Chapter 24 Brazilian Peppertree - Biological Control of Invasive Plants in the Eastern United States

J.P. Cuda - Department of Entomology and Nematology, University of Florida, Gainesville, Florida, USA,
J. C. Medal - Department of Entomology and Nematology, University of Florida, Gainesville, Florida, USA.

In: Van Driesche, R., et al., 2002, Biological Control of Invasive Plants in the Eastern United States, USDA Forest Service Publication FHTET-2002-04, 413 p.

both male and female trees are white and the female plant is a prolific producer of bright red fruits (Fig. 1). Although the plant is still grown as an ornamental in California, Texas, and Arizona, S. terebinthifolius is classified as a state noxious weed in Florida and Hawaii (Ferriter, 1997; Habeck et al., 1994; Morton, 1978).

Economic damage. As a member of the Anacardiaceae, S. terebinthifolius has allergen-causing properties, as do other members of the family. While not affecting as many people as poison ivy (Toxicodendron radicans [L.] Kuntze), poison oak (T. toxicarium [Salisb.] Gillis), or poison sumac (T. vernix [L.] Kuntze), all of which are in the Anacardiaceae, the sap of Brazilian peppertree can cause dermatitis and edema in sensitive people (Morton, 1978). Resin in the bark, leaves, and fruits is sometimes toxic to humans, mammals, and birds (Ferriter, 1997; Morton 1978). Even the odors of the flowers of S. terebinthifolius can induce allergic reactions (Morton, 1978). Abundant growth of this poisonous plant may damage the multi-billion dollar tourist industry in Florida. The value of wildlife-related recreational activities in Florida has been estimated at $5.5 billion (UF-IFAS, 1999). Visitors sensitive to S. terebinthifolius who would otherwise come to Florida for such activities may decide to vacation elsewhere rather than risk exposure to this toxic weed. Wood of Brazilian peppertree is of little value due to its low quality, multiple, low-growing stems, and poisonous resin (Morton, 1978).

is already widespread and has great potential to increase its range even further (Randall, 1993). The U.S. Fish and Wildlife Service (1998) identified S. terebinthifolius as one of the most significant non-indigenous species currently threatening federally-listed threatened and endangered native plants throughout the Hawaiian islands. In Florida S. terebinthifolius is considered one of the worst invasive species by the Florida Exotic Pest Plant Council, and is recognized as the most widespread exotic plant in the state; infesting nearly 300,000 ha and found in all the terrestrial ecosystems of central and southern Florida (Habeck, 1995; Ferriter, 1997).

In southern and central Florida, S. terebinthifolius colonizes disturbed sites such as highways, canals, powerline rights-of-ways, fallow fields, and drained wetlands. It also is able to establish in many undisturbed natural environments (Woodall, 1982), including pine flatwoods, tropical hardwood hammocks, and mangrove forests (Loope and Dunevitz, 1981; Ewel et al., 1982; Woodall, 1982). The invasion of this aggressive, woody plant poses a serious threat to biodiversity in many of Florida’s native ecosystems, and is eliminating many indigenous food sources for wildlife (Morton, 1978). Attributes of the plant that contribute to its invasiveness include a large number of fruits produced per female plant, an effective mechanism of dispersal by birds (Panetta and McKee, 1997), and tolerance to shade (Ewel, 1978), fire (Doren et al., 1991), and drought (Nilsen and Muller, 1980).

Extent of losses. Direct losses have not been quantified due to lack of long-term monitoring programs and data collection and analysis.

