Abstract
Several forest non-native pests and pathogens that are among the most frequently cited invasive species worldwide represent serious economic and conservation concerns for the forest ecosystems in their region of introduction. Such organisms can have adverse impacts on the yield of marketable wood products, such as timber and pulp, as well as non-wood forest products, such as nuts, fruits, and seeds. However, quantitative data about impacts on forest market resources are rare and usually restricted in time and space. Moreover, information on regional impacts, and aggregate data including multiple invasive species, are largely missing or miscalculated. The most comprehensive studies show that the greatest impacts of pest invasions on native tree species are effects on non-market values whereas losses in wood and non-wood forest products account for a small part of the total impacts. Patterns are somewhat different in plantations of non-native trees, where non-native pests are more likely to affect the forestry sector directly through reduced fibre yield and increased management costs, whereas non-market values and environmental impacts are of lesser concern. This chapter argues that direct impacts on market forest resources are sometimes largely exaggerated and provides reasons for these overestimations.
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Keywords
- Economic impact
- Forestry
- Forest market resources
- Invasive pests
- Non-native trees
- Non-wood forest products
- Yield loss
1 Introduction
Non-native damaging invertebrates and pathogens (hereafter pests) are a critical and increasing threat to trees and forest ecosystems. In contrast to many other invasive species arriving on new continents intentionally, tree pests are nearly always introduced accidentally, usually through the trade in live plants, wood, or wood products (Liebhold 2012). As a result, their introduction is particularly difficult to control and, despite the intensification of phytosanitary measures worldwide, the number of new establishments of non-native tree pests and their damage continue to increase (Aukema et al. 2010).
Although most non-native pests cause little impact, a few species cause substantial damage to their host trees and, in a few cases, can locally eliminate tree species and alter ecosystems (Kenis et al. 2009). Native forests of eastern North America have suffered particularly from non-native pests in the past century, with the strong decline of keystone species such as the American chestnut (through chestnut blight, Cryphonectria parasitica), elms (Dutch elm disease, Ophiostoma ulmi and O. novo-ulmi) (Fig. 7.1), eastern and Carolina hemlock (hemlock woolly adelgid, Adelges tsugae), Fraser fir and other firs (balsam wooly adelgid, Adelges piceae), and ash species (emerald ash borer, Agrilus planipennis) (Aukema et al 2010; Liebhold et al. 2013). Such declines affect ecosystems and their services in many ways.
This review is restricted to the impact on production of marketable tree resources, that is, provisioning ecosystem services. For most forests, the primary market product is wood fibre, utilised primarily for lumber, pulp, and fuel, but non-wood forest products (NWFP) such as nuts, fruits, and seeds are also considered. The important ecological impacts that these invasive species have in forests on supporting, regulating, and cultural ecosystems services and human well-being are not considered, although it is clear that all these services are closely interconnected. Effects on ornamental trees and the ornamental plant market are also excluded.
Some studies indicate that wood and NWFP losses account for a small part of the economic impacts of forest pests, the largest part being represented by non-market tree values, such as loss of property values or federal and local government expenditures (Holmes et al. 2009; Aukema et al. 2011). They account for an even smaller part of the impacts when all ecosystem services are considered, even if comparing ecosystem services remains a challenge (Branco et al. 2015). This problem is particularly acute when pests affect native keystone tree species (Kenis et al. 2009; Aukema et al. 2010).
2 Impact on Wood Fibre Production
Impacts on wood fibre production can involve at least three mechanisms: first, pests can affect tree growth increment; second, they can kill mature trees; and third, they can affect regeneration by killing seeds or seedlings in either a seed orchard or nursery or a forest stand. Obviously, the same pest can affect wood production in two or three ways. Another useful categorisation is whether the pest affects native trees or plantations of non-native trees. This concern is important because damage to non-native plantations is likely to affect primarily the forest industry through wood fibre losses and management costs related to invasion, such as mandatory fumigations, whereas pests affecting predominantly native trees are likely to have more complex and integrated economic, social, and ecological impacts in which the damage to the forestry sector may be marginal. However, it is remarkable how few quantitative studies on their impact on wood production have been published. Most data only concern a single species in a single country or even in a specific stand during a limited period of time. Information on regional impacts and aggregate data including multiple pest species are largely missing. Table 7.1 provides a nonexhaustive list of forest pests for which some type of quantitative assessment of their damage to wood and non-wood forest products has been estimated.
