The introduction and release of Chiasmia inconspicua and C. assimilis (Lepidoptera: Geometridae) for the biological control of Acacia nilotica in Australia

Two geometrid moths Chiasmia inconspicua and Chiasmia assimilis, identified as potential biological control agents for prickly acacia Acacia nilotica subsp. indica, were collected in Kenya and imported into quarantine facilities in Australia where laboratory cultures were established. Aspects of the biologies of both insects were studied and CLIMEX® models indicating the climatically favourable areas of Australia were developed. Host range tests were conducted using an approved test list of 74 plant species and no-choice tests of neonate larvae placed on both cut foliage and potted plants. C. inconspicua developed through to adult on prickly acacia and, in small numbers, Acacia pulchella. C. assimilis developed through to adult on prickly acacia and also in very small numbers on A. pulchella, A. deanei, A. decurrens, and A. mearnsii. In all experiments, the response on prickly acacia could be clearly differentiated from the responses on the non-target species. Both insects were approved for release in Australia. Over a three-year period releases were made at multiple sites in north Queensland, almost all in inland areas. There was no evidence of either insect’s establishment and both colonies were terminated. A new colony of C. assimilis was subsequently established from insects collected in South Africa and releases of C. assimilis from this new colony were made into coastal and inland infestations of prickly acacia. Establishment was rapid at one coastal site and the insect quickly spread to other infestations. Establishment at one inland area was also confirmed in early 2006. The establishment in coastal areas supported a CLIMEX model that indicated that the climate of coastal areas was more suitable than inland areas.     

Introduction, establishment, and potential geographic range of Carmenta sp. nr ithacae (Lepidoptera: Sesiidae), a biological control agent for Parthenium hysterophorus (Asteraceae) in Australia

Parthenium (Parthenium hysterophorus L.), a major weed causing economic, environmental, and human and animal health problems in Australia and several countries in Asia, Africa, and the Pacific, has been a target for biological control in Australia since the mid-1970s. Nine species of insects and two rust fungi have been introduced as biological control agents into Australia. These include Carmenta sp. nr ithacae, a root feeding agent from Mexico. The larvae of C. sp. nr ithacae bore through the stem-base into the root where they feed on the cortical tissue of the taproot. During 1998-2002, 2,816 larval-infested plants and 387 adults were released at 31 sites across Queensland, Australia. Evidence of field establishment was first observed in two of the release sites in central Queensland in 2004. Annual surveys at these sites and nonrelease sites during 2006-2011 showed wide variations in the incidence and abundance of C. sp. nr ithacae between years and sites. Surveys at three of the nine release sites in northern Queensland and 16 of the 22 release sites in central Queensland confirmed the field establishment of C. sp. nr ithacae in four release sites and four nonrelease sites, all in central Queensland. No field establishment was evident in the inland region or in northern Queensland. A CLIMEX model based on the native range distribution of C. sp. nr ithacae predicts that areas east of the dividing range along the coast are more suitable for field establishment than inland areas. Future efforts to redistribute this agent should be restricted to areas identified as climatically favorable by the CLIMEX model.     

Agonosoma trilineatum (Heteroptera: Scutelleridae) a biological control agent of the weed bellyache bush,Jatropha gossypiifolia (Euphorbiaceae)

Bellyache bush, Jatropha gossypiifolia L., is a serious weed of northern Australia. Agonosoma trilineatum (F.) is an insect from tropical America released in Australia in 2003 as a biological control agent against bellyache bush. It feeds on seeds and has the potential to reduce seed production, thereby potentially reducing the rate of spread and recruitment. To test the host specificity of A. trilineatum, four biological responses to host plant species were determined: development of nymphs, oviposition preferences, adult feeding and frequency of mating. Development of nymphs to adults and adult feeding only occurred on three Jatropha spp. These species also supported mating and oogenesis but only J. gossypiifolia was accepted for oviposition. Mating did not occur in the presence of other plant species. The evidence indicates that there is little risk associated with the release of this insect species in Australia and probably other countries where this weed is a problem. The probability of this insect expanding its host range is low because multiple aspects of the biology would need to change simultaneously. A. trilineatum was released in Australia between 2003 and 2007. A Climex model indicated that coastal areas of Queensland and the Northern Territory would be climatically most suitable for this insect.     

