Survival strategies of the crab spider Thomisus onustus Walckenaer 1806 (Chelicerata,Arachnida, Thomisidae)

Summary The initial energy supply of emerging spiderlings is relatively meagre, so survival without feeding on insects during a spell of bad weather is limited to a period of a few days or weeks. During our investigations, spiderlings of Thomisus onustus (Arachnida, Thomisidae) were kept on different diets. There was a significant difference in survival rate between spiderlings that were starved or fed on pollen, nectar, or Drosophila. The results showed that pollen and nectar can be a source of energy for spiders for an extensive period. This demonstrates another way in which spiders may survive starvation when insect prey is lacking and thus ensure the survival of a whole population.     

Induced indirect defence in a spider–plant system mediated by pericarpial nectaries

Some plant species attacked by herbivore species produce additional resources to attract predators and induce an indirect defence process. We evaluated whether Palicourea rigida (Rubiaceae) individuals can induce indirect defences as response to herbivory simulation by increasing pericarpial nectar production and volatile emissions, as well as whether spiders are attracted by such induced indirect defences. We selected 30 P. rigida individuals and simulated herbivory in 15 of them by cutting out half of all leaves using pruning shears. We did not manipulate the other 15 plants (control group). At three different times, we measured nectar volume and calories of the pericarpial nectary in the inflorescences of all plants of control and treatment groups. We also quantified spider abundance on these plants. In another experiment, we selected salticid spider, Thiodina sp., to determine whether predators detect chemical tracks of plant volatiles produced by the plant after herbivory simulations. We also tested whether the honey solution could emit olfactory signals capable of attractive spiders. We showed that P. rigida produced higher volume of pericarpial nectar presenting more calories after herbivory simulation. The abundance of spiders was higher in plants subjected to herbivory simulation than control plants. Thiodina sp. did not respond to the volatile chemical tracks produced by the leaves after the simulation, but it had a positive response to olfactory tracks associated with the sucrose solution. Such an outcome indicates the ability of this spider to locate nectar honey plants and olfactory signals of honey. Thus, plants respond to the action of herbivores by producing more pericarpial nectar and nectar with more calories. Although our knowledge about the olfactory physiology of arachnids remains incipient, we highlight the importance of chemical and olfactory tracks for decision‐making of spiders in foraging on plants and the herbivory influence on the behaviour of cursorial spiders.     

Jumping spiders (Salticidae) enhance the seed production of a plant with extrafloral nectaries

Many plants secrete nectar from extrafloral nectaries (EFNs), specialized structures that usually attract ants which can act as plant defenders. We examined the nectar-mediated interactions between Chamaecrista nictitans (Caesalpineaceae) and jumping spiders (Araneae, Salticidae) for 2 years in old fields in New Jersey, USA. Previous research suggests that spiders are entirely carnivorous, yet jumping spiders (Eris sp. and Metaphidippus sp.) on C. nictitans collected nectar in addition to feeding on herbivores, ants, bees, and other spiders. In a controlled-environment experiment, when given a choice between C. nictitans with or without active EFNs, foraging spiders spent 86% of their time on plants with nectar. C. nictitans with resident jumping spiders did set significantly more seed than plants with no spiders, indicating a beneficial effect from these predators. However, the presence of jumping spiders did not decrease numbers of Sennius cruentatus (Bruchidae), a specialist seed predator of C. nictitans. Jumping spiders may provide additional, unexpected defense to plants possessing EFNs. Plants with EFNs may therefore have beneficial interactions with other arthropod predators in addition to nectar-collecting ants. Received: 27 May 1998 / Accepted: 23 December 1998     

Visual preference of flower-visiting crab spiders (Ebrechtella tricuspidata) for host flowers

1. Crab spiders (Thomisidae) are common flower-visiting spiders that ambush prey on inflorescences. As such, they require specific flowers or substrates for hunting, which are most often selected using sensory cues (e.g. vision). However, few studies have examined the visual preference of crab spiders for particular flowers. In this study, the visual preferences of the crab spider Ebrechtella tricuspidata for different inflorescence characteristics (e.g. colour and shape) were investigated. 2. The results showed that adult spiders explored all colours and shapes, whereas juvenile spiders displayed an overall preference for long (red) and short (purple) wavelength colours. Thus, differences in colour were not particularly important for E. tricuspidata with regard to visual attractiveness and selection. 3. However, inflorescence shape (e.g. tulip) was found to be a more desirable trait for selection, which was probably due to the provision of shelter. 4. These results also suggest that male preference for female spiders depended somewhat on the background colour (wavelength) of the flower on which the female was located.     

