Foraging in nature: foraging efficiency and attentiveness in caterpillars with different diet breadths

Abstract. 1. Seventy‐seven individual last‐instar caterpillars foraging in the field were examined for 6 h each. They represented four species of Arctiidae of similar size and habitat use. Two, Hypocrisias minima and Pygarctia roseicapitis, are specialists restricted to particular plant genera. The other two, Grammia geneura and Estigmene acrea, are extreme generalists that use many host plant species from multiple plant families. 2. Parameters of behavioural efficiency were monitored. Generalists spent more time walking, rejected more potential host plants, took longer to decide to feed after inspecting a plant, and took relatively more small feeding bouts compared with specialists. 3. This is the first test of differential foraging efficiency in the field in relation to diet breadth of insects and the data indicate that generalists are less efficient in their foraging activities and may suffer from divided attention. The need for attentiveness to enhance efficiency and thereby reduce ecological risk is discussed.     

Assessment of local predation risk: the role of subthreshold concentrations of chemical alarm cues

The ability to accurately assess local predation risk is criticalto prey individuals, as it allows them to maximize threat-sensitivetrade-offs between predator avoidance and other fitness relatedactivities. A wide range of taxonomically diverse prey (includingmany freshwater fishes) relies on chemical alarm cues (alarmpheromones) as their primary information source for local riskassessment. However, the value of chemical alarm cues has beenquestioned due to the availability of additional sensory inputs(i.e., visual cues) and the lack of an overt antipredator responseunder conditions of low perceived risk. In this paper, we testthe hypothesis that chemical alarm cues at concentrations belowthe point at which they elicit an overt behavioral responsefunction to increase vigilance towards other sensory modalities(i.e., visual alarm cues). Shoals of glowlight tetras (Hemigrammuserythrozonus) exposed to the subthreshold concentration of hypoxanthine-3-N-oxide(the putative Ostariophysan alarm pheromone) did not exhibitan overt antipredator response in the absence of secondary visualcues (not different than the distilled water control). However,when exposed to the sight of a visually alarmed conspecific,they significantly increased the intensity of their antipredatorresponse (not different from shoals exposed to the suprathresholdalarm cue). This study demonstrates that prey may benefit fromresponding to low concentration alarm cues by increasing vigilancetowards secondary cues during local risk assessment, even inthe absence of an overt behavioral response. By increasing vigilancetowards secondary risk assessment cues in the presence of alow risk chemical cue, individuals are likely able to maximizethe threat-sensitive trade-offs between predator avoidance andother fitness related activities.     

Isolation from mammalian predators differentially affects two congeners

Evolutionary isolation from predators can profoundly influencethe morphology, physiology, and behavior of prey, but littleis known about how species respond to the loss of only someof their predators. We studied antipredator behavior of tammarwallabies (Macropus eugenii) and western gray kangaroos (Macropusfuliginosus) on Kangaroo Island (KI), South Australia, andat Tutanning Nature Reserve on the mainland of western Australia.Both species on KI have been isolated from native mammalian predators for several thousand years. On KI, wallabies (becauseof their size) are vulnerable to diurnal aerial predators.In contrast, on the mainland both species have been exposedcontinuously to native and introduced mammalian and avian predators.At both locations, wallabies modified the amount of time they allocated to vigilance and foraging in response to group size,whereas kangaroos did so only at the higher risk Tutanningsite. Both species modified overall time budgets (they werewarier at the higher risk site), and both species modifiedspace-use patterns as a function of risk. At the higher risk site, tammars were closer to cover, whereas kangaroos were,on average, farther from cover. We hypothesize that the presenceof a single predator, even if it is active at a different timeof day, may profoundly affect the way a species responds tothe loss of other predators by maintaining certain antipredatorbehaviors. Such an effect of ancestral predators may be expected as long as species encounter some predators.     

东方田鼠警觉对其功能反应的作用格局

植食性哺乳动物功能反应描述了摄入率与植物可利用性变量的动态关系。动物警觉因占用了处理食物时间即觅食中断时间而延迟与下一口食物相遇,引致摄入率降低,进而对功能反应构型产生影响。在新鲜白三叶叶片构成的各类食物密集斑块上,测定东方田鼠觅食行为,建立功能反应函数模型,检验觅食中断对功能反应的作用格局及机制。结果发现,除小叶片斑块觅食中断时间在觅食活动中所占的比例较低外,在大、中型叶片斑块的觅食中断时间比例均达到15.42%-26.82%;尽管,觅食中断使摄入率降低了33%,但东方田鼠功能反应仍为Ⅱ型功能反应。除东方田鼠采食时间及觅食回合时间随叶片重增大保持相对稳定外,处理时间及觅食中断时间均随叶片重增大呈线性递增趋势;采食时间、处理时间及觅食中断时间随口量的增大呈线性递增趋势;采食率随叶片重和口量增大呈指数递减趋势。研究结果揭示,东方田鼠因警觉引起的觅食中断事件是导致采食率及摄入率降低的主要因子。摄入率测定值与模型预测值的线性回归极显著(P < 0.01),表明,新建立的功能反应模型具有良好的可预测性。推测,东方田鼠因警觉引起采食率及摄入率减小的代价,是以延长觅食时间来补偿的。研究结果充分验证了,在可利用性植物密集斑块,由植物大小调控的动物口量决定其摄入率,且受采食和处理食物竞争及觅食中断的制约,其功能反应为Ⅱ型功能反应的假说。     

