Life histories and host specificities of theEchium flea beetlesLongitarsus echii andL. Aeneus [Col. Chrysomelidae]

Two halticine flea beetles,Longitarsus echii Koch andLongitarsus aeneus Kutsch, occurring on the boraginaceous plantEchium plantagineum L. in the western Mediterranean region are potential biological control agents in Australia where the plant has become a weed (Paterson's curse). The adults of both species feed by making “shot holes” in the leaves. The larvae of both species attack the roots ofEchium, those ofL. echii feeding more centrally in the root than those ofL. aeneus which attack the outer cortex and rootlets. Both species are univoltine. The host restrictions of both flea beetles as adults and as larvae were tested using the criteria already established for theEchium leaf minerDialectica scalariella Zeller (Wapshere & Kirk, 1977). This testing established that it would be safe to introduce the 2 insects into Australia for the biological control ofE. plantagineum and they are now under quarantine.     

Host specificity and biology ofMegacyllene mellyi [Col.: Cerambycidae] introduced into australia for the biological control ofBaccharis halimifolia [Compositae]

Biology and host plant specificity of the stem boring cerambycidMegacyllene mellyi (Chevrolat) were studied in Brazil to determine its suitability for introduction into Australia for control of the shrubBaccharis halimifolia L. Multiple choice host preference testing of plants related toBaccharis, of desirable plants from a range of plant families, and of the host plants of otherMegacyllene species, showed thatM. mellyi was restricted toBaccharis spp. It was introduced into Australia in 1975 and released in 1978. Recoveries were made 3 years after release and some stems were killed, although damage was slight relative to the number ofB. halimifolia plants in the release area.     

Life histories and host specificities of theEchium bugsDictyla echii andDictyla nassata [Hem.: Tingidae]

Two tingidsDictyla echii Schrank andD. nassata Puton are common in the mediterranean region on variousBoraginaceae and are found frequently onEchium plantagineum L. These insects can reduce or even prevent seed formation due to depigmentation and destruction of leaf and mesophyll cells. Both tingids pass through at least 2 or 3 generations per year. The range of plants exposed during specificity tests was selected on criteria established byWapshere & Kirk (1977) and included notably:

-Boraginaceae and plants closely related to them;

- plants representative of the same families on which the same or otherDictyla spp had been recorded. Since onlyBoraginaceae were attacked, this confirmed the specificity of the 2Dictyla spp. to that plant family.

The coexistence in Portugal of both species in the same sites, althoughD. nassata requires a warmer climate thanS. echii, suggests that there is only a small amount of direct interspecific competition. For the above reasons it appears that the 2Dictyla spp. are suitable agents for the biological control ofE. plantagineum in Australia.     

Biological control ofCuscuta spp. III. Phenology,biology and host-specificity ofHerpystis cuscutae Bradley [Lep., Tortricidae]

Life history and status ofHerpystis cuscutae as biological control agent have been investigated. Of the tenCuscuta spp. in Pakistan it infested onlyC. reflexa on six host plants of whichAdhatoda vasica andDodonaea viscosa were the most preferred. Variations in its period of activity in different areas were attributed to the differences in the fruiting periods of its host. It was found to have a tolerance for extremes of climates, was multivoltine, could complete development on some convolvules, legumes and umbellifers among the plants of 28 families tested and was apparently free from natural enemies.     

Host Range ofBrachycaudus rumexicolens(Patch), an Aphid Associated with the Polygonaceae

The aphidBrachycaudus rumexicolensis a recent arrival in Australia where the weedsEmex australis, E. spinosa,andRumexspecies are its recorded hosts. Host range on 114 species representing 42 plant families was assessed in the laboratory to determine the aphid species' potential as a biological control agent againstE. australis.Survival and reproductive success were measured in clip and/or dialysis-tube cages.B. rumexicolensdeveloped most successfully onEmexspp. andRumexspp. and to a lesser extent on other Polygonaceae.Lupinus albus(white lupin) andTriticum aestivum(wheat) were the only non-Polygonaceae plants on whichB. rumexicolensdeveloped to a degree similar to its usual hosts. At a field site in Western Australia,E. australisandPolygonum avicularewere the only Polygonaceae present and the primary host species ofB. rumexicolens.At peak abundance, it was found on other pasture and crop species, but at considerably lower numbers than on its Polygonaceae hosts. It was concluded that this was due to local migration and that populations would not be sustained on non-Polygonaceae plants. It was also concluded that the risk of virus transmission would not be increased by the presence ofB. rumexicolenson nonhosts.B. rumexicolensis considered sufficiently safe to use in programs aimed at augmenting the impact of biological control agents on the weedE. australis.     