2.1 Damage to Native Tree Species
One of the most comprehensive studies on the economic impact of forest pests was that of Aukema et al. (2011), who calculated the economic damage caused by three pests affecting mainly native trees in the USA: Agrilus planipennis, Adelgid tsugae, and the gypsy moth, Lymantria dispar. They classified economic losses in five categories: (1) federal government expenditures (survey, research, regulation, management, and outreach); (2) local government expenditures (tree removal, replacement, and treatment); (3) household expenditures (tree removal, replacement, and treatment); (4) residential property value losses; and (5) timber value losses to forest landowners. For the three species, average annual timber losses in 2009 were estimated at US$60 million, US$1.1 million, and US$4.6 million, respectively. Interestingly, this represented only 3.6 %, 0.5 %, and 1.8 % of the total estimated costs calculated for the three insects, the majority of the costs affecting non-market values and borne by homeowners and municipal governments. When extrapolated across all non-native forest insect pests of the three main guilds (phloem and wood borers, sap feeders, and foliage feeders), the total annual cost was nearly US$5 billion, of which only US$65.7 million was related to timber value loss.
Interestingly, in an earlier study, Pimentel et al. (2000) had estimated the annual losses of timber caused by non-native pests to be much higher, that is, US$4.2 billion (arthropods and pathogens accounting for 50 % each). This estimate was based on an assumption that all (native and non-native) forest pests reduce overall timber productivity by 18 % and non-native species account for 30 % of the damage caused by all forest pests. Colautti et al. (2006) presented several cases of the economic costs of invasive species, including control costs for O. ulmi and O. novo-ulmi in Manitoba and of A. planipennis in a specific county. They also projected the economic losses in value to forest products in Canada to be CAN$9.6 billion (ranging from CAN$7.7 billion to CAN$20 billion). Although these and other basic calculations of economic impacts of invasive species have been useful for drawing attention to the significance of pests, they have been criticised for various reasons, such as failing to account for nonmarket economic values and the ability to substitute one resource for another and double-counting certain costs (Holmes et al. 2009; Aukema et al. 2011). Estimates in Colautti et al. (2006) were made using a price-times-quantity method (Holmes et al. 2009) in which impact is estimated as simply the volume of trees killed multiplied by a stumpage price. This method is problematic because it fails to account for the fact that (1) many affected stands would never be harvested; (2) other stands will be harvested sometime in the future and during this lag surviving trees will grow and compensate for the damage; and (3) forest managers may salvage affected trees, thereby recouping partial losses, or they may adjust their business plan in other ways (e.g., delay harvest or substitute other products). Unfortunately, the price-times-quantity method has been applied in other impact estimates as well.
Although historically European forests have suffered less from non-native pests than other continents, new forest pests are now introduced at a faster rate in Europe than in other continents. A long list of newly established species is threatening European forestry and urban forestry (Roques 2010; Santini et al. 2013). As elsewhere, economic impacts of pests on native ornamental trees are greater than in natural forests and, consequently, costs are mainly borne by municipalities and private owners. For example, damage by O. ulmi and O. novo-ulmi has cost €9–228 million annually since 1979, but mainly for felling and replacing ornamental trees in urban areas (Gren et al. 2009). High costs are also related to control measures, in particular mandatory phytosanitary measures related to eradication or containment programmes. The large efforts to eradicate and contain the pine wood nematode Bursaphelenchus xylophilus, causal agent of the pine wilt disease in Portugal, has been described in detail by Sousa et al. (2011). Although recent estimations of the costs to the Portuguese and EU authorities and the private sector are not available, they are undoubtedly much higher than the loss of timber directly attributable to the pest. Nevertheless, they are surely justified because damage at the European scale could be substantial. Soliman et al. (2012) estimated that an unregulated infestation of B. xylophilus in the EU could cause a loss of forestry stock over 22 years (2008–2030) that would cost €22 billion. In Japan, where the nematode is also invasive, wood losses exceed 2,000,000 m3 per year (CABI 2015). Other examples of pests for which management costs for eradication or containment have so far largely exceeded direct wood losses are the two Asian longhorned beetles, Anoplophora glabripennis and A. chinensis. In the past two decades, both species have been under costly eradication programmes in various regions in Europe and North America. For example, from 1997 to 2006, US federal, state, and local authorities have spent more than US$800 million on A. glabripennis eradication measures in urban settings, involving surveys, removal, treatment to destroy all life stages present (e.g., chipping), and replacement (Smith and Wu 2008).
