Assessments for quarantine pests for which a full pest risk assessment is conducted

Assessments for quarantine pests for which a full pest risk assessment is conducted

4.1Angular leaf spot

Xanthomonas fragariae

Natural hosts of this bacterium appear to be limited to strawberries. Experimental data indicate susceptibility to X. fragariae varies among different strawberry cultivars (Bestfleisch et al. 2015; Maas et al. 2000), with fully resistant genotypes not yet identified.

In Australia X. fragariae has been found in Gosford in 1975, Adelaide Hills in 1994 and Bundaberg in 2010. These outbreaks have since been eradicated and Australia is now considered to be free from X. fragariae (Australian Government Department of Agriculture 2012; EPPO 1996; Gillings, Fahy & Bradley 1998; McGechan & Fahy 1976; Young et al. 2011).

Xanthomonas fragariae may infect all vascular tissue including the crown, leaves, roots, petioles, stolons, daughter plants and calyx (Anco & Ellis 2011; Bestfleisch et al. 2015; Heidenreich & Turechek 2016; Louws, Harrison & Garrett 2014). The bacterium infects the leaves of wild and cultivated strawberry plants causing water-soaked lesions to form on the lower surface of the leaf (Gubler et al. 1999; Kwon et al. 2010; Peres 2014; Stöger et al. 2008). The lesions are initially small and irregular in shape, under high moisture conditions they may enlarge, becoming angular in shape and forming reddish-brown spots. These may develop into necrotic tissue and may exude bacteria in an ooze (Heidenreich & Turechek 2016; Hildebrand, Schroth & Wilhelm 1967; Peres 2014).

Infection of strawberry leaves occurs through the stomata. Under optimal conditions or once the infection has become systemic, the calyx may become infected with symptoms identical to those of leaves (Heidenreich & Turechek 2016; Peres 2014). Under favourable conditions the lesions on the calyx and flowers can secrete bacteria in the form of viscous droplets (Gubler et al. 1999; Peres 2014). In the crown, water-soaked lesions may be localised or confined to one section (Hildebrand, Schroth & Wilhelm 1967).

In addition to host specificity, many Xanthomonas species and pathovars show tissue specificity as well, invading either intercellular spaces of mesophyll tissue (mesophylic pathogens) and/or xylem elements of vascular tissue (vascular pathogens) (Ryan et al. 2011). Hildebrand, Schroth and Wilhelm (1967) reported that X. fragariae is a vascular pathogen, being found in both cambium and xylem tissue. The spread of X. fragariae occurs through infected propagative material, overhead irrigation, rain splash and windblown droplets (Hildebrand, Schroth & Wilhelm 1967). Seed transmission has not been demonstrated.

Outbreaks of this disease in California are associated with rainfall or overhead irrigation, with higher levels of infection in nurseries planted in spring (Hildebrand, Schroth & Wilhelm 1967).

The risk scenario of concern for X. fragariae is that symptomless infected strawberry fruit may be imported into Australia.

4.1.1Likelihood of entry

Likelihood of importation

The following information provides supporting evidence for this assessment.

Angular leaf spot has been reported on strawberries in Korea in both open field farms and greenhouses (Kwon et al. 2010).

Korea currently tests for the presence of X. fragariae in imported runner daughter plants (QIA 2015b). However no testing for this pathogen takes place during production process for certified plantlets. Plantlets with obvious symptoms of infection are likely to be removed during the multiplication process. Some infected plantlets may exhibit no or mild symptoms and may be used during the multiplication process.

Infected plants can remain asymptomatic until optimum conditions for the disease to develop are present (Louws, Harrison & Garrett 2014; Mahuku & Goodwin 1997; NPPO the Netherlands 2013; Roberts et al. 1996; Wang & Turechek 2016).

Transmission of this bacterium can occur over a short distance via rain/water splash (Hildebrand, Schroth & Wilhelm 1967; Roberts, Jones & Chandler 1997). Greenhouse production is not exposed to rainfall and overhead irrigation is not used, which would limit the spread of the bacterium, if present.