Advantages of social foraging in crab spiders: Groups capture more and larger prey despite the absence of a web

Among group‐living spiders, subsocial representatives in the family of crab spiders (Thomisidae) are a special case, as they build protective communal leaf nests instead of extensive communal capture webs. It could thus be inferred that antipredator benefits (e.g., enhanced protection in larger nests) rather than foraging‐related advantages (e.g., capture of more and larger prey) promote sociality in this family. Nonetheless, subsocial crab spiders do share prey, and if this behaviour does not reflect mere food scramble but has a cooperative character, crab spiders may offer insights into the evolution of social foraging applicable to many other cooperative predators that hunt without traps. Here, we performed a comparative laboratory feeding experiment on three of the four subsocial crab spider species—Australomisidia ergandros, Australomisidia socialis and Xysticus bimaculatus—to determine if crab spiders derive advantages from foraging in groups. In particular, we tested artificially composed groups of five sibling spiderlings vs. single siblings in terms of prey capture success and prey size preference. Across species, groups had higher prey capture success (measured in terms of capture rates and capture latency) and were more likely to attack large, sharable prey—dynamics leading to reduced food competition among group members in favour of living and foraging in groups. Within groups, we further compared prey extraction efficiency among the three applied social foraging tactics: producing, scrounging and feeding alone. In A. ergandros, individuals were exceptionally efficient when using the non‐cooperative scrounger tactic, which entails feeding on the prey provided by others. Thus, our multispecies comparison confirms foraging advantages in maintaining a cooperative lifestyle for crab spiders, but also demonstrates the relevance of research into exploitation of cooperative foraging in this family.     

Nectar feeding by wandering spiders on cotton plants

Spiders are assumed to be strictly carnivorous in assessments of their nutritional and energetic requirements, their habitat preferences, and their potential as biological control agents. However, members of Salticidae (jumping spiders), Thomisidae (crab spiders), and the fast-moving Miturgidae, Anyphaenidae, and Corinnidae, all non-webbuilding wandering spiders, have been observed at floral and extrafloral nectaries of plants, presumably feeding on nectar. To test spiders in the field for nectar feeding, we used a cold anthrone test to detect the presence of ingested fructose, a plant-derived sugar, in wandering spiders occupying cotton plants (Gossypium hirsutum L.), which have floral and extrafloral nectaries. Field collections focused on three ecologically similar, highly active nocturnal spiders: Cheiracanthium inclusum (Hentz) (Miturgidae), Hibana futilis (Banks), and H. arunda (Platnick) (Anyphaenidae). During 2002 and 2003, 27 and 21%, respectively, of all field-collected adults and subadults tested positive for fructose, indicating consumption of extrafloral nectar. In both years, significantly more females were positive than males (38 versus 11% in 2002; 26 versus 12% in 2003). Immatures tested positive at a lower rate than adults (3 and 13%, respectively). Smaller numbers of spiders in the Lycosidae, Oxyopidae, and Thomisidae were also tested. Among the thomisids, 38% in 2002 and 41% in 2003 tested positive for fructose. None of the lycosids (wolf spiders) tested positive; two of nine oxyopids (lynx spiders) did test positive. Oxyopidae is new to the list of nectarivorous spiders. These results suggest that nectarivory is common for foliage wandering spiders and may contribute to fitness.     