The suitability ofTeleonemia harleyi for biological control ofLantana camara in Australia

The tingidTeleonemia harleyi Froeschner from Trinidad is known to destroy the flowers ofLantana camara L. and so prevent seed formation. Colonies caged on plants destroy all flowers. Studies on the host range ofT. harleyi indicate that it is highly specific, feeding and ovipositing only onL. camara. It attacks all pest taxa ofL. camara naturalized in Australia and should be a valuable addition to the biological control complex. It was approved for liberation in Australia in September 1972.     

The taxonomic status of Larinus cynarae F. and Larinus latus Herbst (coleoptera: Curculionidae), and its implications for the biological control of Onopordum (asteraceae: Cardueae) in Australia

Analyses were made of the allozyme frequencies of sympatric populations of the capitulum weevils L. latus Herbst and Larinus cyarae F. in Greece. It was found that the two taxa are genetically isolated and that they can therefore be considered as separate species. This complemented ecological data showing separation of the L. latus and L. cynarae populations by their choice of Onopordum illyricum L. and Cynara cardunculus, respectively, as hosts. Onopordum spp. are serious weed problems in Australia while Cynara contains several crop plants. L. latus is a potential biological control agent of Onopordum spp., but its use had been compromised by the uncertainty of the taxonomic distinctness from L. cynarae, biotypes of which are pests of artichoke Cynara scolymus L. Clarification of its taxonomic status lifts these reservations and clears the way for the introduction of L. latus into Australia for the biological control of Onopordum thistles.     

Dryinid (Hym.: Dryinidae) parasitoids ofDalbulus leafhopper (Hom.: Cicadellidae) in Mexico

Little is known about the natural enemies of the leafhopperDalbulus spp. (Homoptera: Cicadellidae). Searches for its dryinid (wasps) parasitoids were made in Jalisco, Mexico. Jalisco contains the greatest number ofDalbulus species, and is considered to be near to the center of origin of this leafhopper genus and its host plants: maize, teosintes (Zea spp.) and gamagrasses (Tripsacum spp.). The dryinidGonatopus bartletti was found parasitizingD. maidis on maize and on annual teosinteZea mays spp.parviglumis. G. flavipes was found parasitizingD. elimatus on perennial teosinteZ. perennis; and a new speciesG. moyaraygozai andAnteon ciudadi parasitizingD. quinquenotatus onTripsacum pilosum andT. dactyloides. Parasitism by dryinids was found at altitudes of 680–2,000 m.Dalbulus maidis, the leafhopper species which causes the greatest losses in maize in Latin America, was found to be parasitized from 680–1,760 m. TheDalbulus species associated with annual host plants (maize andZ. mays spp.parviglumis) were parasitized by dryinids during the rainy season, while theDalbulus species associated with perennial host plants (Z. perennis andTripsacum) were parasitized by dryinids during both the rainy and dry season. The greatest diversity of dryinid parasitoids ofDalbulus spp. and the highest levels of parasitism were recorded from perennial plants, indicating that such species are reservoirs of natural enemies ofDalbulus spp.     

Host specificity of phytophagous organisms and the evolutionary centres of plant genera or sub-genera

Chondrilla juncea is an important weed in Australia. The morphology, ecology and chromosome number of species of the genusChondrilla indicate that the generic centre of evolution is in southern. Bussia and that dispersal has occurred westwards, as far as western Europe, with a reduction in the number ofChondrilla species. The number of organisms specific toChondrilla also increases as one approaches the generic centre of evolution. Therefore, to discover the greatest number of specific, biological control organisms for a weed, surveys should commence initially at its generic evolutionary centre. The application of this principle to genera of other important Australian weeds, namely toEchium which has two evolutionary centres and toHeliotropium which has a number of sub-generic evolutionary centres is discussed.     

