Abstract
Biological invasions in forests are growing in number and importance globally. The best studied examples are those caused by plants and animals, including insects. In contrast, forest invasions caused by microbes, including fungi, have received much lower levels of attention, particularly in the invasion biology literature. This can at least to some extent be due to the large number of these organisms involved and the fact that the majority of these have yet to be discovered and described. This is equally true for tree-infecting fungi, many of which are devastating pathogens responsible for dramatic invasions in natural and planted forests. This situation is changing through the application of molecular genetic tools that make it possible to accurately identify fungal tree pathogens, to determine their origins, pathways of movement, their modes of reproduction and change; all of which can influence invasions. The role and relevance of symbioses between tree pathogens and insects in forest invasions is also gaining increased attention. So too is our understanding that trees live in close association with large numbers of microbes that make up their holobiome. This has substantial relevance to invasion biology (Zenni et al. 2017). This commentary highlights four emerging issues that need to be considered regarding the invasions by fungal pathogens of trees and it emphasizes opportunities to better understand their relevance and impacts on natural and planted forests. A call is also made for plant pathologists to work more closely with ecologists such that fungal pathogens become more commonly integrated into invasion biology programmes.
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Introduction
Invasion Biology was formulated little more than 50 years ago by Charles Elton via the publication of his monumental 1958 treatise “The Ecology of Invasions by Animals and Plants” (Elton 1958). Elton, who is broadly considered the ‘father of the field of Invasion Biology’ (Williamson 1996), barely considered microbial invasion in terms of human, animal and plant health and there were relatively few examples of insect pests presented in his work. Interestingly, Elton did include treatments of two North American tree-invasion problems; those of the devastating Chestnut Blight disease caused by the fungal pathogen Endothia parasitica (now Cryphonectria parasitica) and the gypsy moth (Lymantria dispar) invasion. From an ecological standpoint, invasions by plants and animals have received the bulk of attention. Although forests and woody ecosystems have become more prominent in the scientific literature in recent years, it is clearly a topic that deserves much greater attention, especially where forest pests and pathogens are concerned.
Four key steps have traditionally been used to describe the invasion process and these include (1) Transport, (2) Introduction, (3) Establishment, and (4) Spread of the invasive (Williamson 1996; Richardson et al. 2000; Duncan et al. 2003; Lockwood et al. 2008). Plant and animal ecologists have treated these steps differently mainly because they deal with very different taxa and often work in very different environments. Plant ecologists have traditionally adopted the terminologies of Richardson et al. (2000), considering the barriers that must be overcome before invasions are established. In contrast, animal ecologists have typically followed the definitions of Williamson (1996), that treat the stages of invasion moving from the native environment to becoming invasive aliens. These similar, but sometimes confusing approaches, have been effectively and elegantly consolidated in what was termed a “unified framework for biological invasions” by Blackburn et al. (2011). This “unified framework” sought to integrate the four major stages of invasion (a stage-based approach) with the barrier model, providing an effective terminology to describe the underpinning elements and processes involved in invasions.
While the Blackburn et al. (2011) “unified framework” can be broadly applied to biological invasions, it is predominantly focused on animal and plant examples. Microbiological invasions, caused by viruses, bacteria and fungi, for example, are mentioned, but insufficiently accommodated. In this regard, the vast diversity amongst the organisms termed as ‘microbes’ needs to be recognized. Here for perspective, it is sobering to recognize that the phylogenetic ‘distance’ between mammals and birds is equivalent to that amongst species of a single yeast genus, Saccharomyces (Dujon 2006). This does not yet include all fungi, and of course also not the even greater diversity amongst bacteria and viruses. It would be naïve to believe that the invasion biology of these organisms will not be significantly different to that of plants and animals. Lumping these organisms in a single treatment that is focused on plants and animals dilutes our opportunity to understand and to deal with them effectively.
Blackburn and Ewen (2017) provided a broad consideration of “parasites” in the invasion process without a specific focus on any particular group of invaders or their parasites. The added consideration in that paper is that, in order for invasion to be successful, pathogens need a host. This host would be either native or introduced along with the pathogen. Several implications of this situation are discussed in their work.
