Literature DB >> 35978619

Pest categorisation of Pulvinaria psidii.

Claude Bragard, Paula Baptista, Elisavet Chatzivassiliou, Francesco Di Serio, Paolo Gonthier, Josep Anton Jaques Miret, Annemarie Fejer Justesen, Christer Sven Magnusson, Panagiotis Milonas, Juan A Navas-Cortes, Stephen Parnell, Roel Potting, Philippe Lucien Reignault, Emilio Stefani, Hans-Hermann Thulke, Wopke Van der Werf, Antonio Vicent Civera, Jonathan Yuen, Lucia Zappalà, Jean-Claude Grégoire, Chris Malumphy, Antigoni Akrivou, Virag Kertesz, Andrea Maiorano, Dimitrios Papachristos, Alan MacLeod.   

Abstract

The EFSA Panel on Plant Health performed a pest categorisation of Pulvinaria psidii (Hemiptera: Coccidae), the green shield scale, for the EU. P. psidii was originally described from Hawaii on Psidium sp. and it is now established in many countries in tropical and subtropical regions of the world. Within the EU, the pest has been reported from mainland Spain and the Canary Islands. P. psidii is not listed in Annex II of Commission Implementing Regulation (EU) 2019/2072. It is highly polyphagous, feeding on 230 plant species belonging to more than 70 botanical families with preference for avocado (Persea americana), citrus (Citrus spp.), coffee (Coffea sp.), guava (Psidium guajava), litchi (Litchi chinensis), mango (Mangifera indica), mulberry (Morus sp.) and pomegranate (Punica granatum). It has also been recorded feeding on some solanaceous plants: tomato (Solanum lycopersicum) and pepper (Capsicum annuum), as well as on ornamental plants. Climatic conditions and availability of host plants in southern EU countries would most probably allow this species to successfully establish and spread. Economic impact in cultivated hosts including citrus, mangoes, mulberries, as well as vegetable and ornamental crops is anticipated if establishment occurs. Indeed, P. psidii has already been reported causing damage to Melia azedarach, a widely used ornamental tree that lines streets in Valencia. There is contradictory information regarding impact in mangoes in Spain. This could be due to the relatively recent establishment of the pest. Phytosanitary measures are available to reduce the likelihood of entry and further spread. P. psidii meets the criteria that are within the remit of EFSA to assess for this species to be regarded as a potential Union quarantine pest.
© 2022 Wiley‐VCH Verlag GmbH & Co. KgaA on behalf of the European Food Safety Authority.

Entities:  

Keywords:  Coccidae; Hemiptera; green shield scale; pest risk; plant health; plant pest; quarantine

Year:  2022        PMID: 35978619      PMCID: PMC9372818          DOI: 10.2903/j.efsa.2022.7526

Source DB:  PubMed          Journal:  EFSA J        ISSN: 1831-4732


Introduction

Background and Terms of Reference as provided by the requestor

Background

The new Plant Health Regulation (EU) 2016/2031, on the protective measures against pests of plants, is applying from 14 December 2019. Conditions are laid down in this legislation in order for pests to qualify for listing as Union quarantine pests, protected zone quarantine pests or Union regulated non‐quarantine pests. The lists of the EU regulated pests together with the associated import or internal movement requirements of commodities are included in Commission Implementing Regulation (EU) 2019/2072. Additionally, as stipulated in the Commission Implementing Regulation 2018/2019, certain commodities are provisionally prohibited to enter in the EU (high risk plants, HRP). EFSA is performing the risk assessment of the dossiers submitted by exporting to the EU countries of the HRP commodities, as stipulated in Commission Implementing Regulation 2018/2018. Furthermore, EFSA has evaluated a number of requests from exporting to the EU countries for derogations from specific EU import requirements. In line with the principles of the new plant health law, the European Commission with the Member States are discussing monthly the reports of the interceptions and the outbreaks of pests notified by the Member States. Notifications of an imminent danger from pests that may fulfil the conditions for inclusion in the list of the Union quarantine pest are included. Furthermore, EFSA has been performing horizon scanning of media and literature. As a follow‐up of the above‐mentioned activities (reporting of interceptions and outbreaks, HRP, derogation requests and horizon scanning), a number of pests of concern have been identified. EFSA is requested to provide scientific opinions for these pests, in view of their potential inclusion by the risk manager in the lists of Commission Implementing Regulation (EU) 2019/2072 and the inclusion of specific import requirements for relevant host commodities, when deemed necessary by the risk manager.

Terms of Reference

EFSA is requested, pursuant to Article 29(1) of Regulation (EC) No 178/2002, to provide scientific opinions in the field of plant health. EFSA is requested to deliver 53 pest categorisations for the pests listed in Annex 1A, 1B, 1D and 1E (for more details see mandate M‐2021‐00027 on the Open.EFSA portal). Additionally, EFSA is requested to perform pest categorisations for the pests so far not regulated in the EU, identified as pests potentially associated with a commodity in the commodity risk assessments of the HRP dossiers (Annex 1C; for more details see mandate M‐2021‐00027 on the Open.EFSA portal). Such pest categorisations are needed in the case where there are not available risk assessments for the EU. When the pests of Annex 1A are qualifying as potential Union quarantine pests, EFSA should proceed to phase 2 risk assessment. The opinions should address entry pathways, spread, establishment, impact and include a risk reduction options analysis. Additionally, EFSA is requested to develop further the quantitative methodology currently followed for risk assessment, in order to have the possibility to deliver an express risk assessment methodology. Such methodological development should take into account the EFSA Plant Health Panel Guidance on quantitative pest risk assessment and the experience obtained during its implementation for the Union candidate priority pests and for the likelihood of pest freedom at entry for the commodity risk assessment of High Risk Plants.

Interpretation of the Terms of Reference

Pulvinaria psidii is one of a number of pests listed in Annex 1C to the Terms of Reference (ToRs) to be subject to pest categorisation to determine whether it fulfils the criteria of a potential Union quarantine pest (QP) for the area of the EU excluding Ceuta, Melilla and the outermost regions of Member States referred to in Article 355(1) of the Treaty on the Functioning of the European Union (TFEU), other than Madeira and the Azores, and so inform EU decision‐making as to its appropriateness for potential inclusion in the lists of pests of Commission Implementing Regulation (EU) 2019/ 2072. If a pest fulfils the criteria to be potentially listed as a Union QP, risk reduction options will be identified.

Additional information

This pest categorisation was initiated following the commodity risk assessment of jasmine (Jasminum polyanthum) unrooted cuttings from Israel performed by EFSA PLH Panel (2020), in which P. psidii was identified as a relevant non‐regulated EU pest which could potentially enter the EU on J. polyanthum.

Data and methodologies

Data

Information on pest status from NPPOs

In the context of the current mandate, EFSA is preparing pest categorisations for new/emerging pests that are not yet regulated in the EU. When official pest status is not available in the European and Mediterranean Plant Protection Organization (EPPO) Global Database (EPPO, online), EFSA consults the NPPOs of the relevant MSs. To obtain information on the official pest status for P. psidii, EFSA has consulted the NPPO of Spain. The results of this consultation are presented in Section 3.2.2.

Literature search

A literature search on P. psidii was conducted at the beginning of the categorisation in the ISI Web of Science bibliographic database, using the scientific name of the pest as search term. Papers relevant for the pest categorisation were reviewed, and further references and information were obtained from experts, as well as from citations within the references and grey literature.

Database search

Pest information, on host(s) and distribution, was retrieved from the EPPO Global Database, the CABI databases and scientific literature databases as referred above in Section 2.1.1. Data about the import of commodity types that could potentially provide a pathway for the pest to enter the EU and about the area of hosts grown in the EU were obtained from EUROSTAT (Statistical Office of the European Communities). The Europhyt and TRACES databases were consulted for pest‐specific notifications on interceptions and outbreaks. Europhyt is a web‐based network run by the Directorate General for Health and Food Safety (DG SANTÉ) of the European Commission as a subproject of PHYSAN (Phyto‐Sanitary Controls) specifically concerned with plant health information. TRACES is the European Commission's multilingual online platform for sanitary and phytosanitary certification required for the importation of animals, animal products, food and feed of non‐animal origin and plants into the European Union, and the intra‐EU trade and EU exports of animals and certain animal products. Up until May 2020, the Europhyt database managed notifications of interceptions of plants or plant products that do not comply with EU legislation, as well as notifications of plant pests detected in the territory of the Member States and the phytosanitary measures taken to eradicate or avoid their spread. The recording of interceptions switched from Europhyt to TRACES in May 2020. GenBank was searched to determine whether it contained any nucleotide sequences for Pulvinaria psidii which could be used as reference material for molecular diagnosis. GenBank® (www.ncbi.nlm.nih.gov/genbank/) is a comprehensive publicly available database that as of August 2019 (release version 227) contained over 6.25 trillion base pairs from over 1.6 billion nucleotide sequences for 450,000 formally described species (Sayers et al., 2020).

Methodologies

The Panel performed the pest categorisation for Pulvinaria psidii, following guiding principles and steps presented in the EFSA guidance on quantitative pest risk assessment (EFSA PLH Panel, 2018), the EFSA guidance on the use of the weight of evidence approach in scientific assessments (EFSA Scientific Committee, 2017) and the International Standards for Phytosanitary Measures No. 11 (FAO, 2013). The criteria to be considered when categorising a pest as a potential Union QP is given in Regulation (EU) 2016/2031 Article 3 and Annex I, Section 1 of the Regulation. Table 1 presents the Regulation (EU) 2016/2031 pest categorisation criteria on which the Panel bases its conclusions. In judging whether a criterion is met the Panel uses its best professional judgement (EFSA Scientific Committee, 2017) by integrating a range of evidence from a variety of sources (as presented above in Section 2.1) to reach an informed conclusion as to whether or not a criterion is satisfied.
Table 1

Pest categorisation criteria under evaluation, as derived from Regulation (EU) 2016/2031 on protective measures against pests of plants (the number of the relevant sections of the pest categorisation is shown in brackets in the first column)

Criterion of pest categorisationCriterion in Regulation (EU) 2016/2031 regarding Union quarantine pest (article 3)
Identity of the pest (Section 3.1 ) Is the identity of the pest clearly defined, or has it been shown to produce consistent symptoms and to be transmissible?
Absence/presence of the pest in the EU territory (Section 3.2 ) Is the pest present in the EU territory? If present, is the pest in a limited part of the EU or is it scarce, irregular, isolated or present infrequently? If so, the pest is considered to be not widely distributed.
Pest potential for entry, establishment and spread in the EU territory (Section 3.4 ) Is the pest able to enter into, become established in, and spread within, the EU territory? If yes, briefly list the pathways for entry and spread.
Potential for consequences in the EU territory (Section 3.5 ) Would the pests' introduction have an economic or environmental impact on the EU territory?
Available measures (Section 3.6 ) Are there measures available to prevent pest entry, establishment, spread or impacts?
Conclusion of pest categorisation (Section 4 ) A statement as to whether (1) all criteria assessed by EFSA above for consideration as a potential quarantine pest were met and (2) if not, which one(s) were not met.
Pest categorisation criteria under evaluation, as derived from Regulation (EU) 2016/2031 on protective measures against pests of plants (the number of the relevant sections of the pest categorisation is shown in brackets in the first column) The Panel's conclusions are formulated respecting its remit and particularly with regard to the principle of separation between risk assessment and risk management (EFSA founding regulation (EU) No 178/2002); therefore, instead of determining whether the pest is likely to have an unacceptable impact, deemed to be a risk management decision, the Panel will present a summary of the observed impacts in the areas where the pest occurs, and make a judgement about potential likely impacts in the EU. While the Panel may quote impacts reported from areas where the pest occurs in monetary terms, the Panel will seek to express potential EU impacts in terms of yield and quality losses and not in monetary terms, in agreement with the EFSA guidance on quantitative pest risk assessment (EFSA PLH Panel, 2018). Article 3 (d) of Regulation (EU) 2016/2031 refers to unacceptable social impact as a criterion for QP status. Assessing social impact is outside the remit of the Panel.