An arthropod deterrent attracts specialised bees to their host plants

Many bee species are adapted to just a few specific plants in order to collect pollen (oligolecty). To reproduce successfully, it is important for oligolectic bees to find and recognise the specific host flowers. In this study, we investigated the role of floral volatiles used by an oligolectic bee to recognise its host plants. We compared the attractiveness of natural and synthetic scent samples of host flowers to foraging-naïve and -experienced Hoplitis adunca (Megachilidae) bees that are specialised on Echium and Pontechium (Boraginaceae) plants. The investigations showed that naïve H. adunca females are attracted to 1,4-benzoquinone. During their lifetime, bees learn additional floral cues while foraging on host flowers. In contrast to naïve ones, experienced H. adunca females use, in addition to 1,4-benzoquinone, other compounds to recognise their host plants. 1,4-Benzoquinone is an uncommon floral compound only known from the host plants of H. adunca, and is therefore ideally suited to be used as a plant-specific recognition cue. Several arthropods use this compound to deter insect predators. Therefore, 1,4-benzoquinone as an attractant in Echium flowers may have evolved from a primary function as a defensive compound against insect herbivores.     

Lixus cribricollis [Col.: Curculionidae] for biological control of the weedsEmex spp. andRumex crispus in Australia

The biology and host specificity of a colony ofLixus cribricollis Boheman originating in Morocco were studied in quarantine in Australia.L. cribricollis adults are long lived, have an aestivation and are univoltine.Rumex crispus L.,Emex australis Steinheil andE. spinosa (L.)Campdera were shown to be the only satisfactory hosts of 40 species of plants from 17 families that were exposed to sexually mature adults ofL. cribricollis. Normal feeding and occasional oviposition were observed on some other plants within the same family,Polygonaceae, including the minor crops rhubarb and buckwheat, but almost invariably larvae died in the 1st instar. It was concluded thatL. cribricollis may be a useful biological control agent for the weedsR. crispus, E. australis andE. spinosa and that establishment of this weevil in Australia would be without risk to non-target plants.     

Tingidae for biological control ofLantana camara [Verbenaceae]

The host range, distribution and aspects of the biology ofTingidae recorded from plants in the genusLantana are reviewed. Tingids possess attributes predisposing them for use as biological control agents. Possible benefits from importation of a larger gene pool ofTeleonemia scrupulosa are discussed. The host ranges ofT. elata andLeptobyrsa decora were studied under simulated field conditions. Results indicated that both species are restricted almost entirely toL. camara. SubsequentlyT. scrupolosa, collected from diverse habitats throughout its range,T. elata andL. decora have been liberated in Australia.     

Echium and Pontechium specific floral cues for host–plant recognition by the oligolectic bee Hoplitis adunca

Flowering plants often have specific floral cues, which allow bees and other pollinators to differentiate between them. Many bee species exhibit specialised associations with flowers (oligolecty) and it is important for them to find and recognise their specific host plants. In this study we compared the visual and olfactory floral cues of different Echium and Pontechium (Boraginaceae) species with the closely related Anchusa officinalis (Boraginaceae). We tested whether plant-specific cues occur in Echium and Pontechium which may allow oligolectic Hoplitis adunca (Megachilidae) to recognise its host plants and to distinguish them from Anchusa non-hosts. Our investigations showed that Echium/Pontechium provides a specific scent bouquet. Furthermore, we identified compounds which were not described as floral scent before ((Z)-3-nonenal and 1,4-benzoquinone). These unique volatiles and the specific bouquet could act as a recognition cue for H. adunca. The corolla colours differed between all species, but were grouped together in the bee colour categories blue and UV-blue and can indicate potential host flowers for H. adunca.     