Use of CLIMEX modelling to identify prospective areas for exploration to find new biological control agents for prickly acacia

Abstract  Selection of biocontrol agents that are adapted to the climates in areas of intended release demands a thorough analysis of the climates of the source and release sites. We present a case study that demonstrates how use of the CLIMEX software can improve decision making in relation to the identification of prospective areas for exploration for agents to control the woody weed, prickly acacia Acacia nilotica ssp. indica in the arid areas of north Queensland.     

Survey and prioritisation of potential biological control agents for prickly acacia (Acacia nilotica subsp. indica) in southern India

Prickly acacia, Acacia nilotica subsp. indica (Benth.) Brenan (Mimosaceae), a multi-purpose tree native to the Indian subcontinent, is a weed of national significance, widespread throughout the grazing areas of western Queensland and has the potential to spread throughout northern Australia. Biological control of prickly acacia has been in progress since the early 1980s, but with limited success to date. Based on genetic and climate matching studies, native surveys for potential biological control agents were conducted in 64 sites in Tamil Nadu state and eight sites in Karnataka state from November 2008 to December 2011. Surveys yielded 33 species of phytophagous insects (16 species of leaf-feeders, eight species of stem feeders, four species with leaf-feeding adults and root-feeding larvae, two stem-borers and bark-feeders and three flower-feeders) and two rust fungi. The number of species recorded at survey sites increased with the number of times the sites were surveyed. Using a scoring system based on field host range, geographic range, seasonal incidence and damage levels, we prioritised a scale insect (Anomalococcus indicus Ramakrishna Ayyar), two leaf-webbing caterpillars (Phycita sp. A and Phycita sp. B), a leaf weevil (Dereodus denticollis Boheman), a leaf beetle (Pachnephorus sp.), a gall-inducing rust (Ravenelia acacia-arabica Mundk. & Thirumalachari) and a leaf rust (Ravenelia evansii Syd. & P.) for detailed host specificity tests. The two rusts were sent to CABI-UK for preliminary host-specificity testing. Three insects (A. indicus, D. denticollis and Phycita sp. A) were imported into a quarantine facility in Brisbane, Australia where host-specificity tests are in progress.     

Biology and host range of Tecmessa elegans (Lepidoptera: Notodontidae), a leaf-feeding moth evaluated as a potential biological control agent for Schinus terebinthifolius (Sapindales: Anacardiaceae) in the United States

During surveys for natural enemies that could be used as classical biological control agents of Schinus terebinthifolius Raddi (Brazilian pepper), the caterpillar, Tecmessa elegans Schaus (Lepidoptera: Notodontidae), was recorded feeding on the leaves of the shrub in South America. The biology and larval and adult host range of this species were examined to determine the insect's suitability for biological control of this invasive weed in North America and Hawaii. Biological observations indicate that the larvae have five instars. When disturbed, the late instar larvae emit formic acid from a prothoracic gland that may protect larvae from generalist predators. Larval host range tests conducted both in South and North America indicated that this species feeds and completes development primarily on members of the Anacardiaceae within the tribe Rhoeae. Oviposition tests indicated that when given a choice in large cages the adults will select the target weed over Pistacia spp. However, considering the many valued plant species in its host range, especially several North American natives, this species will not be considered further for biological control of S. terebinthifolius in North America.     

Effect of Silt Coverage of Water Hyacinth Roots on Pupation of Neochetina eichhorniae Warner and N. bruchi Hustache (Coleoptera: Curculionidae)

Observations under field conditions in Bangalore showed that release of Neochetina eichhorniae and N. bruchi (Coleoptera: Curculionidae) brought about successful control of the water hyacinth in water bodies where the plants were free-floating. However, in situations where the plants were partly anchored, suppression of the weed was achieved only 8 years after insect release. Studies carried out under glasshouse conditions, in which plants with free-floating and silt-covered roots were exposed to Neochetina spp., showed that fully grown larvae were incapable of pupating on silted roots of the water hyacinth. This resulted in reduced adult emergence of N. eichhorniae and N. bruchi, indicating that delayed suppression of water hyacinth in silted tanks may be due to the low population build-up of the weevils.     

