Pw Walker

Adaptations of locusts and grasshoppers to the low and variable rainfall of Australia

Abstract In Australia, where approximately 80% of the land area is arid or semiarid, rainfall is the major factor limiting acridid populations. Rainfall is not only limiting in terms of quantity but also in being highly variable, both temporally and spatially. In this paper, the main adaptations seen in Australian Acrididae to overcome limiting rainfall are discussed with special reference to economically important species. In the arid to semiarid subtropics (lat 23–33°S) rainfall is slightly summer-dominant but extended dry periods can occur in any season. Chortoicetes terminifera, the main pest species, avoids dry periods through embryonic diapause or survives dry periods as quiescent eggs or adults. Migration is critical for survival as it allows locusts to locate areas of localized rainfall. Outbreaks are frequent and develop when enough rain falls to allow continuous breeding over three to four generations. In temperate areas of subcoastal southern Australia, summers are dry and most rain falls in winter or early spring. Austroicetes cruciata, a univoltine pest species, avoids the dry summers by having an embryonic diapause between summer and early winter. In the tropical north (lat 13–23°S), rainfall is strongly summer-dominant and Austracris guttulosa, another univoltine species, survives the dry winter as immature adults in reproductive diapause. Adults mature after feeding on the green vegetation present following early rains of the wet season. But the early rains are often localized and adults migrate until they encounter these localized areas of rain. Adults then mature and lay, but the survival of their offspring eggs and very young nymphs is assured only if there is further rain within 6 weeks. Outbreaks develop only when there are several years of regular rains both in outbreak areas and adjacent areas of the arid zone. Locusta migratoria does not have a stage that can survive extended dry periods. Consequently, it is mainly restricted to subcoastal areas of moderate rainfall. In the main outbreak areas of subtropical Queensland, populations often decline during the commonly dry winters but outbreaks develop when good rain falls in all seasons.

Interactions between Papilionidae and ancient Australian Angiosperms: evolutionary specialization or ecological monophagy?

The evolution of host range for insect herbivores involves many behavioral, physiological, and biochemical adaptations that often lead to locally specialized populations or species. Such specialization may be constrained by ecological factors (e.g., local host availability) or by evolutionary factors (e.g., phylogenetic divergence in behavioral, physiological, or biochemical detoxification enzymes; and potential inabilities to return to ancestral hosts). While insect adaptations to new hosts can be rapid, ancient detoxification systems may persist in some lineages of swallowtail butterflies (Papilionidae) for millions of years. Here, we test various species of specialized species/populations of Papilionidae (Lepidoptera) from North America and from Australia on an array of Australian host plant families in order to determine whether the current feeding constraints reflect loss of capabilities to recognize and use hosts other than their current (local) favorites. We selected two species of Lauraceae specialists (Papilio troilus L. and Papilio palamedes Drury) from North America and one locally specialized population of Papilio glaucus L. that only uses one plant species in the Magnoliaceae in Florida. We also examined three species/populations of Australian swallowtails for comparison, including the Monimiaceae‐specialized Graphium macleayanum moggana L. E. Couchman, the Rutaceae‐specialized Papilio aegeus Donovan, and the Annonaceae‐specialized Graphium eurypylus L. Our aim was to determine whether neonate larvae of these six specialists could survive on any plants other than their currently favored species. While the Lauraceae specialists could use nothing else and were thus evolutionarily constrained, the Magnoliaceae‐, Rutaceae‐, and Monimiaceae specialists all had common abilities to accept, feed, and grow on plants in the Lauraceae, Monimiaceae, Magnoliaceae, and Rutaceae families. Even the Annonaceae specialist was discovered using Magnoliaceae in the field, suggesting existence here also of both flexiblity in preferences and detoxification abilities and ‘ecological monophagy’.

A Case Study of the Australian Plague Locust Commission and Environmental Due Diligence: Why Mere Legislative Compliance Is No Longer Sufficient for Environmentally Responsible Locust Control in Australia

Abstract The Australian Plague Locust Commission (APLC) manages locust populations across 2 million square kilometers of eastern Australia using the aerial application of chemical and biological control agents to protect agricultural production. This occurs via a preventative control strategy involving ultralow-volume spray equipment to distribute small droplets of control agent over a target area. The economic costs of, and potential gains stemming from, locust control are well documented. The application of insecticides, however, to fragile arid and semiarid ecosystems is a task that brings with it both real and perceived environmental issues. The APLC is proactive in addressing these issues through a combination of targeted environmental operational research, an ISO-14001–aligned Environmental Management System (EMS), and links with environmental regulatory and research institutions. Increasing due diligence components within Australian environmental legislation dictate that mere legislative compliance is no longer sufficient for industries to ensure that they meet their environmental obligations. The development of external research links and the formulation of an EMS for locust control have enabled the APLC to identify environmental issues and trends, quantify objective environmental targets and strategies, and facilitate continuous improvement in its environmental performance, while maintaining stakeholder support. This article outlines the environmental issues faced by the APLC, the research programs in place to address these issues, and the procedures in place to incorporate research findings into the organizations operational structure.

