| Legend |
|---|
| Justification for qualification based on EPPO PM 4 Standards |
| Justification for disqualification |
| Additional or non-conclusive information |
| Standard text |
NAME OF THE ORGANISM: Phytophthora cactorum (PHYTCC)
GENERAL INFORMATION ON THE PEST
Name as submitted in the project specification (if different):
Pest category:
Chromista
1- Identity of the pest/Level of taxonomic listing:
Is the organism clearly a single taxonomic entity and can it be adequately distinguished from other entities of the same rank?
Yes
Is the pest defined at the species level or lower?:
Yes
Can listing of the pest at a taxonomic level higher than species be supported by scientific reasons or can species be identified within the taxonomic rank which are the (main) pests of concern?
- Not relevant: Fruits (including hops) sector
If necessary, please list the species:
-
Is it justified that the pest is listed at a taxonomic rank below species level?
Not relevant
Conclusion:
- Candidate: Fruits (including hops) sector
Justification (if necessary):
-
2 – Status in the EU:
Is this pest already a quarantine pest for the whole EU?
No
Presence in the EU:
Yes
List of countries (EPPO Global Database):
Austria (1993); Belgium (1992); Bulgaria (1993); Czech Republic (2011); Denmark (2019); Finland (2011); France (1993); Germany (1993); Greece (1992); Hungary (1992); Italy (1994); Lithuania (2007); Netherlands (1992); Poland (2011); Romania (1992); Slovakia (2023); Spain (2012)
Conclusion:
Candidate
Justification (if necessary):
Data of the presence of this pest on the EU territory are available in EPPO Global Database (https://gd.eppo.int/).
HOST PLANT N°1: Prunus dulcis (PRNDU) for the Fruits (including hops) sector.
Origin of the listing:
Commission Implementing Directive (EU) 2014/98/EU and Commission Implementing Regulation (EU) 2019/2072
Plants for planting:
Plants intended for planting
3 - Is the pest already listed in a PM4 standard on the concerned host plant?
No
Conclusion:
Evaluation continues
Justification (if necessary):
Remarks: EPPO Standard PM 4-30 Certification scheme for almond, apricot, peach and plum recommends inspection for 'Phytophthora spp.'
The assessment performed covers the given host species as well as interspecific hybrids with other Prunus species.
The assessment performed covers the given host species as well as interspecific hybrids with other Prunus species.
4 - Are the listed plants for planting the main* pathway for the "pest/host/intended use" combination? (*: significant compared to others):
No
Conclusion:
Not candidate
Justification:
Phytophthora cactorum has a cosmopolitan distribution and a reported host range of more than 200 species, spanning at least 154 genera of vascular plants within 54 families (e.g. Erwin & Ribeiro, 1996), including herbaceous and woody plants, e.g. Cydonia, Malus and Pyrus (Grígel et al., 2019; Garmaroodi et al., 2023), Juglans regia (Mircetich & Matheron, 1983), Prunus dulcis (Pérez-Sierra et al., 2010), P. armeniaca, P. avium, P. cerasus, P. domestica, P. persica (Grígel et al., 2019), and Prunus salicina (Plantwise Knowledge Bank, 2022).
Although traditionally considered to be a generalist, marked differences of P. cactorum isolates occur in degree of pathogenicity to different hosts. When P. cactorum isolates from different host plants were tested on a common host, significant differences of virulence were observed (Chen et al., 2023). For example, the strains isolated from hosts other than strawberry are not able to cause crown rot symptoms on strawberry (Eikemo et al., 2004), but all pathotypes were able to cause strawberry leather rot (Nellist et al., 2021; Seemüller & Schmidle, 1979). It was found that P. cactorum isolates from strawberry crowns were less pathogenic on apple barks than isolates from strawberry fruit or apple and vice versa, with apple and strawberry fruit isolates being less pathogenic on strawberry crowns (Nellist et al., 2021; Seemüller & Schmidle, 1979, Chen et al., 2023).
Although Phytophthora cactorum can be transported with plants for planting (e.g. rootstocks Carisse & Khanizadeh, 2006), it is foremost a soilborne pathogen. The pathogen was also isolated from soil from unaffected orchards and forest soil samples (Turechek, 2004 in Garmaroodi et al. 2023). The most important propagules concerned with survival of P. cactorum are oospores, which are formed as a result of sexual reproduction, and the asexually produced chlamydospores. Both of these structures can survive for years in orchard soils (Erwin & Ribeiro, 1996). Predisposing factors, such as waterlogging or planting of trees on sites not suitable for the species, as well as contributing factors which either reduce the vitality of the tree (e.g., extreme droughts or defoliations) or favor the pathogen (e.g., excess soil moisture following heavy rain, flooding or irrigation), can accelerate the disease process or make it possible in the first place (Jung et al., 2018).