The host range and biology of <Emphasis Type="Italic">Cometaster pyrula</Emphasis>; a biocontrol agent for <Emphasis Type="Italic">Acacia nilotica</Emphasis> subsp. <Emphasis Type="Italic">indica</Emphasis> in Australia

Prickly acacia, Acacia nilotica subsp. indica (Benth.) Brenan, a major weed of the Mitchell Grass Downs of northern Queensland, Australia, has been the target of biological control projects since the 1980s. The leaf-feeding caterpillar Cometaster pyrula (Hopffer) was collected from Acacia nilotica subsp. kraussiana (Benth.) Brenan during surveys in South Africa to find suitable biological control agents, recognised as a potential agent, and shipped into a quarantine facility in Australia. Cometaster pyrula has a life cycle of approximately 2 months during which time the larvae feed voraciously and reach 6 cm in length. Female moths oviposit a mean of 339 eggs. When presented with cut foliage of 77 plant species, unfed neonates survived for 7 days on only Acacia nilotica subsp. indica and Acacia nilotica subsp. kraussiana. When unfed neonates were placed on potted plants of 14 plant species, all larvae except those on Acacia nilotica subsp. indica and Acacia nilotica subsp. kraussiana died within 10 days of placement. Cometaster pyrula was considered to be highly host specific and safe to release in Australia. Permission to release C. pyrula in Australia was obtained and the insect was first released in north Queensland in October 2004. The ecoclimatic model CLIMEX indicated that coastal Queensland was climatically suitable for this insect but that inland areas were only marginally suitable.     

Risk to non-target plants from Charidotis auroguttata (Chrysomelidae: Coleoptera), a potential biocontrol agent for cat’s claw creeper Macfadyena unguis-cati (Bignoniaceae) in Australia

The potential of the leaf beetle Charidotis auroguttata as a biocontrol agent for cat’s claw creeper Macfadyena unguis-cati (Bignoniaceae), an environmental weed in Australia, and risk to non-target plants was evaluated under quarantine conditions. In no-choice tests, C. auroguttata adults and larvae fed on many plant species across different families, but egg to adult development occurred only on the target weed. However, when neonate larvae from the target weed were transferred onto Myoporum boninense australe (Myoporaceae), a non-target native plant, 11.7% completed development, as compared to 95% of larvae that completed development on the target weed. Larval development on this non-target species also took twice as long as on the target weed. No larvae completed development on other test plants. In choice tests, leaf area consumption by adults and larvae was significantly more on the target weed than on other plants, and oviposition occurred only on the target weed. In the no-choice demography trials, adults laid eggs from the second week after emergence on the target weed, with an average of 0.286 eggs/female/day, resulting in an 18-fold increase in the adult population over 16 weeks. On My. boninense australe adult survival remained high, but oviposition commenced only from the 10th week after emergence with an average of 0.023 eggs/female/day, and none of the eggs developed into adults. In the choice demography trials, oviposition on the target weed was evident from the fourth week onwards, while on the non-target plant oviposition commenced only from the 14th week. Only 10% of total adults and 11.3% of total eggs were found on the non-target plant, and none of these eggs developed into adults. Although the biocontrol agent can ‘spill-over’ from the target weed to the non-target native plant and cause adult feeding damage, the non-target plant could not sustain a viable insect population on its own. This agent was not approved for field release in Australia due to perceived risk to non-target species.     