Xanthomonas fragariae can infect strawberry leaves and crowns through the stomata and fresh wounds (Anco & Ellis 2011; George & Fox 2014; Schilder 2016; University of Minnesota 2016). No information has been found on how other tissues can be infected.

Strawberries with obvious symptoms of infection in the calyx are likely to be removed during harvesting and packing procedures and would not be packed for export. Strawberries that are asymptomatic or with only mild symptoms on the calyx could escape detection during packing procedures and be exported.

Strawberries are usually stored and transported at low temperatures to prolong shelf life. Xanthomonas fragariae is slow growing and can survive cold storage in host tissue up to one year (Hildebrand, Schroth & Wilhelm 1967; Louws, Harrison & Garrett 2014). Some infected fruit may exhibit no or mild symptoms at the time they arrive in Australia.

Xanthomonas fragariae has been reported on strawberries in both open field farms and greenhouses in Korea. Strawberry plants used in fruit production are the progeny of registered plantlets which have been through rigorous selection process. This would reduce the likelihood of infected plants being used in fruit production. Conditions in greenhouse production limits the ability to spread of the bacterium, if present. Fruit (calyx) infection only occurs under optimum conditions or when the infection is systemic. Infected calyx may be symptomless and are likely to pass through the packing procedures undetected. The bacterium is likely to survive cold temperatures during storage and transportation. Some infected strawberry fruit may still exhibit no or mild symptoms on arrival in Australia. This information supports a likelihood estimate for importation of ‘moderate’.

Likelihood of distribution

The following information provides supporting evidence for this assessment.

Imported strawberries are intended for human consumption. Distribution would be for retail sale and likely to be Australia wide.

As strawberries will be packaged in punnets, packed strawberries may not be processed or handled again until they arrive at retailers. Therefore, the bacterium, if present in packed strawberries, is unlikely to be detected during transportation and distribution to retailers.

Strawberries with obvious symptoms of infection would not be marketable and would not be sold. Strawberries without symptoms, or with only minor symptoms, could be marketable and sold.

Most fruit waste will be discarded into managed waste systems and will be disposed of in municipal tips and would therefore pose little risk of exposure to a suitable host.

Consumers will discard small quantities of fruit waste in urban, rural and natural localities. Small amounts of fruit waste will be discarded in domestic compost. There is some potential for consumer waste being discarded near host plants (strawberry plants), including commercially grown, household or wild host plants. If present in fruit waste, the bacterium would then need to be transferred to the host plants.

Xanthomonas fragariae cannot survive in soil without a host (Anco & Ellis 2011). However, the bacterium can remain viable from one season to the next on tissue and dried leaves under the soil for up to a year (Anco & Ellis 2011; Heidenreich & Turechek 2016; Kennedy & King 1962b; Naqvi 2004; Peres 2014).

Generally survival of a pathogen in fruit waste is expected to be short due to dehydration and competition with other organisms. However, based on the above studies regarding the survival of this bacteria in soil on tissue and dried leaves, it is possible that the bacterium could survive in fruit waste for a longer period of time increasing the chances of the bacterium coming into contact with the host plants.

To date, strawberries are the only confirmed natural hosts of X. fragariae (Kennedy 1965; NPPO the Netherlands 2013). In Australia strawberries are grown in all states commercially and are also grown as a garden plant in household (ABS 2016). Strawberries are infrequently encountered as a weed in Australia (CHAH 2016; Groves 2002). There are reports of naturalised Fragaria vesca in localised areas in New South Wales and Queensland and Fragaria × ananassa in localised areas in South Australia (CHAH 2016; Groves 2002).

Kennedy (1965) reported that under experimental conditions species in the genus Potentilla can become infected by X. fragariae. Species in the genus Potentilla can be found distributed throughout Australia (CHAH 2016). However, there have been no reports of infection of Potentilla under natural conditions in the field.

