adaptive explanations. Scyphomedusae are diploblastic animals with a primitive level of neurological complexity, yet they exhibit a wide range of complex and sophisticated behaviors, such as sun compass navigation and daily horizontal migrations. This paper reviews the sensory ecology of orientation and migratory behavior in scyphomedusae, with an emphasis on data from Aurelia aurita. Adaptive explanations for complex behavior of individuals must be evaluated at the population level in order to assess their ecological importance.