Lessons from Unsuccessful Attempts to Establish Spodoptera pectinicornis (Lepidoptera: Noctuidae), a Biological Control Agent of Waterlettuce

We released nearly 332 000 Spodoptera pectinicornis individuals for biological control of the floating aquatic weed Pistia stratiotes (waterlettuce) at 22 sites in Florida during December 1990-December 1997. Predation (by boat-tailed grackles, fire ants, and spiders) and Allee effects (resulting from rapid dispersal of adults) prevented populations from persisting during early attempts. These efforts consisted of small releases at multiple sites, with no nurturing of the introduced populations. Modification of our initial approach resulted in a series of release strategies that consisted of multiple releases at fewer sites and employed progressively more intensive nurturing of the introduced populations. The most successful strategy incorporated: (i) cages to restrict adult dispersal and exclude flying predators; (ii) plant-free zones around the cages to exclude crawling predators; (iii) enhancement of the nutritional quality of waterlettuce in the cages; and (iv) frequent inoculation of the cages with laboratory-reared insects. Use of this strategy resulted in several provisionally-established S. pectinicornis populations, numbering as much as 23.5 S. pectinicornis individuals m -2 , and produced up to seven post-release generations. Unfortunately, all of these incipient populations declined until S. pectinicornis was undetectable. We conclude that field populations of this moth no longer persist in Florida, and offer an introspective assessment of how this project might have been improved.     

Introduction, Rearing, and Host Range of Aerenicopsis championi Bates (Coleoptera: Cerambycidae) for the Biological Control of Lantana camara L. in Australia

The biology and host range of the cerambycid beetle Aerenicopsis championi Bates, a potential biological control agent for the weed Lantana camara L., were studied. A. championi is a univoltine species associated with L. camara, L. urticifolia, and L. hirsuta in Mexico and Central America. In Mexico, adult emergence occurred in May and June at the start of the rainy season. Larvae fed within the stems over a 9- to 12-month period and caused damage to the plant. The insect was imported into Australia, where a procedure for rearing it in the laboratory was developed. Host-range tests indicated that adults oviposited and larvae commenced development in L. camara and L. montevidensis but not in any of 57 other species tested. A CLIMEX model indicated that most areas infested with lantana in Australia would have a favorable climate for A. championi. Permission to release this insect in Australia was obtained and three small releases were made in southern Queensland in February 1995.     

Influence of release size on establishment and impact of a root weevil for the biocontrol of houndstongue (Cynoglossum officinale)

The root-boring weevil, Mogulones cruciger, was introduced into Canada to control the weed, houndstongue (Cynoglossum officinale). To optimise its use as a biocontrol agent, a 2-year study was performed in British Columbia, Canada to test if the number of M. cruciger released at sites predicted subsequent declines in weed populations. No, 100, 200, 300 or 400 weevils were released in 1999 at field sites (five replicates) corresponding to discrete populations of houndstongue separated by distances of 0.3–3 km. The sites were subsequently monitored for weevil establishment, population change, and host attack, and houndstongue population change. By 2001, M. cruciger had established at all 20 release sites and was present in low numbers in three of five control sites. The year following release, release size was positively correlated with number of adult weevils collected, their damage to host plants, and with subsequent numbers of larvae per plant. In contrast, houndstongue populations were reduced at the same rate and amount, regardless of the experimental release size, within 2 years of release. Significant release treatment×time interactions indicated that factors other than M. cruciger contributed to houndstongue reductions (e.g. drought). However, overall the addition of weevils accelerated the reductions relative to sites with no weevils added. Our study demonstrated that the lowest number within a range of release sizes typically used in weed biocontrol programmes (i.e. 100) was as effective as 200–400 weevils in achieving a consistent amount and rate of houndstongue reduction, and thus, could be implemented to optimise weevil use and achieve predictable biocontrol.     

Suitability of Agonopterix ulicetella (Lepidoptera: Oecophoridae) as a Control for Ulex europaeus (Fabaceae: Genisteae) in New Zealand

The larvae of Agonopterix ulicetella (Stainton) (Lepidoptera: Oecophoridae) feed on the green foliage of gorse, Ulex europaeus L., and this insect is a potential biological control agent of this weed in New Zealand. The biology of the insect is described and its known parasitoids are listed. In experiments to measure oviposition preference, 46 plant species from 11 families were exposed to adult moths. Gorse was highly preferred over other plants, and there was no oviposition on 33 species tested. Eggs were found on Spartium junceum, Chamaecytisus palmensis, Lupinus arboreus, L. polyphyllus, Genista tinctoria and occasionally on eight other species. In experiments to measure the ability of first instar larvae to feed on 70 test plant species, 59 did not support development beyond the first instar and only seven species supported development to the pupal stage. These results show that under laboratory conditions this moth can lay its eggs and complete development on five members of the tribe Genisteae other than gorse. A. ulicetella was released in New Zealand in 1990 but has not yet established.     

