EPPO Global Database

Entoleuca mammata(HYPOMA)

EPPO Datasheet: Entoleuca mammata

IDENTITY

Preferred name: Entoleuca mammata
Authority: (Wahlenberg) Rogers & Yu
Taxonomic position: Fungi: Ascomycota: Pezizomycotina: Sordariomycetes: Xylariomycetidae: Xylariales: Xylariaceae
Other scientific names: Hypoxylon holwayi Ellis, Hypoxylon mammatum (Wahlenberg) J.H.Miller, Hypoxylon pruinatum (Klotzsch) Cooke, Nemania mammata (Wahlenberg) Granmo, Rosellinia pruinata (Klotzsch) Saccardo, Sphaeria mammata Wahlenberg, Sphaeria pruinata Klotzsch
Common names in English: canker of aspen, canker of poplar, hypoxylon canker of poplar
view more common names online...
Notes on taxonomy and nomenclature

Entoleuca mammata (Wahlenb.) Rogers et Ju (1996) is a fungus of the genus Entoleuca (family Xylariaceae) which consists of both saprobic and plant pathogenic species (Jayawardena et al., 2019). E. mammata was moved from the genus Hypoxylon to the genus Entoleuca following a revision of the genus (Rogers and Ju, 1996) during which the genus Entoleuca was re-established.

EPPO Categorization: A1/A2 (formerly)
EU Categorization: PZ Quarantine pest (Annex III)
view more categorizations online...
EPPO Code: HYPOMA

HOSTS 2023-04-18

In Europe, the principal host is the native species Populus tremula (common aspen, especially its mountain race), and, in North America, P. tremuloides (quaking aspen), which has also been introduced into Europe, as well as the hybrid aspen (Populus tremula × P. tremuloides) (Ostry and Anderson, 2009). However, as E. mammata can infect various Populus species, it has a high potential to damage monocultural hybrid aspen plantations in Northern Europe (Lutter et al., 2019). Hypoxylon canker for hybrid aspen has been reported in clonal comparison trials in Sweden (Stener and Karlsson, 2004) and Latvia (Lutter et al., 2019). The fungus has also been reported on other aspens and poplars, Salix myrsinifolia and other willow species (e.g., S. daphnoides), rowan (Sorbus aucuparia), Sitka alder (Alnus viridis), birch (Betula spp.), apple (Malus spp.), oak (Quercus spp.), and hop-hornbeam (Ostrya spp.) (Kasansen et al., 2004; Eriksson, 2014; EFSA, 2017; NBN Atlas, 2022). E. mammata also occurs as a saprobe or innocuous pathogen on other trees: Betula spp., Fagus spp., Malus spp., Quercus spp., Ostrya spp. The main species at risk in Europe is the commercially exploited P. tremuloides (P. tremula mainly grows as a wild species, especially in mountain areas) but a range of other ecologically and economically important hosts may also be affected.

Host list: Alnus sinuata, Betula sp., Fagus sp., Malus sp., Ostrya sp., Populus adenopoda, Populus alba, Populus balsamifera, Populus grandidentata, Populus hybrids, Populus tremula, Populus tremuloides, Populus trichocarpa, Populus x wettsteinii, Quercus sp., Salix caprea, Salix cinerea, Salix daphnoides, Salix myrsinifolia, Salix pentandra, Salix phylicifolia, Salix sp., Salix triandra, Sorbus aucuparia

GEOGRAPHICAL DISTRIBUTION 2023-04-18

The analyses of various isolates from different continents and countries demonstrates that E. mammata is native to North America and that it was introduced into Eurasia (Kasanen et al., 2004). E. mammata is reported in North America, Europe, Asia (western Siberia of Russia), and Australia (Jeger et al., 2017). The pathogen has been reported in many EU countries. Its presence does not seem to be limited by the different ecoclimatic conditions in the EU, but it mainly has (with the exception of Sweden) a restricted distribution (Jeger et al., 2017).

EPPO Region: Czech Republic, France (mainland), Germany, Italy (mainland), Netherlands, Russia (Southern Russia, Western Siberia), Serbia, Slovakia, Sweden, Switzerland, Ukraine, United Kingdom (Channel Islands, England, Scotland)
North America: Canada (Alberta, British Columbia, Manitoba, New Brunswick, Nova Scotia, Ontario, Prince Edward Island, Québec, Saskatchewan), United States of America (Alaska, Iowa, Michigan, Minnesota, Montana, New Hampshire, New York, Wisconsin)
Oceania: Australia

BIOLOGY 2023-04-18

E. mammata is the causal agent of hypoxylon canker of quaking aspen (P. tremuloides) and other poplars (Populus spp.). Hypoxylon canker’s life cycle takes at least four growing seasons (Sinclair and Lyon, 2005). Ascospores are wind-disseminated. Spores infect host trees by entering the xylem through damaged bark, e.g. via pruning wounds or insect galleries. In the USA, a high proportion of cankers have been found to originate from insect wounds, notably galls caused by the cerambycid beetle Saperda inornata or cicada oviposition wounds (Ostry and Anderson, 2009; Ostry, 2013). The fungus is not thought to infect hosts via buds, leaves, petioles, or leaf axils (Ostry, 2013).