Pest categorisation

Identity and biology of the pest

Identity and taxonomy

Is the identity of the pest clearly defined, or has it been shown to produce consistent symptoms and/or to be transmissible? Yes. The identity of the species is established and Pulvinaria psidii (Maskell, 1893) is the accepted scientific name. Pulvinaria psidii (Maskell, 1893) (Figure 1) is a scale insect within the order Hemiptera and the family Coccidae. It is commonly known as green shield scale, guava mealy scale and guava soft scale. It was originally described as Pulvinaria psidii by Maskell (1893) from specimens collected in Hawaii (USA), on Psidium sp. (Germain et al., 2008). Synonyms include Chloropulvinaria psidii, Pulvinaria cupaniae, P. darwiniensis, P. cussoniae, P. gymnosporiae and P. psidii philippina (García Morales et al., 2016 ).
Figure 1

Pulvinaria psidii: (a), teneral adult female (body length 4 mm); (b), mature adult (body length 4.5 mm) female with ovisac (Source: Chris Malumphy)

Pulvinaria psidii: (a), teneral adult female (body length 4 mm); (b), mature adult (body length 4.5 mm) female with ovisac (Source: Chris Malumphy) The EPPO code (Griessinger and Roy, 2015; EPPO, 2019) for this species is: PULVPS (EPPO, online).

Biology of the pest

P. psidii is parthenogenetic and males are unknown (Mau and Kessing, 1992). Hamon and Williams (1984) reported that it takes 2–3 months to complete one life cycle; in Egypt and Taiwan, it has two or three overlapping generations each year (Salama and Saleh, 1970; Bakr et al., 2012, García Morales et al., 2016). Observations in an Egyptian guava orchard suggest that the optimal temperature for development of P. psidii is 26.0–27.3°C, and relative humidity about 72% (Salama and Saleh, 1970; Biosecurity Australia, 2004). On guava, each female lays an average of about 200 eggs (El‐Minshawy and Moursi, 1976; Mohamed et al., 2012), which are protected beneath the body of the female and a waxy ovisac that projects out posteriorly from beneath the female (El‐Minshawy and Moursi, 1976, Mohamed et al., 2012). It has three nymphal instars. Table 2 summarises key features of the biology of each life stage.
Table 2

Important features of the life history strategy of Pulvinaria psidii

Life stagePhenology and relation to hostOther relevant information
EggEggs are deposited in an ovisac on twigs or leaves (Mau and Kessing, 1992). In Egypt, ovisacs appear throughout the year although their numbers are very low from January to April. Peak numbers of ovisacs occur in mid‐June and mid‐September. There can be a later, smaller peak in November or December (Bakr et al., 2012).The formation of the ovisac and egg deposition takes 5 days (Hamon and Williams, 1984).
NymphFirst instar nymphs are known as crawlers. They move to find a suitable place to settle and feed (El‐Minshawy and Moursi, 1976). On guava trees in Egypt, the numbers of nymphs peak in mid‐May and mid‐August (Elwan et al., 2011); further peaks are possible in September or October (Bakr et al., 2012).The nymphal stage lasts from 50 to 70 days (Mau and Kessing, 1992).
AdultIn Egypt, the first generation occurs on guava from early March to early/mid‐August; the second from early May to mid‐November with a peak in mid‐August. There are three overlapping generations on mango trees and ornamental plants (spring, summer, autumn) (Elwan et al., 2011; Bakr et al., 2012)

The duration of the 1st generation is 5–5.5 months (mean Temp: 20.7–21.3°C, RH: 70.7–71.9%). The 2nd generation lasts 6–6.5 months (mean Temp: 24.2–25°C, RH: 69.4–70.4%) (Elwan et al., 2011).

Laboratory experiments revealed that among three constant temperatures tested (18, 24 and 30°C), highest fecundity on guava and mango trees occurred at 30°C and adult life span was 33.4 and 37.1 days respectively (Moustafa and Abd‐Rabou, 2010)

Important features of the life history strategy of Pulvinaria psidii The duration of the 1st generation is 5–5.5 months (mean Temp: 20.7–21.3°C, RH: 70.7–71.9%). The 2nd generation lasts 6–6.5 months (mean Temp: 24.2–25°C, RH: 69.4–70.4%) (Elwan et al., 2011). Laboratory experiments revealed that among three constant temperatures tested (18, 24 and 30°C), highest fecundity on guava and mango trees occurred at 30°C and adult life span was 33.4 and 37.1 days respectively (Moustafa and Abd‐Rabou, 2010)

Host range/species affected

P. psidii is a polyphagous insect which can feed on more than 230 plant species belonging to more than 70 botanical families (Appendix A provides a full host list) with preference for avocado (Persea americana), citrus (Citrus sp.), coffee (Coffea sp.), guava (Psidium guajava), litchi (Litchi chinensis), mango (Mangifera indica), mulberry (Morus sp.) and pomegranate (Punica granatum) (García Morales et al., 2016). P. psidii has also been recorded feeding on Solanaceae such as tomato (Solanum lycopersicum) and pepper (Capsicum annuum), and ornamental plants such as Anthurium sp., Camellia sp., Ficus sp., Gardenia sp., Jasminum sp. and Nerium oleander (García Morales et al., 2016).

Intraspecific diversity

No intraspecific diversity has been reported for P. psidii.

Detection and identification of the pest

Are detection and identification methods available for the pest? Yes, visual detection is possible, and morphological and molecular identification methods are available.

Detection

Careful visual examination of plants and fruits is an effective way for the detection of P. psidii. Accumulation of honeydew, sooty mould and honeydew‐seeking ants are general signs of phloem feeding insect infestations; they can be used to pinpoint the areas where plants may be inspected for the presence of soft scales (Camacho and Chong, 2015). P. psidii occurs on leaves and small young stems (Hamon and Williams, 1984) but quickly colonises flower panicles, and then fruits when they appear on the tree (Biosecurity New Zealand, 2008). P. psidii scales produce a mass of eggs in a cottony ovisac which is relatively easy to detect (EFSA PLH Panel, 2020). Double‐sided sticky tape around stems can also be used to monitor the crawlers (Bethke and Wilen, 2010).

Symptoms

According to Swirski et al. (1997), Bakr et al. (2009), Koul and Taak (2017), EFSA PLH Panel (2021) the main symptoms of P. psidii infestation are: large quantities of honeydew egested by the scales; black sooty mould growing on the honeydew; fruit discoloration; plants covered with flocculent white egg sacs attached to the body of the female; leaf curling; heavy infestation causes yellowing, defoliation, reduction in fruit set and loss in plant vigour. With the exception of the white ovisacs, these symptoms are similar to those caused by many other phloem‐feeding insects and should not be considered as diagnostic.

Identification

The identification of P. psidii requires microscopic examination of slide‐mounted adults and verification of the presence of key morphological characteristics. Detailed morphological descriptions, illustrations, and keys of adult P. psidii and other species of the family Coccidae can be found in Qin (1989), Qin and Gullan (1992) and Tanaka and Kamitani (2020). Molecular techniques based on the nucleotide sequences of the mitochondrial cytochrome c oxidase subunit I (COI) gene (barcoding region) and 28S rDNA have been developed for species identification (Wang et al., 2015). GenBank contains gene nucleotide sequences for P. psidii.

Description

Qin and Gullan (1992) describe all the developmental stages of P. psidii. The egg of P. psidii is pale green, oval and measures 0.22 × 0.17 mm. Eggs are embedded in the cottony matter of the ovisac. The ovisac is white, and projects posteriorly at first but eventually more or less surrounds the insect and measures 4–7 mm long (El‐Minshawy and Moursi, 1976). First instar nymphs (crawlers) are covered with a few spiral wax filaments (Beshr et al., 2009). Second instar nymphs are elongate about 0.83 mm wide and characterised by having an eight‐segmented antenna which is about 0.16 mm in length (El‐Minshawy and Moursi, 1976). Older instars are flat and green (Nafus, 1996). The body of the adult female is oval, relatively convex in cross‐section, up to 4.5 mm long. The body of young females is green, becoming darker as they mature, and completely brown after oviposition, with fluffy white wax covering the dorsum at the time of oviposition. The ovisac produced beneath and behind the female, it is slightly convex (Miller et al., 2014). Further detailed description is available in Henderson and Crosby (2011).

Pest distribution

Pest distribution outside the EU

P. psidii occurs in southeast Asia, North, Central and South America, including the Antilles, Africa and Oceania (Clausen, 1978; Williams & Williams, 1988; García Morales et al., 2016; CABI, online) (Figure 2). For a detailed list of countries where P. psidii is present, see Appendix B.
Figure 2

Global distribution of Pulvinaria psidii (data source: García Morales et al., 2016; CABI, online)

Global distribution of Pulvinaria psidii (data source: García Morales et al., 2016; CABI, online) Records from Missouri and north‐east USA may be from findings in greenhouses or other protected environments. García Morales et al. (2016) report P. psidii as present in the UK based on a finding in a greenhouse in the 1920s (Green, 1928). However, it has not been found again and is considered not to be present in the UK.

Pest distribution in the EU

Is the pest present in the EU territory? If present, is the pest in a limited part of the EU or is it scarce, irregular, isolated or present infrequently? If so, the pest is considered to be not widely distributed. Yes. P. psidii has been recorded in Spain in the city of Valencia and in Andalusia. In Spain, the pest has been detected in the Canary Islands (Gómez‐Menor Guerrero, 1967; Jaques and Urbaneja, 2006), which are not part of the pest risk assessment area, and in mainland Spain (Boyero et al., 2017; Rodrigo et al., 2020; Del Pino et al., 2021a,b). The Spanish NPPO confirmed its presence in Spain (Table 3) on ornamental plants in the city of Valencia and in Andalusia, where it was also found on mangoes. No formal action has been taken.
Table 3

Status of Pulvinaria psidii in Spain according to the information received from the NPPO

Autonomous communityInformation from NPPO regarding P. psidii
Canary IslandsDetected on the island of Tenerife. The last record of this species is from 1986 and since that date there is no knowledge of it. We cannot consider that it is established. No phytosanitary measures are applied.
ValenciaDetected in the city of Valencia in municipally owned gardens. No measures are applied.
AndalusiaThis harmful organism was notified on 19/2/2018 being detected in the mango crop. In this Service there is no evidence that it is giving problems in the cultivation of mango. No formal action has been taken.
Status of Pulvinaria psidii in Spain according to the information received from the NPPO CABI distribution maps indicate the presence of P. psidii in Germany (likely an invalid record, perhaps based on an interception). It has also been intercepted in USA ports between 1995 and 2012 in commodities from France and the Netherlands (Miller et al., 2014). However, there are no records of P. psidii being found in France or the Netherlands. Such US interceptions likely result from plant products being imported to France and the Netherlands from areas where the pest occurs and re‐exported to the USA. Recent comprehensive checklists (Foldi and Germain, 2018) of Coccoidea of France do not mention P. psidii. Jansen (2000) reports P. psidii has only been found in the Netherlands during import inspections.

Regulatory status

Commission implementing regulation 2019/2072

P. psidii is not listed in Annex II of Commission Implementing Regulation (EU) 2019/2072, an implementing act of Regulation (EU) 2016/2031. However, the species is included in the list of pests that are regulated by the Commission Implementing Regulation (EU) 2021/419 as regards certain plants for planting of Jasminum polyanthum Franchet originating in Israel and Commission Implementing Regulation (EU) 2021/1936 as regards certain plants for planting of Ficus carica L. and Persea americana Mill. originating in Israel.