Side-effects of insecticides on two erigonid spider species

The current rearing technique forErigone atra (Blackwall) andOedothorax apicatus (Blackwall) (Araneae, Erigonidae) was improved. To reduce time spent rearing on live fruit flies the spiders were kept on a culture of the Collembola speciesLepidocyrtus lanuginosus (Gmelin) (Entomobryidae). Side-effects on spiders of two pyrethroid insecticides (fenvalerate and lambda-cyhalothrin) and one carbamate insecticide (pirimicarb) were tested. Sensitivity of adults of both sexes and juveniles to insecticides and their influence on the rate of emergence of spiderlings from cocoons were investigated using topical application, spraying or residual contact. LD₅₀ values for adults ranged from 0.49 to 2.52 ng a.i./spider for lambda-cyhalothrin and from 5.75 to 98.20 ng a.i./spider for fenvalerate. Topical application also resulted in up to a week's delay of web-building. A moving laboratory spraying equipment was used to spray spiders with different insecticide dosages and water volumes. Pyrethroids sprayed onto adults in webs had stronger effects than pyrethroids sprayed onto sitting or walking spiders on the soil surface. Residual contamination caused higher mortality of spiders after contact with lambda-cyhalothrin than fenvalerate. In all tests, males were more susceptible to pyrethroids than females; this difference was related to body weight. Mortality rate was higher forE. atra than forO. apicatus. Both pyrethroids were also toxic to spiderlings. Lambda-cyhalothrin inhibited emergence ofE. atra spiderlings from cocoons. Pirimicarb was harmless to both spider species.     

Odor-based recognition of nectar in cursorial spiders

Carnivorous arthropods are known to rely on non‐prey foods, such as honeydew, pollen, and nectar. Consumption of plant‐based nutrients by spiders also appears to be widespread, especially in cursorial species. This is not surprising, as studies have shown that these spiders’ activity levels, survivorship, and reproduction are increased when their diet includes plant‐based nutrients, especially under conditions of prey scarcity. However, the sensory and behavioral means by which they recognize and locate non‐prey food is unknown. Here we show that immatures of a nectarivorous spider [Hibana futilis Banks (Araneae: Anyphaenidae)] can recognize and remember particular chemical stimuli associated with nectar. Following ingestion of minute amounts of sugar, these spiders exhibited counterturning and other local searching behaviors that increased their chances of finding more nectar. When placed on test arenas, spiders that were naïve with respect to nectar aroma located artificial nectaries composed of diluted honey significantly faster than unscented nectaries composed of 1 m sucrose solution. These results indicate that H. futilis is neurophysiologically and behaviorally adapted for recognizing olfactory stimuli. Interestingly, only spiders that ingested sugar and were engaged in local search responded to nectar aroma, suggesting that stimulation into local search is necessary to prime olfactory responses. We found that H. futilis could be conditioned to associate the presence of nectar with a novel aroma, in this case vanilla, and remember this aroma over the course of several hours. In arenas with vanilla‐scented nectaries, spiders that had previous experience feeding on vanilla‐scented sucrose droplets located the nectaries significantly faster than did vanilla‐naïve spiders. The capacity to remember specific aromas could enhance the spiders’ ability to find nectar, either when moving between different parts of the same plant or among different plant species. The results here indicate that nectarivorous spiders possess the sensory capabilities and programed behaviors necessary for efficient detection, recognition, and location of nectar sources.     

Potential predation of non-webbuilding spider assemblage on cotton pests Helicoverpa armigera and Spodoptera littoralis (Lepidoptera: Noctuidae)

The relative feeding rates and preferences of a hunting-spider assemblage inhabiting southern Spanish cotton fields for two major cotton pests, Helicoverpa armigera (Hübner) and Spodoptera littoralis (Boisdubal) (Lepidoptera: Noctuidae), were analyzed under laboratory conditions. First, a no-choice feeding test was used to determine relative feeding rates for hunting-spider families and species, offering a fixed number of 10 neonate larvae of H. armigera or S. littoralis and observing predation after 2 h, 4 h, 8 h, and 24 h. In a second test, Drosophila melanogaster, a very palatable alternative prey, was used to determine the degree of preference for cotton pest larvae. The mean number of first-instar lepidoptera larvae consumed by hunting spiders after 24 h was 8.57±0.25. As expected, spiders showed no preference for either of the two cotton pest species H. armigera and S. littoralis over the other. Results also showed that cursorial spiders of the families Miturigidae (represented here by Cheiracanthium pelasgicum) and Philodromidae consumed significantly higher percentages of larvae than crab spiders belonging to the Thomisidae family after 2 h and 24 h, respectively. In the prey choice test, Cheiracantium pelasgicum displayed a strong preference for cotton pest larvae while Thomisidae and Oxyopidae showed no significant preference. In addition, as the attack sequence progressed, Ch. pelasgicum showed a clear tendency towards the alternation of prey while Thomisidae, and more irregularly Oxyopidae, maintained their preference for D. melanogaster. These findings confirmed both the considerable potential value of some cursorial spiders (e.g. Ch. pelasgicum) in the biological control of lepidopteran cotton pests and the relatively low impact of other hunting spiders, e.g. Thomisidae, on pests of this kind.     