On host plants the bacterium can be transmitted over short distances via water splash approximately three metres, possibly further under extreme weather conditions (Roberts, Jones & Chandler 1997). Any bacteria splashed onto a non-host or soil is expected to not survive for long.

To date, there have been no vectors identified for this bacterium.

Transmission of X. fragariae through seeds is suspected to be possible (Mark Herrington [Queensland Department of Agriculture and Fisheries] 2016 pers. comm., 20 May). However, there is no evidence to confirm seed transmission of this bacterium yet.

Strawberry seeds (achenes) may germinate producing plants. However, most seeds are dormant and will not germinate without scarification (Galvão et al. 2014). Scarification may include heat treatment, cutting the seed or the use of chemicals (El Hamdouni 2001; Guttridge & Bright 1978; Ito et al. 2011; Miller et al. 1992; Nakamura 1972; Thompson 1968; Wilson, Goodall & Reeves 1973). These treatments are unlikely to be met outside of commercial situations. Due to this reason, germination of strawberry seed from fruit waste is considered unlikely.

Imported strawberries are intended for human consumption and would likely be distributed Australia wide. Strawberries will be packaged in punnets and may not be processed or handled again until they arrive at retailers. Small quantities of fruit waste could be discarded in urban, rural and natural localities. Xanthomonas fragariae can potentially survive for a long period of time on infested fruit waste. Natural hosts of X. fragariae are limited to plants of the genus Fragaria. This bacterium is transmitted via water splash which limits its potential for dispersal to short distances and no vectors have been identified. Although the possibility of this bacterium being transmitted through seed is suspected, seed transmission is not confirmed. Strawberry seeds are unlikely to germinate without treatment. This information supports a likelihood estimate for distribution of ‘low’.

Overall likelihood of entry

The likelihood that Xanthomonas fragariae will enter Australia as a result of trade in strawberry fruit from Korea and be distributed in a viable state to a susceptible host is: Low.

4.1.2Likelihood of establishment

The following information provides supporting evidence for this assessment.

Strawberries, the natural host for X. fragariae, are widely grown commercially and domestically across Australia. Plants in the genus Fragaria are highly susceptible to X. fragariae (Bestfleisch et al. 2015; Maas et al. 2000).

Xanthomonas fragariae cannot survive in soil without a host (Anco & Ellis 2011). However, it can remain viable from one season to the next on tissue and dried leaves under the soil for up to a year (Anco & Ellis 2011; Kennedy & King 1962b; Naqvi 2004; Peres 2014). Xanthomonas fragariae gathered from leaf material stored for 21 years has been found to be viable (Kong 2010).

Preferred environmental conditions for bacterial development are warm days around 20 °C and cold nights at 2 °C (Kennedy-Fisher 1997; Kennedy & King 1962b; Naqvi 2004; Peres 2014). High humidity levels affect disease development (Hildebrand et al. 2005; Kennedy & King 1962b) with rain and overhead irrigation increasing the chances of disease outbreak (Epstein 1966; Hildebrand, Schroth & Wilhelm 1967). These climate conditions can be found in some strawberry production regions of Australia. In some areas overhead irrigation may also be used to protect strawberries from frost damage, increasing the likelihood of establishment in those areas (DAFWA 2015; Naqvi 2004; Nicholls et al. 2008).

Korean strawberries are expected to be exported between January and March, during Australia’s summer. Average temperatures in Australia during this period range from 12 °C to 36 °C (Bureau of Meteorology 2016). High temperatures above 28 °C are unfavourable for the expression of angular leaf spot and may reduce the potential for the bacterium to infect the host plants (Kennedy & King 1962a). However, Roberts et al. (1996) reported that bacteria are likely to survive higher temperatures, remaining asymptomatic in the plant material until optimum conditions are available.