Hosts or species affected that are prohibited from entering the Union from third countries

According to the Commission Implementing Regulation (EU) 2019/2072, Annex VI, introduction of several P. psidii hosts in the Union from certain third countries is prohibited (Table 4).
Table 4

List of plants, plant products and other objects that are Pulvinaria psidii hosts whose introduction into the Union from certain third countries is prohibited (Source: Commission Implementing Regulation (EU) 2019/2072, Annex VI)

List of plants, plant products and other objects whose introduction into the Union from certain third countries is prohibited
DescriptionCN CodeThird country, group of third countries or specific area of third country
8.Plants for planting of Chaenomeles Ldl., Crateagus L., Cydonia Mill., Malus Mill., Prunus L., Pyrus L. and Rosa L., other than dormant plants free from leaves, flowers and fruits

ex 0602 10 90

ex 0602 20 80

ex 0602 40 00

ex 0602 90 41

ex 0602 90 45

ex 0602 90 46

ex 0602 90 47

ex 0602 90 48

ex 0602 90 50

ex 0602 90 70

ex 0602 90 91

ex 0602 90 99

Third countries other than:

Albania, Andorra, Armenia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canary Islands, Faeroe Islands, Georgia, Iceland, Liechtenstein, Moldova, Monaco, Montenegro, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Turkey, Ukraine and the United Kingdom.

9.Plants for planting of Cydonia Mill., Malus Mill., Prunus L. and Pyrus L. and their hybrids, and Fragaria L., other than seeds

ex 0602 10 90

ex 0602 20 20

ex 0602 90 30

ex 0602 90 41

ex 0602 90 45

ex 0602 90 46

ex 0602 90 48

ex 0602 90 50

ex 0602 90 70

ex 0602 90 91

ex 0602 90 99

Third countries, other than:

Albania, Algeria, Andorra, Armenia, Australia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canada, Canary Islands, Egypt, Faeroe Islands, Georgia, Iceland, Israel, Jordan, Lebanon, Libya, Liechtenstein, Moldova, Monaco, Montenegro, Morocco, New Zealand, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Syria, Tunisia, Turkey, Ukraine, the United Kingdom and United States other than Hawaii

11.Plants of Citrus L., Fortunella Swingle, Poncirus Raf., and their hybrids, other than fruits and seeds

ex 0602 10 90

ex 0602 20 20

0602 20 30

ex 0602 20 80

ex 0602 90 45

ex 0602 90 46

ex 0602 90 47

ex 0602 90 50

ex 0602 90 70

ex 0602 90 91

ex 0602 90 99

ex 0604 20 90

ex 1404 90 00

All third countries
12.Plants for planting of Photinia Ldl., other than dormant plants free from leaves, flowers and fruits

ex 0602 10 90

ex 0602 90 41

ex 0602 90 45

ex 0602 90 46

ex 0602 90 47

ex 0602 90 48

ex 0602 90 50

ex 0602 90 70

ex 0602 90 91

ex 0602 90 99

China, Democratic People's Republic of Korea, Japan, Republic of Korea and United States
18.Plants for planting of Solanaceae other than seeds and the plants covered by entries 15, 16 or 17

ex 0602 10 90

ex 0602 90 30

ex 0602 90 45

ex 0602 90 46

ex 0602 90 48

ex 0602 90 50

ex 0602 90 70

ex 0602 90 91

ex 0602 90 99

Third countries other than:

Albania, Algeria, Andorra, Armenia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canary Islands, Egypt, Faeroe Islands, Georgia, Iceland, Israel, Jordan, Lebanon, Libya, Liechtenstein, Moldova, Monaco, Montenegro, Morocco, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Syria, Tunisia, Turkey, Ukraine and the United Kingdom

List of plants, plant products and other objects that are Pulvinaria psidii hosts whose introduction into the Union from certain third countries is prohibited (Source: Commission Implementing Regulation (EU) 2019/2072, Annex VI) ex 0602 10 90 ex 0602 20 80 ex 0602 40 00 ex 0602 90 41 ex 0602 90 45 ex 0602 90 46 ex 0602 90 47 ex 0602 90 48 ex 0602 90 50 ex 0602 90 70 ex 0602 90 91 ex 0602 90 99 Third countries other than: Albania, Andorra, Armenia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canary Islands, Faeroe Islands, Georgia, Iceland, Liechtenstein, Moldova, Monaco, Montenegro, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Turkey, Ukraine and the United Kingdom. ex 0602 10 90 ex 0602 20 20 ex 0602 90 30 ex 0602 90 41 ex 0602 90 45 ex 0602 90 46 ex 0602 90 48 ex 0602 90 50 ex 0602 90 70 ex 0602 90 91 ex 0602 90 99 Third countries, other than: Albania, Algeria, Andorra, Armenia, Australia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canada, Canary Islands, Egypt, Faeroe Islands, Georgia, Iceland, Israel, Jordan, Lebanon, Libya, Liechtenstein, Moldova, Monaco, Montenegro, Morocco, New Zealand, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Syria, Tunisia, Turkey, Ukraine, the United Kingdom and United States other than Hawaii ex 0602 10 90 ex 0602 20 20 0602 20 30 ex 0602 20 80 ex 0602 90 45 ex 0602 90 46 ex 0602 90 47 ex 0602 90 50 ex 0602 90 70 ex 0602 90 91 ex 0602 90 99 ex 0604 20 90 ex 1404 90 00 ex 0602 10 90 ex 0602 90 41 ex 0602 90 45 ex 0602 90 46 ex 0602 90 47 ex 0602 90 48 ex 0602 90 50 ex 0602 90 70 ex 0602 90 91 ex 0602 90 99 ex 0602 10 90 ex 0602 90 30 ex 0602 90 45 ex 0602 90 46 ex 0602 90 48 ex 0602 90 50 ex 0602 90 70 ex 0602 90 91 ex 0602 90 99 Third countries other than: Albania, Algeria, Andorra, Armenia, Azerbaijan, Belarus, Bosnia and Herzegovina, Canary Islands, Egypt, Faeroe Islands, Georgia, Iceland, Israel, Jordan, Lebanon, Libya, Liechtenstein, Moldova, Monaco, Montenegro, Morocco, North Macedonia, Norway, Russia (only the following parts: Central Federal District (Tsentralny federalny okrug), Northwestern Federal District (Severo‐Zapadny federalny okrug), Southern Federal District (Yuzhny federalny okrug), North Caucasian Federal District (Severo‐Kavkazsky federalny okrug) and Volga Federal District (Privolzhsky federalny okrug)), San Marino, Serbia, Switzerland, Syria, Tunisia, Turkey, Ukraine and the United Kingdom Plants for planting of Annona L., Diospyros L., Ficus L., Jasminum L., Nerium L., Persea Mill., Prunus L., and Salix L., which are hosts of P. psidii (Appendix A) are considered High Risk Plants for the EU and their import is prohibited pending risk assessment (EU 2018/2019).

Entry, establishment and spread in the EU

Entry

Is the pest able to enter into the EU territory? If yes, identify and list the pathways. Yes, the pest has already entered the EU territory. It could further enter the EU territory with plants for planting, cut flowers, vegetables and fruits. Comment on plants for planting as a pathway. Plants for planting are one of the main pathways for P. psidii to enter the EU (Table 5).
Table 5

Potential pathways for Pulvinaria psidii into the EU 27

PathwaysLife stageRelevant mitigations [e.g. prohibitions (Annex VI), special requirements (Annex VII) or phytosanitary certificates (Annex XI) within Implementing Regulation 2019/2072, Commission Implementing Regulation (EU) 2021/419, Commission Implementing Regulation (EU) 2021/1936]
Plants for plantingAll life stages

Plants for planting that are hosts of P. psidii and are prohibited to import from third countries (Regulation 2019/2072, Annex VI), are listed in Table 4.

Plants for planting from third countries require a phytosanitary certificate (Regulation 2019/2072, Annex XI, Part A).

Some hosts are considered high risk plants (EU 2018/2019) for the EU and their import is prohibited subject to risk assessment

Fruits, vegetables and cut flowersAll life stagesFruits, vegetables and cut flowers from third countries require a phytosanitary certificate to be imported into the EU (2019/2072, Annex XI, Part A). However, no requirements are specified for P. psidii.
Potential pathways for Pulvinaria psidii into the EU 27 Plants for planting that are hosts of P. psidii and are prohibited to import from third countries (Regulation 2019/2072, Annex VI), are listed in Table 4. Plants for planting from third countries require a phytosanitary certificate (Regulation 2019/2072, Annex XI, Part A). Some hosts are considered high risk plants (EU 2018/2019) for the EU and their import is prohibited subject to risk assessment Plants for planting and fruits, vegetables and cut flowers are the main potential pathways for entry of P. psidii (Table 5). Annual imports of P. psidii hosts from countries where the pest is known to occur are provided in Appendix C. Notifications of interceptions of harmful organisms began to be compiled in Europhyt in May 1994 and in TRACES in May 2020. As at 25/02/2022, there were no records of interception of P. psidii in the Europhyt and TRACES databases. Miller et al. (2014) reports that P. psidii was intercepted 142 times between 1995 and 2012 on a variety of hosts at USA ports of entry with specimens originating from Australia, Barbados, Cambodia, Cook Islands, Costa Rica, Cuba, Egypt, France, Grenada, Guam, Guatemala, Hawaii, Honduras, India, Indonesia, Jamaica, Laos, Lebanon, Mexico, the Netherlands, Panama, the Philippines, Puerto Rico, Singapore, South Korea, Sri Lanka, Taiwan, Thailand, Tonga and Vietnam. Miller et al. (2014) goes on to list countries and the host plants on which P. psidii has been found as interceptions by the USA (Appendix D). As noted in Section 3.2.2, there are no reports of P. psidii being found in France or the Netherlands. Records reported as interceptions on plants originating from France and the Netherlands by Miller et al. (2014) are likely to be the result of infested plant products being imported to France and the Netherlands from areas where the pest occurs and then being re‐exported to the USA. In Australia, between 2000 and 2018, P. psidii was intercepted six times on Nephelium lappaceum and Catha edulis leaves (DAWE, 2021).

Establishment

Is the pest able to become established in the EU territory? Yes, the climate in the EU countries of southern Europe is suitable and there are many available hosts that can support establishment.

EU distribution of main host plants

P. psidii is a polyphagous pest. The main hosts of the pest cultivated in the EU between 2016 and 2020 are shown in Table 6. Among others, citrus, mangoes, avocados, tomatoes, peppers and ornamental plants are important crops in the EU.
Table 6

Crop area of Pulvinaria psidii key hosts in EU in 1,000 ha (Eurostat accessed on 16/2/2022)

Crop20162017201820192020
Citrus519.01502.84508.99512.83519.98
Tomatoes253.95247.95239.48242.52233.20
Peppers59.9559.5058.9259.6058.27
Avocados12.2412.7213.2217.5019.60

Statistics refer to EU 27.

Crop area of Pulvinaria psidii key hosts in EU in 1,000 ha (Eurostat accessed on 16/2/2022) Statistics refer to EU 27.

Climatic conditions affecting establishment

P. psidii occurs mainly in tropical and subtropical regions in Asia, Africa, Australia, America and Macaronesia (Canary Islands). Moreover, in Europe it has been recorded in Spain in regions with a Mediterranean climate. Figure 3 shows the world distribution of Köppen–Geiger climate types (Kottek et al., 2006) that occur in the EU and which occur in countries where P. psidii has been reported.
Figure 3

World distribution of Köppen—Geiger climate types that occur in the EU and which occur in countries where Pulvinaria psidii has been reported

World distribution of Köppen—Geiger climate types that occur in the EU and which occur in countries where Pulvinaria psidii has been reported Southern EU countries provide suitable climatic conditions for the establishment of P. psidii. Indeed, it is already established in a small area of mainland Spain. There is uncertainty as to whether P. psidii could establish in outdoors in central Europe. Establishment outdoors in Northern Europe is unlikely. Nevertheless, there is a possibility that P. psidii could occur in glasshouses and on indoor plantings in cooler areas.

Spread

Describe how the pest would be able to spread within the EU territory following establishment? Natural spread by first instar nymphs crawling or being carried by wind, other animals, or machinery, will occur locally and relatively slowly. All stages may be moved over long distances in trade of infested plant materials, specifically plants for planting, fruits, vegetables and cut flowers. Comment on plants for planting as a mechanism of spread. Plants for planting provide a main spread mechanism for P. psidii over long distances. First instar nymphs (crawlers) may be carried to neighbouring plants by their own movement, wind (Bakr et al., 2012) or by hitchhiking on clothing, equipment or animals (EFSA PLH Panel, 2020). Plants for planting, fruits, vegetables and cut flowers are the main pathways of spread of P. psidii over long distances.