The present commentary adds to the views of Blackburn and Ewen (2017), specifically with relation to invasions by fungal pathogens of forests trees. In this regard, it seeks to extract a single group of microbes, in recognition of the huge diversity and very different biological strategies of microbial invaders. While this is a relatively narrow topic, it is of global and growing relevance. As mentioned previously, Elton (1958) included chestnut blight that has devastated natural Castanea dentate (March.) Borkh. forests in North America; the numbers of other such tree pathogens destroying both planted and natural forests continues to grow annually (Wingfield et al. 2015). The aim of this commentary is not to present lists of alien invasive fungal tree pathogens, a topic that has been well treated elsewhere (Desprez-Loustau et al. 2007; Loo 2009; Müller et al. 2016). Our intention is rather to highlight four emerging issues that are important to understand fungal invasions of forests, plantations and natural woody ecosystems, and that require more focused research in coming years. We hope to stimulate a better recognition of the importance of these issues and their integration with the invasion biology literature and ongoing research.
Underlying eco-evolutionary processes
It would be fair to argue that we significantly lack a depth of knowledge regarding all invasions, irrespective of class of organisms involved. Zenni et al. (2017) have raised this issue seeking to highlight aspects concerned with evolutionary mechanisms to be considered as part of the ‘unified framework’ in addition to ecological aspects. These influencing factors include founder effects, epigenetics, population genetics, hybridization, genotype-by-environment interactions and the importance of symbionts (the so-called ‘second genome’). These evolutionary mechanisms are poorly understood for most invasive aliens and this is certainly true in the case of fungal pathogens of forest trees.
The most comprehensively studied fungal tree pathogens are obviously those that we have known for the longest period of time and are all of northern hemisphere origin. These include the already mentioned chestnut blight pathogen, C. parasitica (Elton 1958; Hepting 1974; Anagnostakis 1987), the Dutch elm disease pathogens, Ophiostoma ulmi (Buisman) Nannf. and Ophiostoma novo-ulmi Brasier (Gibbs 1978; Brasier and Buck 2001), the white pine blister rust pathogen, Cronartium ribicola J.C. Fisch. (Butin 1995; Kinloch 2003), and Heterobasidion spp. (Woodward et al. 1998) For these pathogens, we have some knowledge of their origins, pathways of movement, spread and their population genetics (Et-Touil et al. 1999; Brasier 2001; Allen and Humble 2002; Hamelin et al. 2005; Milgroom et al. 2008). Some more recent invaders in these environments for which a growing body of knowledge is becoming available include Phytophthora ramorum and Hymenoscyphus fraxineus (Drenkhan et al. 2017; Grünwald et al. 2016; Prospero and Cleary 2017). Against the background of the large and growing numbers of fungal tree pathogens, this is a sparse base of knowledge. Yet we can, at least to some extent, apply this knowledge to some other tree pathogens and use it to motivate for studies on them.
Much of the work concerning fungal tree pathogens other than those mentioned above, and in other parts of the world, revolve around the identification, and in some cases the biology, of these organisms. In terms of tree health, proof of pathogenicity (Koch’s Postulates) is a fundamental requirement. New tree pathogens are being recognized and described increasingly regularly. In some cases, knowledge is provided regarding host ranges and the environmental factors that allow infection to occur. This work is heavily skewed to pathogens of commercial importance such as those of trees grown for fruit production or forestry products. But even for these pathogens, there are relatively few examples where knowledge is available regarding their origins, population structures or pathways of spread. Notable examples include those for the pine needle pathogen Dothistroma (Fig. 1c) (Dorogin) M. Morelet (Barnes et al. 2014; Drenkhan et al. 2016), the pine pitch canker pathogen Fusarium (Fig. 1b) Nirenberg & O’Donnell (Wingfield et al. 2008; Berbegal et al. 2013; Santana et al. 2016), the Eucalyptus stem canker pathogen Chrysoporthe cubensis (Bruner) Gryzenh. & M.J. Wingf., as well as its close relatives (Gryzenhout et al. 2006; Nakabonge et al. 2006; Chen et al. 2010; Pegg et al. 2010; Van Der Merwe et al. 2013), and the Eucalyptus leaf pathogen Teratosphaeria nubilosa (Cooke) Crous & U. Braun (Fig. 1e) (Hunter et al. 2008, 2009; Pérez et al. 2010). In these four cases, the pathogens are important to commercial forestry and this has, at least to some extent, provided the motivation and funding to study them.