Strawberries are infrequently encountered outside managed cultivation in Australia (CHAH 2016; Groves 2002). There are reports of naturalised Fragaria vesca in localised areas in New South Wales and Queensland and Fragaria × ananassa in localised areas in South Australia (CHAH 2016; Groves 2002). These plants may become infected becoming a source of inoculum for the bacterium. The localised and infrequent distribution of these plants will limit them as a source of inoculum for infection.

Previous outbreaks of X. fragariae occurred in Gosford in 1975, in Adelaide Hills in 1994 and in Bundaberg in 2010 (Gillings, Fahy & Bradley 1998; McGechan & Fahy 1976; Young et al. 2011) indicating that suitable environmental conditions for X. fragariae exist in Australia.

Currently X. fragariae is known to be established in multiple countries over a variety of climatic zones including Argentina, Brazil, Canada, Ethiopia, France, Germany, Italy, Korea, Paraguay, Taiwan, United States, Uruguay and Venezuela (CABI & EPPO 1997b; NPPO the Netherlands 2013). Environments with climate conditions similar to these regions exist in various parts of Australia, suggesting X. fragariae has the potential to establish in Australia.

Transmission of X. fragariae through seeds is suspected to be possible (Mark Herrington [Queensland Department of Agriculture and Fisheries] 2016 pers. comm., 20 May). However, there is no evidence to confirm seed transmission of this bacterium yet.

Plants in the genus Fragaria are highly susceptible to X. fragariae. Xanthomonas fragariae is able to survive long periods of time in adverse conditions. Environmental conditions suitable for the development of angular leaf spot can be found in some strawberry growing areas of Australia. Outbreaks of X. fragariae previously occurred in Australia. This information supports a likelihood estimate for establishment of ‘high’.

4.1.3Likelihood of spread

The following information provides supporting evidence for this assessment.

Long distance dispersal of X. fragariae is more likely to be through the movement of infected strawberry planting material (runners). However, strawberry planting material certified as being free of pests and pathogens is available from the Queensland Strawberry Runner Accreditation Scheme and the Victorian Certified Runner Scheme (DAFWA 2016; Strawberries Australia 2016; Strawberries Australia Inc 2012). The Victorian Certified Runner Scheme produces 75 per cent of Australian strawberry runners used in national fruit production (Victorian Strawberry Industry Certification Authority 2010), making this pathway for spread less likely.

Natural hosts of X. fragariae are limited to plants in the genus Fragariae. Strawberries are grown commercially and domestically in all states of Australia and can be grown domestically in the ACT and NT (ABS 2016). Fragaria vesca and Fragaria × ananassa can be infrequently encountered in unmanaged environment of Australia (CHAH 2016; Groves 2002).

Xanthomonas fragariae has been isolated from Potentilla under experimental conditions (Kennedy 1965). Species in Potentilla can be found distributed throughout Australia (CHAH 2016). However, there have been no reports of infection of these hosts under natural conditions in the field. Transmission of X. fragariae through seeds is suspected to be possible (Mark Herrington [Queensland Department of Agriculture and Fisheries] 2016 pers. comm., 20 May). However, there is no evidence to confirm seed transmission of this bacterium yet.

To date, there have been no vectors identified for this bacterium.

4.1.4Overall likelihood of entry, establishment and spread

The overall likelihood that Xanthomonas fragariae will enter Australia as a result of trade in strawberry fruit from Korea, be distributed in a viable state to a susceptible host, establish in Australia and subsequently spread within Australia is: Low.

4.1.5Consequences

4.1.6Unrestricted risk estimate

Assessments for quarantine pests for which the URE outcome is adopted from previous assessments

4.2Thrips

Frankliniella intonsa (EP) and Frankliniella occidentalis (EP, NT)

Both thrips species were assessed previously in a number of existing import policies, for example, in the import policy for capsicums from Korea (Biosecurity Australia 2009a), unshu mandarins from Japan (Biosecurity Australia 2009b), and stone fruit from the United States (Biosecurity Australia 2010b). Frankliniella occidentalis was also included in the import policy for table grapes from China (Biosecurity Australia 2011a), Japan (Australian Department of Agriculture 2014) and Korea (Biosecurity Australia 2011b), as well as several other existing policies. In these policies, the unrestricted risk estimates for thrips were all assessed as exceeding the ALOP for Australia. Therefore, specific risk management measures are required for thrips.