Irrigation can sometimes contribute to development of Phytophthora diseases, both by spreading the pathogens over long distances through surface water supply networks of rivers and canals and by favoring production, dispersal, and infection by the pathogens’ zoospores (Browne et al., 2012; Felix-Gastelum & Mircetich, 2005 – cited from Brown, 2017).
Because of the wide host range and longevity of inoculum sources in the environment, planting material are not considered to be a significant pathway for introduction under outdoor field conditions. Plants for planting produced under at-risk situations could only be considered a significant pathway if the intended use was for a protected facility that used uninfested soil media and had been thoroughly cleaned of potential infection sources before use.
Although traditionally considered to be a generalist, marked differences of P. cactorum isolates occur in degree of pathogenicity to different hosts. When P. cactorum isolates from different host plants were tested on a common host, significant differences of virulence were observed (Chen et al., 2023). For example, the strains isolated from hosts other than strawberry are not able to cause crown rot symptoms on strawberry (Eikemo et al., 2004), but all pathotypes were able to cause strawberry leather rot (Nellist et al., 2021; Seemüller & Schmidle, 1979). It was found that P. cactorum isolates from strawberry crowns were less pathogenic on apple barks than isolates from strawberry fruit or apple and vice versa, with apple and strawberry fruit isolates being less pathogenic on strawberry crowns (Nellist et al., 2021; Seemüller & Schmidle, 1979, Chen et al., 2023).
Although Phytophthora cactorum can be transported with plants for planting (e.g. rootstocks Carisse & Khanizadeh, 2006), it is foremost a soilborne pathogen. The pathogen was also isolated from soil from unaffected orchards and forest soil samples (Turechek, 2004 in Garmaroodi et al. 2023). The most important propagules concerned with survival of P. cactorum are oospores, which are formed as a result of sexual reproduction, and the asexually produced chlamydospores. Both of these structures can survive for years in orchard soils (Erwin & Ribeiro, 1996). Predisposing factors, such as waterlogging or planting of trees on sites not suitable for the species, as well as contributing factors which either reduce the vitality of the tree (e.g., extreme droughts or defoliations) or favor the pathogen (e.g., excess soil moisture following heavy rain, flooding or irrigation), can accelerate the disease process or make it possible in the first place (Jung et al., 2018).
Irrigation can sometimes contribute to development of Phytophthora diseases, both by spreading the pathogens over long distances through surface water supply networks of rivers and canals and by favoring production, dispersal, and infection by the pathogens’ zoospores (Browne et al., 2012; Felix-Gastelum & Mircetich, 2005 – cited from Brown, 2017).
Because of the wide host range and longevity of inoculum sources in the environment, planting material are not considered to be a significant pathway for introduction under outdoor field conditions. Plants for planting produced under at-risk situations could only be considered a significant pathway if the intended use was for a protected facility that used uninfested soil media and had been thoroughly cleaned of potential infection sources before use.
5 - Economic impact:
Are there documented reports of any economic impact on the host?
Yes
Justification:
P. cactorum can cause damage in Prunus dulcis, but tends to infect from below ground. Other Phytophthora spp. e.g. P. niederhausii have caused severe decline of young almond trees (Pérez-Sierra et al., 2010).
Reported impact on Prunus spp.: More than 10 species of the genus Phytophthora are reported to affect cultivated Prunus L. worldwide, causing root rot, crown rot, trunk and scaffold cankers, and even fruit rots. Although species of Phytophthora can
infect Prunus scions directly, Prunus rootstocks are often infected first, sometimes providing the route to further pathogen ingress into a tree (Browne and Viveros, 1999). Phytophthora cactorum and Phytophthora megasperma were often associated with root and crown rots and trunk cankers resulting from subterranean infections, whereas Phytophthora citricola tended to invade almond scions directly, aboveground (Browne et al., 1998; Browne and Viveros, 1999). Recently, Phytophthora niederhauserii was described (Abad et al., 2014) and reported as a new root and crown pathogen of almond nursery trees in Spain (Pérez-Sierra et al., 2010) and almond orchard trees in Turkey (Kurbetli̇; and Değiṙ menci,̇ 2012) and California (Browne et al., 2015) (cited from Brown, 2017).