The fungus only damages live wood, and it does not expand far into dead wood (Ostry and Anderson, 2009; Jeger et al., 2017). Aspen bark contains natural fungicide substances that inhibit mycelia growth, so the pathogen invades the bark from within or through dying branches and then continues the expansion into the stem to avoid these compounds (Jeger et al., 2017; Lutter et al., 2019). Cankers result from infection by single ascospores (Ostry and Anderson, 2009). The period of colonization of aspen tissue by E. mammata before symptoms develop has been called both endophytic or latent phase and lasts on average 24 months (Ostry and Anderson, 2009).

Different studies (Anderson, 1964; Ostry and Anderson, 2009; Jeger et al., 2017; Lutter et al., 2019) showed that trees of all ages can be attacked, but disease incidence is often low and there are clonal differences in the resistance and susceptibility to hypoxylon canker. Host-specific toxins are involved in pathogenesis (Stermer et al., 1984; Ostry, 2013).

For more information, see Ostry and Anderson (2009), Ostry (2013), and Jeger et al. (2017).

DETECTION AND IDENTIFICATION 2023-04-18

Symptoms

Symptoms may vary depending on the stage of disease development. Symptoms appear on average two years after ascospore infection, cankers develop on branches and the trunk (Ostry, 2013). No signs are produced during the first year of infection. At the beginning, cankers become visible as slightly sunken, yellow-orange irregular areas (Sinclair and Lyon, 2005). Dying branches have yellow undersized leaves, dead branches have brown adhering leaves (Sinclair and Lyon, 2005). The outermost bark (periderm) becomes blistered and eventually hyphae break through and reveal a grey layer of fungal tissue with conidia (Ostry and Anderson, 2009). Hyphal pillars are produced during the second year and stromata with perithecia begin to form during the third year. A typical several year-old canker is elongated, may be up to 2.5 m in length and is usually centered at branch bases or galls induced by Saperda sp. (poplar gall longhorn beetle) and may be found near the site of wounds caused by wood boring insects or damage caused by woodpeckers foraging for insect larvae (Sinclair and Lyon, 2005; Ostry 2013; Jeger et al., 2017). From a distance, an infected trunk appears mottled while the canker has one or a few wood ridges and cracked bark (Sinclair and Lyon, 2005). The cankers expand at the margins, elongating 7–8 cm per month during the summer and a few mm per month during the winter (Sinclair and Lyon, 2005). Cankers usually expand too fast for callus to develop.

For more information, see Sinclair and Lyon (2005), Ostry (2013), Jeger et al. (2017).

Morphology

Cutting the infected yellow-orange bark of young cankers, or near the margin of old ones reveals a laminated or mottled, black and yellowish-white cortex (Sinclair and Lyon, 2005). This distinguishes hypoxylon canker from bark yellowing due to other pathogenic fungi (e.g., Valsa spp.). White mycelial fans occur in the cambial zone at the margin of the cankers, and can be seen when the bark is removed. Characteristic ‘conidial pillars’ formed below the periderm can be seen (Sinclair and Lyon, 2005).

Conidia are produced in grey, powdery masses under the blistered bark in a grey mat of fungal tissue; one-celled, nearly colourless, oblong-ovoid, hyaline, 5.5–8.0 x 1.5–4.0 µm in size (Sinclair and Lyon, 2005). The conidia are not infectious but are thought to function as spermatia and are thus important for the sexual reproduction (Ostry, 2013). Perithecial stromata develop about 3 years after conidia on blackened, cracked bark and stromata are round in outline, erumpent, flattened, hard, whitish when young and black when mature, 2–5 mm in diameter and 1–2 mm thick (Sinclair and Lyon, 2005). Stroma are uni- to most often multiperitheciate, they contain up to 30 perithecia 0.7–1.0 mm in diameter, white pruinose when young, dull black with age, strongly carbonaceous, with well-exposed perithecial mounds (Ju and Rogers, 1996). Ascospores are unicellular, brown, oblong-ellipsoid ascospores emerge, 22–33 x 9–13 µm in size (Sinclair and Lyon, 2005; Jeger et al., 2017). The ascospores are dispersed from perithecia during wet weather throughout most of the year when the air temperature is as low as −4°C (Sinclair and Lyon, 2005). Germination occurs during humid conditions at temperatures above 16°C but is more rapid at 28–32°C (Sinclair and Lyon, 2005). Ascospores continue to be dispersed from cankers on felled trees which remain on the ground for up to 23 months (Jeger et al., 2017).