The allometry of CNS size and consequences of miniaturization in orb-weaving and cleptoparasitic spiders

Allometric studies of the gross neuroanatomy of adults from nine species of spiders from six web-weaving families (Orbicularia), and nymphs from six of these species, show that very small spiders resemble other small animals in having disproportionately larger central nervous systems (CNSs) relative to body mass when compared with large-bodied forms. Small spiderlings and minute adult spiders have similar relative CNS volumes. The relatively large CNS of a very small spider occupies up to 78% of the cephalothorax volume. The CNSs of very small spiders extend into their coxae, occupying as much as 26% of the profile area of the coxae of an Anapisona simoni spiderling (body mass < 0.005 mg). Such modifications occur both in species with minute adults, and in tiny spiderlings of species with large-bodied adults. In at least one such species, Leucauge mariana, the CNS of the spiderling extends into a prominent ventral bulge of the sternum. Tiny spiders also have reduced neuronal cell body diameters. The adults of nearly all orbicularian spiders weave prey capture webs, as do the spiderlings, beginning with second instar nymphs. Comparable allometric relations occur in adults of both orb-weaving and cleptoparasitic species, indicating that this behavioral difference is not reflected in differences in gross CNS allometry.     

Characterization of restricted area searching behavior following consumption of prey and non-prey food in a cursorial spider, Hibana futilis

Cursorial spiders are important predators of crop pests in a variety of agricultural systems. Their survivorship, growth, and fecundity can be enhanced by the consumption of extra‐floral nectar. We recently showed that Hibana futilis (Banks) (Araneae: Anyphaenidae) engages in restricted area search following contact with nectar, is stimulated by nectar aroma, and can learn to recognize novel aroma cues. Studies have shown that H. futilis is also responsive to solvent extracts of the eggs and scales of the corn earworm, Helicoverpa zea Boddie (Lepidoptera: Noctuidae), one of its primary prey insects in cotton. The arrestment behavior of cursorial spiders following consumption of prey and non‐prey food has not been characterized. In the present study, the responses of spiders were measured following consumption of prey (H. zea eggs) or non‐prey (droplets of dilute honey) food items and compared with individuals tested without food items. The food items were presented to the spiders in test arenas constructed from the top of an inverted glass Petri dish cover. A combination of real time and recorded observations were made via a video camera attached to a computer. The behaviors and movement patterns of individual spiders were analyzed with behavioral tracking software. Significant differences in the behaviors and motion paths of spiders tested in the different treatments were observed. Hibana futilis displayed significantly more dispersal behavior on a blank test arena, than on test arenas supplied with honey droplets or moth eggs. Likewise, spiders tested on the blank arena crawled faster and their motion paths were significantly less tortuous than those of spiders tested in the arenas with honey or moth eggs. Following consumption of both the honey droplets and moth eggs, spiders showed elevated levels of restricted area search and lowered levels of dispersal behavior. The analysis showed that these spiders could crawl rapidly for extended distances. Behaviors such as restricted area search and learned recognition of food‐based stimuli would facilitate efficient location of the food resources needed to maintain their high activity levels.     