Impacts

Would the pests' introduction have an economic or environmental impact on the EU territory? Yes, if P. psidii established more widely in the EU, it would most probably have an economic impact. P. psidii sucks phloem sap from leaves and thin‐barked shoots. When abundant it egests large amounts of honeydew on which blackish sooty mould grows, covering the leaf and fruit surfaces, causing foliage drop and making fruits unmarketable (Mau and Kessing, 1992; Mohamed et al., 2012). In south Florida, P. psidii caused damage to ornamental plants, especially Ficus sp. during the warmer months (Hamon and Williams, 1984). In Egypt it is a pest of citrus, mango, guava, and ornamentals such as Ficus and Aralia (Bakr et al., 2012; García Morales et al., 2016; EFSA PLH Panel, 2021). Concerning guava, P. psidii is reported as one of the most important pests (El‐Serafi et al., 2004; Moustafa and Abd‐Rabou, 2010). In Pakistan it is a serious pest of mango (Mohyuddin and Mahmood, 1993) while in Bangladesh it has become an increasingly serious pest of guava and citrus (Bhuiya, 1998). In the tropical South Pacific region P. psidii is a serious pest of Citrus, Coffea, Capsicum and Ficus plants (Bhuiya, 1998). In Hawaii, in 1892, coffee plants were almost totally destroyed (Pemberton, 1964). In Israel, P. psidii is reported mainly in litchi and mango and on ornamental plants (EPPO, online). It is an insect of economic interest present in natural ecosystems of the Sierra de los Órganos in Mexico (Novoa et al., 2011). P. psidii was detected on mango crops in Andalusia in summer 2017 (MAPA, 2021). An official response from the NPPO notes that there is no evidence that it is giving problems in the cultivation of mango. However, MAPA (2021) reports P. psidii occasionally causing damage in mango, litchi and ornamental ficus only when densities are high. Moreover, Del Pino et al. (2021a) report that densities of P. psidii are increasing and the scale is becoming an important pest of mango. These differences in appreciation give rise to uncertainty regarding impact in mango, taking into account that the pest has been introduced only recently. Rodrigo et al. (2020) indicate that P. psidii is causing damage to Melia azedarach, a widely used ornamental tree that lines streets in Valencia; large amounts of dripping honeydew is a nuisance to the public.

Available measures and their limitations

Are there measures available to prevent pest entry, establishment, spread or impacts such that the risk becomes mitigated? Yes. Although the existing phytosanitary measures identified in Section 3.3.2 do not specifically target P. psidii, they mitigate the likelihood of its entry into, establishment and spread within the EU (see also Section 3.6.1).

Identification of potential additional measures

Phytosanitary measures (prohibitions) are currently applied to some host plants for planting (see Section 3.3.2). Additional potential risk reduction options and supporting measures are shown in Sections 3.6.1.1 and 3.6.1.2.

Additional potential risk reduction options

Potential additional control measures are listed in Table 7.
Table 7

Selected control measures (a full list is available in EFSA PLH Panel, 2018) for pest entry/establishment/spread/impact in relation to currently unregulated hosts and pathways. Control measures are measures that have a direct effect on pest abundance

Control measure/Risk reduction option ((Blue underline = Zenodo doc, Blue = WIP) RRO summaryRisk element targeted (entry/establishment/spread/impact)
Require pest freedomPest free place of production (e.g. place of production and its immediate vicinity is free from pest over an appropriate time period, e.g. since the beginning of the last complete cycle of vegetation, or past 2 or 3 cycles). Pest free production site.Entry/Spread
Growing plants in isolation Place of production is insect proof originate in a place of production with complete physical isolation.Entry/Spread
Managed growing conditionsUsed to mitigate likelihood of infestation at origin. Plants collected directly from natural habitats, have been grown, held and trained for at least two consecutive years prior to dispatch in officially registered nurseries, which are subject to an officially supervised control regime.Entry/Spread
Biological control and behavioural manipulation

Biological control is successfully implemented worldwide against P. psidii, by predators and parasitoids. Cryptolaemus montrouzieri is an effective predator of P. psidii on guava, sapota, lemon, and coffee plants (Pemberton, 1964; Mani, 2016), it is commercially available in the EU. The parasitoids Microterys kotinskyi and Coccophagus scutellaris (also available in the EU) have been reported as effective biological agents in Bermuda, Egypt, India and other countries (Mani et al., 2009; Abd‐Rabou, 2011; Mani, 2016).

The efficacy of a formulation of Beauveria bassiana (bioinsecticide) was tested in different pest stages in guava field trials (Bakr et al., 2012)

Spread/Impact
Chemical treatments on crops including reproductive material Used to mitigate likelihood of infestation of pests susceptible to chemical treatments. The effectiveness of insecticide applications against soft scales may be reduced by the waxy coating of the adult. The efficacy of mineral oils, insect growth regulators and organophosphorus insecticides was tested in different pest stages in guava field trials (Bakr et al., 2012; Helmy et al., 2012).Entry/Establishment / Spread/Impact
Chemical treatments on consignments or during processing Treatments can be applied to plants or to plant products after harvest, during process or packaging operations and storage. e.g. fumigation; spraying/dipping pesticides; surface disinfectants.Entry/Spread
Cleaning and disinfection of facilities, tools and machinery The physical and chemical cleaning and disinfection of facilities, tools, machinery, facilities and other accessories (e.g. boxes, pots, hand tools).Spread
Heat and cold treatments Controlled temperature treatments aimed to kill or inactivate pests without causing any unacceptable prejudice to the treated material itself.Entry/Spread
Controlled atmosphere

Treatment of plants by storage in a modified atmosphere (including modified humidity, O2, CO2, temperature, pressure).

Used to mitigate likelihood of infestation of pests susceptible to modified atmosphere (usually applied during transport) hence to mitigate entry.

Controlled atmosphere storage can be used in commodities such as fresh and dried fruits.

Entry/Spread (via commodity)
Selected control measures (a full list is available in EFSA PLH Panel, 2018) for pest entry/establishment/spread/impact in relation to currently unregulated hosts and pathways. Control measures are measures that have a direct effect on pest abundance Biological control is successfully implemented worldwide against P. psidii, by predators and parasitoids. Cryptolaemus montrouzieri is an effective predator of P. psidii on guava, sapota, lemon, and coffee plants (Pemberton, 1964; Mani, 2016), it is commercially available in the EU. The parasitoids Microterys kotinskyi and Coccophagus scutellaris (also available in the EU) have been reported as effective biological agents in Bermuda, Egypt, India and other countries (Mani et al., 2009; Abd‐Rabou, 2011; Mani, 2016). The efficacy of a formulation of Beauveria bassiana (bioinsecticide) was tested in different pest stages in guava field trials (Bakr et al., 2012) Treatment of plants by storage in a modified atmosphere (including modified humidity, O2, CO2, temperature, pressure). Used to mitigate likelihood of infestation of pests susceptible to modified atmosphere (usually applied during transport) hence to mitigate entry. Controlled atmosphere storage can be used in commodities such as fresh and dried fruits.

Additional supporting measures

Potential additional supporting measures are listed in Table 8.
Table 8

Selected supporting measures (a full list is available in EFSA PLH Panel, 2018) in relation to currently unregulated hosts and pathways. Supporting measures are organisational measures or procedures supporting the choice of appropriate risk reduction options that do not directly affect pest abundance

Supporting measure ((Blue underline = Zenodo doc, Blue = WIP) SummaryRisk element targeted (entry/establishment/spread/impact)
Inspection and trapping

Inspection is defined as the official visual examination of plants, plant products or other regulated articles to determine if pests are present or to determine compliance with phytosanitary regulations (ISPM 5).

The effectiveness of sampling and subsequent inspection to detect pests may be enhanced by including trapping and luring techniques.

Entry/Spread/Impact
Laboratory testing Examination, other than visual, to determine if pests are present using official diagnostic protocols. Diagnostic protocols describe the minimum requirements for reliable diagnosis of regulated pests.Entry/Spread
Sampling According to ISPM 31, it is usually not feasible to inspect entire consignments, so phytosanitary inspection is performed mainly on samples obtained from a consignment. It is noted that the sampling concepts presented in this standard may also apply to other phytosanitary procedures, notably selection of units for testing.Entry
Phytosanitary certificate and plant passport

An official paper document or its official electronic equivalent, consistent with the model certificates of the IPPC, attesting that a consignment meets phytosanitary import requirements (ISPM 5)

(a) export certificate (import)

(b) plant passport (EU internal trade)

Entry/Spread
Certified and approved premises Mandatory/voluntary certification/approval of premises is a process including a set of procedures and of actions implemented by producers, conditioners and traders contributing to ensure the phytosanitary compliance of consignments. It can be a part of a larger system maintained by the NPPO in order to guarantee the fulfilment of plant health requirements of plants and plant products intended for trade. Key property of certified or approved premises is the traceability of activities and tasks (and their components) inherent the pursued phytosanitary objective. Traceability aims to provide access to all trustful pieces of information that may help to prove the compliance of consignments with phytosanitary requirements of importing countries.Entry/Spread
Certification of reproductive material (voluntary/official) Plants come from within an approved propagation scheme and are certified pest free (level of infestation) following testing; Used to mitigate against pests that are included in a certification schemeEntry/Spread
Delimitation of Buffer zones ISPM 5 defines a buffer zone as “an area surrounding or adjacent to an area officially delimited for phytosanitary purposes in order to minimise the probability of spread of the target pest into or out of the delimited area, and subject to phytosanitary or other control measures, if appropriate” (ISPM 5). The objectives for delimiting a buffer zone can be to prevent spread from the outbreak area and to maintain a pest free production place (PFPP), site (PFPS) or area (PFA).Spread
Surveillance Surveillance to guarantee that plants and produce originate from a pest free area could be an option.Spread
Selected supporting measures (a full list is available in EFSA PLH Panel, 2018) in relation to currently unregulated hosts and pathways. Supporting measures are organisational measures or procedures supporting the choice of appropriate risk reduction options that do not directly affect pest abundance Inspection is defined as the official visual examination of plants, plant products or other regulated articles to determine if pests are present or to determine compliance with phytosanitary regulations (ISPM 5). The effectiveness of sampling and subsequent inspection to detect pests may be enhanced by including trapping and luring techniques. An official paper document or its official electronic equivalent, consistent with the model certificates of the IPPC, attesting that a consignment meets phytosanitary import requirements (ISPM 5) (a) export certificate (import) (b) plant passport (EU internal trade)

Biological or technical factors limiting the effectiveness of measures

P. psidii may not be easily detected in cases where low densities occur. P. psidii is polyphagous, making the inspections of all consignments containing hosts from countries where the pest occurs difficult. Limited number of available registered active substances against P. psidii. Limited effectiveness of insecticides due to the presence of protective cover over the scales.

Uncertainty

The main source of uncertainty regards the magnitude of potential impact within the EU. There is contradictory information regarding the impact of P. psidii in mango in Spain.

Conclusions

Pulvinaria psidii satisfies all the criteria that are within the remit of EFSA to assess for it to be regarded as a potential Union QP (Table 9).
Table 9

The Panel's conclusions on the pest categorisation criteria defined in Regulation (EU) 2016/2031 on protective measures against pests of plants (the number of the relevant sections of the pest categorisation is shown in brackets in the first column)

Criterion of pest categorisationPanel's conclusions against criterion in Regulation (EU) 2016/2031 regarding Union quarantine pestKey uncertainties

Identity of the pest

(Section 3.1 )

The identity of Pulvinaria psidii is established. Taxonomic keys based on morphology of adults exist. There are also molecular techniques for species identification.None
Absence/presence of the pest in the EU (Section 3.2 ) The pest has a restricted distribution in the EU territory (mainland Spain: the city of Valencia, and Andalusia).None

Pest potential for entry, establishment and spread in the EU

(Section 3.4 )

P. psidii is able to further enter, become established and spread within the EU territory, especially in the southern EU MS. The main pathways are plants for planting, cut flowers, fruits, and vegetables.None

Potential for consequences in the EU

(Section 3.5 )

The introduction of the pest could cause yield and quality losses on several crops and reduce the value of ornamental plants.There is contradictory information regarding the impact of the pest on mangoes in Spain.