Schinus terebinthifolius is native to Argentina, Brazil, and Paraguay (Barkley, 1944, 1957). The plant was spread around the world as an ornamental, beginning in the mid to late 1800s (Barkley, 1944; Mack, 1991). Naturalization of S. terebinthifolius has occurred in more than 20 countries worldwide throughout subtropical areas (15 to 30°N or S latitudes) (Ewel et al., 1982). In the United States, the plant occurs in Hawaii, California, Arizona, Texas, and Florida (Habeck et al., 1994; Ferriter, 1997). In Hawaii, the plant is commonly called Christmasberry due to its attractive green foliage and red fruits present in December. The plant is sensitive to cold temperatures (Langeland, 1998). Its distribution in eastern North America is limited to central and southern Florida, although along the Florida coast, plants can be found as far north as Levy and St. Johns Counties (ca. 29°N).

The order Sapindales, one of the eighteen orders within the subclass Rosidae, contains fifteen families and about 5,400 species. More than half of the species belong to only two families, the Sapindaceae and Rutaceae, each with nearly 1,500 species. The Anacardiaceae is a small but well known family, consisting of 60 to 80 genera and about 600 species (Cronquist, 1981). The family is primarily pantropical, but some species occur in temperate regions. Species of Anacardiaceae, which may be trees, shrubs, or woody vines, are characterized by well developed resin ducts or latex channels throughout most plant parts. Leaves of these plants are typically alternate and either pinnately compound or trifoliolate. Flowers are usually unisexual, with parts in groups of five. Nectary disks are five-lobed and fruits are typically drupes (Cronquist, 1981). The genus Schinus has 28 species and its center of distribution is northern Argentina (Barkley, 1944, 1957). Schinus species are native to Argentina, southern Brazil, Uruguay, Paraguay, Chile, Bolivia, and Peru (Barkley, 1944, 1957). Barkley (1944) recognized five varieties of S. terebinthifolius. Differences between the varieties are based on leaf length, leaflet number and shape, and the form of leaflet margins (Barkley, 1944). Two varieties of S. terebinthifolius have been introduced into Florida, but the most abundant is S. terebinthifolius var. radianus (M. Vitorino, pers. comm.).

The main flowering period of S. terebinthifolius in Florida is September through October, with a much-reduced bloom from March to May. Small, white flowers occur in dense axillary panicles near the end of branches. The flowers are insect pollinated and successful fertilization leads to the production of prolific numbers of bright red fruits from November to February. A small fruit set occurs from June to August. Fruits are eaten and dispersed by birds and mammals. In fact, fruits have a near-obligate requirement for ingestion before seeds can germinate, as seeds within fruits that have not passed through the digestive tract have little chance of germinating before they loose viability (Panetta and McKee, 1997). Seeds remain viable in soil for six or nine months, in Florida and Australia, respectively (Ewel et al., 1982; Panetta and McKee, 1997). Removal of the seed from the fruit by ingestion and excretion or mechanical means promotes seed germination, and germination rates do not differ between bird-ingested seeds or mechanically cleaned seeds (Panetta and McKee, 1997). Water extracts of S. terebinthifolius fruits inhibit germination of S. terebinthifolius seed as well as other plant species, presumably due to the presence of phenolic acid compounds (Nilsen and Muller, 1980).

Leaves are present on S. terebinthifolius plants throughout the year. However, vegetative growth ceases in winter (October to December), corresponding to the flowering period. Growth and extension of the shoot tips occurs more or less continuously throughout the rest of the year (Tomlinson, 1980; Ewel et al., 1982).

Similar to many hardwood species, S. terebinthifolius is capable of resprouting from above-ground stems and crowns after damage from cutting, fire, or herbicide treatment. In addition, root sprouts form from trees with or without evidence of damage and can develop into new individuals. Resprouting and suckering is often profuse and the growth rates of the sprouts are high, leading to the formation of dense clumps (Ferriter, 1997; Woodall, 1979).