An example of a pathogen threatening native wood fibre production is the fungus Cronartium ribicola, the agent of the white pine blister rust. This pathogen completes its life cycle between five-needle pines (Pinus, subgenus Strobus) and plants of the genus Ribes. This fungus is able to kill trees of all ages, but the rust is particularly damaging in young stands, preventing them from growing to a merchantable age. Cronartium ribicola is considered endemic to Siberia and was first reported in eastern North America in 1906 and western North America in 1921. It has become the most important disease of several white pine species in North America (Maloy 1997). However, damage is now most severe in Western North America, for example, on Pinus monticola, P. flexilis, P. albicaulis, and P. lambertiana, for which mortality rates of 95 % have been reported in Sierra Nevada. These species are not extensively planted for timber, and thus the pathogen now causes more concern for its environmental impact than for its impact on the forest industry (CABI 2015).
In contrast to bark and wood borers and certain tree pathogens, defoliators and sap feeders often do not directly kill trees but more commonly affect wood fibre production through growth losses. Outbreaks of the gypsy moth in North America can cause up to 50 % reduction in annual growth increment in broad-leaved trees (Muzika and Liebhold 1999; Naidoo and Lechowicz 2001) (Fig. 7.2). Simmons et al. (2014) also reported a growth rate reduction of nearly 50 % as a result of defoliation of oak by the winter moth, Operophtera brumata. However, defoliation can often lead to crown dieback and ultimately tree mortality, although very often secondary insects and pathogens are involved. In the case of outbreaks of the invasive gypsy moth in North America, this mortality can sometimes be extensive, especially in oaks, but then increased growth typically occurs in non-hosts and surviving hosts consequent to a thinning effect. As such, in many areas with a long history of gypsy moth outbreaks, long-term regional impacts on merchantable volume may be minimal (Gansner et al. 1993).
2.2 Damage to Non-native Tree Species
Fast-growing non-native tree species (e.g., eucalyptus, pine, cypress, spruce) are frequently planted in the Southern Hemisphere and elsewhere. These plantations often exhibit exceptionally high growth increment and their economic success can, at least in part, be attributed to the fact that trees are growing largely pest free (Liebhold 2012). These plantations are thus particularly sensitive to the introduction of non-native pests. Various introductions of insects and pathogens have seriously affected such plantations in the past century. For example, the most damaging pest of non-native pine plantations in the Southern Hemisphere is probably the European sirex woodwasp, Sirex noctilio (Fig. 7.3). However, only damage records in specific stands or areas are available (e.g., mortality rates of 30 % in New Zealand in 1946–1951; 40 % in Tasmania and up to 75 % in Victoria, Australia, between 1932 and 1979; 60 % in Brazil in 1989). In Southern Australia between 1987 and 1989, an outbreak of S. noctilio caused the death of 5 million trees with a value of AUS$10–12 million (CABI 2015), but such estimates are calculated using the volume-times-price method, which does not provide a meaningful quantification of economic impact, as described previously.
The green spruce aphid is one of the few species for which data are abundantly available. Elatobium abietinum originates in Central Europe where it occurs on Picea abies and has been introduced in many parts of the world, affecting both native and non-native spruce stands and plantations. In the UK and Northern Europe, it causes extensive defoliation of Sitka spruce, Picea sitchensis, severely reducing height increment by 20–60 % in the year of attack. Similarly, defoliation also decreases diameter increment for 7–8 years, with a mean reduction of 18.5–40.5 %. Even moderate defoliation can cause increment loss in some spruce species (CABI 2015). In Iceland, damage was so severe that initiation of new spruce plantations has largely been abandoned in southern regions (Halldórsson et al. 2003). Interestingly, although in Europe E. abietinum rarely kills trees, it has devastated natural stands of P. englemannii and P. pungens in the interior southwest USA. In New Zealand, tree mortality was also observed, and the aphid is considered to be the main factor preventing spruce being used as a production species in the country (CABI 2015).