Nectar feeding increases exploratory behaviour in the aphid parasitoid Diaeretiella rapae (McIntosh)

Feeding on floral nectar has multiple positive effects on parasitic wasps, including increased longevity and fecundity, and in addition, nectar feeding can also alter parasitoid behaviour. To advance understanding of the effects of nectar feeding on Diaeretiella rapae (McIntosh) [Hymenoptera: Braconidae], the activities of 1‐day‐old female D. rapae with or without a prior buckwheat (Fagopyrum esculentum) nectar meal were quantified. Nectar increased searching time of D. rapae by a factor of 40 compared with individuals provided with water only and reduced the time spent stationary. The number of attacks to aphids by nectar‐fed parasitoids was not significantly (P = 0.06) higher than that of unfed D. rapae, suggesting that the conditions of the experiment facilitated host finding by ‘quiet’ parasitoids. Nevertheless, nectar feeding modified the behaviour of D. rapae in a way that parasitoids were more explorative and less inactive. This represents one additional mechanism through which nectar feeding impacts parasitoid biology and suggests that a synergy between increased host searching, increased longevity and increased fecundity should lead to an enhancement of biocontrol when D. rapae females have access to nectar in the field.     

Field energetics and the estimation of pollen and nectar intake in the marsupial honey possum, Tarsipes rostratus, in heathland habitats of South-Western Australia

A method is described, based on the simultaneous turnover of both stable (¹⁸O) and radioactive isotopes (³H and ²²Na), whereby the daily nectar and pollen intake of free-ranging marsupial honey possums (Tarsipes rostratus) may be estimated. The field metabolic rate is measured using doubly labelled water and nectar intake is estimated independently from the measured water and sodium fluxes. The method assumes that free-water intake is negligible (but may be accounted for if not the case), that virtually all dietary sodium is derived from nectar rather than from pollen, and that the animals are in energetic balance over the period of measurement. These assumptions have been tested and found to be robust, except during periods of heavy rain when significant intakes of free-water were recorded. Leaching experiments with pollen grains suggest that less than 10% of the sodium ingested by honey possums is derived from pollen and calculations thus assumed a 90%:10% split between nectar and pollen. Nectar intake averaged 5.9 ± 0.6 ml · day⁻¹ and regressing nectar intake on daily change in body mass predicts an intake of approximately 7 ml · day⁻¹ nectar to maintain balance for a 9 g honey possum. Estimates of pollen intake averaged 660 ± 156 mg · day⁻¹ and a similar regression analysis of the data predicts that a daily intake of approximately 1 g pollen would be needed to maintain mass balance of honey possums. Estimated nectar and pollen intakes did not differ significantly between males and females, but nectar intake was higher in winter compared with dry periods of the year. The sugar content of nectar falls during winter, however, and the overall energy derived from nectar thus remains roughly constant. Estimates of pollen and nectar intake for individual animals were not significantly correlated, suggesting that honey possums forage selectively for these two food items. Accepted: 19 August 1999     

Resident spiders as predators of the recently introduced light brown apple moth,Epiphyas postvittana

The invasive light brown apple moth, Epiphyas postvittana (Walker) (Lepidoptera: Tortricidae), has not reached damaging levels on crops in California (USA), suggesting that its populations and impact are limited by generalist natural enemies. In a series of laboratory experiments, we examined resident spiders as predators of E. postvittana larvae on two host plants, the ornamental Australian tea tree, Leptospermum laevigatum (Gaertn.) F. Muell (Myrtaceae), and the weed French broom, Genista monspessulana (L.) L.A.S. Johnson (Fabaceae). Of three abundant spider species in Australian tea tree, two hunting spiders measurably reduced the numbers of E. postvittana larvae and plant damage, whereas a web‐weaving spider had no detectable impact. The adult stage of the dominant hunting spider Anyphaena aperta Banks (Anyphaenidae) consumed E. postvittana larvae, but neither large nor small juveniles had statistically detectable effects on numbers of larvae. However, plant damage was reduced in the presence of large juvenile A. aperta, suggesting that A. aperta may also have non‐consumptive effects on the feeding behavior of E. postvittana larvae. Anyphaena aperta consumed larvae only when larval densities exceeded a low threshold in a functional response experiment, leading to a type III functional response. Adult A. aperta showed no preference for different E. postvittana instars, whereas Cheiracanthium mildei L. Koch (Miturgidae), an abundant hunting spider on French broom, showed a partial preference for late‐instar larvae. The generalist feeding habits of the spiders may have precluded strong prey preferences. Results show that hunting spiders may help limit E. postvittana populations in California, and that they may in turn reduce the impact of E. postvittana on its host plants.     