The order Sapindales includes fifteen families, of which ten (Staphyleaceae, Sapindaceae, Hippocastanaceae, Aceraceae, Burseraceae, Anacardiaceae, Simaroubaceae, Meliaceae, Rutaceae, and Zygophyllaceae) have native members in eastern North America. Nine of these ten families have native species within the range of S. terebinthifolius in Florida. The tenth family, Staphyleaceae, has a species that occurs in northern Florida. The Rutaceae includes important fruit crops grown in subtropical Florida (Citrus spp.). Four genera of Anacardiaceae are indigenous to eastern North America: Rhus, Toxicodendron, Metopium, and Cotinus (Brizicky, 1962; Gleason and Cronquist, 1963). Except for Cotinus, the above genera are each represented by several species in Florida that overlap in range with S. terebinthifolius (Ferriter, 1997). A number of additional species of Anacardiaceae have been introduced and are currently cultivated in Florida for their edible fruits or seeds, including Mangifera indica L. (mango), Pistacia spp. (pistachio), and Spondias spp. (purple mombin).

The center of distribution of the genus Schinus is northern Argentina, and its natural distribution is in South America (Argentina, southern Brazil, Uruguay, Paraguay, Chile, Bolivia, and Perú) (Barkley, 1944, 1957). Only the species Schinus molle L. historically extended north into Mexico (Barkley, 1944, 1957). However, Barkley (1957) believed that even S. molle was originally from warm temperate regions of South America and has been introduced throughout Central America where it became readily established. Barkley (1944, 1957) lists the South American distribution of the five varieties of Brazilian peppertree as follows: S. terebinthifolius var. terebinthifolius Raddi – from Venezuela to Argentina; S. terebinthifolius var. acutifolius Engl. – southern Brazil and Paraguay to Missiones, Argentina; S. terebinthifolius var. pohlianus Engl. (the most common variety of the species) – southern Brazil, Paraguay, and northern Argentina; S. terebinthifolius var. raddianus Engl. – south-central Brazil; and S. terebinthifolius var. rhoifolius (Mart.) Engl. – south-central Brazil.

Natural enemies associated with S. terebinthifolius have been evaluated in Florida (Cassani, 1986) and Hawaii (Hight, unpub.). During a 14-month survey in Florida, 115 arthropods were recorded. Even though 40% of the arthropods were phytophagous on S. terebinthifolius, they did not cause significant damage to the plant (Cassani, 1986). Collections that occurred over approximately one year in Hawaii revealed only 34 insect species feeding inconsequentially on introduced S. terebinthifolius. Occasional outbreaks of an introduced polyphagous noctuid caterpillar, Achaea janata L., have occurred in Hawaii. Although the caterpillars may defoliate large stands of S. terebinthifolius, outbreaks tend to last only one generation and occur sporadically at various locations on the island of Hawaii, having no effect on populations of S. terebinthifolius (Yoshioka and Markin, 1994; Hight, unpub.).

Surveys were conducted in South America (primarily Brazil) for potential biological control agents by researchers from Hawaii in the 1950s (Krauss, 1962, 1963) and by Florida researchers in the late 1980s to 1990s (Bennett et al., 1990; Bennett and Habeck, 1991; Medal et al., 1999). Krauss (1963) provided an annotated list of 33 insect species that he collected from Schinus species, many of which were undescribed. Exploratory surveys in southern Brazil conducted by Floridian researchers identified at least 200 species of arthropods associated with S. terebinthifolius (Bennett et al., 1990; Bennett and Habeck, 1991).

Surveys of S. terebinthifolius in both Hawaii and Florida revealed only one species that was potentially damaging to this plant. The seed-feeding wasp Megastigmus transvaalensis (Hussey) (Hymenoptera: Torymidae), originally from South Africa, was accidentally introduced into both Hawaii (Beardsley, 1971) and Florida (Habeck et al., 1989; Cuda et al., 2002). The original host plants of this insect were four South African Rhus species (Grissell and Hobbs, 2000). In Florida and Hawaii, this wasp has been found only in S. terebinthifolius fruits (Wheeler et al., 2001; Hight, unpub.). Overall mortality of S. terebinthifolius seeds caused by this wasp was reported to be as high as 76% in Florida (Wheeler et al., 2001) and 80% in Hawaii (Hight, unpub.). Given that seedling survival is low (Ewel, 1986), wasp damage may contribute significantly to reducing the spread of this weed species.