False alarms and information transmission in grouping animals

A key benefit of grouping in prey species is access to social information, including information about the presence of predators. Larger groups of prey animals respond both sooner and at greater distances from predators, increasing the likelihood that group members will successfully avoid capture. However, identifying predators in complex environments is a difficult task, and false alarms (alarm behaviours without genuine threat) appear surprisingly frequent across a range of taxa including insects, amphibians, fish, mammals, and birds. In some bird flocks, false alarms have been recorded to substantially outnumber true alarms. False alarms can be costly in terms of both the energetic costs of producing alarm behaviours as well as lost opportunity costs (e.g. abandoning a feeding patch which was in fact safe, losing sleep if an animal is resting/roosting, or losing mating opportunities). Models have shown that false alarms may be a substantial but underappreciated cost of group living, introducing an inherent risk to using social information and a vulnerability to the propagation of false information. This review will focus on false alarms, introducing a two-stage framework to categorise the different factors hypothesised to influence the propensity of animal groups to produce false alarms. A number of factors may affect false alarm rate, and this new framework splits these factors into two core processing stages: (i) individual perception and response; and (ii) group processing of predator information. In the first stage, individuals in the group monitor the environment for predator cues and respond. The factors highlighted in this stage influence the likelihood that an individual will misclassify stimuli and produce a false alarm (e.g. lower light levels can make predator identification more difficult and false alarms more common). In the second stage, alarm information from individuals is processed by the group. The factors highlighted in this stage influence the likelihood of alarm information being copied by group members and propagated through the group (e.g. some animals implement group processing mechanisms that regulate the spread of behavioural responses such as consensus decision making through the quorum response). This review follows the structure of this new framework, focussing on the causes of false alarms, factors that influence false alarm rate, the transmission of alarm information through animal groups, mechanisms to mitigate the spread of false alarms, and the consequences of false alarms.     

Collective Vigilance in the Wintering Hooded Crane: The Role of Flock Size and Anthropogenic Disturbances in a Human‐Dominated Landscape

Vigilance achieved at the group level, known as collective vigilance, can enhance the ability to assess threats and confer benefits to gregarious prey species. Examining the factors that influence collective vigilance and exploring how individual vigilance is organized at the group level can help to understand how prey groups respond to potential threats. We quantified collective vigilance and determined its temporal pattern in a natural wintering population of the hooded crane Grus monacha in the Shengjin Lake reserve in China. We examined the role of flock size and anthropogenic disturbances in the human‐dominated landscape on collective vigilance and level of synchronization. The proportion of time during which at least one individual scanned the surroundings (collective vigilance) increased with flock size and was higher in the more disturbed buffer zone of the lake. Synchronization of vigilance occurred more frequently in the smaller flocks but was not related to the risk of disturbance. Synchronization implies that individuals tend to monitor and copy the vigilance of neighbors. In the degraded wetlands, the wintering hooded crane benefits from foraging in groups and synchronizing their vigilance in response to human disturbances.     

Coalition formation,mate selection and pairing behaviour of the Crested Francolin

Transect field observations were conducted on the behaviour of Crested Francolin Dendroperdix sephaena to describe male coalitions in the Borakalalo National Park, North West province, South Africa during May, August, October and December 2008, and again in July 2009. Crested Francolin form male coalitions following the breeding season in May. Young males leave their natal coveys and join old males in these coalitions, which are not based on kinship and consist of up to nine members. These coalitions are joined by a young female from June to October, followed by the breeding season when pairs replace coalitions. The coalition is a prelude to successful mating. The single female calls in the coalition, which triggers a cacophony, and her presence often erupts in physical conflicts between males. This cacophony is interpreted as signal jamming where males prevent one another from forming a duet with the female, clearly showing competition between them for winning over the female for mating. A well-synchronised duet forms the basis of pair formation. Old females are not particularly selected for pairing. The coalition is also a surrogate covey for young males because it optimises predator surveillance. The pair bond also optimises predator surveillance for each other throughout the year.