For more information, see Hawksworth (1972), Ostry (2013), and Jeger et al. (2017).

Detection and inspection methods

E. mammata can be identified based on the very specific canker symptoms and the species specific morphological structures of perithecia and the ascospores (Jeger et al., 2017). Due to the presence of clear papillate ostioles, E. mammata can be distinguished from the species belonging to the closely related genera such as Amphirosellinia, Nemania, and Rosellinia (Sinclair and Lyon, 2005; Jeger et al., 2017). The whole genome of E. mammata is sequenced and available for the development of fungal specific primers for conventional PCR or real-time PCR tests or for population studies, phylogenetic studies, etc. (Lutter et al., 2019).

PATHWAYS FOR MOVEMENT 2023-04-18

E. mammata is able to spread via airborne ascospores, infected plants for planting, and wood with bark. Ascospores are expelled from perithecia throughout the year after rain, when stromata are wet and even at air temperatures as low as -4°C (Sinclair and Lyon, 2005). Airborne ascospores constitute the main inoculum for disease spread during a large part of the year (Rogers and Yu, 1996; Jeger et al., 2017). As the latent period of infection is more than 2 years, the pathogen could also be moved over long distances on infected but asymptomatic plants (Jeger et al., 2017). Several insects, mostly poplar borers and cicadas, cause wounds that may serve as entry points and hence may facilitate spread in localized areas (Ostry and Anderson, 2009). A strong association between pruning wounds and cankers has also been indicated (Sinclair and Lyon, 2005).

PEST SIGNIFICANCE 2023-04-18

Economic impact

The area of Populus plantations has recently increased in Europe due to the demand for woody biomass and local P. tremula is highly valued for biodiversity purposes (Lutter et al., 2019). Currently, hybrid aspen is the most frequently grown species for short-rotation forestry and long-term breeding programs, although, such monocultural plantations with a few clones might be highly susceptible to outbreaks of different pests including E. mammata (Lutter et al., 2019). In the EPPO region, E. mammata has been recorded as occurring mainly on the mountain race of P. tremula which is widely distributed in Europe. Generally, E. mammata is not reported to be of significant economic importance in any European countries (Jeger et al., 2017), although the risk presented by E. mammata in Europe depends on the susceptibility of the clones which are planted (Lutter et al., 2019). In Sweden, hypoxylon canker has been reported to have caused extensive damage during the 1950s, as the fungus can severely affect vitality of the trees (Stener, 2010). Environmental impacts can be expected in some cases, and this provides an additional threat to the biodiversity of Populus spp., especially P. nigra, which is endangered through much of Western Europe because of the loss of floodplain forest habitats and replacement of P. nigra by the hybrid poplars (Jeger et al., 2017).

Control

There are no available reports of eradication of E. mammata from an infested area. Also, there are no satisfactory control measures, although, in North America, aspen breeding for canker resistance has had some success (Ostry and Anderson, 2009; Jeger et al., 2017; EPPO, 2023). However, the majority of interspecific hybrids were found to be susceptible to other bark and leaf diseases, and natural hybrids (P. grandidentata x P. tremuloides) were also vulnerable to other disease, including hypoxylon canker (Ostry and Anderson, 2009). Selection of resistant clonal material, and genetic improvements are actively continuing, and tissue culture screening methods are being used. Eradication of the pathogen inoculum by felling infected trees is not an optimal strategy to prevent new infections because a single overlooked canker can produce an abundance of spores, thus demonstrating the lack of feasibility of local eradication (Manion and Griffin, 1986). Site selection for new plantations with optimal conditions for planting and growth, winter pruning of infected branches before canker spread to the stem as well as maintaining high stocking densities (so removal of infected material will have a limited impact on overall production levels) are of key importance to reduce losses due to the infection of E. mammata (Ostry and Anderson, 2009; Jeger et al., 2017).

Phytosanitary risk

Plants for planting and wood with bark are considered the host commodities which provide the main pathway for entry for the E. mammata (Ostry, 2013; EPPO, 2023).