Based on the Hawaiian surveys for natural enemies in South America, three insect species native to Brazil were released into Hawaii: a seed-feeding beetle, Lithraeus (=Bruchus) atronotatus Pic (Coleoptera: Bruchidae), in 1960 (Davis, 1961; Krauss, 1963); a leaf-rolling moth, Episimus utilis Zimmerman (Lepidoptera: Tortricidae), in 1954 to 1956 (Beardsley, 1959; Davis, 1959; Krauss, 1963); and a stem-galling moth, Crasimorpha infuscata Hodges (Lepidoptera: Gelechiidae), in 1961 and 1962 (Davis and Krauss, 1962; Krauss, 1963). The first two species became established but cause only minor damage (Clausen, 1978; Yoshioka and Markin, 1991).

Based on surveys in Brazil by Florida scientists, two insect species were selected as initial biological control agents to undergo host specificity studies – the sawfly Heteroperreyia hubrichi Malaise (Hymenoptera: Pergidae) and the thrips Pseudophilothrips ichini Hood (Thysanoptera: Phlaeothripidae). The sawfly was introduced into the Gainesville quarantine facility in 1994 and underwent host specificity tests from March 1995 to June 1998 (Medal et al., 1999). An additional plant species (Rhus michauxii Sargent) was tested at the request of the U.S. Fish and Wildlife Service in 1999 (Cuda and Medal, 2002). Host specificity testing of the thrips began in the Gainesville quarantine in 1995, and is expected to be completed in 2002.

No-choice, larval development tests were conducted with the sawfly H. hubrichi on 34 plant species in 14 families at the Gainesville quarantine facility and 12 species in seven families in Brazil (Table 1) (Medal et al., 1999). None of these plants were used successfully as hosts by this insect. Hight et al. (2003) conducted no-choice, host specificity tests in Hawaiian quarantine on 20 plant species in 10 families. The Hawaiian analysis included both larval development tests and female oviposition tests. While only three of the Hawaiian test plants had been evaluated in Florida, 17 plant species were tested for the first time (Table 1).

Table 1. Plants Used in Host Specificity Tests at Various Locations with Heteroperreyia hubrichi for Biological Control of Schinus terebinthifolius¹.

¹ List of plant species are arranged in phylogenetic order with regards to their degree of relationship to the target weed, i.e.,
plants at the beginning of the list are more closely related to S. terebinthifolius than plants at the end of the list.

A petition to release the schinus sawfly into the Florida environment was submitted to the Technical Advisory Group (TAG), USDA, APHIS in 1996. TAG reviewed the petition and considered the sawfly sufficiently host specific for introduction into Florida. An Environmental Assessment (EA) was prepared by APHIS and submitted for public comment. The U.S. Fish and Wildlife Service requested host specificity tests be conducted on R. michauxii, a federally-listed endangered species that was not on the original test plant list. Tests indicated that R. michauxii was not an acceptable host plant of the sawfly (Cuda, 2002), and the information was sent to APHIS. Field observations in Brazil and laboratory feeding trials indicated H. hubrichi to be highly host specific to S. terebinthifolius. This insect was able to feed, develop, and become a reproductively mature adult only on S. terebinthifolius (Medal et al., 1999).