Maternal Care and Infanticide by Males in Helvibis longicauda (Araneae: Theridiidae)

Maternal care in spiders varies from just the construction of a protective silken structure for the eggs and the selection of a safe site to place them, to a long period of association between the mother and spiderlings. Such extended care may involve the active protection from predators and parasitoids, food regurgitation, the production of trophic eggs and even matriphagy. In this study, we describe extended maternal care in Helvibis longicauda (Theridiidae) and evaluate the effectiveness of maternal protection against predators of eggs and spiderlings. We conducted experiments comparing the frequency of egg sac destruction and mortality of spiderlings in the presence and absence of mothers. We also observed the behaviour of the mother and spiderlings during prey capture events and interactions with possible predators. Helvibis longicauda females guard their egg sacs until the emergence of the young and guard the spiderlings for several instar stages, fighting possible predators, including conspecifics. We found that aggressive behaviour by females increased the survival of both eggs and spiderlings in our experiments. Intruder males were the main source of mortality in the absence of females. The benefits of maternal care for the young also include the acquisition of prey items that are captured, immobilized and pre‐digested by the mother. Effective maternal protection and the extended period of supplying food to juveniles probably contribute to the late dispersal of offspring in H. longicauda.     

Flowers and fruits prolong survival of drosophila pupal parasitoids

Adult parasitoids often feed on sugar sources for survival and to fuel energy. Therefore, the provision of sugar sources, such as nectar from flowers, can enhance biological control. We assessed whether Pachycrepoideus vindemmiae and Trichopria drosophilae, two pupal parasitoids of Drosophila spp., can profit from different sugar sources. In a laboratory experiment, we offered honey, cornflower and buckwheat flowers, crushed and Drosophila suzukii-infested blueberries as well as hosts together with honey. In both parasitoid species, all food sources significantly prolonged the lifespan of females compared to the control. The flowers prolonged the lifespan in both species threefold or fourfold, in P. vindemmiae from a mean of 6 to 28 days, in T. drosophilae from 13 to 49 days. Infested and damaged blueberries also enhanced mean survival in both species. When fed honey, the presence of hosts slightly decreased lifespan in P. vindemmiae and strongly decreased it in T. drosophilae. Our results suggest that the parasitoids can utilize the fruits they encounter during host search. Flowers could enhance their biological control function even further, as long as they do not benefit the pest.     

一些蜘蛛类群味觉毛的形态、数量和分布

化学通讯是蜘蛛最基础和最普遍的种内及种间通讯方式之一,蜘蛛体表的味觉毛能够接触性地或者近距离地感知环境中的化学物质,但味觉毛的相关研究仅在少数几种蜘蛛中有过报道。我们通过扫描电镜分别对幽灵蛛科(Pholcidae)、弱蛛科(Leptonetidae)、泰莱蛛科(Telemidae)、蟹蛛科(Thomisidae)和球蛛科(Theridiidae)共5科32种蜘蛛味觉毛的形态、数量及分布进行了观察。结果显示:蜘蛛味觉毛一般呈"S"形或弧形;毛根部与体表形成较大角度,末端开口。一般分布在步足的跗节和后跗节,一些种类在步足胫节亦有味觉毛分布。所观察的蜘蛛中绝大部分种类在触肢上未发现味觉毛,仅有2种蟹蛛即角红蟹蛛(Thomisus labefactus)和膨胀微蟹蛛(Lysiteles inflatus)以及1种球蛛即鼬形微姬蛛(Phycosomamustelinum)在触肢上有味觉毛。味觉毛的数量在不同蜘蛛种类中有较大差异,从十几根到上百根不等。蜘蛛味觉毛的形态、数量和分布等特征除了与遗传相关外,亦有可能与其生境和生活方式等有关。     

Biology, rearing and field release on Guam of Euplectrus maternus, a parasitoid of the fruit-piercing moth, Eudocima fullonia

