Biological Control of St. John's Wort: Past, Present and Future

Biological Control of St. John's Wort: Past, Present and Future

Plant Protection Quarterly Vol.12(2) 1997 73 decision to shift survey operations to France, where the climatic conditions were Biological control of St. John’s wort: past, present considered closer to those of temperate and future Australia, and the chance of finding suit- able insects thus higher (Wilson 1943). The English work, however, did produce late D.T. Briese, CSIRO Entomology and Co-operative Research Centre for Weed fruits, for in 1939 C. hyperici reappeared in Management Systems, GPO Box 1700, Canberra, ACT 2601, Australia. large numbers at the original release site in Bright and began to spread into new areas (Wilson and Campbell 1943). Biologi- Summary has proven to be effective under certain cal control of St. John’s wort in Australia Work on the biological control of St. conditions, but has not stopped the contin- had commenced. John’s wort (Hypericum perforatum L.) in ued spread of the weed (Campbell et al. Australia first commenced almost sev- 1995). The other, the eriophyid mite Phase 2: 1935–1942 enty years ago, and has passed through a Aculus hyperici, was only released in 1990 The shift to southern France in 1935 saw number of discrete phases, leading up to and, while it has yet to realise its full poten- studies concentrate on five potential con- the current program of work. A total of tial, has been attributed with causing con- trol agents (Wilson 1943) (see Table 1), and 15 agents have been studied in some de- siderable reduction in plant vigour at a continued until the onset of World War II tail with a view to introduction, and 12 of number of St. John’s wort infestations forced the field station to close in 1940. these were eventually released. Six (Jupp and Cullen 1996). Wilson (1943) considered the buprestid agents became established, four during This paper looks at the history of intro- root-borer, Agrilus hyperici and the earlier phases of work in the 1930s to ductions and factors that have led to the chrysomelid defoliator, Chrysolina quad- 1950s and two in the current phase of success or failure of particular agents. The rigemina, to be the two dominant insects work from the mid 1970s on. Two of the current prospects for control are consid- on St. John’s wort stands in southern original agents to establish, the defoliat- ered and the desirability of further intro- France, with the root-borer exerting the ing chrysomelid beetles Chrysolina ductions for biological control of St. John’s greatest impact, and being associated with quadrigemina and C. hyperici, provide wort discussed in the light of available in- large declines in the density of local some degree of control in certain situa- formation on the remaining candidate patches of the weed. Both these insects tions, but are unable to prevent the con- agents. were established relatively easily in 1939– tinued spread of the weed. There is, how- 40 at sites near Bright, Victoria, and ever, some early evidence that the re- History of biological control of St. Mudgee, NSW, and colonies showed early cently released eriophyid mite, Aculus John’s wort in Australia increase and dispersal (Wilson and hyperici, can cause substantial reduction Campbell 1943). Ag. hyperici populations in the vigour of St. John’s wort Phase 1: 1928–1939 built up steadily at the two release sites populations and might therefore im- Although first mooted in 1917, it was not and within two years individual plants prove the overall level of biological con- until 1928 that research actually com- were being killed and the growth of oth- trol. This paper looks at the history of in- menced on the biological control of St. ers restricted by heavy attack (Wilson and troductions of agents into Australia in the John’s wort, with the setting up of a labo- Campbell 1943). Large populations of C. context of changing strategies for bio- ratory in Buckinghamshire, England quadrigemina were also recovered in the logical control of the target weed, and (Currie and Garthside 1932). Eight insects, field in 1942, causing substantial defolia- looks at the potential for further intro- all but one of which were leaf-feeders, tion at the release site as well as dispersing ductions of new agents. Whether further were studied in some detail and eventu- to other areas (Wilson and Campbell work is required, however, depends on ally sent to Australia (Table 1). Three of 1943). The potential of these two beetles, the eventual impact of A. hyperici, and these were not released, however; the along with C. hyperici, was quickly appre- the need for careful evaluation of this two leaf-webbing insects, Lathronympha ciated in the light of the extensive damage agent is stressed. hypericana and Depressaria hypericella, were to roots and local defoliation of infesta- considered unlikely to be effective due to tions of target weed. The other three Introduction the nature of their damage to the target agents imported into Australia were not The biological control project