Reported impact on Prunus spp.: More than 10 species of the genus Phytophthora are reported to affect cultivated Prunus L. worldwide, causing root rot, crown rot, trunk and scaffold cankers, and even fruit rots. Although species of Phytophthora can
infect Prunus scions directly, Prunus rootstocks are often infected first, sometimes providing the route to further pathogen ingress into a tree (Browne and Viveros, 1999). Phytophthora cactorum and Phytophthora megasperma were often associated with root and crown rots and trunk cankers resulting from subterranean infections, whereas Phytophthora citricola tended to invade almond scions directly, aboveground (Browne et al., 1998; Browne and Viveros, 1999). Recently, Phytophthora niederhauserii was described (Abad et al., 2014) and reported as a new root and crown pathogen of almond nursery trees in Spain (Pérez-Sierra et al., 2010) and almond orchard trees in Turkey (Kurbetli̇; and Değiṙ menci,̇ 2012) and California (Browne et al., 2015) (cited from Brown, 2017).
What is the likely economic impact of the pest irrespective of its infestation source in the absence of phytosanitary measures? (= official measures)
Is the economic impact due to the presence of the pest on the named host plant for planting, acceptable to the propagation and end user sectors concerned?
Is there unacceptable economic impact caused to other hosts (or the same host with a different intended use) produced at the same place of production due to the transfer of the pest from the named host plant for planting?
Conclusion:
Justification:
6 - Are there feasible and effective measures available to prevent the presence of the pest on the plants for planting at an incidence above a certain threshold (including zero) to avoid an unacceptable economic impact as regards the relevant host plants?
Conclusion:
Justification:
It is considered that cultural practices and cultivar choice are more important than recommending phytosanitary measures for this pest.
7- Is the quality of the data sufficient to recommend the pest to be listed as a RNQP?
Conclusion:
Justification:
CONCLUSION ON THE STATUS:
Disqualified: plants for planting is not considered to be a significant pathway compared to others.
8 - Tolerance level:
Is there a need to change the Tolerance level:
Yes
Proposed Tolerance levels:
Delisting
9 - Risk management measures:
Is there a need to change the Risk management measure:
Yes
Proposed Risk management measure:
Delisting
REFERENCES:
- Abad ZG, Abad JA, Cacciola SO, Pane A, Faedda R, Moralejo E, Péerez-Sierra A, Abad-Campos P, Alvarez-Bernaola LA, Bakonyi J, Józsa A, Herrero ML, Burgess TI, Cunnington JH, Smith IW, Balci Y, Blomquist C, Henricot B, Denton G, Spies C, Mcleod A, Belbahri L, Cooke D, Kageyama K, Uematsu S, Kurbetli I & Değirmenci K (2014) Phytophthora niederhauserii sp. nov., a polyphagous species associated with ornamentals, fruit trees and native plants in 13 countries. Mycologia 106, 431–447.
- Browne GT (2017) Resistance to Phytophthora species among rootstocks for cultivated Prunus species. HortScience 52(11), 1471-1476. Retrieved Mar 10, 2024, from https://doi.org/10.21273/HORTSCI10391-17
- Browne GT, Beede RH & Schmidt LS (2012). Irrigation water relation to the health of deciduous fruit and nut crops. In Biology, detection and management of plant pathogens in irrigation water (Eds Hong C & Moorman G) APS Press, St. Paul, MN.
- Browne G, Schmidt L & Brar G (2015). First report of Phytophthora niederhauserii causing crown rot of almond (Prunus dulcis) in California. Plant Disease 99:1863
- Browne GT & Viveros MA (1999). Lethal cankers caused by Phytophthora spp. in almond scions: Specific etiology and potential inoculum sources. Plant Disease 83, 739–745.
- Carisse O & Khanizadeh S (2006) Relative resistance of newly released apple rootstocks to Phytophthora cactorum. Canadian Journal of Plant Science 86(1), 199-204. https://cdnsciencepub.com/doi/10.4141/P04-176.
- Chen XR, Wen K, Zhou X, Zhu MY, Liu Y, Jin JH, Nellist CF (2023). The devastating oomycete phytopathogen Phytophthora cactorum: Insights into its biology and molecular features. Molecular Plant Pathology 24, 1017–1032. DOI: 10.1111/mpp.13345.
- Erwin DC & Ribeiro OK (1996). Phytophthora Diseases Worldwide. St Paul, Minnesota, USA: American Phytopathological Society Press.
- Eikemo H., Klemsdal SS, Riisberg I, Bonants P, Stensvand A, Tronsmo AM (2004) Genetic variation between Phytophthora cactorum isolates differing in their ability to cause crown rot in strawberry. Mycological Research 108(3), 317-324. DOI: 10.1017/s0953756204009244.
- Erwin DC & Ribeiro OK (1996) Phytophthora diseases worldwide. St. Paul, MN: The American Phytopathological Society.
- Félix-Gastélum R & Mircetich SM (2005) Influence of flooding duration on the development of root and crown rot of lovell peach (Prunus persica (L.) Batsch) caused by three different Phytophthora species. Revista Mexicana de Fitopatología 23, 33–41.
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