Eucalyptus is one of the most widely planted tree genera worldwide (Branco et al. 2015). Various species are planted for pulp and other purposes in all tropical and warm temperate climates. In the past 20–30 years, almost all plantation regions have suffered from a series of invasions by insects originating from Australia (Branco et al. 2015). Damage has often been very serious but, here again, precise data are scarce and limited in time and space. For example, in southwestern Spain, the cost of damage caused by the Australian longhorn borer, Phoracantha semipunctata, on timber yield losses, plus the costs of disposing of non-usable timber, were estimated at more than US$9 million in 1983, and US$7 million in 1984, for an area of 300,000 ha of eucalyptus plantations (Branco et al. 2015). In Galicia, Spain, the snout beetle, Gonipterus platensis, was estimated to reduce tree growth by 30 %, causing an economic loss of US$10.5 million annually. In Portugal, the same insect decreased wood volume (projected to 10 years of age) by 51 % in the affected areas in 2004–2006, with losses increasing exponentially with tree defoliation, by up to 43 % and 86 %, corresponding to 75 % and 100 % defoliation, respectively (Branco et al. 2015).
These and other pests have also caused serious problems to eucalyptus forestry elsewhere. In some areas, damage was so severe that planting of susceptible eucalyptus species was abandoned or greatly decreased, such as in New Zealand following the establishment of the eucalyptus tortoise beetle, Paropsis charybdis, and other insects and pathogens of Australian origin (CABI 2015). In the absence of precise data on economic losses, the abandonment of commercial tree species because of pests is a good indication of the economic importance of the damage. Another example is provided by cypress plantations in eastern Africa. In this region, damage from the cypress canker, Lepteutypa cupressi, led to the replacement of Cupressus macrocarpa by C. lusitanica, which in turn became severely affected by the introduced cypress aphid, Cinara cupressivora, in the 1980s (Cock 2003). Several studies attempted to estimate the economic damage of the latter species and two other invasive conifer aphids in eastern Africa, the pine woolly aphid, Pineus boerneri, and the pine needle aphid, Eulachnus rileyi, (Cock 2003). In 1991, it was estimated that, up to 1990, C. cupressivora had killed trees worth US$44 million and was causing an additional loss of a further US$14.6 million per year through reduction in annual growth increment. The two pine aphids caused a loss of US$2.4 million per year in the region by reductions in the annual growth increment. These figures were considered conservative because they did not include the impact of the aphids on indigenous tree species or allow for any subsequent mortality from C. cupressivora. In Kenya, another study estimated that C. cupressivora had the potential to kill up to 50 % of all cypress trees during the 30-year harvest cycle.
It should be noted that many insect pest problems in non-native plantations have been solved through the introduction of natural enemies from the area of origin of the pests. For example, the aforementioned beetles, P. semipunctata and Gonipterus spp., are successfully controlled by egg parasitoids and, to a lesser extent, populations of C. cupressivora in East Africa have also been reduced by a parasitoid (CABI 2015). Sirex noctilio has been controlled to varying degrees in New Zealand and Australia by introductions of a nematode and parasitoids. Changes in silvicultural practices have also greatly contributed to reducing impacts, particularly in New Zealand.
Plantations of non-native trees are also very sensitive to tree pathogens. A recent example is provided by the Japanese larch, Larix kaempferi, widely planted in the British Isles for timber production but also for landscaping and recreational purposes. Since 2009, a widespread dieback and mortality was reported in various parts of the UK and Ireland. Up to 2010, 2400 ha, or about 0.6 million mature larch, were affected. The disease was caused by Phytophthora ramorum, an invasive pathogen already known as the cause of “Sudden Oak Death” in western USA (Brasier and Webber 2010; CABI 2015). Trees in affected plantations are felled to minimise further spread, both to forests and to susceptible heathland vegetation. This development could therefore have a significant impact on local economies and Britain’s strategic reserve of timber (Brasier and Webber 2010).
Another older case of an invasive pathogen affecting non-native plantations in Europe is that of the white pine blister rust, Cronartium ribicola. In addition to its damage on native five-needle pines in North America as already mentioned, it also eliminated plantations of the American white pine, Pinus strobus, in Europe in the nineteenth to twentieth century. In this case, the abandonment was also motivated by the fact that the disease was also seriously threatening cultivated Ribes plantations, in particular black currant, as the fungus requires the two hosts to complete its development (Maloy 1997; CABI 2015).
3 Impact on Non-wood Forest Products
A variety of other marketable products, such as nuts, berries, and seeds, game animals, mushrooms, oils, medicinal plants, tannins, peat, and forage are often harvested from forests and have considerable value. Their availability can also be affected by pests, but quantitative data are even scarcer than for wood.