Available measures

(Section 3.6 )

There are measures available to prevent further entry, establishment and spread of P. psidii within the EU. Risk reduction options include inspections, chemical and physical treatments on consignments of fresh plant material from infested countries and the production of plants for import in the EU in pest free areas.None

Conclusion

(Section 4 )

P. psidii satisfies all the criteria that are within the remit of EFSA to assess for it to be regarded as a potential Union quarantine pest.
Aspects of assessment to focus on/scenarios to address in future if appropriate
The Panel's conclusions on the pest categorisation criteria defined in Regulation (EU) 2016/2031 on protective measures against pests of plants (the number of the relevant sections of the pest categorisation is shown in brackets in the first column) Identity of the pest (Section ) Pest potential for entry, establishment and spread in the EU (Section ) Potential for consequences in the EU (Section ) Available measures (Section ) Conclusion (Section ) Application of phytosanitary measures in and around an infested area to prevent spread of a pest (FAO, 2018) Suppression, containment or eradication of a pest population (FAO, 2018) Movement of a pest into an area where it is not yet present, or present but not widely distributed and being officially controlled (FAO, 2018) Application of phytosanitary measures to eliminate a pest from an area (FAO, 2018) Perpetuation, for the foreseeable future, of a pest within an area after entry (FAO, 2018) A walk‐in, static, closed place of crop production with a usually translucent outer shell, which allows controlled exchange of material and energy with the surroundings and prevents release of plant protection products (PPPs) into the environment. An organism sheltering or transported accidentally via inanimate pathways including with machinery, shipping containers and vehicles; such organisms are also known as contaminating pests or stowaways (Toy and Newfield, 2010). The impact of the pest on the crop output and quality and on the environment in the occupied spatial units The entry of a pest resulting in its establishment (FAO, 2018) Any means that allows the entry or spread of a pest (FAO, 2018) Any legislation, regulation or official procedure having the purpose to prevent the introduction or spread of quarantine pests, or to limit the economic impact of regulated non‐quarantine pests (FAO, 2018) A pest of potential economic importance to the area endangered thereby and not yet present there, or present but not widely distributed and being officially controlled (FAO, 2018) A measure acting on pest introduction and/or pest spread and/or the magnitude of the biological impact of the pest should the pest be present. A RRO may become a phytosanitary measure, action or procedure according to the decision of the risk manager Expansion of the geographical distribution of a pest within an area (FAO, 2018) European and Mediterranean Plant Protection Organization Food and Agriculture Organization International Plant Protection Convention International Standards for Phytosanitary Measures Member State EFSA Panel on Plant Health Protected Zone Treaty on the Functioning of the European Union Terms of Reference

Appendix A – Pulvinaria psidii host plants/species affected

Source: CABI (online, accessed on 16/2/2022), and García Morales et al. (2016). Common names derived from EPPO (online, accessed on 16/2/2022).

Appendix B – Distribution of Pulvinaria psidii

Distribution records based on CABI (online, accessed on 16/2/2022), and García Morales et al. (2016), and other references. Present, no details Valencia, Andalusia

Appendix C – Import data

Tables C.1, C.2, C.3, C.4, C.5–C.1, C.2, C.3, C.4, C.5.
Table C.1

Fresh or dried citrus (CN code: 0805) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Country201620172018201920202021
Afghanistan7.00
Angola43.00
Antigua and Barbuda20.00
Australia3,280.001,284.00645.0010,645.002,343.004,097.00
Bangladesh228.00230.00160.00322.001,184.00289.00
Brazil864,863.00903,433.00900,907.00822,134.00902,590.001,058,807.00
China827,841.001,084,857.001,024,163.001,108,595.001,098,690.00646,652.00
Colombia44,825.0079,401.00123,887.00136,915.00172,198.00194,963.00
Congo, Democratic Republic of2.00
Costa Rica4,700.00921.00705.00231.00462.0035.00
Cuba7,166.003,864.004,438.003,422.00556.0019.00
Dominican Republic11,179.009,337.0010,427.007,355.0012,887.0012,780.00
Ecuador949.002,127.00730.001,115.00127.002,313.00
Egypt1,931,587.002,246,999.002,643,272.002,206,933.002,850,746.003,398,717.00
Ghana280.00348.00100.00262.00
Guatemala11,409.0017,178.0027,057.0011,816.0017,814.008,481.00
Guyana24.00
Haiti207.00177.0072.0031.00248.00337.00
India247.001.00450.0089.00255.0022.00
Indonesia567.00556.00779.00837.00865.00873.00
Israel799,118.00969,404.00824,602.00812,739.00878,713.00780,426.00
Jamaica3,634.003,325.00676.002,410.001,647.002,442.00
Japan353.00417.00271.00319.00162.00184.00
Kenya9.0035.000.00
Lao People's Democratic Republic (Laos)52.002.0020.001.00
Madagascar3.0026.0012.007.0022.002.00
Malaysia4.0039.0083.008.00
Mexico570,403.00553,819.00589,021.00443,744.00349,649.00184,532.00
Nepal1,170.001.00
New Zealand0.0013.00205.00355.000.000.00
Nigeria0.000.00200.00
Pakistan2.001.00272.00
Philippines0.008.000.00
South Africa5,278,831.005,802,018.006,381,125.006,196,838.007,830,148.007,941,164.00
Taiwan157.000.00
Tanzania, United Republic of180.00190.00144.0036.0076.00132.00
Thailand426.001,283.00660.00625.00195.00245.00
Tunisia175,011.00172,516.00125,258.00133,950.0075,620.00115,587.00
Uganda4.004.007.007.0012.009.00
United States301,229.00231,210.00185,707.00177,755.00148,609.00113,949.00
Venezuela, Bolivarian Republic of744.002,216.00681.00
Zimbabwe297,551.00328,595.00397,906.00348,303.00391,869.00434,497.00
Table C.2

Fresh or dried avocados (CN code: 080440) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Country201620172018201920202021
Angola3.853.54
Australia0.010.31
Brazil44,357.3671,040.5068,697.6178,673.7348,183.8350,803.63
Congo, Democratic Republic of0.661.470.100.655.96
China193.9735.281.230.040.12
Colombia152,115.55210,139.60251,050.33387,367.23663,148.97852,152.72
Costa Rica21.569.98428.45686.40201.60
Cuba109.0973.9441.53131.0834.3356.00
Dominican Republic53,962.4155,001.5052,897.1895,531.91100,024.05104,078.68
Algeria0.52
Ecuador5.271,052.411,264.872,314.261,763.143,368.06
Ghana18.48134.5822.6440.4521.8815.33
Guatemala46.604,291.987,487.4217,084.0915,383.9224,717.30
Indonesia0.02
Israel301,123.91424,267.97370,378.23437,318.01345,664.24451,393.77
India0.042.060.520.062.35
Kenya228,426.16243,947.31404,593.87346,231.90435,308.72487,575.86
Madagascar0.961.11
Mexico503,687.52445,611.06463,741.28767,878.48716,092.02750,720.48
Malaysia0.0347.040.04
Nigeria1.063.153.180.51
New Zealand0.850.610.03
Philippines0.05
Thailand3.689.769.669.063.3925.85
Tanzania26,823.0525,773.5855,517.1660,480.9650,769.7456,339.46
Uganda1,912.572,195.252,233.813,364.253,575.683,343.38
United States8,819.531.192,546.860.024.6645.38
Venezuela0.09233.40111.1271.29
South Africa419,768.89315,854.56652,817.98401,352.79416,290.22417,357.70
Zimbabwe13,030.0620,378.8536,539.2432,020.5238,872.6327,696.56
Table C.3

Fresh or dried guavas, mangoes and mangosteens (CN code: 080450) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Country201620172018201920202021
Angola486.65658.15351.50522.66
Antigua and Barbuda193.61
Australia25.7294.1862.920.01
Bangladesh438.53256.66331.27310.73323.911,538.10
China38.9551.87180.8178.23104.34248.77
Colombia2,321.382,553.753,139.676,833.024,131.755,218.98
Congo, Democratic Republic of0.500.123.450.417.13
Costa Rica17,281.1319,119.5818,368.6812,830.6214,950.5922,697.44
Cuba117.98216.5714.36103.34230.60135.11
Dominican Republic96,728.2285,119.28105,553.46118,508.00110,481.33160,995.72
Ecuador20,830.0113,840.919,491.239,608.8710,660.027,684.59
Ghana8,896.279,114.5110,672.3511,138.0630,296.5515,258.17
Guatemala5,124.019,771.9825,768.7010,953.408,099.526,680.24
Haiti4.87
India5,989.348,148.879,470.369,315.517,347.6116,575.69
Indonesia1,981.202,004.362,926.642,386.271,406.941,629.72
Israel143,726.08140,551.30108,353.48121,875.1698,143.59124,186.49
Japan0.660.017.66
Kenya232.064.0865.0910.3066.531,497.12
Laos753.34620.36603.14806.50525.32285.98
Madagascar246.9422.1015.020.661.0520.64
Malaysia289.86197.22170.6472.7244.5619.01
Mexico35,095.0740,848.3646,001.6850,935.7951,841.8946,655.48
New Zealand0.010.080.090.070.100.22
Nigeria0.780.101.131.950.0328.59
Pakistan17,149.7815,912.5821,867.4329,207.3316,196.5019,707.93
Philippines1,028.05519.88795.56368.97128.10152.74
South Africa8,550.1313,015.459,739.9912,116.958,656.285,777.97
Taiwan3.4817.340.925.28
Tanzania0.501.140.09
Thailand6,460.817,401.806,911.896,743.925,260.844,918.89
Tunisia0.080.01
Uganda257.30452.71360.01662.25389.56669.01
United States78,874.1145,478.2154,660.3482,580.5482,852.2151,111.18
Venezuela2,917.572,033.752,401.441,939.11282.69522.30
Table C.4

Tomatoes, fresh or chilled (CN code: 05440) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Country201620172018201920202021
Angola0.18
Australia2.52
Brazil27.60
Colombia2,828.76236.09689.58
Costa Rica1,323.843,068.811,227.34343.97287.90221.82
Dominican Republic19,550.8721,840.0219,688.1915,920.8917,237.8512,557.61
Egypt9,135.4314,023.9415,102.5518,876.689,491.424,133.46
Ghana1.60
India0.010.79
Israel16,739.2110,861.226,392.59782.65138.00913.18
Japan13.758.9813.3145.6734.372.49
Madagascar7.3140.00
Malaysia0.04
Philippines5.23
Mexico0.80
Thailand0.080.080.080.020.020.04
Tunisia101,703.12101,127.84149,456.18162,662186,037.72208,140.48
Uganda0.12
United States00.040.130.42
Table C.5

Fresh or chilled sweet peppers (CN code: 07096010) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Country201620172018201920202021
Algeria107.77204.47142.72145.5898.25
Angola0.10
China100.00
Costa Rica58.24
Cuba3.00
Dominican Republic159.01197.94424.55475.10147.3373.11
Ecuador0.25
Ghana0.49
India1,479.221,511.72824.402,989.781,692.78758.98
Indonesia0.47
Israel219,675.87190,775.79175,658.87127,218.5379,714.1987,683.00
Japan1.273.380.003.75
Kenya0.16223.20226.46124.77112.97
Laos351.151,037.85722.850.72
Madagascar2.940.479.21
Mexico20.449.50118.4375.1116.30
Nigeria0.553.447.58
Pakistan124.6632.60100.14335.62119.6582.63
South Africa77.4972.5569.5226.503.923.45
Sri Lanka24.291.2526.8039.37
Thailand1.0224.7835.4524.900.00
Tunisia1,929.283,557.676,724.863,608.729,916.0815,911.61
Uganda228.10122.50729.69345.48622.64839.89
United States0.09
Fresh or dried citrus (CN code: 0805) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022) Fresh or dried avocados (CN code: 080440) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022) Fresh or dried guavas, mangoes and mangosteens (CN code: 080450) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022) Tomatoes, fresh or chilled (CN code: 05440) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022) Fresh or chilled sweet peppers (CN code: 07096010) imported in 100 kg into the EU (27) from regions where Pulvinaria psidii is known to occur (Source: Eurostat accessed on 18/2/2022)