Rapid preliminary characterisation of host specificity of leaf-beetles (Coleoptera: Chrysomelidae)

Rapid characterisation of host specificity is important both in biological control of weeds and studies in ecology and evolution. A means for doing this was developed and tested on four species of leaf beetles of interest for biological control of the weed Mimosa pigra (Mimosaceae). We identified the most promising for the more detailed tests necessary to obtain release approval. The impact of time-dependent effects and effects of experience were also investigated as part of this study but were not detected. Short-term host specificity tests on adult feeding accurately predicted the results of longer term trials. The long-term trial showed that survival on a plant species depended on feeding on it. Hence short-term feeding trials can predict the longer term survival of adults on other plant species. Different feeding results were obtained in cut foliage versus entire plants but no consistent pattern was shown: of the two insect species tested, one species ate more of the cut material while the opposite was demonstrated for the second species. Species in order of priority for further consideration as biocontrol agents were Syphrea bibiana, Genaphthona sp., Syphrea sp. and Paria sp. The latter three species were probably not sufficiently specific for release. The tests done here allow the identification of the most likely species upon which to conduct the more laborious and difficult larval developmental tests, saving considerable resources.     

Status of Charidotis pygmaea (Coleoptera: Chrysomelidae) as a Biological Control Agent of Lantana montevidensis (Verbenaceae) in Australia

The establishment of the leaf-feeding beetle Charidotis pygmaea Klug and its potential to control Lantana montevidensis (Sprengel) Briquet, a serious pasture weed of central and southern Queensland, Australia, were assessed. C. pygmaea was collected in Brazil from Lantana fucata Lindley, a plant morphologically similar to L. montevidensis. Over 40,000 beetles were released over 3 years by use of caged and uncaged techniques at 25 sites throughout southeast and central Queensland. At 6 of the sites where detailed and frequent monitoring occurred, no adults were found 6 months after the release. At another 2 sites, adults were present for only 12 months. Only a small number of eggs were laid at any single site and few larvae completed development to the adult stage. No signs of insect activity were found at any site after 24 months. Comparative laboratory and experimental field plot trials with both the weedy (field host) and the ornamental (glasshouse host) forms of L. montevidensis did not show significant differences in insect performance. Assessment of nitrogen, phosphorous, potassium, and water contents, leaf hairiness, and leaf toughness of both the weedy and the ornamental forms of L. montevidensis grown under glasshouse and field plot conditions did not show differences between the two plant forms. There were, however, differences in the percentage of adults that developed in the glasshouse trials compared to the field plot trials (55% vs 5%). Field observations in Brazil showed that C. pygmaea was found only on L. fucata and L. tiliifolia Chamisso and was not seen on L. montevidensis growing in the same region. Climate matching with CLIMEX showed that most areas in Australia where L. montevidensis is a major problem are not climatically similar to the collection sites of C. pygmaea in Brazil. Whereas populations of C. pygmaea can be maintained on L. montevidensis under glasshouse conditions, it performs poorly on that species under field conditions. Unsuitable climatic conditions and an incompatible target plant are the most likely factors affecting the poor performance of C. pygmaea. Consequently, field releases of the agent in Australia have ceased and C. pygmaea is not recommended as a biological control agent for L. montevidensis in Australia.     