Probably the best data on NWFP losses are from conifer seed orchards. Commercial seed production in the European seed orchards is largely affected by non-native seed chalcids of the genus Megastigmus, and especially by the American Douglas-fir seed chalcid, M. spermotrophus. Douglas-fir seeds for reforestation are sold at a price of approximately 6000 €/kg, but chalcid infestation may decrease the number of healthy seeds by as much as 95 % (Auger-Rozenberg and Roques 2012). The recent arrival of the western North American conifer seed bug, Leptoglossus occidentalis, decreased the seed yields in Douglas-fir and pine seed orchards in France by as much as 25.7 % and 15 %, respectively (Lesieur et al. 2014) (Fig. 7.4).
Wild fruits for human consumption can also be affected by forest pests. The strong decline in the production of edible nuts of the stone pine, Pinus pinea, observed all around the Mediterranean Sea, is attributed in large part to the arrival of L. occidentalis. Roversi et al. (2011) mention an unpublished study in an Italian forest measuring that 80 % of the 2-year-old conelets aborted, but large-scale assessments of the effect of the bug on seed production decline are still lacking.
Chestnut production, both in orchards and forests, has been devastated by two Asian invaders, the chestnut blight, Cryphonectria parasitica, and the chestnut gall wasp, Dryocosmus kuriphilus. In the first half of the twentieth century, almost all mature American chestnut trees were killed by chestnut blight (CABI 2015). The tree now survives as small understory trees. The disappearance of chestnut from American forests also affected the production of other NWFP, such as tannic acid used in leather production. In Europe, the pathogen has been less destructive but, recently the European chestnut has been strongly affected by the arrival of the chestnut gall wasp with losses in nut production as great as 80 % (Battisti et al. 2014).
4 Conclusions
There is no doubt that invasions of non-native invertebrates and pathogens can have dramatic economic and ecological impacts on trees and forests. However, direct impacts on market forest resources may sometimes be largely overestimated. Although there are numerous cases of serious impact on tree mortality or tree growth, we are aware of just a few cases where a pest invasion has actually reversed the profitability of forest production. Examples of such reversals include plantations of spruce in southern Iceland and New Zealand, as a result of invasion by Elatobium abietinum, and the abandonment of white pine plantations in Europe because of Cronartium ribicola, and of several eucalyptus species in New Zealand following the invasion of Australian insects and pathogens. There are numerous reasons why impacts may sometimes be exaggerated. First, for most species, a true assessment of pest species across entire regions over many years is often missing. Such assessments are necessary to form a reliable characterisation of the economic impact of an invading species over an extended period of time (Epanchin-Niell and Liebhold 2015). Second, studies that quantify impacts simply as total numbers of trees or volume killed are inadequate for evaluating the ultimate impacts of a pest on the forest, because between the time of tree mortality (or loss of growth) and harvest, trees in a stand will grow and compensate, at least partly, for mortality or growth loss (Holmes et al. 2009). Thus, simply multiplying the volume of trees killed by its value is completely inadequate for estimating impacts. Impacts on non-market values are undoubtedly highly important, especially when native trees are affected, and fully justify measures put in place to prevent and manage non-native pests (Aukema et al. 2011). However, methods need to be developed to quantify and aggregate market and non-market impacts caused by forest non-native pests.