There is a multiplicity of sexual reproductive systems in fungi (Taylor et al. 1999; Ni et al. 2011; Heitman et al. 2013; Wilson et al. 2015). These range from typical mating between strains having different mating types (heterothallism) to an ability to self (homothallism) where sexual outcrossing does not necessarily occur, but with a growing list of variants between these sexual systems (Lin and Heitman 2007; Wilson et al. 2015). There are also growing numbers of examples of fungi that have been shown to outcross despite the fact that they are also able to self (Perkins 1987; Milgroom et al. 1993; Lin and Heitman 2007), and these include examples of important tree pathogens and common invaders such as those in the Ceratocystidaceae (Harrington and Mcnew 1997; Witthuhn et al. 2000; De Beer et al. 2014; Wilken et al. 2014; Lee et al. 2015). This complexity complicates the characterisation of fungal reproductive systems. Sexual outcrossing promotes diversity and could consequently influence the outcomes of invasions (Gladieux et al. 2015). Unfortunately these reproductive systems are poorly understood for many invading tree fungi. The increasing ease of sequencing fungal genomes and development of population genetics markers should help to address this shortcoming.
Reduced genetic diversity is expected in introduced populations in the early phases of the invasion as a consequence of founder effects or genetic bottlenecks (Sakai et al. 2001; Gladieux et al. 2015). Reduced genetic diversity can have a negative effect on populations due to the loss of alleles that might have adaptive value in a new environment (Sakai et al. 2001; Mcdonald and Linde 2002; Allendorf and Lundquist 2003). It can also have a positive effect through purging of deleterious alleles or maintenance of particularly successful genotypes. This is evident in some fungal pathogens of trees, especially where they are able to reproduce asexually or where clonal lineages of a single mating type dominates in an area. Cryphonectria parasitica, for example, has been shown to have colonized south-eastern Europe and it is spreading through many adjacent countries (Milgroom et al. 2008). These populations are all considered highly clonal with low levels of genetic diversity and vegetative compatibility groups, and the presence of a single dominant mating type (Milgroom et al. 2008; Dutech et al. 2012). Milgroom et al. (2008) proposed that these “clones have greater fitness than others” and that they are able to spread because they are well adapted to the new environmental conditions. Other examples of aggressive clonal lineages of fungal tree pathogens invading new areas include the “pandemic” strain of Austropuccinia (Puccinia) psidii on Myrtaceae (Ross-Davis et al. 2013; Mctaggart et al. 2016; Beenken 2017), Dothistroma septosporum on Pinus spp. in Australasia and South America (Barnes et al. 2014) and Ceratocystis platani on Platanus orientalis and P. × acerifolia in southern Europe (Ghelardini et al. 2017; Tsopelas et al. 2017).
The importance of hybridization in plant pathogen invasions is well recognized and there are growing numbers of examples of hybrid fungi resulting in serious tree diseases (Brasier et al. 1999; Brasier 2000; Newcombe et al. 2000; Brasier 2001; Gonthier et al. 2007; Érsek and Nagy 2008). Hybridisation and admixture are important sources of novel variation that could influence the evolution of fungal pathogens and their invasiveness (Brasier 2000; Allendorf and Lundquist 2003; Gladieux et al. 2015; Ghelardini et al. 2016). Interspecific hybridisation between two fungal species can produce hybrid species that have the ability to infect novel hosts with enhanced pathogenicity leading to greater levels of invasiveness than either of its parent species (Brasier 2001; Brasier and Buck 2001). For example, the hybridisation of introduced poplar rust pathogens Melampsora medusae and M. larici-populina in New Zealand resulted in a hybrid with a broader host range than that of the parent species (Spiers and Hopcroft 1994; Burdon et al. 2006). Similarly, the hybridisation of M. occidentalis and M. medusae that infect only Populus trichocarpa and P. deltoides, respectively, have hybridised to form the species Melampsora x columbiana. This phenotypically different species is capable of infecting both hosts mentioned above and hybrid clones of these hosts (Newcombe et al. 2000). In the oomycetes, an allopolyploid recombination between hybrids of Phytophthora alni uniformis and Phytophthora alni multiformis resulted in a new species, Phytophthora alni subsp. alni (Brasier et al. 2004). This persistent sub-species is part of a new taxon (P. alni), and is spreading throughout European riparian forests, killing Alnus trees (Ioos et al. 2006).