The potential host range in Hawaii appears to be slightly broader than that identified in Florida and Brazil. Tests in Florida evaluated two North American species of sumac (Rhus copallina L. and R. michauxii) and found them unsuitable for H. hubrichi oviposition and incapable of supporting larval development (Medal et al., 1999). Hawaiian tests indicated that the Hawaiian sumac (Rhus sandwicensis A. Gray) did support larval development and was highly attractive to the female for oviposition. Chemicals still present in ancestral, continental species that deter herbivorous insects may have been lost over time in the Hawaiian sumac. Of the five varieties of S. terebinthifolius recognized in South America (Barkley, 1944), H. hubrichi prefers the most pubescent varieties (S. t. rhoifolius and S. t. pohlianus) (M. Vitorino, pers. comm.). The dense pubescent nature of R. sandwicensis may stimulate female oviposition regardless of the quality of the plant for larval development. Both S. terebinthifolius and R. sandwicensis were comparable in their acceptability to ovipositing females as measured by the proportion of females that oviposited on the test plant and the number of eggs that a female laid. But R. sandwicensis was a dramatically poor host for H. hubrichi larvae in both performance characteristics of larval survival (1%) and development time (30% longer) (Hight et al., 2003).

Field surveys of plants in Brazil indicated that P. ichini is probably host specific to S. terebinthifolius (Garcia, 1977). Larval feeding and adult oviposition tests for P. ichini were completed and a petition for field release in Florida was submitted to TAG in October 2002. The test plant list was the same as that approved by TAG for H. hubrichi with the addition of the native plant R. michauxii. The results of field surveys in Brazil and host specificity tests indicated that P. ichini can reproduce only on S. terebinthifolius and S. molle (Cuda, unpub.).

To date, no biological control agents have been purposefully introduced in Florida against S. terebinthifolius. A decision to release the sawfly in Florida has been delayed pending a finding of no significant impact of the vertebrate toxins lophyrotomin and pergidin discovered in the larvae of H. hubrichi (Cuda, unpub.; see also p. 125).

Adults of the leaf-feeding sawfly are generally black in color with yellow legs (Fig. 3). The life cycle begins when females emerge from pupal cases in soil near the base of S. terebinthifolius trees and search for well-developed, non-woody young stems in which to oviposit. A female and male H. hubrichi mate on the surface of the soil or on plants, although females do not need to mate for oviposition to occur. Each female inserts a single egg mass shallowly into non-woody stems. Eggs are arranged in rows and the female “guards” her eggs until she dies, just before the eggs hatch (Fig. 3). Eggs hatch in 14 days. Neonate larvae feed gregariously on both surfaces of young leaflets at the tip of shoots (Fig. 4). As they grow they move as a group onto new leaflets and larger leaves until the third to fourth instar when they disperse throughout the plant and feed individually. Larvae are green with red spots and black legs. After reaching the seventh instar, larvae move into soil and pupate. Insects reared on S. terebinthifolius took 26 to 42 days from egg hatch to pupation. The pupal stage lasts from 2 to 7 months (Medal et al., 1999; Hight et al., , 2002).

Adult and larval meristem-sucking thrips are generally red and black in color (Figs. 5 and 6). Adults are usually found on new unfolding leaves of S. terebinthifolius while immatures occur on stems of young shoots (Cuda et al., 1999). Both immature and adult stages consume plant juices with their rasping-sucking mouthparts, often killing new shoots. Eggs are laid singly or in small groups at the base of leaves or within terminal shoots and hatch in seven to eight days. Eggs from unmated females produce male offspring whereas eggs from mated females give rise to female offspring. The nymphal stage lasts

No classical biological control agents have yet been purposefully introduced into Florida against S. terebinthifolius. However, plans are being developed to evaluate the establishment and spread of H. hubrichi in Florida once the insect has been approved for field release (Cuda, unpub.). At least three study sites will be established in Florida throughout the geographical range of S. terebinthifolius. Releases of H. hubrichi will be made in cages. A series of annual photographs from fixed locations will be taken at each release site to document vegetation changes. Solar powered remote weather stations will be placed at each release site to monitor and identify environmental conditions that may lead to H. hubrichi establishment. Weather data also will be used to separate effects of H. hubrichi on S. terebinthifolius from annual variations in plant growth due to abrupt differences in weather patterns. Effects of this insect on S. terebinthifolius and non-target plants will be evaluated in release cages. Annual productivity of S. terebinthifolius and dominant native vegetation will be compared between cages with and without H. hubrichi. To monitor changes and effects on vegetation over a landscape scale, a remote sensing project is being developed that will allow automated computer recognition of various vegetation components and monitor changes in vegetation over time. Finally, conventional vegetation analysis techniques will be used to evaluate the effect of H. hubrichi on the target and non-target plants.