Appendix D – Interceptions reported by USA

Miller et al. (2014) reports interceptions of P. psidii from several countries on a variety of host genera, as listed below.
Host statusHost namePlant familyCommon nameReference
Cultivated hosts Aizoaceae AizoaceaeGarcía Morales et al. (2016)
Alpinia purpurata ZingiberaceaeRed gingerGarcía Morales et al. (2016)
Alpinia ZingiberaceaeGarcía Morales et al. (2016)
Alstonia scholaris ApocynaceaeDevil tree, dita bark, milk wood, scholar tree, white cheesewoodGarcía Morales et al. (2016)
Alternanthera ficoidea AmaranthaceaeCarb white, rabbit meat, rabbit weed, rupturewort, sanguinaria, shoo‐fly joyweedGarcía Morales et al. (2016)
Annona AnnonaceaeGarcía Morales et al. (2016)
Anthurium cubense AraceaeGarcía Morales et al. (2016)
Anthurium AraceaeGarcía Morales et al. (2016)
Antidesma bunius PhyllanthaceaeBignay, China laurel, salamander treeGarcía Morales et al. (2016)
Antidesma membranaceum PhyllanthaceaeGarcía Morales et al. (2016)
Antidesma PhyllanthaceaeGarcía Morales et al. (2016)
Antigonon leptopus PolygonaceaeBride's tears, cemetery vine, chain of love, coral vine, corallita, Mexican creeper, pink vine, St James' flower, St Michael's flowerGarcía Morales et al. (2016)
Aralia AraliaceaeGarcía Morales et al. (2016)
Ardisia sieboldii PrimulaceaeGarcía Morales et al. (2016)
Artocarpus heterophyllus MoraceaeJackfruitGarcía Morales et al. (2016)
Artocarpus integer MoraceaeChampedak, chempedak, jack fruit, tjampedakGarcía Morales et al. (2016)
Asplenium nidus AspleniaceaeBird's‐nest fernGarcía Morales et al. (2016)
Asplenium AspleniaceaeGarcía Morales et al. (2016)
Barringtonia LecythidaceaeGarcía Morales et al. (2016)
Bidens pilosa AsteraceaeBeggartick, blackjack, common blackjack, railway daisy, Spanish needleGarcía Morales et al. (2016)
Bignonia BignoniaceaeGarcía Morales et al. (2016)
Bischofia javanica PhyllanthaceaeBishopwood, Java bishopwood, toogGarcía Morales et al. (2016)
Blighia sapida SapindaceaeAchee, ackee apple, akee, akiGarcía Morales et al. (2016)
Boronia serrulata RutaceaeNative rose, rose boroniaGarcía Morales et al. (2016)
Bouvardia RubiaceaeGarcía Morales et al. (2016)
Callicarpa glabra LamiaceaeGarcía Morales et al. (2016)
Callistemon MyrtaceaeGarcía Morales et al. (2016)
Calycorectes ferrugineus MyrtaceaeGarcía Morales et al. (2016)
Camellia sinensis TheaceaeTea, tea plantGarcía Morales et al. (2016)
Camellia TheaceaeGarcía Morales et al. (2016)
Canna indica CannaceaeArrowroot canna, Indian cannaGarcía Morales et al. (2016)
Capsicum annuum SolanaceaeChilli, bell pepper, paprika, red pepper, sweet pepperGarcía Morales et al. (2016)
Capsicum frutescens SolanaceaeBird chilli, bird pepper, Cayenne pepper, chilli, chilli pepper, hot pepperGarcía Morales et al. (2016)
Carissa carandas ApocynaceaeCaranda (plum), karandaGarcía Morales et al. (2016)
Carissa macrocarpa ApocynaceaeCarissa, Natal plumGarcía Morales et al. (2016)
Carissa ApocynaceaeGarcía Morales et al. (2016)
Centrosema plumieri FabaceaeButterfly peaGarcía Morales et al. (2016)
Ceodes grandis NyctaginaceaeLettuce treeGarcía Morales et al. (2016)
Chiococca alba RubiaceaeMilkberryGarcía Morales et al. (2016)
Chrysanthemum indicum AsteraceaeChrysanthemumGarcía Morales et al. (2016)
Chrysophyllum cainito SapotaceaeStar appleGarcía Morales et al. (2016)
Chrysophyllum oliviforme SapotaceaeSatinleafGarcía Morales et al. (2016)
Cibotium CibotiaceaeGarcía Morales et al. (2016)
Cinchona RubiaceaeGarcía Morales et al. (2016)
Citrus aurantiifolia RutaceaeKey lime, lime, Mexican lime, West Indian limeGarcía Morales et al. (2016)
Citrus aurantium RutaceaeBigarade, bitter orange, Seville orange, sour orangeGarcía Morales et al. (2016)
Citrus limon RutaceaeLemonGarcía Morales et al. (2016)
Citrus maxima RutaceaeBali lemon, pummelo, shaddockGarcía Morales et al. (2016)
Citrus reticulata RutaceaeClementine, clementine tree, mandarin, tangerineGarcía Morales et al. (2016)
Citrus sinensis RutaceaeSweet orangeGarcía Morales et al. (2016)
Citrus trifoliata RutaceaeGolden apple, hardy orange, trifoliate orangeGarcía Morales et al. (2016)
Citrus RutaceaeGarcía Morales et al. (2016)
Clerodendrum LamiaceaeGarcía Morales et al. (2016)
Clusia rosea ClusiaceaeAutograph tree, balsam apple, balsam fig, pitch apple, Scotch attorneyGarcía Morales et al. (2016)
Codiaeum EuphorbiaceaeGarcía Morales et al. (2016)
Coffea arabica RubiaceaeArabian coffee, coffee treeGarcía Morales et al. (2016)
Coffea canephora RubiaceaeCongo coffee, robusta coffeeGarcía Morales et al. (2016)
Coffea liberica RubiaceaeLiberian coffeeGarcía Morales et al. (2016)
Coffea RubiaceaeGarcía Morales et al. (2016)
Colocasia antiquorum AraceaeChinese potato, cocoyam, dasheen, eddoe, Egyptian colocasia, elephant's‐ear, kalo, taro, wild taro, yamGarcía Morales et al. (2016)
Colocasia esculenta AraceaeChinese potato, cocoyam, dasheen, eddoe, Egyptian colocasia, elephant's‐ear, kalo, taro, wild taro, yamGarcía Morales et al. (2016)
Comocladia AnacardiaceaeGarcía Morales et al. (2016)
Cordia alliodora BoraginaceaeEcuador laurel, onion cordia, salmwoodGarcía Morales et al. (2016)
Cordia myxa BoraginaceaeAssyrian plum, sebesten, Sudan teakGarcía Morales et al. (2016)
Cordia BoraginaceaeGarcía Morales et al. (2016)
Cordyline fruticosa AsparagaceaeTi plantGarcía Morales et al. (2016)
Costus spicatus CostaceaeSpiked spiralflag gingerGarcía Morales et al. (2016)
Crinum moorei AmaryllidaceaeNatal lilyGarcía Morales et al. (2016)
Cussonia arborea AraliaceaeOctopus cabbage treeGarcía Morales et al. (2016)
Dahlia pinnata AsteraceaeDahlia, garden dahliaGarcía Morales et al. (2016)
Dianthus CaryophyllaceaeGarcía Morales et al. (2016)
Dimocarpus longan SapindaceaeDragon's eye, longan,García Morales et al. (2016)
Diospyros kaki EbenaceaeChinese date plum, Chinese persimmon, Japanese persimmon, kaki plum, persimmonGarcía Morales et al. (2016)
Diploknema butyracea SapotaceaeGarcía Morales et al. (2016)
Dodonaea triquetra SapindaceaeCommon hopbushGarcía Morales et al. (2016)
Dodonaea SapindaceaeGarcía Morales et al. (2016)
Duranta VerbenaceaeGarcía Morales et al. (2016)
Dysphania pumilio AmaranthaceaeClammy goosefoot, Tasmanian goosefootGarcía Morales et al. (2016)
Elettaria cardamomum ZingiberaceaeCardamom, cardamonGarcía Morales et al. (2016)
Eriobotrya japonica RosaceaeJapanese medlar, loquatGarcía Morales et al. (2016)
Erythrospermum candidum AchariaceaeGarcía Morales et al. (2016)
Etlingera ZingiberaceaeGarcía Morales et al. (2016)
Eucalyptus deglupta MyrtaceaeKamarere, Mindanao gum, rainbow eucalyptus, rainbow gumGarcía Morales et al. (2016)
Eugenia bullata MyrtaceaeGarcía Morales et al. (2016)
Eugenia MyrtaceaeGarcía Morales et al. (2016)
Euonymus frigidus CelastraceaeGarcía Morales et al. (2016)
Eupatorium AsteraceaeGarcía Morales et al. (2016)
Euphorbia EuphorbiaceaeGarcía Morales et al. (2016)
Ficus MoraceaeGarcía Morales et al. (2016)
Ficus amplissima MoraceaeGarcía Morales et al. (2016)
Ficus benghalensis MoraceaeBanyan, banyan fig, East India fig, horn fig, Indian banyan,García Morales et al. (2016)
Ficus benjamina MoraceaeBenjamin's fig, ficus tree, Java fig, small‐leaved rubber plant, tropical laurel, weeping figGarcía Morales et al. (2016)
Ficus boninsimae MoraceaeGarcía Morales et al. (2016)
Ficus elastica MoraceaeAssam rubber tree, Indian rubber fig, Indian rubber plant, rubber fig, rubber plantGarcía Morales et al. (2016)
Ficus lyrata MoraceaeBanjo fig, fiddle‐leaf, fiddle‐leaf figGarcía Morales et al. (2016)
Ficus macrophylla MoraceaeAustralian banyan, Moreton Bay figGarcía Morales et al. (2016)
Ficus membranacea MoraceaeGarcía Morales et al. (2016)
Ficus racemosa MoraceaeCluster fig, red river figGarcía Morales et al. (2016)
Ficus religiosa Moraceaebo, bo tree, bodhi tree, holy fig tree, peepul, sacred figGarcía Morales et al. (2016)
Ficus retusa MoraceaeChinese banyan, glossy‐leaf figGarcía Morales et al. (2016)
Ficus rubiginosa MoraceaeRusty figGarcía Morales et al. (2016)
Ficus sur MoraceaeGarcía Morales et al. (2016)
Ficus thonningii MoraceaeGarcía Morales et al. (2016)
Garcinia mangostana ClusiaceaeMangosteenGarcía Morales et al. (2016)
Garcinia ClusiaceaeGarcía Morales et al. (2016)
Gardenia jasminoides RubiaceaeCape jasmine, Cape jessamine, common gardenia, gardeniaGarcía Morales et al. (2016)
Gardenia taitensis RubiaceaeSymbol flower, Tahitian gardenia, tiare, Tiaré flowerGarcía Morales et al. (2016)
Gardenia RubiaceaeGarcía Morales et al. (2016)
Gerbera AsteraceaeGarcía Morales et al. (2016)
Gossypium MalvaceaeGarcía Morales et al. (2016)
Guarea guidonia MeliaceaeGarcía Morales et al. (2016)
Gymnosporia CelastraceaeGarcía Morales et al. (2016)
Handroanthus chrysanthus BignoniaceaeGold tree, golden tabebuia, yellow pouiGarcía Morales et al. (2016)
Hedera helix AraliaceaeCommon ivy, ivyGarcía Morales et al. (2016)
Hedychium ZingiberaceaeGarcía Morales et al. (2016)
Heliconia psittacorum HeliconiaceaeParakeet flower, parakeet heliconia, parrot flower, parrot's plantainGarcía Morales et al. (2016)
Hibiscus rosa‐sinensis MalvaceaeChina rose, Chinese hibiscus, Chinese rose, Hawaiian hibiscus, rose mallow, rose of China, shoe‐black plant, shoe‐flowerGarcía Morales et al. (2016)
Hibiscus syriacus MalvaceaeAlthaea, blue hibiscus, rose of Sharon, shrubby althaea, Syrian hibiscus, Syrian ketmiaGarcía Morales et al. (2016)
Hibiscus MalvaceaeGarcía Morales et al. (2016)
Homalocladium platycladum PolygonaceaeCentipede plant, ribbonbush, tapeworm plantGarcía Morales et al. (2016)
Ipomoea alba ConvolvulaceaeWhite‐flowered morning gloryGarcía Morales et al. (2016)
Ixora chinensis RubiaceaeFlame of the woods, jungle flame, jungle geraniumGarcía Morales et al. (2016)
Ixora coccinea RubiaceaeBurning love, flame flower, flame of woods, jungle flame, palm of the woodGarcía Morales et al. (2016)
Ixora macrothyrsa RubiaceaeGarcía Morales et al. (2016)
Ixora RubiaceaeGarcía Morales et al. (2016)
Jasminum humile OleaceaeItalian jasmine, Italian yellow jasmineGarcía Morales et al. (2016)
Jasminum OleaceaeGarcía Morales et al. (2016)
Juncus concinnus JuncaceaeGarcía Morales et al. (2016)
Kalanchoe CrassulaceaeGarcía Morales et al. (2016)