Insect symbioses
In the case of fungal tree pathogens, symbioses are also fundamentally important for invasion success (Paine et al. 1997; Kirisits 2004; Six and Wingfield 2011). Symbioses with insects are prominent in this regard and include some of the most important alien invasives affecting forests and forestry (Wingfield et al. 2010; Hulcr and Dunn 2011; Ploetz et al. 2013). The classic example in this case is that of the Dutch Elm Disease (DED) fungi, Ophiostoma ulmi and O. novo-ulmi. The DED fungi are vectored by Scolytine (Coleoptera: Scolytinae) (Webber and Brasier 1984; Jacobi et al. 2013) that maturation feed on the twigs of healthy trees, allowing the pathogens to enter the vascular tissues and to result in rapid tree death (Gibbs 1978; Sinclair and Campana 1978; Gibbs et al. 1994). An interesting aspect of the invasion of these fungi in Europe and North America is that the pathogens have acquired native insect vectors in their invasive ranges (Wingfield et al. 2016; and see Ghelardini et al. 2017 this issue). This has come about by these insects infesting pathogen infected wood that probably entered the invaded areas in untreated timber. In terms of invasion biology, the dangers of the movement of untreated timber and the emergence of diseases such as DED are increasingly being recognized (Roy et al. 2014; Wingfield et al. 2015).
The recent appearance of the dramatic wilt disease known as Laurel Wilt caused by the fungus Raffaelea lauricola T.C. Harr., Fraedrich & Aghayeva provides another dramatic example of a symbiotic relationship between a wood-infesting beetle and a pathogenic fungus. The disease is devastating natural stands of Persea borbonia (L.) Spreng. (redbay) in the southeastern USA (Fraedrich et al. 2008; Hanula et al. 2008; Harrington et al. 2011). Neither the insects nor the fungal pathogen would most likely cause significant tree damage in the absence of the other, but rather it is their novel associations that are driving the epidemic.
The red turpentine beetle provides another example where the introduction of an invasive insect, along with its symbiont, is responsible for a dramatic forest disease outbreak. In its native range in North America, Dendroctonus valens Le Conte is not known as an aggressive pest and attacks only stressed or dying trees. In China, however, where D. valens was introduced into the country in the 1980s, beetle attack of healthy native pines has resulted in millions of trees being killed (Sun et al. 2013). Based on population genetic analyses, eastern North America appears to be the likely source of the introduction (Taerum et al. 2016), most probably due to the intercontinental anthropogenic movement of woody material. The aggressive nature of the beetle in China is hypothesized to be due to the presence of its fungal symbiont Leptographium procerum (W.B. Kend.) M.J. Wingf. that most likely has been introduced from Europe (Taerum et al. 2013, 2017). Although L. procerum is considered a commensalist fungus in North America and Europe (Jacobs and Wingfield 2001), it is apparently an aggressive pathogen of Asian pine and is only found in association with D. valens. The introduction of a non-aggressive pest and its association with a fungus in an area where together they form an aggressive beetle-fungal association highlights the complexity and risks associated with introductions linked to fungus beetle symbioses.