Development and survival of immature Culex annulirostris mosquitoes in southeast Queensland

Abstract. The rates of development and survival of the immature stages of Culex annulirostris were studied in three different breeding sites in the Brisbane area of southeast Queensland: a temporary rain-filled pool (TP), a semi-permanent pool (SPP), and an area of flooded grassland (FG) arising from the overflow of a permanent pond. Parallel observations were made on larvae and pupae either exposed to predation or in predator-free cages for 12 and 15 consecutive days respectively. Development was fastest and survival highest in the warmer TP. Average daily mortality of larvae (L) and pupae (P) was TP: L 8.3%, P 9.5%; SPP: L 25.2%, P 34.6%; FG: L 18.8%, P 35.4%. From life-tables and survivorship curves, survival from first instar to adult was TP 34.8%, SPP 2.0% and FG 4.2%. Mortality from predation was TP 43.2%, SPP 68.7% and FG 69.1 %. Predator density was TP 0.32, SPP 1.48 and FG 1.76 per 300ml sample.     

喙尾琵甲（鞘翅目：拟步甲科）形态记述及生物学特性观察

记述了喙尾琵甲Blaps rhynchopetera Fairmaire各虫态特征,观察了其生物学特性.实验种群1月下旬至12月上旬产卵,卵期为8～15 d;幼虫期141～213 d,共9～13龄,第9龄以后,龄期较长;蛹前期8～14 d;蛹期12～24 d.成虫羽化24～92 d后性成熟,开始交配产卵活动,成虫期超过18个月.自然种群在昆明和曲靖1年发生1～1.5代,世代重叠严重;以不同龄期幼虫和成虫越冬,越冬幼虫于次年4月上旬开始化蛹,新羽化成虫于4月下旬至12月上旬交配产卵,成虫全年都能活动、产卵.该虫为夜出型、暂栖性土壤昆虫,喜潮湿阴暗的环境.成虫具有夜出习性、防御性和群聚性.     

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.     

Yeast hydrolysate supplement increases starvation vulnerability of Queensland fruit fly

Post‐teneral diets containing yeast hydrolysate are reported to increase longevity, reproductive development and sexual performance of Queensland fruit fly (‘Q‐fly’) Bactrocera tryoni Froggatt (Diptera: Tephritidae). Consequently, diets including yeast hydrolysate are recommended for sterile Q‐flies before release in sterile insect technique (SIT) programmes. However, in some tephritids, diets including yeast hydrolysate are associated with an increased vulnerability to starvation. In the present study, the effects of yeast hydrolysate supplementation before release are considered with respect to the longevity of released Q‐fly when food becomes scarce. Experiments are carried out in three settings of varying resemblance to field conditions: 5‐L laboratory cages, 107‐L outdoor cages and 14 140‐L field cages containing potted citrus trees. In all experimental settings, compared with flies that received only sucrose, male and female Q‐flies that are provided with yeast hydrolysate during the first 2 days of adult life have a significantly shorter survival when subsequently deprived of food. Yeast supplementation appears to commit Q‐flies to a developmental trajectory that renders them more vulnerable to starvation. The practical significance of these findings for SIT depends on how often the releases are carried out under conditions in which Q‐flies experience extreme food shortages in the field.     

The dietary relationships of Tribolium castaneum (Herbst) with microfungi

The ecology of Tribolium castaneum (Herbst) outside of grain storage facilities is poorly known. However, high densities of T. castaneum adults are known to infest stored cotton seeds (Gossypium hirsutum (L.)) in Queensland, Australia, despite the absence of stored food products in the immediate vicinity. Previous studies suggest that the beetles are attracted to the fungal colonies growing on the residual fibres that remain on the cotton seeds after ginning, but the specifics of this remain unclear, even as to the species of fungi involved. In the current study, 14 fungal species were isolated from stored cotton seeds collected from four sites in Queensland. The feeding preferences of the adult beetles and the developmental success of the larvae were recorded for each fungal species. Gut analyses of T. castaneum adults, after exposure in no-choice feeding tests, showed that the beetles will feed on any one of the 14 fungal species when exposed (over 14 days) to cotton seeds that had been inoculated with one particular fungal species. The developmental success of the larvae varied depending on the fungal species, with most fungal species supporting only low levels of successful development (<30%). Tests with each fungal species and the volatiles they release revealed that neither adult nor larval survival was significantly affected by the presence of any particular fungal isolate. These results indicate that T. castaneum will feed on a variety of fungal species but that none of the tested fungal species on its own provides a good larval diet for T. castaneum.