The eulophid parasitoid, Euplectrus maternus, is a gregarious ectoparasitoid of the larvae of thefruit-piercing moth, Eudocima (Othreis) fullonia. This parasitoid is indigenous to India and was released into Guam in 1998–99 to aid in the biological control of E. fullonia, an important pest of ripeguava, banana, mango, pomegranate, litchi,papaya, tomato, orange and other fruit crops.In the laboratory, biology and rearing of E. maternus on the larvae of E. fulloniawere studied. In no-choice tests, ovipositionby E. maternus was significantly greateron first and second instar larvae than on thirdinstar larvae. However, in free-choice tests,oviposition by E. maternus wassignificantly greater on second instar larvae,followed by first and third instar larvae. Thisparasitoid did not lay eggs on later instars,either in no-choice or free-choice tests.Females laid a significantly greater number ofeggs (>80%) on the dorsal surface of thelarvae than on either lateral or ventralsurfaces (1 to 8%). In general, more eggs werelaid on abdominal segments 1–3 on larvalinstars one to three. The survival of theimmature stages (from egg to adult) of E. maternus on second instar E. fullonialarvae was 61%, which was significantlygreater than the survival rates on first andthird instar larvae (32% and 26%), indicatingthat second instar host larvae are ideal formass rearing of the parasitoid. Mated femaleE. maternus continuously laid eggs on thesecond instar larvae of E. fullonia forup to 30 days, but the greatest number of eggswere laid during the first week after exposure.When E. maternus laid more than two eggson host larva, more female progeny wereproduced, indicating female-biasedreproduction. Adult parasitoids lived longerwhen fed with a honey: water (50% w/v)solution than with pure honey. Similarly, thefecundity of females increased significantlywhen fed with the honey-water solution whencompared to feeding with pure honey. To date,E. maternus has not established in Guam.     

Use of prey and non-prey food by the ladybird beetle Eriopis connexa (Coleoptera: Coccinellidae) under laboratory-rearing conditions

Prey for predators can fluctuate in abundance and in quality over time requiring predator strategies to cope with food shortage. Coccinellinae are often associated with sap-sucking pests that exhibit high population unpredictability such as aphids and psyllids. Eriopis connexa (Germar) (Coleoptera: Coccinellidae) is a predator with potential for biological control, especially a well-studied population which is resistant to pyrethroids used to control insect defoliators. Both larvae and adult E. connexa were provided ad libitum prey and non-prey foods (pollen and honey water solution) at increasing intervals from 1 to 10 days. Neonate larvae of E. connexa required eating prey daily to develop into adults. However, non-prey food such as honey water solution did prolong larval and adult survival but neither fulfilled larval development nor adult reproduction. Honey water solution promoted 100% adult survival up to 25 days in the adult stage without prey with oviposition returning after daily feeding on prey. Females subjected to increased feeding intervals over four days reduced oviposition and lived longer, but 10-day feeding intervals correlated with risk to adult survival. These results indicate the importance of non-food sources in E. connexa maintenance and the ability of larvae and adult females to compensate for prey scarcity.     

Adult male bolas spiders retain juvenile hunting tactics

Bolas spiders in the genus Mastophora exhibit extreme sexual size dimorphism. In temperate regions, the diminutive males become adults about 2 months before females mature. Late-instar and adult females attract certain male moths by aggressive chemical mimicry of those moth species' sex pheromones. While hunting, these larger female spiders hang from a horizontal silken line and capture moths by swinging a “bolas” (i.e., a sticky globule suspended on a thread) at the approaching moths. Small, early-instar bolas spiders of both sexes attract moth flies in the genus Psychoda, which they capture without using a bolas or web. Instead, they position themselves along leaf margins and use their front two pairs of legs to grab approaching prey. The predatory habits of adult male bolas spiders have never been reported. Our field experiments demonstrated that adult males of the bolas spider Mastophora phrynosoma attract adult male Psychoda phalaenoides. Each year during our 3-year study, significantly more P. phalaenoides were captured on sticky traps baited with live adult male M. phrynosoma than on unbaited control traps. Thus, the tiny adult male bolas spiders retain the juvenile hunting tactic of attracting psychodid flies, while female bolas spiders switch from hunting psychodid flies as spiderlings to hunting moths when the female spiders become older and larger. Received: 5 May 1997 / Accepted: 14 July 1997