Lagerstroemia indica LythraceaeIndian crape myrtleGarcía Morales et al. (2016)
Lagerstroemia lanceolata LythraceaeGarcía Morales et al. (2016)
Lagerstroemia LythraceaeGarcía Morales et al. (2016)
Lasianthus lanceolatus RubiaceaeGarcía Morales et al. (2016)
Laurus LauraceaeGarcía Morales et al. (2016)
Lawsonia LythraceaeGarcía Morales et al. (2016)
Litchi chinensis SapindaceaeLitchee, litchiGarcía Morales et al. (2016)
Livistona chinensis ArecaceaeChinese fan palmGarcía Morales et al. (2016)
Ludwigia octovalvis OnagraceaeMexican primrose‐willow, swamp primrose, water primroseGarcía Morales et al. (2016)
Macaranga EuphorbiaceaeGarcía Morales et al. (2016)
Mallotus philippensis EuphorbiaceaeKamalaGarcía Morales et al. (2016)
Malvaviscus arboreus MalvaceaeFire dart, marsh‐mallow, scarlet rose‐mallow, sleeping hibiscus, sleepy mallow, Turk's cap, wax mallow, wild cottonGarcía Morales et al. (2016)
Mangifera indica AnacardiaceaeMangoGarcía Morales et al. (2016)
Manilkara zapota SapotaceaeBully tree, chapoti, chicle, chiku, marmalade plum, noseberry, sapodilla, sapodilla plum, sapotaGarcía Morales et al. (2016)
Melanthera biflora AsteraceaeBeach sunflowerGarcía Morales et al. (2016)
Melastoma MelastomataceaeGarcía Morales et al. (2016)
Melastomataceae MelastomataceaeGarcía Morales et al. (2016)
Melia azedarach MeliaceaeBead tree, China berry, chinaberry tree, Indian lilac, Persian lilac, pride of India, seringa, umbrella tree, white cedarGarcía Morales et al. (2016)
Meryta macrophylla AraliaceaeGarcía Morales et al. (2016)
Meryta sinclairii AraliaceaeGarcía Morales et al. (2016)
Metrosideros MyrtaceaeGarcía Morales et al. (2016)
Miconia robinsoniana MelastomataceaeGarcía Morales et al. (2016)
Monstera deliciosa AraceaeBreadfruit vine, ceriman, hurricane plant, Mexican breadfruit, split‐leaf philodendron, Swiss cheese plantGarcía Morales et al. (2016)
Morinda citrifolia RubiaceaeIndian mulberry, noniGarcía Morales et al. (2016)
Morinda RubiaceaeGarcía Morales et al. (2016)
Morus alba MoraceaeSilkworm mulberry, white mulberryGarcía Morales et al. (2016)
Morus indica MoraceaeJapanese mulberryGarcía Morales et al. (2016)
Myristica castaneifolia MyristicaceaeGarcía Morales et al. (2016)
Myrtus communis MyrtaceaeCommon myrtle, myrtle, true myrtleGarcía Morales et al. (2016)
Neolamarckia RubiaceaeGarcía Morales et al. (2016)
Nephelium lappaceum SapindaceaeRambutanGarcía Morales et al. (2016)
Nephelium ramboutan‐ake SapindaceaePulasanGarcía Morales et al. (2016)
Nerium ApocynaceaeGarcía Morales et al. (2016)
Oleaceae OleaceaeGarcía Morales et al. (2016)
Oxera LamiaceaeGarcía Morales et al. (2016)
Palicourea domingensis RubiaceaeGarcía Morales et al. (2016)
Pandanus PandanaceaeGarcía Morales et al. (2016)
Pelargonium GeraniaceaeGarcía Morales et al. (2016)
Persea americana LauraceaeAvocadoCABI (online)
Persea LauraceaeGarcía Morales et al. (2016)
Philodendron AraceaeGarcía Morales et al. (2016)
Phlox PolemoniaceaeGarcía Morales et al. (2016)
Photinia serratifolia RosaceaeChinese hawthorn, Chinese photiniaGarcía Morales et al. (2016)
Pinus caribaea PinaceaeCuban pineGarcía Morales et al. (2016)
Piper methysticum PiperaceaeKava pepper bushGarcía Morales et al. (2016)
Pisonia NyctaginaceaeGarcía Morales et al. (2016)
Pistacia atlantica AnacardiaceaeAtlas pistachio, Mount Atlas mastic treeGarcía Morales et al. (2016)
Pittosporum boninense PittosporaceaeGarcía Morales et al. (2016)
Pittosporum PittosporaceaeGarcía Morales et al. (2016)
Planchonella obovata SapotaceaeGarcía Morales et al. (2016)
Plumeria ApocynaceaeGarcía Morales et al. (2016)
Plumeria rubra ApocynaceaeFrangipani, red frangipani, temple treeGarcía Morales et al. (2016)
Pometia pinnata SapindaceaeFijian longan, island lychee, kasai, kava, langsir, matoa, taun treeGarcía Morales et al. (2016)
Pouteria sapota SapotaceaeMamey, mammee sapota, mammey sapote, marmelade plumCABI (online)
Prunus cerasifera RosaceaeCherry plum, myrobalan plumGarcía Morales et al. (2016)
Psidium guajava MyrtaceaeCommon guava, guava, yellow guavaGarcía Morales et al. (2016)
Psidium MyrtaceaeGarcía Morales et al. (2016)
Psychotria asiatica RubiaceaeGarcía Morales et al. (2016)
Psychotria elliptica RubiaceaeGarcía Morales et al. (2016)
Psychotria nervosa RubiaceaeSeminole balsamo, wild coffeeGarcía Morales et al. (2016)
Psychotria RubiaceaeGarcía Morales et al. (2016)
Pteralyxia macrocarpa ApocynaceaeGarcía Morales et al. (2016)
Pteridium DennstaedtiaceaeGarcía Morales et al. (2016)
Pteris biaurita PteridaceaeGarcía Morales et al. (2016)
Punica granatum LythraceaePomegranateGarcía Morales et al. (2016)
Pycnandra SapotaceaeGarcía Morales et al. (2016)
Russelia PlantaginaceaeGarcía Morales et al. (2016)
Salix SalicaceaeGarcía Morales et al. (2016)
Sanchezia AcanthaceaeGarcía Morales et al. (2016)
Scaevola floribunda GoodeniaceaeGarcía Morales et al. (2016)
Scaevola gaudichaudiana GoodeniaceaeGarcía Morales et al. (2016)
Schaefferia frutescens CelastraceaeFlorida boxwoodGarcía Morales et al. (2016)
Schefflera actinophylla AraliaceaeOctopus tree, Queensland umbrella tree, star leaf, umbrella treeGarcía Morales et al. (2016)
Schefflera AraliaceaeGarcía Morales et al. (2016)
Schima wallichii TheaceaeGarcía Morales et al. (2016)
Schinus molle AnacardiaceaeCalifornia pepper tree, pepper tree, Peruvian mastic, Peruvian mastic tree, Peruvian pepper treeGarcía Morales et al. (2016)
Schinus terebinthifolia AnacardiaceaeBrazilian pepper tree, broad‐leaf pepper tree, Christmas berry, Florida holly, pepper berry, schinusGarcía Morales et al. (2016)
Schinus AnacardiaceaeGarcía Morales et al. (2016)
Sedum CrassulaceaeGarcía Morales et al. (2016)
Solanum lycopersicum SolanaceaeTomatoGarcía Morales et al. (2016)
Spathodea campanulata BignoniaceaeAfrican tulip tree, fire tree, flame of the forest, fountain tree, nandi flame treeGarcía Morales et al. (2016)
Spondias dulcis AnacardiaceaeAmbarella, golden apple, great hog plum, jew‐plum, Jewish plum, otaheite appleGarcía Morales et al. (2016)
Stachytarpheta VerbenaceaeGarcía Morales et al. (2016)
Streblus asper MoraceaeSandpaper tree, toothbrush treeGarcía Morales et al. (2016)
Strychnos nux‐vomica LoganiaceaeNux‐vomica poison nut, strychnine treeGarcía Morales et al. (2016)
Syzygium aqueum MyrtaceaeWatery rose apple, wax jamboGarcía Morales et al. (2016)
Syzygium aromaticum MyrtaceaeClove, Zanzibar redheadGarcía Morales et al. (2016)
Syzygium buxifolium MyrtaceaeBoxleaf eugeniaGarcía Morales et al. (2016)
Syzygium calophyllifolium MyrtaceaeGarcía Morales et al. (2016)
Syzygium cumini MyrtaceaeBlack plum, jambolan, jamun, Java plum, Malabar plumGarcía Morales et al. (2016)
Syzygium jambos MyrtaceaeMalabar plum, rose apple, wax jambuGarcía Morales et al. (2016)
Syzygium malaccense MyrtaceaeLong‐fruited rose apple, Malay apple, mountain apple, ohia, otaheite apple, otaheite apple, pomeracGarcía Morales et al. (2016)
Tamarix gallica TamaricaceaeFrench tamarisk, French tree, manna plantGarcía Morales et al. (2016)
Tarenna sambucina RubiaceaeGarcía Morales et al. (2016)
Tarenna subsessilis RubiaceaeGarcía Morales et al. (2016)
Tecoma stans BignoniaceaeTrumpet flower, yellow elder, yellow trumpet bush, yellow‐bellsGarcía Morales et al. (2016)
Tecoma BignoniaceaeGarcía Morales et al. (2016)
Terminalia brassii CombretaceaeGarcía Morales et al. (2016)
Tetrapanax papyrifer AraliaceaeChinese rice paper treeGarcía Morales et al. (2016)
Thespesia populnea MalvaceaeCork tree, Indian tulip tree, milo, Pacific rosewood, portea oil‐nut, portea tree, portia, seaside mahoe, Seychelles rosewood, umbrella treeGarcía Morales et al. (2016)
Toxicodendron AnacardiaceaeGarcía Morales et al. (2016)
Trema orientalis CannabaceaeGarcía Morales et al. (2016)
Uapaca kirkiana PhyllanthaceaeWild loquatGarcía Morales et al. (2016)
Vanilla OrchidaceaeGarcía Morales et al. (2016)
Violaceae ViolaceaeGarcía Morales et al. (2016)
Zantedeschia aethiopica AraceaeAltar lily, arum lily, calla lily, garden calla lily, pig lily, trumpet lily, white arum lilyGarcía Morales et al. (2016)
Zingiber officinale ZingiberaceaeCommon ginger, garden gingerGarcía Morales et al. (2016)
Zingiber ZingiberaceaeGarcía Morales et al. (2016)
RegionCountrySub‐national (e.g. State)StatusReference
North AmericaBahamasPresent, no detailsGarcía Morales et al. (2016)
BermudaPresent, no detailsGarcía Morales et al. (2016)
CubaPresent, no detailsGarcía Morales et al. (2016)
MexicoPresent, no detailsGarcía Morales et al. (2016)
MontserratPresent, no detailsGarcía Morales et al. (2016)
United StatesAlabamaPresent, no detailsGarcía Morales et al. (2016)
CaliforniaPresent, no detailsGarcía Morales et al. (2016)
District of ColumbiaPresent, no detailsGarcía Morales et al. (2016)
FloridaPresent, no detailsGarcía Morales et al. (2016)
GeorgiaPresent, no detailsGarcía Morales et al. (2016)
MississippiPresent, no detailsGarcía Morales et al. (2016)
MissouriPresent, no detailsGarcía Morales et al. (2016)
New YorkPresent, no detailsGarcía Morales et al. (2016)
PennsylvaniaPresent, no detailsGarcía Morales et al. (2016)
Central AmericaCosta RicaPresent, no detailsGarcía Morales et al. (2016)
GuatemalaPresent, no detailsGarcía Morales et al. (2016)
CaribbeanAntigua and BarbudaAntiguaPresent, no detailsGarcía Morales et al. (2016)
BarbadosPresent, no detailsGarcía Morales et al. (2016)
Dominican RepublicPresent, no detailsGarcía Morales et al. (2016)
GrenadaPresent, no detailsGarcía Morales et al. (2016)
GuadeloupePresent, no detailsGarcía Morales et al. (2016)
HaitiPresent, no detailsGarcía Morales et al. (2016)
JamaicaPresent, no detailsGarcía Morales et al. (2016)
MartiniquePresent, no detailsGarcía Morales et al. (2016)
Puerto Rico & Vieques IslandPuerto RicoPresent, no detailsGarcía Morales et al. (2016)
Ryukyu IslandsPresent, no detailsGarcía Morales et al. (2016)
Saint CroixPresent, no detailsGarcía Morales et al. (2016)
Saint Kitts and Nevis IslandsSaint KittsPresent, no detailsGarcía Morales et al. (2016)
Saint Vincent and the GrenadinesPresent, no detailsGarcía Morales et al. (2016)
Trinidad and TobagoTrinidadPresent, no detailsGarcía Morales et al. (2016)
U.S. Virgin IslandsPresent, no detailsGarcía Morales et al. (2016)
EU (27)Spain