The role of insects as ‘drivers’ of fungal tree pathogen invasions is well recognised for the symbiosis involving bark and wood-boring insects mentioned above (Wingfield et al. 2016). But there are growing numbers of tree-health problems where the relationship between the insect vector and fungal pathogen is apparently ‘casual’ with a range of insects. Ceratocystis pathogens of trees provide some of the best contemporary examples. For example, Ceratocystis albifundus M.J. Wingf., De Beer & M.J. Morris, is native to southern Africa where it occurs on many native woody plants (Barnes et al. 2005; Roux and Wingfield 2013; Lee et al. 2016). The pathogen is vectored by sap-feeding nitidulid beetles (Coleoptera: Nitidulidae) that visit freshly made wounds on trees (Heath et al. 2009). These wounds provide the infection points for the pathogens to invade. In the case of C. albifundus, the fungus has become a serious pathogen of non-native Acacia mearnsii De Wild. (Roux et al. 2007; Roux and Wingfield 2009) and it now threatens to become an alien invasive in other parts of the world (Roux et al. 2001, 2005). A similar situation has recently emerged in South East Asia where the related C. manginecans M. van Wyk, Al-Adawi & M.J. Wingf. (Van Wyk et al. 2007) has emerged as an important pathogen of non-native Acacia mangium (Fig. 1a) (Tarigan et al. 2011; Brawner et al. 2015). While the origin of C. manginecans remains to be determined, preliminary evidence suggests that in some areas where disease occurs, the pathogen appears not to be native (Al Adawi et al. 2014; Fourie et al. 2016), but is vectored by bark beetle Hypocryphalus mangiferae Stebbing (Scolytinae) that has co-evolved with mango (Al Adawi et al. 2013).
Another significant issue affecting our understanding of invasions by fungi and their vectors in tree systems is the depth and coverage of sampling. The example of ambrosia beetles and their symbioses with fungi provides an apt example. With low or poor coverage, patterns of co-evolution have failed to emerge. However, these patterns become very obvious as sampling intensity is increased (Farrell et al. 2001; Kostovcik et al. 2014). Because there are increasing numbers of serious tree diseases caused by fungi associated with ambrosia beetles, for example the devastating Laurel wilt disease (Fraedrich et al. 2008; Hanula et al. 2008; Harrington et al. 2011), the role of novel fungal-insect associations in tree disease warrants much greater attention.
The fungal hologenome of trees
There is a growing realization that organisms constitute complex systems that are sometimes referred to as the holobiont or hologenome (Bordenstein and Theis 2015). Consequently invasions are more complex than simply including the most prominent organism involved. For example, most tree invasions are closely linked to symbioses with microbes (ranging from parasitic to mutualistic, but with many not understood yet) although the microbes in these relationships have received much less attention than their plant hosts during invasions (Hayward et al. 2015; Blackburn and Ewen 2017; Zenni et al. 2017). For pines and many other trees, obligate mycorrhizal relationships are the most prominent of these symbioses (Chu-Chou 1979; Richardson et al. 1994; Díez 2005; Dickie et al. 2010; Hayward et al. 2015). In the case of the many legume tree invasive species, notably Acacia spp., their relationships with nitrogen fixing bacteria (rhizobia) is a requirement for establishment and consequently successful invasion (Rodríguez-Echeverría et al. 2009; Ndlovu et al. 2013). While these topics have been studied in some detail, their role in invasion biology requires considerably better understanding (Blackburn and Ewen 2017; Zenni et al. 2017).
It has been known for a number of decades that trees (and other plants) harbour large numbers and a great diversity of fungal endophytes (Ganley et al. 2004; Sieber 2007; Pirttilä and Frank 2011). Our understanding of these fungal tree microbiomes is cursory at best. This is both in terms of the composition, as well as the role (if any) of these organisms. It is evident from the few studies that have been undertaken that there are large numbers of fungal taxa resident in healthy tree tissues and these far exceed those that can be isolated using conventional microbiological methods. For example, Kemler et al. (2013), showed that single Eucalyptus trees potentially harbour thousands of fungal taxa and that many of these reside in fungal groups known to include tree pathogens (eg. the Mycosphaerellaceae and Teratosphaeriaceae). Molecular genetic tools to characterize the metagenomes of plants including trees are becoming increasingly available. Our knowledge of tree microbiomes and their role in both fungal and tree invasions is likely to grow rapidly.
