Role of Olfactory and Visual Cues in the Attraction/Repulsion Responses to Conspecifics by Gregarious and Solitarious Desert Locusts

Desert locusts [Schistocerca gregaria Forskål (Orthoptera, Acrididae)] change phase in response to population density: solitarious insects avoid one another, but when crowded they change to the gregarious phase and aggregate. The attraction/repulsion responses of gregarious and solitarious locusts maintain phase differences in locust populations. Despite considerable research, the cues for aggregation are poorly understood; moreover, the repulsion response of solitarious locusts has not previously been investigated. This study analyzes the role of visual and olfactory stimuli in triggering these different responses to conspecifics. Isolation-reared insects were repelled by both olfactory and visual stimuli from other locusts. Crowd-reared insects were attracted by the combination of olfactory and visual cues. In addition, olfactory stimuli affected other behaviors in both phases, and behavioral differences between isolation- and crowd-reared locusts were clear even in the absence of conspecifics. The sensory and neurological mechanisms underlying these responses are not well understood and will form the basis for neurobiological investigations of locust phase.     

Characteristics of action potentials in Helianthus annuus

The action potentials induced by nondamaging electrical stimuli in 16- to 22-day-old plants of Helianthus annuus were examined. Typical recordings are presented. Mean values of their amplitudes and conduction velocities in the stem, the strength-duration relation, the 'all-or-none' law and the refractory periods have been determined. The amplitude and velocity of propagation were essentially identical in the upward and downward direction, but greater in the upper than in the lower half. In 'electrically active' plants, the rheobase value is 2 V, the minimum period for stimulation is 1.8 s. and the chronaxie 2.3 s. It is noted that the excitability level between similar plants on the same day and in the same plant on different days is highly variable and undergoes periodic changes.     

Annulus cells release ATP in response to vibratory loading in vitro

Mechanical forces regulate the developmental path and phenotype of a variety of tissues and cultured cells. Vibratory loading as a mechanical stimulus occurs in connective tissues due to energy returned from ground reaction forces, as well as a mechanical input from use of motorized tools and vehicles. Structures in the spine may be particularly at risk when exposed to destructive vibratory stimuli. Cells from many tissues respond to mechanical stimuli, such as fluid flow, by increasing intracellular calcium concentration ([Ca(2+)](ic)) and releasing adenosine 5'-triphosphate (ATP), extracellularly, as a mediator to activate signaling pathways. Therefore, we examined whether ATP is released from rabbit (rAN) and human (hAN) intervertebral disc annulus cells in response to vibratory loading. ATP release from annulus cells by vibratory stimulation as well as in control cells was quantitated using a firefly luciferin-luciferase assay. Cultured hAN and rAN cells had a basal level of extracellular ATP ([ATP](ec)) in the range of 1-1.5 nM. Vibratory loading of hAN cells stimulated ATP release, reaching a net maximum [ATP] within 10 min of continuous vibration, and shortly thereafter, [ATP] declined and returned to below baseline level. [ATP] in the supernatant fluid of hAN cells was significantly reduced compared to the control level when the cells received vibration for longer than 15 min. In rAN cells, [ATP] was increased in response to vibratory loading, attaining a level significantly greater than that of the control after 30 min of continuous vibration. Results of the current study show that resting annulus cells secrete ATP and maintain a basal [ATP](ec). Annulus cells may use this nucleotide as a signaling messenger in an autocrine/paracrine fashion in response to vibratory loading. Rapid degradation of ATP to ADP may alternatively modulate cellular responses. It is hypothesized that exposure to repetitive, complex vibration regimens may activate signaling pathways that regulate matrix destruction in the disc. As in tendon cells, ATP may block subsequent responses to load and modulate the vibration response. Rabbit annulus cells were used as a readily obtainable source of cells in development of an animal model for testing effects of vibration on the disc. Human cells obtained from discarded surgical specimens were used to correlate responses of animal to human cells.     