E. mammata is already present in the EPPO region and has been reported from many EPPO countries. However, E. mammata has been removed from the EPPO lists of quarantine pests in 1984 as E. mammata was found to be much more widely distributed in the EPPO region than it was previously thought and European cultivars were practically all resistant, so the seriousness of the disease in relation to the EPPO region was felt to be unfounded (EPPO, 1988). On native species, it seems to have reached the limits of its potential distribution; on hybrid Populus, while it does present some danger, it is already a common pathogen (Pinon, 1986). Accordingly the Commission Implementing Regulation (EU) 2019/2072, E. mammata is included in Annex III (List of protected zones and the respective protected zone quarantine pests) for Ireland and United Kingdom (Northern Ireland) (EU, 2019).

PHYTOSANITARY MEASURES 2023-04-18

E. mammata is a quarantine pest for protected zones (Ireland and United Kingdom (Northern Ireland)) (EU, 2019). It is also a quarantine pest in Israel (since 2009) and China (since 2021) (EPPO, 2023). Currently, EPPO does not recommend any particular phytosanitary measures for this pest. However, if needed, the following measures outlined in the EFSA pest categorization (Jeger et al., 2017) might be followed:

- selecting suitable sites for planting and avoiding host wounding,
- nursery inspections to ensure that plantations or landscape plantings are not made with infected stock,
- selection of resistant clonal material and genetic improvement.

Import of host plants for planting and wood with bark from pest-free areas might also serve as phytosanitary measures for this pest.

REFERENCES 2023-05-12

CABI (2020) Distribution Maps of Plant Diseases. Entoleuca mammata. https://doi.org/10.1079/DMPD/20203227937

Dickmann DI & Kuzovkina J (2014) Poplars and willows of the world, with emphasis on silviculturally important species. In: Isebrands JG, Richardson J (eds) Poplars and willows: trees for society and the environment. FAO and CABI, London, 8–91.

EFSA Panel on Plant Health (PLH) Jeger M, Bragard C, Caffier D, Candresse T, Chatzivassiliou E, Dehnen-Schmutz K, Gilioli G, Gregoire J-C, Jaques Miret JA, MacLeod A, Navajas Navarro M, Niere B, Parnell S, Potting R, Rafoss T, Rossi V, Urek G, Van Bruggen A, Van der Werf W, West J, Winte, S, Boberg J, Gonthier P & Pautasso M (2017) Scientific opinion on the pest categorisation of Entoleuca mammata. EFSA Journal, 15(7), 4925. https://doi.org/10.2903/j.efsa.2017.4925

EPPO (2017) EPPO Standard PM 8/7(1) Populus. EPPO Bulletin 47(3), 470–478. https://doi.org/10.1111/epp.12414

EPPO (1988) EPPO Global Database Reporting Service no. 02 1988 Num. article: 1988/01 https://gd.eppo.int/reporting/article-5677 [last accessed 20 Feb 2023].

EPPO (2022) EPPO Global Database page on EPPO A1 and A2 lists of pests recommended for regulation as quarantine pests. PM 1/002(30). https://gd.eppo.int/standards/PM1/ [last accessed 20 Feb 2023].

EPPO (2023) EPPO Global Database page on Entoleuca mammata. https://gd.eppo.int/taxon/HYPOMA [last accessed 20 Feb 2023].

Eriksson OE (2014) Checklist of the non-lichenized ascomycetes of Sweden (2nd ed.). Acta Universitatis Upsaliensis, 499 pp. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-228443 [last accessed 20 Feb 2023].

EU (2019) Commission Implementing Regulation (EU) 2019/2072 of 28 November 2019 establishing uniform conditions for the implementation of Regulation (EU) 2016/2031 of the European Parliament and the Council, as regards protective measures against pests of plants. https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX%3A32019R2072 [last accessed 20 Feb 2023].

GBIF.org (Global Biodiversity Information Facility) (2022) GBIF Occurrence of Entoleuca mammata (Wahlenb.) J.D. Rogers & Y.M. Ju. Download https://doi.org/10.15468/dl.w8vdpk. https://www.gbif.org/species/2576553 [last accessed 20 Feb 2023].

Hawksworth DL (1972) Hypoxylon mammatum. CMI Descriptions of Pathogenic Fungi and Bacteria No. 356. CABI, Wallingford, UK.

Jayawardena RS, Hyde KD, McKenzie EH, Jeewon R, Phillips AJ, Perera RH, ... & Wang Y (2019) One stop shop III: taxonomic update with molecular phylogeny for important phytopathogenic genera: 51–75. Fungal Diversity 98(1), 77–160. https://doi.org/10.1007/s13225-019-00433-6

Ju YM (1995) A revision of the genus Hypoxylon. Washington State University. American Phytopathological Society Mycologia Memoir no. 20. 382 pp.