against St. weed, while the English population of the released as they were considered to be not John’s wort, together with those against aphid, Aphis chloris, was sexually-repro- capable of the same levels of damage, and prickly pear and lantana, heralded the ducing and overwintered as an egg work entered a third phase, which was to start of weed biological control in Aus- (Wilson 1938). Cold-requirements for sub- concentrate on the evaluation and large- tralia. Despite this, after almost seventy sequent emergence of nymphs were not scale redistribution of the two chryso- years, the introduction of natural enemies met in Australia, thus preventing its re- melid beetles and the root-borer. The has not yet managed to reduce St. John’s lease. The five defoliating species were re- prospects for successful biological control wort infestations to levels that do not leased in Victoria between 1930 and 1937 looked promising indeed, with Ag. cause unacceptable economic or environ- but with little initial success (Currie and hyperici expected to be the predominant mental damage. Since surveys for poten- Fyfe 1938). By 1938, it was considered that agent (Wilson and Campbell 1943). tial control agents of St. John’s wort first introductions of the two geometrid commenced in 1928, there have been four moths, Anaitis efformata and A. plagiata, and Phase 3: 1940–1956 distinct phases of work leading to the es- the three chrysomelid beetles, Chrysolina Redistribution of C. hyperici commenced tablishment of six agents in Australia brunsvicensis, C. hyperici and C. varians, on a broad scale in 1940, and of C. (Campbell et al. 1995). Only two of these had failed. Heavy predation on newly re- quadrigemina in 1943. Agencies such as currently appear to have the potential to leased insect colonies by indigenous natu- CSIRO and the Victorian Department of contribute to the overall control of the ral enemies was considered to be the main Lands and Survey distributed over 10 mil- weed. One species, a defoliating beetle cause of this failure, though unfavourable lion chrysomelid beetles in Victoria (1940– Chrysolina quadrigemina, which established physical conditions were thought to have 51), New South Wales (1941–56), Tasma- in the early 1940s and was widely redis- played a role in the case of the chryso- nia (1943), South Australia (1943–49) and tributed throughout the next two decades, melids (Currie and Fyfe 1938). This led to a Western Australia (1947–53) (Wilson 1960), 74 Plant Protection Quarterly Vol.12(2) 1997 Table 1. Natural enemies of Hypericum perforatum in Australia. Species Mode of action Origin Year released Relative occurrenceA Ref.B Phase 1 Col: Chrysomelidae Chrysolina varians (Schall.) leaf defoliator England 1930–33 did not establish a C. brunsvicensis (Grav.) leaf defoliator England 1930–34 did not establish a C. hyperici (Forster) leaf defoliator England 1930–34 occasional** b Lep: Geometridae Anaitis efformata L. leaf defoliator England 1936–38 did not establish b A. plagiata Guenée leaf defoliator England 1936–38 did not establish b Lep: Eucosmidae Lathronympha hypericana Hubn. leaf webber England not released a Lep: Oecophoridae Depressaria hypericella Hubn. leaf webber England not released a Aphididae Aphis chloris Koch sap sucker England not released a Phase 2 Col: Chrysomelidae Chrysolina quadrigemina (Suffr.) leaf defoliator France 1939 common** c,d Buprestidae Agrilus hyperici (Creutzer) root-borer France 1939–40 rare* c,d Lep: Noctuidae Actinotia hyperici Schiff. leaf defoliator France not released c Dip: Cecidomyiidae Zeuxidiplosus giardi Kieff. leaf-bud galler France not released c Lep: Gelechiidae Aristotelia morphocroma Wals. stem and seed France not released c capsule borer Phase 3 Dip: Cecidomyiidae Zeuxidiplosus giardi Kieff. leaf-bud galler California 1953-54 common* e (ex France) Phase 4 Col: Chrysomelidae Chrysolina hyperici (Forster) leaf defoliator France 1980 uncertain f,g C. quadrigemina (Suffrian) leaf defoliator France 1981 uncertain f,g Lep: Geometridae Anaitis efformata L. leaf defoliator France 1981–83 did not establish h Lep: Noctuidae Actinotia hyperici Schiff. leaf defoliator France 1985–86 did not establish g Buprestidae Agrilus hyperici (Creutzer) root-borer France 1984, 1989 uncertain g Aphididae Aphis chloris Koch sap sucker France 1986–87 common* i Acarina: Eriophyidae Aculus hyperici (Liro) sap sucker France 1990 common* j Lep: Gelechiidae Aristotelia morphocroma Wals. stem and seed France not released capsule borer A *= has caused localised damage, ** = has caused heavy damage at a number of sites. B Sources: a = Currie and Garthside (1932), b = Currie and Fyfe (1938), c = Wilson (1943), d = Wilson and Campbell (1943), e = Wilson (1960), f = Delfosse and Cullen (1981), g = Wapshere (1984), h = Briese (1986), i = Briese and Jupp (1995), j = Jupp and Cullen (1996). with distributions peaking in the late 1940s responsible for one of the classical biologi- Despite the initial steady increase and and early 1950s (Figure 1).

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