Maintaining nitric oxide-induced airway relaxation with superoxide dismutase

BACKGROUND: We have previously shown that the protective effect of inhaled nitric oxide (iNO) against methacholine-induced bronchoconstriction is negated in airways subjected to hyperosmotic stress. In this study, hypothesizing that the impaired efficiency of iNO was caused by release of reactive oxygen radicals, we examined the effect of the radical scavenging enzyme superoxide dismutase (SOD). METHODS: Hemodynamic and respiratory measurements were performed on anesthetized rabbits after (1) inhalation of methacholine (MCh), (2) iNO (80ppm), followed by MCh, (3) inhalation of hypertonic saline (HS), followed by iNO and MCh and (4) pre-treatment with inhalation of SOD, followed by HS, iNO and MCh. We analyzed plasma for a marker of oxidative stress, 8-iso-prostaglandin (PG)F(2alpha) and for a marker of activation of COX-mediated inflammatory cascades, PGF(2alpha) metabolite. RESULTS: Pre-treatment with SOD restored the bronchoprotective response to iNO in hyperosmotic airways. No direct effect was seen by SOD treatment on levels of 8-iso-PGF(2alpha), but this marker of oxidative stress correlated positively with increased bronchoconstriction. Hyperosmotic challenge elevated levels of PGF(2alpha) metabolite, and pre-treatment with SOD protected against this activation of the inflammatory cascade. CONCLUSION: SOD pre-treatment restores the relaxant effects of iNO in hyperosmotically challenged airways by attenuating oxidative stress and activation of COX-mediated inflammatory cascades.     

Behavioral responses of maned wolves (Chrysocyon brachyurus, Canidae) to different categories of environmental enrichment stimuli and their implications for successful reintroduction

The maned wolf (Chrysocyon brachyurus, Illiger, 1815, Canidae) is a threatened species that inhabits the cerrados of Brazil, Argentina, Peru, Bolivia, Paraguay, and Uruguay. Captive maned wolves could be potentially used in reintroduction programs for species conservation; however, it is necessary that their behavior and cognitive abilities are conserved. Environmental enrichment is a tool used to stimulate captive animals and maintain a natural behavioral repertoire. To compare the variation of captive maned wolves' behavioral responses to environmental enrichment, we studied three maned wolves held by Belo Horizonte Zoo, Brazil. Foraging, interspecific, and intraspecific stimuli were offered to the animals and their responses were compared with a baseline and postenrichment treatments. The test was used to help in choosing which one of the three individuals would participate in a reintroduction project. The results showed that stimuli type did influence the animal's responses, and that individually wolves responded differently to foraging, interspecific, and intraspecific enrichment items (P80.05 for some behaviors in each enrichment category). The individual's personality seemed to influence their behavioral responses, with animals showing bold and shy responses, and this trait should be considered during decision makings for reintroduction.     

Self-control and honesty depend on exposure to pictures of the opposite sex in men but not women

Research has shown that viewing stimuli that induce mating or sex motivation can push men towards greater impulsivity, a manifestation of lower self-control. Recent advances in research on the connection between self-control and moral behavior indicate that low self-control is associated with increased dishonesty. From an evolutionary perspective, when mating motivation is activated, men may behave in dishonest ways by projecting characteristics in line with women's mate preferences to enhance their sexual attractiveness. We tested the possibility that exposure to pictures of sexually appealing women would engender lower self-control, leading men to behave dishonestly. The results showed that a state of lower self-control was observed in males who viewed women rated high on sexual attractiveness but not in males who viewed women rated low on sexual attractiveness or in females who viewed men (Experiment 1). Compared with control participants, male participants exposed to pictures of sexy women were less likely to return excess money received for participating (Experiment 2) and more likely to cheat in a matrix task (Experiments 3 and 4). State self-control mediated the link between exposure to sexual stimuli and dishonest behavior in men (Experiments 2 and 4). For men whose mating motivation is heightened by exposure to sexual stimuli, dishonesty appears to be a tactic for projecting characteristics preferred by women (e.g., large economic resources).     