Kasanen R, Hantula J, Ostry M, Pinon J & Kurkela T (2004) North American populations of Entoleuca mammata are genetically more variable than populations in Europe. Mycological Research 108, 766–774. https://doi.org/10.1017/S0953756204000334

Lutter R, Drenkhan R, Tullus A, Jürimaa K, Tullus T & Tullus H (2019) First record of Entoleuca mammata in hybrid aspen plantations in hemiboreal Estonia and stand-environmental factors affecting its prevalence. European Journal of Forest Research 138(2), 263–274. https://doi.org/10.1007/s10342-019-01165-7

Manion PD & Griffin DH (1986) Sixty-five years of research on hypoxylon canker of aspen. Plant Disease 70, 803–805.

Miller JH (1961) A monograph of the world species of Hypoxylon. University of Georgia Press, Athens, Georgia, USA.

NBN Atlas (2022) National Biodiversity Network: Fungal Records Database of Britain and Ireland for Entoleuca mammata. British Mycological Society Available online: https://species.nbnatlas.org/species/BMSSYS0000006456# [last accessed 20 Feb 2023].

Ostry ME & Anderson NA (2009) Genetics and ecology of the Entoleuca mammata-Populus pathosystem: Implications for aspen improvement and management. Forest Ecology and Management 257(2), 390–400. https://doi.org/10.1016/j.foreco.2008.09.053

Ostry ME (2013) Hypoxylon canker. In: Gonthier P & Nicolotti G (eds.). Infectious Forest Diseases. CABI, Wallingford. 407–419.

Pinon J (1986) Situation d'Hypoxylon mammatum en Europe. EPPO Bulletin 16, 543–546.

Rogers JD & Ju YM (1996) Entoleuca mammata comb. nov. for Hypoxylon mammatum and the genus Entoleuca. Mycotaxon 59, 441–448.

Sinclair WA & Lyon HH (2005) Diseases of Trees and Shrubs, 2nd Edition. Comstock Publishing Associates, a division of Cornell University Press, Ithaca, NY.

Seebens H, Blackburn TM, Dyer EE, Genovesi P, Hulme PE, Jeschke JM, Pagad S, Pyšek P, Winter M, Arianoutsou M, Bacher S, Blasius B, Brundu G, Capinha C, Celesti-Grapow L, Dawson W, Dullinger S, Fuentes N, Jäger H, Kartesz J, Kenis M, Kreft H, Kühn I, Lenzner B, Liebhold A, Mosena A et al. (2017) No saturation in the accumulation of alien species worldwide. Nature Communications 8(2), 14435. http://www.nature.com/articles/ncomms14435

Stener LG & Karlsson B (2004) Improvement of Populus tremula × P. tremuloides by phenotypic selection and clonal testing. Forest Genetics 11(1), 13–24.

Stener LG (2010) Tillväxt, vitalitet och densitet för kloner av hybridasp och poppel i sydsvenska fältförsök [Growth, vitality and density of hybrid aspen and poplar clones from field trials in Southern Sweden]. Arbetsrapport 717, Skogforsk, Sweden. https://www.skogforsk.se/cd_20190114162830/contentassets/bdd944d7edd04630b86d97d6fd172009/arbetsrapport-988-2018.pdf [last accessed 20 Feb 2023].

ACKNOWLEDGEMENTS 2023-04-18

This datasheet was extensively revised in 2023 by Kateryna Davydenko, the Ukrainian Research Institute of Forestry and Forest Melioration and the Swedish University of Agricultural Science. Her valuable contribution is gratefully acknowledged.

How to cite this datasheet?

EPPO (2024) Entoleuca mammata. EPPO datasheets on pests recommended for regulation. https://gd.eppo.int (accessed 2024-11-23)

Datasheet history 2023-05-12

This datasheet was first published in the EPPO Bulletin in 1983 and revised in the two editions of 'Quarantine Pests for Europe' in 1992 and 1997, as well as in 2023. It is now maintained in an electronic format in the EPPO Global Database. The sections on 'Identity', ‘Hosts’, and 'Geographical distribution' are automatically updated from the database. For other sections, the date of last revision is indicated on the right.

CABI/EPPO (1992/1997) Quarantine Pests for Europe (1st and 2nd edition). CABI, Wallingford (GB).

EPPO (1983) Data sheets on quarantine organisms No. 72, Hypoxylon mammatum. EPPO Bulletin 13(1), 4 pp. https://onlinelibrary.wiley.com/doi/epdf/10.1111/j.1365-2338.1983.tb01719.x