Additional surveys for phytophagous insects of S. terebinthifolius need to be conducted in northern Argentina, the most likely center of origin of this species (Barkley, 1944). Virtually all previous South American explorations by workers from Hawaii (Krauss, 1962, 1963) or Florida (Bennett et al., 1990; Bennett and Habeck, 1991) have taken place in southern Brazil. Although this work has identified several promising biological control candidates, surveys might be more successful in Argentina. For example, on a 10-day survey in January 2000 of S. terebinthifolius natural enemies in the state of Missiones, Argentina, two species of stem-boring cerambycids and a bark-girdling buprestid were collected (Hight, unpub.). Identifications of these insect species are pending. No stem-boring or bark-girdling insects were identified from Brazilian surveys.

Barkley, F. A. 1957. A study of Schinus L. Lilloa Revista do Botanica. Tomo 28. Universidad Nacional
del Tucumen, Argentina.

Beardsley, J. W. 1959. Episimus sp. Proceedings, Hawaiian Entomological Society 17: 28.

Beardsley, J. W. 1971. Megastigmus sp. Proceedings, Hawaiian Entomological Society 21: 28.

Bennett, F. D., L. Crestana, D. H. Habeck, and E. Berti-Filho. 1990. Brazilian peppertree - prospects for
biological control, pp. 293-297. In Delfosse, E. S. (ed.). Proceedings of the VII International
Symposium on Biological Control of Weeds. March 6-11, 1988. Rome, Italy.

Bennett, F. D. and D. H. Habeck. 1991. Brazilian peppertree - prospects for biological control in Florida,
     pp. 23-33. In Center, T. D., R. F. Doren, R. L. Hofstetter, R. L. Myers, and L. D. Whiteaker (eds.).
     Proceedings of the Symposium of Exotic Pest Plants, November 2-4, 1988. Miami, Florida, USA.
     U.S.Department Interior, National Park Service, Washington, DC, USA.

Brizicky, G. K. 1962. The genera of Anacardiaceae in the southeastern United States. Journal of the
Arnold Arboretum 43: 359-375.

Cassani, J. R. 1986. Arthropods on Brazilian peppertree, Schinus terebinthifolius (Anacardiaceae), in
south Florida. Florida Entomologist 69: 184-196.

Clausen, C. P. (ed). 1978. Introduced Parasites and Predators of Arthropod Pests and Weeds: A World
View. Agriculture Handbook 480. U.S. Department of Agriculture, Agricultural Research Service,
Washington, DC, USA.

Cronquist, A. 1981. An Integrated System of Classification of Flowering Plants. Columbia University
Press, New York, USA.

Cuda, J. P., J. C. Medal, D. H. Habeck, J. H. Pedrosa-Macedo, and M. Vitorino. 1999. Classical
     Biological Control of Brazilian Peppertree (Schinus terebinthifolius) in Florida. Circular ENY-820.
     University of Florida, Cooperative Extensive Service, Institute of Food and Agricultural Sciences,
     Gainesville, Florida, USA.

Cuda, J. P., G. S. Wheeler, and D. H. Habeck. 2002. Brazillian peppertree seed chalcid: Wasp wage
war on widespread weed. Wildland Weeds 6(1):18-20.

Davis, C. J. 1959. Recent introductions for biological control in Hawaii - IV. Proceedings, Hawaiian
Entomological Society 17: 62-66.

Davis, C. J. 1961. Recent introductions for biological control in Hawaii - VI. Proceedings, Hawaiian
Entomological Society 17: 389-393.