Regulation of the Pleuronectes americanus Na+/H+ exchanger by osmotic shrinkage, β-adrenergic stimuli, and inhibition of Ser/Thr protein phosphatases

The ubiquitous Na⁺/H⁺ exchanger NHE1 is regulated by protein phosphorylation events, but the mechanisms involved are incompletely understood. We recently cloned NHE1 from the red blood cells of the winter flounder, Pleuronectes americanus (paNHE1), and demonstrated its activation by osmotic cell shrinkage, β-adrenergic stimuli, and the Ser/Thr protein phosphatase PP1 and PP2A inhibitor calyculin A (CLA) (Pedersen et al. [2003] Am. J. Physiol. 284, C1561–C1576). Here, we investigate the mechanisms involved in paNHE1 activation by these stimuli. Osmotic shrinkage and CLA were only partially additive in their effects on paNHE1 activity, and CLA-mediated paNHE1 activation was inhibited by osmotic cell swelling. Activation by the β-adrenergic agonist isoproterenol (IP) was fully additive to activation by osmotic shrinkage or CLA. IP-mediated, but neither shrinkage-nor CLA-mediated paNHE1 activation were associated with an increase in cellular cyclic adenosine monophosphate (cAMP) level. IP-mediated activation was partially blocked by the protein kinase A (PKA) inhibitor H89 (10μM), wherease shrinkage- and CLA-mediated activation were unaffected. All three stimuli activated paNHE1 in a manner unaffected by inhibitors of protein kinase C (calphostin C, 5 μM) and protein kinase G (KT5823, 10 μM) as well as of myosin light chain kinase (ML-7, 10 μM). IP-mediated, but not shrinkage-mediated, paNHE1 activation was associated with an increase in serine phosphorylation of the paNHE1 protein. It is suggested that paNHE1 activation by osmotic shrinkage and by PP1/PP2A inhibition involves partially convergent signaling pathways, whereas activation of paNHE1 by β-adrenergic stimuli is mediated by a separate pathway.     

Beyond Eyeballing: Fitting Models to Experimental Data

Abstract

As we learn more about the biology of the Toll-like receptors (TLRs), a wide range of molecules that can activate this fascinating family of pattern recognition receptors emerges. In addition to conserved pathogenic components, endogenous danger signals created upon tissue damage are also sensed by TLRs. Detection of these types of stimuli results in TLR mediated inflammation that is vital to fight pathogenic invasion and drive tissue repair. Aberrant activation of TLRs by pathogenic and endogenous ligands has also been linked with the pathogenesis of an increasing number of infectious and autoimmune diseases, respectively. Most recently, allergen activation of TLRs has also been described, creating a third broad class of TLR stimulus that has helped to shed light on the pathogenesis of allergic disease. To date, microbial activation of TLRs remains best characterized. Each member of the TLR family senses a specific subset of pathogenic ligands, pathogen associated molecular patterns (PAMPS), and a wealth of structural and biochemical data continues to reveal the molecular mechanisms of TLR activation by PAMPs, and to demonstrate how receptor specificity is achieved. In contrast, the mechanisms by which endogenous molecules and allergens activate TLRs remain much more mysterious. Here, we provide an overview of our current knowledge of how very diverse stimuli activate the same TLRs and the structural basis of these modes of immunity.     

The experience in the water maze task can affect the circadian rhythm of locomotor activity

Wistar rats maintained in cages with running wheels and submitted to a skeleton photoperiod or to a light - dark cycle were tested in the Morris water maze. Half of the animals were exposed to the task during their active phase while the other half was exposed during their inactive phase. The effect of the experience in the water maze, a strong arousing event, on the rhythm of wheel-running activity was evaluated. In the first experiment, a group of animals submitted to a skeleton photoperiod was trained every day in the reference memory version of the task. The novel experience in the water maze had a strong phase-dependent masking effect: it produced an intense post-training bout of activity in the animals tested during their inactive phase. Another experiment was run using single working memory sessions in the water maze and with animals submitted to a light - dark cycle. The circadian rhythm of locomotor activity was evaluated on undisturbed days and compared with testing days. The experience in the water maze produced a significant increase in variability of activity onset during both circadian phases. Taken together, the data suggest that there is a modulating effect of the arousing experience in the pool on the overt circadian rhythm of locomotor activity.