Ecological monophagy in Tasmanian Graphium macleayanum moggana with evolutionary reflections of ancient angiosperm hosts

Abstract Local host plant specialization in an insect herbivore may be caused by numerous factors, including host‐specific natural enemy pressures or a local lack of suitable host‐plant choices that are available elsewhere in its range. Such local specialization or “ecological monophagy”, for whatever reason, may reflect reduced ability to behaviourally accept or physiologically utilize other allopatric hosts that are naturally used elsewhere by the species. We tested this feeding specialization hypothesis using the Tasmanian subspecies of Macleays swallowtail butterfly, Graphium macleayanum moggana (Papilionidae), which uses only a single host‐plant species, Antherosperma moschatum (southern sassafras, of the Monimiaceae). Further north, this same butterfly species (G. m. macleayanum) uses at least 13 host‐plant species from seven genera and four families (Lauraceae, Rutaceae, Winteraceae, and Monimiaceae). Our larval feeding assays with G. m. moggana from Tasmania showed that certain Magnoliaceae and Lauraceae could support some larval growth to pupation. However, such growth was slower and survival was lower than observed on their normal southern sassafras host (Monimiaceae). We also found that toxicity of particular plant species varied tremendously within plant families (for both the Magnoliceae and the Monimiaceae).

Mating frequency and reproductive success in an income breeding moth, Mnesampela privata

The frequency of mating in insects is often an important determinant of female reproductive output and male sperm competition. In Lepidoptera that provide male nutrients to the female when mating, it is hypothesized that polyandry may be more prevalent. This is thought to be especially so among species described as income breeders; that is, in species who do not derive all their nutrients for reproductive output entirely from the resources obtained during the larval stage. We selected the geometrid moth, Mnesampela privata (Guenée) (Lepidoptera: Geometridae), to examine this hypothesis further. We found this species was best characterized as an income breeder with female weight on emergence positively correlated with total egg load but not with the number of eggs laid. Further, in accord with income breeders, females emerged with a partially developed egg load and lifetime fecundity was positively correlated with the number of oviposition days. However, in the laboratory we found that incidence of repeated matings or polyandry was rare. When moths were paired singly over their lifetime, only 4% of mated females multiple mated. When females were paired with three males concurrently, female mating success increased from 60 to 81% with multiple mating among mated females increasing to just 15%. Dissection of wild caught M. privata found that polyandry levels were also low with a maximum of 16.4% of females collected at any one time being multiple mated. In accord with theory, mating significantly increased the longevity of females, but not of males, suggesting that females acquire essential resources from male ejaculates. Despite this, multiple mated females showed a trend toward decreasing rather than increasing female reproductive output. Spermatophore size, measured on death of the female, was not correlated with male or female forewing length but was negatively correlated with the number of fertile eggs laid and female longevity. Smaller spermatophore width may be related to uptake of more nutrients by the female from a spermatophore. We discuss our findings in relation to income breeding and its relationship to polyandry in Lepidoptera.

Delayed mating and reproduction in the autumn gum moth Mnesampela privata

1 The success of mating disruption using synthetic sex pheromones depends not only on preventing mating, but also on delaying mating in the target insect. Using the geometrid pest of Eucalyptus plantations, Mnesampela privata (Guenée), we determined the effect of delaying mating when imposed on males only, females only or on both sexes simultaneously, for 1, 3, 5 and 7 days. 2 Delayed mating had a significant negative impact on reproduction, with a 0.89‐fold decrease in the likelihood of mating and a 0.67‐fold decrease in the likelihood of that mating resulting in fertile eggs for every day that mating is delayed. A mating delay of 7 days reduced the mean number of viable eggs laid to 4–13% of that laid by moths paired immediately after emergence. 3 Male only imposed mating delays had a significantly lower effect on reducing the likelihood of pairs mating than when both sexes were delayed. A delay imposed on one sex only or on both sexes simultaneously, however, had a similar negative impact on the proportion of fertile matings as well as on the total number of fertile eggs laid. 4 Longevity of mated female and male M. privata was significantly different between mating delay treatments, with a significant decline in female longevity when they mated with older males. 5 The underlying mechanisms causing a decline in female reproductive output when a mating delay was imposed on males versus females are discussed in relation to the reproductive biology of M. privata and the potential of using mating disruption strategies to control populations in Eucalyptus plantations.