Davis, C. J. and N. L. H. Krauss. 1962. Recent introductions for biological control in Hawaii - VII.
Proceedings, Hawaiian Entomological Society 18: 125-129.

Doren, R. F., L. D. Whiteaker, and L. M. LaRosa. 1991. Evaluation of fire as a management tool for
controlling Schinus terebinthifolius as secondary successional growth on abandoned agricultural
land. Environmental Management 15: 121-129.

Ewel, J.J. 1978. Ecology of Schinus, pp. 7-21. In Anon. Schinus: Technical Proceedings of Techniques
for Control of Schinus in South Florida: A Workshop for Natural Area Managers, December 2, 1978.
The Sanibel Captiva Conservation Foundation, Inc., Sanibel, Florida, USA.

Ewel, J. J. 1986. Invasibility: Lessons from South Florida, pp. 214-230. In Mooney, H. A. and J. A.
Drake (eds.). Ecology of Biological Invasions of North America and Hawaii. Springer-Verlag, New
York, USA.

Ewel, J. J., D. S. Ojima, K. A. Karl, and W. F. DeBusk. 1982. Schinus in Successional Ecosystems of
Everglades National Park. South Florida Research Center Report T-676. U.S. Department of Interior,
National Park Service, Washington, DC, USA.

Ferriter, A. (ed). 1997. Brazilian Pepper Management Plan for Florida: Recommendations from the
Brazilian Pepper Task Force, Florida Exotic Pest Plant Council. The Florida Exotic Pest Plant
Council,Gainesville, Florida, USA.

Garcia, C. A. 1977. Biology and Ecology of Liothrips ichini (Thysanoptera: Phlaeothripidae).
Unpublished thesis, Universidade Federal do Parana, Curitiba, Brazil.

Gleason, H. A. and A. Cronquist. 1963. Manual of Vascular Plants of Northeastern United States and
Adjacent Canada. D. Van Nostrand Company, New York, USA.

Grissell, E. E. and K. R. Hobbs. 2000. Megastigmus transvaalensis (Hussey) (Hymenoptera:
     Torymidae) in California: Methods of introduction and evidence of host shifting, pp. 265-278. In
     Austin, A.D. and M. Dowton (eds.). Hymenoptera: Evolution, Biodiversity and Biological Control.
     Commonwealth Scientific and Industrial Research Organization Publishing, Melbourne, Australia.

Habeck, D. H. 1995. Biological control of Brazilian peppertree. Florida Nature 68: 9-11.

Habeck, D. H., F. D. Bennett, and E. E. Grissell. 1989. First record of a phytophagous seed chalcid
from Brazilian peppertree in Florida. Florida Entomologist 72: 378-379.

Habeck, D. H., F. D. Bennett, and J. K. Balciunas. 1994. Biological control of terrestrial and wetland
weeds, pp. 523-547. In Rosen, D., F. D. Bennett, and J. L. Capinera (eds.). Pest Management in the
Subtropics: Biological Control - a Florida Perspective. Intercept, Andover, United Kingdom.

Hight, S. D., I. Horiuchi, M.D. Vitorino, C.W. Wikler, and J.H. Pedrosa-Macedo. 2003. Biology, host
specificity tests, and risk assessment of the sawfly Heteroperreyia hubrichi, a potential biological
control agent of Schinus terebinthifolius in Hawaii. BioControl. Submitted.

Krauss, N. L. H. 1962. Biological control investigations on insect, snail and weed pests in tropical
America, 1961. Proceedings, Hawaiian Entomological Society 18: 131-133.

Krauss, N. L. H. 1963. Biological control investigations on Christmasberry (Schinus terebinthifolius) and
emex (Emex spp.). Proceedings, Hawaiian Entomological Society 18: 281-287.