References
Auger-Rozenberg MA, Roques A (2012) Seed wasp invasions promoted by unregulated seed trade affect vegetal and animal biodiversity. Integr Zool 7:228–246
Aukema JE, McCullough DG, Von Holle B et al (2010) Historical accumulation of nonindigenous forest pests in the continental US. Bioscience 60:886–897
Aukema JE, Leung B, Kovacs K et al (2011) Economic impacts of non-native forest insects in the continental United States. PLoS One 6(9):e24587
Battisti A, Benvegnù I, Colombari F et al (2014) Invasion by the chestnut gall wasp in Italy causes significant yield loss in Castanea sativa nut production. Agric For Entomol 16:75–79
Branco S, Videira N, Branco M et al (2015) A review of invasive alien species impacts on eucalypt stands and citrus orchards ecosystem services: towards an integrated management approach. J Environ Manag 149:17–26
Brasier C, Webber J (2010) Sudden larch death. Nature (Lond) 466:824–825
CABI (2015) Invasive species compendium. CAB International, Wallingford. http://www.cabi.org/isc. Accessed 15 July 2015
Cock MJW (2003) Biosecurity and forests: an introduction, with particular emphasis on forest pests. FAO Forest Health and Biosecurity working paper FBS/2E
Colautti RI, Bailey AS, van Overdijk CDA et al (2006) Characterised and projected costs of nonindigenous species in Canada. Biol Invasions 8:45–59
Epanchin-Niell RS, Liebhold AM (2015) Benefits of invasion prevention: effect of time lags, spread rates, and damage persistence. Ecol Econ 116:146–153
Gansner DA, Arner SL, Widman RH et al (1993) After two decades of gypsy moth, is there any oak left? North J Appl For 10:184–186
Gren IM, Isacs L, Carlsson M (2009) Costs of alien invasive species in Sweden. Ambio 38:135–140
Halldórsson G, Benedikz T, Oddsdóttir E et al (2003) The impact of the green spruce aphid Elatobium abietinum (Walker) on long-term growth of Sitka spruce in Iceland. For Ecol Manag 181:281–287
Holmes TP, Aukema JE, VonHolle B et al (2009) Economic impacts of invasive species in forests past, present, and future. The year in ecology and conservation biology. Ann N Y Acad Sci 1162:18–38
Kenis M, Auger-Rozenberg M-A, Roques A et al (2009) Ecological effects of invasive alien insects. Biol Invasions 11:21–45
Lesieur V, Yart A, Guilbon S et al (2014) The invasive Leptoglossus seed bug, a threat for commercial seed crops, but for conifer diversity? Biol Invasions 16:1833–1849
Liebhold AM (2012) Forest pest management in a changing world. Int J Pest Manag 58:289–295
Liebhold AM, McCullough DG, Blackburn LM et al (2013) A highly aggregated geographical distribution of forest pest invasions in the USA. Divers Distrib 19:1208–1216
Maloy OC (1997) White pine blister rust control in North America: a case history. Annu Rev Phytopathol 35:87–109
Muzika RM, Liebhold AM (1999) Changes in radial increment of host and nonhost tree species with gypsy moth defoliation. Can J For Res 29:1365–1373
Naidoo R, Lechowicz MJ (2001) Effects of gypsy moth on radial growth of deciduous trees. For Sci 47:338–348
Pimentel D, Lach L, Zuniga R, Morrison D (2000) Environmental and economic costs of nonindigenous species in the United States. Bioscience 50:53–65
Roques A (2010) Alien forest insects in a warmer world and a globalised economy: impacts of changes in trade, tourism and climate on forest biosecurity. N Z J For Sci 40(suppl):S77–S94
Roversi PF, Strong WB, Caleca V et al (2011) Introduction into Italy of Gryon pennsylvanicum (Ashmead), an egg parasitoid of the alien invasive bug Leptoglossus occidentalis Heidemann. EPPO Bull 41:72–75
Santini A, Ghelardini L, De Pace C et al (2013) Biogeographical patterns and determinants of invasion by forest pathogens in Europe. New Phytol 197:38–250
Shaw CG, Taes EHA (1977) Impact of Dothistroma needle blight and Armillaria root rot on diameter growth of Pinus radiata. Phytopathology 67:1319–1323
Simmons MJ, Lee TD, Ducey MJ et al (2014) Effects of invasive winter moth defoliation on tree radial growth in eastern Massachusetts, USA. Insects 5:301–318
Smith MT, Wu J (2008) Asian longhorned beetle: renewed threat to northeastern USA and implications worldwide. Int Pest Control 50(6):311–316
Soliman T, Mourits MCM, van der Werf W et al (2012) Framework for modelling economic impacts of invasive species, applied to pine wood nematode in Europe. PLoS One 7(9):e45505
Sousa E, Rodrigues JM, Bonifácio L et al (2011) Management and control of the pine wood nematode, Bursaphelenchus xylophilus, in Portugal. In: Boeri F, Chung JA (eds) Nematodes: morphology, functions and management strategies. Nova Science, Hauppauge, pp 157–178
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We thank B. Hurley and E. Brockerhoff for assistance in obtaining technical information, and M. Vilà and S. Woodward for useful comments on the manuscript.
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Kenis, M., Roques, A., Santini, A., Liebhold, A.M. (2017). Impact of Non-native Invertebrates and Pathogens on Market Forest Tree Resources. In: Vilà, M., Hulme, P. (eds) Impact of Biological Invasions on Ecosystem Services. Invading Nature - Springer Series in Invasion Ecology, vol 12. Springer, Cham. https://doi.org/10.1007/978-3-319-45121-3_7
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