Present, no details

Valencia, Andalusia

CABI (online); Boyero et al., 2017; Rodrigo et al. (2020); Del Pino et al. (2021a,b)
SpainCanary IslandsPresent, no detailsCABI (online); Gómez‐Menor Guerrero (1967); Jaques and Urbaneja (2006)
AfricaAlgeriaPresent, no detailsGarcía Morales et al. (2016)
AngolaPresent, no detailsGarcía Morales et al. (2016)
Ascension IslandPresent, no detailsGarcía Morales et al. (2016)
Cape VerdePresent, no detailsGarcía Morales et al. (2016)
ComorosPresent, no detailsGarcía Morales et al. (2016)
CongoPresent, no detailsGarcía Morales et al. (2016)
Cote d'IvoirePresent, no detailsGarcía Morales et al. (2016)
EgyptPresent, no detailsGarcía Morales et al. (2016)
EritreaPresent, no detailsCABI (online)
GhanaPresent, no detailsGarcía Morales et al. (2016)
KenyaPresent, no detailsGarcía Morales et al. (2016)
MadagascarPresent, no detailsGarcía Morales et al. (2016)
MalawiPresent, no detailsGarcía Morales et al. (2016)
MauritiusPresent, no detailsGarcía Morales et al. (2016)
MozambiquePresent, no detailsGarcía Morales et al. (2016)
NigeriaPresent, no detailsGarcía Morales et al. (2016)
ReunionPresent, no detailsGarcía Morales et al. (2016)
Saint HelenaPresent, no detailsGarcía Morales et al. (2016)
SenegalPresent, no detailsGarcía Morales et al. (2016)
SeychellesAldabra IslandPresent, no detailsGarcía Morales et al. (2016)
Farquhar IslandPresent, no detailsGarcía Morales et al. (2016)
Providence IslandPresent, no detailsGarcía Morales et al. (2016)
South AfricaPresent, no detailsGarcía Morales et al. (2016)
SpainCanary IslandsPresent in TenerifeNPPO
SudanPresent, no detailsGarcía Morales et al. (2016)
TanzaniaPresent, no detailsGarcía Morales et al. (2016)
TanzaniaZanzibar IslandPresent, no detailsCABI (online)
TunisiaPresent, no detailsGarcía Morales et al. (2016)
UgandaPresent, no detailsGarcía Morales et al. (2016)
ZimbabwePresent, no detailsGarcía Morales et al. (2016)
AsiaAfghanistanPresent, no detailsGarcía Morales et al. (2016)
BangladeshPresent, no detailsGarcía Morales et al. (2016)
BhutanPresent, no detailsGarcía Morales et al. (2016)
Bonin IslandsPresent, no detailsGarcía Morales et al. (2016)
BruneiPresent, no detailsGarcía Morales et al. (2016)
CambodiaPresent, no detailsCABI (online)
ChinaGuangdongPresent, no detailsGarcía Morales et al. (2016)
HenanPresent, no detailsGarcía Morales et al. (2016)
Hong KongPresent, no detailsGarcía Morales et al. (2016)
HubeiPresent, no detailsGarcía Morales et al. (2016)
HunanPresent, no detailsGarcía Morales et al. (2016)
ZhejiangPresent, no detailsGarcía Morales et al. (2016)
Christmas IslandPresent, no detailsGarcía Morales et al. (2016)
IndiaAndhra PradeshPresent, no detailsGarcía Morales et al. (2016)
BiharPresent, no detailsGarcía Morales et al. (2016)
GujaratPresent, no detailsGarcía Morales et al. (2016)
KarnatakaPresent, no detailsGarcía Morales et al. (2016)
KeralaPresent, no detailsGarcía Morales et al. (2016)
MaharashtraPresent, no detailsGarcía Morales et al. (2016)
OdishaPresent, no detailsGarcía Morales et al. (2016)
SikkimPresent, no detailsCABI (online)
Tamil NaduPresent, no detailsGarcía Morales et al. (2016)
Uttar PradeshPresent, no detailsGarcía Morales et al. (2016)
West BengalPresent, no detailsGarcía Morales et al. (2016)
IndonesiaFloresPresent, no detailsGarcía Morales et al. (2016)
Irian JayaPresent, no detailsGarcía Morales et al. (2016)
JavaPresent, no detailsGarcía Morales et al. (2016)
SulawesiPresent, no detailsGarcía Morales et al. (2016)
SumatraPresent, no detailsGarcía Morales et al. (2016)
IsraelPresent, no detailsGarcía Morales et al. (2016)
JapanPresent, no detailsGarcía Morales et al. (2016)
LaosPresent, no detailsGarcía Morales et al. (2016)
MalaysiaPresent, no detailsCABI (online)
Peninsular MalaysianPresent, no detailsCABI (online)
SabahPresent, no detailsGarcía Morales et al. (2016)
SarawakPresent, no detailsGarcía Morales et al. (2016)
NepalPresent, no detailsGarcía Morales et al. (2016)
PakistanPresent, no detailsGarcía Morales et al. (2016)
PhilippinesPresent, no detailsGarcía Morales et al. (2016)
SingaporePresent, no detailsGarcía Morales et al. (2016)
Sri LankaPresent, no detailsGarcía Morales et al. (2016)
TaiwanPresent, no detailsGarcía Morales et al. (2016)
ThailandPresent, no detailsGarcía Morales et al. (2016)
OceaniaAustraliaAustralian Capital TerritoryPresent, no detailsGarcía Morales et al. (2016)
New South WalesPresent, no detailsGarcía Morales et al. (2016)
Northern TerritoryPresent, no detailsGarcía Morales et al. (2016)
QueenslandPresent, no detailsGarcía Morales et al. (2016)
Cook IslandsPresent, no detailsGarcía Morales et al. (2016)
Federated States of MicronesiaCaroline IslandsPresent, no detailsGarcía Morales et al. (2016)
Ponape IslandPresent, no detailsGarcía Morales et al. (2016)
Truk IslandsPresent, no detailsGarcía Morales et al. (2016)
FijiPresent, no detailsGarcía Morales et al. (2016)
French PolynesiaTahitiPresent, no detailsGarcía Morales et al. (2016)
Hawaiian IslandsHawaiiPresent, no detailsGarcía Morales et al. (2016)
KampucheaPresent, no detailsGarcía Morales et al. (2016)
KiribatiPresent, no detailsGarcía Morales et al. (2016)
Marshall IslandsPresent, no detailsGarcía Morales et al. (2016)
NauruPresent, no detailsCABI (online)
New BritainPresent, no detailsGarcía Morales et al. (2016)
New CaledoniaPresent, no detailsGarcía Morales et al. (2016)
NiuePresent, no detailsGarcía Morales et al. (2016)
Northern Mariana IslandsPresent, no detailsGarcía Morales et al. (2016)
PalauPresent, no detailsGarcía Morales et al. (2016)
Papua New GuineaPresent, no detailsGarcía Morales et al. (2016)
Solomon IslandsPresent, no detailsGarcía Morales et al. (2016)
VanuatuPresent, no detailsGarcía Morales et al. (2016)
Western SamoaPresent, no detailsGarcía Morales et al. (2016)
TongaPresent, no detailsGarcía Morales et al. (2016)
CountryHost
Antigua Chalcas
Australia Ixora, Litchi
Bahamas Gardenia, Psidium
Barbados Euonymus, Psychotria
Bermuda Bryophyllum, Campsis, Codiaeum, Duranta, Laurus, Nerium, Pittosporum, Rhododendron, Sedum, Tecoma
Brazil Mammea
China Dracontomelon, Gardenia, Lansium, Litchi
China ‐ Hong Kong Litchi
Colombia Citrus, Eugenia
Costa Rica Anthurium, Coffea, Gardenia
Cuba Ficus, Litchi, Psidium
Fiji Ixora
Guatemala Dracaena
India Coffea, Litchi, Psidium
Indonesia Lagerstroemia, Myristica, Thea
Jamaica Anthurium, Bidens, Citrus, Mangifera, Myristica, Phaeomena, Punica
Japan Gardenia, Litchi
Maldives Annona, Psidium
Mexico Carissa, Chenopodium, Citrus, Diospyros, Ficus, Gardenia, Litchi, Plumeria, Psidium, Rhus, Zingiber
Montserrat Psidium
Panama Anthurium, Tectona
Peru Mangifera
The Philippines Eugenia, Gardenia, Lansium, Litchi, Psidium, Vanda
Puerto Rico Gardenia
Samoa Cordyline
Singapore Nephelium
Tahiti Alpinia, Annona, Gardenia
Taiwan Dimocarpus
Thailand Cordyline, Dracaena, Eugenia, Nephelium
Trinidad Anthurium, Gardenia
  11 in total

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Authors:  S J Toy; M J Newfield
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Authors:  Sahar M Beshr; I Soad Abdel-Razak; A K Mourad; S Khadiga Moursi
Journal:  Commun Agric Appl Biol Sci       Date:  2009

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Authors:  Eric W Sayers; Mark Cavanaugh; Karen Clark; James Ostell; Kim D Pruitt; Ilene Karsch-Mizrachi
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Authors:  Mayrolin García Morales; Barbara D Denno; Douglass R Miller; Gary L Miller; Yair Ben-Dov; Nate B Hardy
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Authors:  Ernesto Robayo Camacho; Juang-Horng Chong
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