Langeland, K. A. 1998. Help protect Florida’s natural areas from non-native invasive plants. Circular
1204. University of Florida, Cooperative Extensive Service, Institute of Food and Agricultural
Sciences,Gainesville, Florida, USA.

Loope, L. L. and V. L. Dunevitz. 1981. Investigations of Early Plant Succession on Abandoned
Farmland in Everglades National Park. Report T-644. National Park Service, Everglades National
Park, Homestead, Florida, USA.

Mack, R. N. 1991. The commercial seed trade: an early disperser of weeds in the United States.
Economic Botany 45: 257-273.

Medal, J. C., M. D. Vitorino, D. H. Habeck, J. L. Gillmore, J. H. Pedrosa, and L. D. De Sousa. 1999.
Host specificity of Heteroperreyia hubrichi Malaise (Hymenoptera: Pergidae), a potential biological
control agent of Brazilian Peppertree (Schinus terebinthifolius Raddi). Biological Control 14: 60-65.

Morton, J. F. 1978. Brazilian pepper - its impact on people, animals and the environment. Economic
Botany 32: 353-359.

Nilsen, E. T. and W. H. Muller. 1980. A comparison of the relative naturalization ability of two Schinus
species in southern California. I. Seed germination. Bulletin Torrey Botanical Club 107: 51-56.

Panetta, F. D. and J. McKee. 1997. Recruitment of the invasive ornamental, Schinus terebinthifolius, is
dependent upon frugivores. Australian Journal Ecology 22: 432-438.

Randall, J. M. 1993. Exotic weeds in North American and Hawaiian natural areas: The Nature
Conservancy’s plan of attack, pp. 159-172. In McKnight, B.N. (ed.). Biological Pollution: The Control
and Impact of Invasive Exotic Species. Indiana Academy of Sciences, Indianapolis, Indiana, USA.

Tomlinson, P. B. 1980. The Biology of Trees Native to Tropical Florida. Harvard University Printing
Office, Allston, Massachusetts, USA.

U.S. Fish and Wildlife Service. 1998. Draft Recovery Plan for Multi-Island plants. U.S. Fish and Wildlife
Service, Portland, Oregon, USA.

UF/IFAS (University of Florida, Institute of Food and Agricultural Sciences). 1999. Putting Florida First:
Focusing IFAS Resources on Solutions for Tomorrow. University of Florida, Gainesville, Florida,
USA.

Wheeler, G. S., L. M. Massey, and M. Endries. 2001. The Brazilian peppertree drupe feeder
Megastigmus transvaalensis (Hymenoptera: Torymidae); Florida distribution and impact. Biological
Control 22: 139-148.

Woodall, S. L. 1979. Physiology of Schinus, pp. 3-6. In Workman, R. (ed.). Schinus – Technical
Proceedings of Techniques for Control of Schinus in South Florida: A Workshop for Natural Area
Managers. The Sanibel-Captiva Conservation Foundation, Inc., Sanibel, Florida, USA.

Woodall, S. L. 1982. Herbicide Tests for Control of Brazilian-Pepper and Melaleuca in Florida. U.S.
Department of Agriculture, Forest Service Research Note SE 314. Southeastern Forest Experiment
Station, Asheville, North Carolina, USA.

Yoshioka, E. R. and G. P. Markin. 1991. Efforts of biological control of Christmas berry (Schinus
     terebinthifolius) in Hawaii, pp. 377-387. In Center, T. D., R. F. Doren, R L. Hofstetter, R. L. Myers,
     andL. D. Whiteaker (eds.). Proceedings of the Symposium of Exotic Pest Plants. November 2-4,
     1988, Miami, Florida, USA. U.S. Department of the Interior, National Park Service, Washington, DC,
     USA.

Yoshioka, E. R. and G. P. Markin. 1994. Outbreak of Achaea janata (Linnaeus) (Lepidoptera:
Noctuidae) on Christmasberry in Hawaii. Proceedings of the Hawaiian Entomological Society
32: 153-155.


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