The department considered factors affecting the likelihood of importation for thrips for strawberries from Korea and those previously assessed. The department considers that the likelihood of importation for thrips for strawberries from Korea would be comparable to that in the previous assessments.

Thrips have a wide host range and host material is likely to be available all year round in Australia. The likelihood of distribution for these pests for strawberries from Korea would be comparable to that for commodities assessed previously.

The likelihood of establishment and spread of F. intonsa in Australia and F. occidentalis in the Northern Territory for strawberries from Korea will be comparable to previous assessments. These likelihoods relate specifically to events that occur in Australia and are principally independent of the importation pathway. The consequences of F. intonsa in Australia and F. occidentalis in the Northern Territory are principally independent of the importation pathway.

In addition, the department has also reviewed the latest literature and no new information is available that would significantly change the risk ratings for importation, distribution, establishment, spread and consequences as set out for thrips in existing policies.

4.2.1Unrestricted risk estimate

Assessments for quarantine pests for which some of the likelihood and/or consequence ratings are adopted from previous assessments

4.3Kanzawa spider mite

Tetranychus kanzawai (EP, WA)

The risk scenario of concern is that T. kanzawai adults and larvae are present on harvested strawberry fruit and brought to Australia.

The likelihood of establishment and spread of T. kanzawai in Western Australia for strawberries from Korea will be comparable to previous assessments. These likelihoods relate specifically to events that occur in Australia and are principally independent of the importation pathway. The consequences of T. kanzawai in Western Australia are also principally independent of the importation pathway.

In addition, the department has also reviewed the latest literature and no new information is available that would significantly change the risk ratings for distribution, establishment, spread and consequences as set out for T. kanzawai in the existing policies.

However, differences in climatic conditions, the commodity, pest prevalence and commercial production practices between previous exporting areas and Korea make it necessary to reassess the likelihood of importation of T. kanzawai into WA with strawberries from Korea.

4.3.1Likelihood of entry

Likelihood of importation

The following information provides supporting evidence for this assessment.

Whilst Tetranychus mites feed mainly on leaves, they may be found on fruit during high infestation levels (NAPPO 2014).

High infestation levels of T. kanzawai leads to noticeable direct damage to the plant as well as silk webbing on the areas infested (Zhang 2008). There is also comparatively small space for T. kanzawai to hide on strawberry fruit when compared to grape bunches, and strawberries are picked and packed individually. Therefore, more heavily infested fruit is likely to be detected and removed during standard commercial quality processes.

Tetranychus mites are capable of entering diapause when under stress, and can survive for long periods of time in low temperatures and even develop a tolerance for low oxygen levels (Suzuki et al 2015) which may be experienced during air freight. Unpublished Department of Agriculture and Water Resources data indicate that Tetranychus mites have been intercepted in strawberries from the United States and were found under the calyx.

Tetranychus kanzawai has been found to survive temperatures of -5 °C for ten days, suggesting it can survive cold storage and transport (Yang, Cao & Chen 1991).

Tetranychus kanzawai is a pest of strawberries in Korea and is capable of completing its lifecycle on strawberry plants. They may not be detected during harvest or packing house procedures due to their small size. They can survive low temperatures during storage and transportation. However, during high infestation levels, significant damage occurs on fruit which would lead to their removal from the export pathway. In the case of lower infestation levels, T. kanzawai is highly unlikely to be present on the fruit at all. This information supports a likelihood estimate for importation into Western Australia of ‘moderate’.