The tomato potato psyllid, Bactericera cockerelli (Šulc, 1909) (Hemiptera: Triozidae): a review of the threat of the psyllid to Australian solanaceous crop industries and surveillance for incursions in potato crops

The tomato potato psyllid, Bactericera cockerelli (Šulc, 1909), is a major biosecurity threat to Australian solanaceous crop industries. Native to North and Central America, B. cockerelli was accidentally introduced into New Zealand in the mid‐2000s. The psyllid is a vector of a phloem‐limited, alpha‐proteobacterium, ‘Candidatus Liberibacter solanacearum’ (= ‘Ca. L. psyllaurous’), which is associated with psyllid yellows disease in tomatoes, potatoes, capsicums, eggplants and tamarillos, and zebra chip disease in potatoes. Both the vector and pathogen have had a devastating impact on the solanaceous crop industries they affect, resulting in millions of dollars of losses annually through increased pest control and surveillance, reduced yields and disruption to commodity export markets. In April 2014, B. cockerelli and ‘Ca. L. solanacearum’ were reported on Norfolk Island, and it is feared that they could enter other Australian States or Territories either through the accidental importation of infested plant material or by the dispersal of psyllids on easterly airflows from New Zealand. In this paper, we give an overview of the threat of the vector and pathogen to Australian commodities. We report on an ongoing surveillance program, initiated in February 2011, designed to detect incursions of B. cockerelli in eastern Australian potato fields using yellow sticky traps. During the last 3 years, over 2300 traps were placed in the major potato growing regions of Tasmania, Victoria, South Australia and Queensland. No B. cockerelli were detected but over 9600 other Psylloidea were trapped, mainly Ctenarytaina spp. and Acizzia spp. (Psyllidae). Only 0.3% of all Psylloidea caught belonged to the Triozidae allowing the rapid differentiation of the majority of trapped psyllids from B. cockerelli based on wing venation. Recommendations are made for further research and to extend the surveillance program to include other Australian solanaceous crop industries.

Not a one-way trip: historical distribution data for Australian plague locusts support frequent seasonal exchange migrations

Abstract An analysis of the development of infestations of the Australian plague locust (Chortoicetes terminifera) (Walker) (Orthoptera: Acrididae) from 1977–1995 in eastern Australia is presented which traces the sequence of generations and redistribution of gregarious populations through migration. Migration in this species has previously been viewed as a one-way trip, locusts reaching southern regions of the species range were thought to have no reliable means of return to the areas of summer population increase in western Queensland. However, a study of outbreaks over recent years, using new technologies for simulating and observing migratory events, suggested a pattern of exchange migrations, with northward movements in November and December. In this paper we provide further evidence of migrations to western Queensland from populations in the southern or eastern parts of the species range. Several northward or westward migrations from New South Wales, South Australia or eastern Queensland are identified from historic distribution data and supported by meteorological records. These migrations were significant in that they allowed the rapid re-establishment of gregarious populations in arid western Queensland after summer rains. The frequency of late-spring northward migrations is comparable to that of the better-known southward migrations in autumn. The evidence for previous conclusions about the source of historical plagues and the importance of spring breeding in arid southwest Queensland are re-examined in the light of these findings.

Sex-biased parasitism of adult spring beetles, Heteronyx dimidiata and Heteronyx crinitus, by Tachinidae in Eucalyptus nitens plantations in Australia

Parasitism of adult Heteronyx dimidiata (Erichson) and H. crinitus Blackburn (Scarabaeidae: Melolonthinae), that attack Eucalyptus nitens plantation seedlings in southern Australia, was recorded over 3 years. An undescribed genus of Blondeliini (Tachinidae: Exoristinae) was reared from both scarab species while a Palpostoma sp. (Tachiinae) was reared from H. crinitus. Flies were observed parasitising flying beetles by intercepting them mid‐air. Eggs were laid externally on the exoskeleton, mainly on the dorsum of abdominal tergites. Male H. dimidiata were parasitised significantly more (40%) than female conspecifics (13%) and male or female H. crinitus (both 13%), which was attributed to their greater flight activity searching for mates. Superparasitism was common in both species, particularly in male H. dimidiata (56% of parasitised beetles, up to 22 eggs/beetle), despite evidence that only a single tachinid could complete development in a beetle. Early stages of parasitism in H. dimidiata females did not appear to affect ovarian development nor the ability of beetles to feed on young trees. However, we infer that the tachinids had a significant impact on Heteronyx spp. populations through a reduction in adult beetle longevity and fitness.