Some endophytes, such as members of the Botryosphaeriaceae, are well known latent pathogens, existing for long periods of time in asymptomatic tissue, but able to cause disease under conditions of stress (Slippers and Wingfield 2007; Marsberg et al. 2017). In this regard, movement of trees harbouring asymptomatic latent pathogens to areas where the trees are poorly suited to the prevailing environmental conditions can result in serious disease problems. Other than for the Botryosphaeriaceae, important examples are emerging for members of the Cryphonectriaceae that include some of the most aggressive pathogens of trees (Gryzenhout et al. 2009). These fungi can have a negative impact on the establishment of potentially invasive tree species (Wingfield 2003; Crous, et al. 2017). But there are also examples where the fungi are moved via traded plants or plant material to new environments where they become invasive aliens in their own right (Anderson et al. 2004; Santini et al. 2013; Marsberg et al. 2017). It is clear that future considerations on how we might tackle invasions by tree microbes that do not have any direct obvious effects on their hosts has been neglected and needs to be addressed.
Taxonomic conundrums
Accurate and thus meaningful identification of fungi as a whole, including those that cause diseases of trees, has been a challenge for many years (Crous et al. 2016). Until only 30 years ago, the identification of fungi was based almost entirely on the morphological features of these organisms. Their relatively simple morphologies have consequently meant that the identification of many tree pathogenic fungi has been incorrect. The availability of DNA-based sequence technologies and thus phylogenetic inference has for the first time in centuries given rise to what will become a natural classification of these organisms. This technology has revolutionized fungal taxonomy not only providing universal bar-coding genes (Schoch et al. 2012; Stielow et al. 2015), but also the manner in which fungi are named (Hawksworth et al. 2011; Hawksworth 2015). Thus, the confusing ‘dual nomenclature’ system where the same fungi could have different names has now been replaced by the so-called ‘One Fungus = One Name’ (1F1 N) classification (Taylor 2011; Wingfield et al. 2012). This alone will simplify fungal taxonomy and it will also substantially advance studies in fungal invasion biology.
The incorrect identification of fungal tree pathogens prior to the availability of DNA-based techniques has caused considerable confusion in the plant pathology literature, including for some of the most important tree pathogens. For example, the canker pathogens in the Cryphonectriaceae are now known to include very distinct groups; those in the northern hemisphere that include the chestnut blight pathogen Cryphonectria parasitica (Murrill) M.E. Barr and those in the tropics and Southern Hemisphere in Crysoporthe including the Eucalyptus pathogen Chrysoporthe cubensis (Fig. 1f) and its various sibling species (Heath et al. 2006; Gryzenhout et al. 2009). Likewise, tree pathogens previously treated in Ceratocystis including the DED pathogens are now known to reside in two different Orders of fungi. Moreover, they represent distinct genera and species complexes with significantly different ecologies (Hausner et al. 1993a, b; Spatafora and Blackwell 1994; Seifert et al. 2013; Wingfield et al. 2017). Understanding these differences is already providing an improved knowledge relating to invasions caused by these fungi, and the picture that emerges is that fungal invasions are much more complex and frequent than previously realized.
One of the most vivid recent examples of problems relating to the identification of tree pathogens has been that concerning the myrtle rust pathogen A. psidii (Fig. 1d). This pathogen is considered native to Central and South America and it is unusual amongst the rusts (Uredinales) in having a very broad range of hosts within Myrtaceae (Coutinho et al. 1998; Glen et al. 2007; Zhong et al. 2008; Carnegie et al. 2010; Giblin and Carnegie 2014). Austropuccinia psidii has been one of the most feared tree pathogens in Australia (Coutinho et al. 1998; Glen et al. 2007), a continent that has an extensive natural diversity in the Myrtaceae. When A. psidii reached Australia in 2010, it was argued that the invasion was of a different fungus known as Uredo rangelii J.A. Simpson, K. Thomas & Grgur. (Carnegie et al. 2010). This fungus was believed to differ from A. psidii based on minor morphological difference in the urediniospores but mainly on the presence of a tonsure on this spore type (Simpson et al. 2006). This taxonomic confusion led to dissent regarding a tree disease that was spreading rapidly in Australia’s natural environment and one that has now accumulated more than 232 different tree hosts (Carnegie et al. 2016). A more rapid identification of the pathogen applying the techniques that were commonly available at the time (Glen et al. 2007; Mctaggart et al. 2016), might not necessarily have reduced the impact of A. psidii in Australia, but it would at least have provided an impressive example of ‘best practices’ in dealing with invasive fungal pathogens.