Likelihood of distribution

Overall likelihood of entry

The likelihood that Tetranychus kanzawai will enter Australia as a result of trade in strawberries from Korea and be distributed in a viable state to a susceptible host is: Low.

4.3.2Likelihood of establishment and spread

Likelihood of establishment High

4.3.3Overall likelihood of entry, establishment and spread

The overall likelihood that Tetranychus kanzawai will enter Australia as a result of trade in strawberries from Korea, be distributed in a viable state to a susceptible host, establish in Australia and subsequently spread within Australia is: Low.

4.3.4Consequences

4.3.5Unrestricted risk estimate

4.4Brown rot

Monilinia fructigena (EP) and Monilia polystroma (EP)

The biology and taxonomy of Monilinia fructigena and Monilia polystroma are considered sufficiently similar to justify combining them into a single assessment. The assessment of the pathogens has been largely based on the scientific information on Monilinia fructigena as it is predicted to pose a similar risk and require similar mitigation measures. Unless explicitly stated, the information presented is considered as applicable to both species. In this assessment, the common name ‘brown rot’ is used to refer to both species unless otherwise specified.

The risk scenario of concern for Monilinia fructigena and Monilia polystroma is that symptomless infected fruit might enter Australia and result in the establishment of these fungi in Australia.

Monilinia fructigena was assessed in the existing import policy for apples (Biosecurity Australia 2010a), and table grapes from China (Biosecurity Australia 2011a). Both Monilinia fructigena and Monilia polystroma were included in the existing policy for nectarines from China (Australian Government Department of Agriculture and Water Resources 2016) and table grapes from Japan (Australian Department of Agriculture 2014). The assessment of Monilinia fructigena and Monilia polystroma presented here builds on these existing policies.

Differences in commodity climate conditions, pest prevalence and horticultural practices between previous export areas and Korea make it necessary to reassess the likelihood of importation of brown rot into Australia with strawberries from Korea.

Brown rot fungi has multiple hosts. After importation, strawberries will be distributed throughout Australia for retail sale in a similar way to table grapes assessed previously. The likelihood of distribution for these fungi for strawberries from Korea would be comparable to that assessed previously.

The likelihood of establishment and spread of brown rot fungi in Australia will be comparable to previous assessments. These likelihoods relate specifically to events that occur in Australia and are principally independent of the importation pathway. The consequences of brown rot in Australia are also principally independent of the importation pathway.

In addition, the Australian Government Department of Agriculture and Water Resources has reviewed the latest literature and no new information is available that would significantly change the risk ratings for distribution, establishment, spread and consequences as set out for brown rot fungi in the existing policies.

Monilinia fructigena is recorded in Korea (CABI 2016; Kim & Koo 2009). In Japan, Monilia polystroma was identified from pear and apple isolates previously identified as Monilinia fructigena (Van Leeuwen et al. 2002). It has been suggested isolates of Monilinia fructigena should be re-examined to determine whether they may be Monilia polystroma (Chalkley 2010; Van Leeuwen et al. 2002). For this reason, it is assumed that Monilia polystroma is likely to be present in Korea.

4.4.1Likelihood of entry

Likelihood of importation

The following information provides supporting evidence for this assessment.

Brown rot is a pathogen favoured by moist conditions (rain, fog and other factors that increase humidity), especially at the beginning of the host’s growth periods. High light levels with warm temperatures and wet and humid conditions favour spore germination and infections (Batra 1991; Byrde & Willets 1977; CABI 2016; Jones 1990). Korea has mild springs with warm and humid summers (KMA 2011). The green house climate is controlled to replicate summer/spring conditions with day time temperatures between 20 and 25 °C. This climate is conducive to the development of brown rot and suggests that the disease, if present, is likley be detected.

However, no records have been found of Monilinia fructigena or Monilia polystroma on strawberries in Korea.

Brown rot fungi have the ability to cause latent infection in fruit (Gell et al. 2009). The infected fruit may not produce symptoms of disease until the fruit begins to ripen during storage and transport, on the market shelf, or as the fruit senesces (Byrde & Willets 1977).