Malacorhinus irregularis for biological control of Mimosa pigra: host-specificity,life cycle,and establishment in Australia

Malacorhinus irregularis Jacoby (Coleoptera: Chrysomelidae: Galerucinae: Galerucini), from Mexico is identified as a potential biological control agent for Mimosa pigra L. (Mimosaceae), a serious weed of northern Australia and Asia. The adults feed on leaves of the host, and the larvae develop on seedlings, roots, and perhaps other plant parts. The damage to the target plant is substantial, indicating that this insect could be an effective control agent. Host-specificity tests examined the suitability of seedlings and leaves for larval development, and suitability of leaves for adult feeding. In no-choice tests, no larval development occurred on any of the 81 test plant species other than M. pigra. The extent of adult feeding on the test plants was negligible in the tests using a choice-minus-control design, being less than 1% of that which occurred on M. pigra. We conclude that M. irregularis is a specialist on its host and the risk associated with its release in Australia is low. It was released in infestations of M. pigra in the Northern Territory of Australia in 2000. Establishment and abundance was monitored at one site where the number and distribution of adult beetles fluctuated widely as soil moisture conditions varied through the seasons. Adults were found for two years after release and local defoliation of plants was attributed to this species. Although only limited observations were made, adult feeding was not recorded from Neptunia major (Benth). Windler plants growing in close proximity to M. pigra, indicating specificity under field conditions.     

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.     

Host-specificity and biology ofMetallactus patagonicus [Col.: Chrysomelidae] introduced into Australia for the biological control ofBaccharis halimifolia [Compositae]

Biology and host-specificity of the foliage-feeding chrysomelidMetallactus patagonicus Suffrian were studied in Brazil to determine its suitability for introduction into Australia to control the shrubBaccharis halimifolia L. Multiple-choice host preference testing of plants related toBaccharis and of desirable plants from a range of plant families, showed thatM. patagonicus was restricted toBaccharis spp. It was released in Australia in 1975, but did not establish.      

Host specificity testing ofRhodometra sacraria [Lep.: Geometridae], a possible biological control candidate forEmex australis in Australia

The foliage feeding geometridRhodometra sacraria L. was collected onEmex australis Steinheil in South Africa, cultured, then tested as a possible biological control agent forE. australis, in Australia. Tests on its host specificity were carried out in South Africa and Australia.R. sacraria was specific to plants of the familyPolygonaceae rather than toE. australis. Request for the reintroduction and release ofR. sacraria into Australia has not been made.      

Samea multiplicalis [Lep.: Pyralidae], for biological control of two water weeds,Salvinia molesta andPistia stratiotes in Australia

The biology and host specificity ofSamea multiplicalis (Guenée) were studied in quarantine in Australia. Immature stages completed development onSalvinia molesta Mitchell,Pistia stratiotes L. andAzolla pinnata R.Br. In starvation tests, although larvae which had first fed onS. molesta produced minor leaf scarring on some other plants, they were unable to complete development. Damage toS. molesta andP. stratiotes indicated thatS. multiplicalis may be a valuable biological control agent for these weeds in Australia.S. multiplicalis was first liberated in northern Queensland in 1981 where it has become established onS. molesta.     

ACactoblastis [Lep.: Phycitidae] for the biological control ofEriocereus martinii [Cactaceae] in Australia

ACactoblastis sp. was found on Harrisia cactus (Eriocereus martinii Lab.) in north-eastern Argentina. In biology and life history it is similar toCactoblastis cactorum (Berg.) though attacking different cacti. Laboratory tests and field observations demonstrate that it will only damage plants in the sub-tribeCereanae of theCactaceae. It was approved for liberation in Queensland, Australia in August 1975 for the control ofEriocereus spp., and field releases were made in October 1978.     

Host specificity and biology ofLioplacis elliptica [Col.: Chrysomelidae] introduced into Australia for the biological control ofBaccharis halimifolia [Compositae]

The nocturnal foliage feeding ChrysomelidLioplacis elliptica Stal occurs onBaccharis gaudichaudiana DC. in Brazil. Studies of its biology and host plant specificity showed it was restricted tobaccharis spp. It was introduced into Australia for the control ofB. halimifolia L. in 1976 and first released in 1977. Field colonies persisted for up to 3 years after which no further evidence of survival was found.