Conclusions
In this paper we have highlighted some emerging issues pertaining to invasive fungi associated with trees. The topic, however, also has relevance to fungi as invasives in other ecosystems, such as agricultural systems, and also invasions by other microbes. We highlight four issues that are of particular relevance to understanding these invasions, but that are relatively poorly understood, and that are typically poorly considered in general invasion biology literature. These include biological issues relating to emergence of novel diversity through complex recombination and hybridization processes, as well as symbionts of fungal pathogens that are essential to their spread and host associations. We have also raised practical considerations such as the uncontrolled global movement of the endophytic fungal community with healthy plants, and the taxonomic issues that hamper the accurate identification of tree pathogens.
In eco-evolutionary terms, biological invasions have not been studied for particularly long time frames. Thus, seriously invasive alien organisms could cease to remain dominant over longer periods of time. As an example, trees that are invasive tend to be genetically uniform and in this respect they are not much different to those cultivated in uniform plantation environments. There is growing evidence to suggest that both native, as well as accidentally introduced pests and pathogens could eventually ‘catch up’ with these invasive plants and consequently reduce their impacts (Burgess and Wingfield 2017; Crous et al. 2017; Hurley et al. 2016). This might, for example, be considered the ‘sting in the tail’ of commercial tree-planting programmes that are clearly significantly threatened by pests and pathogens. It could also, at least partially, account for what is known as the ‘boom and bust cycles’, which are poorly understood and where invasive alien organisms suddenly cease to be invasive or disappear entirely.
Invasion biology is beset by numerous conflicts of interest. These conflicts tend to obscure or even retard our understanding of them. For example, there are many tree species that are important commercially, but that are also considered noxious weeds. Invasion biologists seek to manage these problems using biological control strategies (Desprez-Loustau et al. 2007; Wood 2012; Hajek et al. 2016) but many of these can involve the introduction of tree pathogenic fungi. While these fungi might, on the one hand, reduce the invasiveness of the weed tree species, they also threaten commercial enterprises that rely upon these trees growing vigorously, as well as potentially the surrounding native systems. What is clearly required is common ground between parties seeking to grow trees and those that see the same tree species as a serious threat to the natural environment. This will require sober debate and a mutual understanding of often significantly opposing points of view.
Most studies dealing with invasion biology are dominated by zoologists and plant scientists with a strong interest in ecology. It is our view that most of these researchers have been trained in ecological theory and that this is a field that is not typically included in the curricula of plant pathologists. The education of microbiologists and pathologists tends to be more strongly focused on local and micro-processes, and individual organisms and their interactions. This is in contrast to a more complex and holistic community-environment interactions, and broad spatial scales. Although this might be an over-simplification, it is our impression that there remains a great need for deeper levels of communication and collaboration between invasion biologists and microbiologists that study, for example, fungal pathogens that are alien invasives.
Tree diseases caused by invasive alien fungal pathogens are increasing in number annually. These are seriously damaging to economies where the trees are grown for commercial purposes and they are destroying natural ecosystems, ultimately impacting negatively on general human well-being. There is clearly a great need for research to better understand these invasions and thus to provide opportunities to reduce their impact. In many cases, the technologies are already available to accurately identify the pathogens, to understand their pathways of introduction and to potentially manage their means of spread. What we lack is a considerably expanded effort to deal with these growing threats and to have the funding to apply these technologies.
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Acknowledgements
We acknowledge the DST/NRF Centre of Excellence in Tree Health Biotechnology, the National Research Foundation (South Africa) and the Tree Protection Cooperative Programme (TPCP) for financial support. We thank Dr. Carlos Rodas and Ms Izette Greyling for providing us with the photographs for Fig. 1c and Fig. 1b respectively.
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Guest Editors: Andrew Liebhold, Eckehard Brockerhoff and Martin Nunẽz/Special issue on Biological Invasions in Forests prepared by a task force of the International Union of Forest Research Organizations (IUFRO).
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Wingfield, M.J., Slippers, B., Wingfield, B.D. et al. The unified framework for biological invasions: a forest fungal pathogen perspective. Biol Invasions 19, 3201–3214 (2017). https://doi.org/10.1007/s10530-017-1450-0
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DOI: https://doi.org/10.1007/s10530-017-1450-0