On stone fruit healthy fruit can be contaminated with conidia in the field or during processes in the packing house (Ma 2006). Wounded fruit may also be contaminated with conidia during packing house processes via fruit to fruit contact (Xu & Robinson 2000) allowing brown rot to develop during the postharvest period. It is assumed this may be possible for strawberries, increasing the chance of strawberries with no or mild symptoms to be packed for export if they are infected during the packing process.

On stone fruit, brown rot fungi overwinter mainly in or on infected mummified fruit, either attached to the tree or on the ground (Byrde & Willets 1977). Mycelia can survive long periods of adverse environmental conditions within mummified fruits, twigs, cankers and other infected tissues (Byrde & Willets 1977). This suggests that in infected fruit fungi may survive cold storage and transportation processes.

Brown rot fungi have the ability to cause latent infection in fruit, with symptomless infected fruit likely to pass through packing house processes undetected. Brown rot mycelia in infected fruit are likely to survive cold storage and transportation. However, strawberry is not a major host of brown rot fungi and there have been no reports of brown rot fungi affecting strawberries in Korea. This information supports a likelihood estimate for importation of ‘very low’.

Likelihood of distribution

Overall likelihood of entry

The likelihood that Monilinia fructigena and Monilia polystroma will enter Australia as a result of trade in strawberry fruit from Korea and be distributed in a viable state to a susceptible host is: Very low.

4.4.2Likelihood of establishment and spread

Likelihood of establishment High

Likelihood of spread High

4.4.3Overall likelihood of entry, establishment and spread

The overall likelihood that Monilinia fructigena and Monilia polystroma will enter Australia as a result of trade in strawberry fruit from Korea, be distributed in a viable state to a susceptible host, establish in Australia and subsequently spread within Australia is: Very low.

4.4.4Consequences

4.4.5Unrestricted risk estimate

Assessments for quarantine pests for which the likelihood and consequence ratings have been determined in a previous assessment

4.5Spotted wing drosophila

Drosophila suzukii (EP)

Monitoring programs in the northwest of the United States show trap catches in strawberry fields are high and strawberries are a preferred host for D. suzukii (OSU 2010a, b; Peerbolt 2010). In the eastern United States, high larval infestations in strawberries in North Carolina have been reported (Burrack 2010). Damage to commercial strawberries has also been recorded in Europe (EPPO 2010), with 60–100 per cent damage in infested areas (Grassi, Giongo & Palmieri 2011; Grassi & Pallaoro 2012; Süss & Costanzi 2010). Early in the season, when D. suzukii populations are lower and insecticide application more frequent, infestation levels range from 2–10 per cent (Grassi, Giongo & Palmieri 2011; Grassi & Pallaoro 2012).

The risk scenario of concern for Drosophila suzukii is the presence of the larvae and eggs in strawberries.

4.5.1Overall likelihood of entry, establishment and spread

4.5.2Consequences

4.5.3Unrestricted risk estimate

4.6Pest risk assessment conclusions

Genus species (EP): pests for which policy already exists. The outcomes of previous assessments and/or reassessments in this risk analysis are presented in Table 4.6 to 4.8.

Genus species (Acronym for state/territory): state/territory in which regional quarantine pests have been identified

Likelihoods for entry, establishment and spread

N negligible

EL extremely low

VL very low

L low

M moderate

EES overall likelihood of entry, establishment and spread

PLH plant life or health

OE other aspects of the environment

EC eradication, control

DT domestic trade

IT international trade

ENC environmental and non-commercial

AG consequence impact scores are detailed in section 2.2.3

A Indiscernible at the local level

B Minor significance at the local level

C Significant at the local level

D Significant at the district level

E Significant at the regional level

F Significant at the national level

G Major significance at the national level

URE unrestricted risk estimate. This is expressed on an ascending scale from negligible to extreme.