Gene flow between introduced and native Eucalyptus species: exotic hybrids are establishing in the wild

Barbour, RC; Potts, Brad M.; Vaillancourt, René E.

doi:10.1071/bt03016

Cited by 34 publications

(51 citation statements)

References 38 publications

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“…Because of the very similar juvenile morphology of E. globulus and E. nitens, this could result in situations where the parentage of hybrids detected with E. ovata would be ambiguous. Exotic hybrids between E. ovata and both plantation species are well known [31,79] and do show similar morphology. The three-way simulation (E. globulus, E. nitens, and E. ovata) here showed the utility of the microsatellite based approach in overcoming ambiguity in this situation, and it could be an important management tool for distinguishing between exotic and natural hybridisation where E. nitens grows within the native range of E. globulus.…”

Section: Performance Of the Approachmentioning

confidence: 99%

“…An assessment of the species growing where the hybrid was collected would probably narrow down the number of potential parents. Also most exotic plantation hybrids identified in the field are found among pure seedlings of the native species [31,83], likely enabling the identification of a single putative maternal species. In an operational context where a putative exotic hybrid has been identified in the field, an effective approach may be to run a full six-way analysis to rule out other species contributing pollen, which can travel long distances [84], then reduce the number of species to those found in the vicinity of the putative hybrid.…”

Section: Performance Of the Approachmentioning

confidence: 99%

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Assessing a Bayesian Approach for Detecting Exotic Hybrids between Plantation and Native Eucalypts

Larcombe

Vaillancourt

Jones

et al. 2014

International Journal of Forestry Research

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Eucalyptus globulus is grown extensively in plantations outside its native range in Australia. Concerns have been raised that the species may pose a genetic risk to native eucalypt species through hybridisation and introgression. Methods for identifying hybrids are needed to enable assessment and management of this genetic risk. This paper assesses the efficiency of a Bayesian approach for identifying hybrids between the plantation species E. globulus and E. nitens and four at-risk native eucalypts. Range-wide DNA samples of E. camaldulensis, E. cypellocarpa, E. globulus, E. nitens, E. ovata and E. viminalis, and pedigreed and putative hybrids (n = 606), were genotyped with 10 microsatellite loci. Using a two-way simulation analysis (two species in the model at a time), the accuracy of identification was 98% for first and 93% for second generation hybrids. However, the accuracy of identifying simulated backcross hybrids was lower (74%). A six-way analysis (all species in the model together) showed that as the number of species increases the accuracy of hybrid identification decreases. Despite some difficulties identifying backcrosses, the two-way Bayesian modelling approach was highly effective at identifying 1 , which, in the context of E. globulus plantations, are the primary management concern.

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Section: Performance Of the Approachmentioning

confidence: 99%

Section: Performance Of the Approachmentioning

confidence: 99%

Assessing a Bayesian Approach for Detecting Exotic Hybrids between Plantation and Native Eucalypts

Larcombe

Vaillancourt

Jones

et al. 2014

International Journal of Forestry Research

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“…These hybrid seedlings originated from open pollinated seed from an E. nitens seed orchard that was surrounded by native forest containing E. ovata and E. viminalis. Subsequent research revealed that exotic E. nitens hybrids were also occuring in open pollinated seed collected from the adjacent E. ovata trees (hybridisation rate ranged from 0.04 to 16% per tree - Barbour et al 2002), demonstrating a potential avenue for exotic gene flow. Furthermore, E. ovata × nitens hybrid seedlings were found soon after, growing in disturbed areas near plantations .…”

Section: The Case Of Eucalyptus Nitens In Tasmaniamentioning

confidence: 99%

“…Hybridisation was highest on the edges of patches and declined very rapidly with distance. the species means that detection of exotic hybrids in the wild has usually been restricted to early life cycle, first generation hybrids (F 1 s between exotic plantation species and a native eucalypt - Figure 1) (Barbour et al 2002;Barbour et al 2003;Barbour et al 2008b;Larcombe et al 2014), although progression to the second generation of hybridisation (F 2 and backcrossing) has been reported in Corymbia (Shepherd & Lee 2016).…”

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confidence: 99%

Managing Australia’s eucalypt gene pools: assessing the risk of exotic gene flow

Larcombe¹,

Potts²,

Jones³

et al. 2016

Proc. R. Soc. Vic.

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Most eucalypts are endemic to Australia but they have been introduced into more than 100 countries and there are now over 20 million hectares of eucalypt plantations globally. These plantations are grown mainly for pulpwood but there is expanding interest in their use as a renewable source of solid wood products and energy. In Australia, the eucalypt plantation estate is nearing one million hectares, located mainly in temperate regions and dominated by Eucalyptus globulus and E. nitens (subgenus Symphyomyrtus), which are grown mainly outside their natural ranges. While eucalypt species from different major subgenera do not hybridise, hybrids within subgenera are often reported, including hybrids with plantation species. Concerns were raised in the late 1990s that pollen-mediated gene flow from locally exotic plantation eucalypts may affect the integrity of adjacent native eucalypt gene pools. As Australia is the centre-of-origin of most eucalypt species used in plantations around the world, exotic gene flow is one of the many issues that require management for industry sustainability and certification purposes. We here summarise over a decade of research aimed at providing the framework and biological data to help assess and manage the risk of gene flow from these plantations into native gene pools in Australia.

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“…Because trees are perennial plants with a long rotation time and remain in the same place for a considerable period, long-term evaluation of the impact of GM trees on the surrounding environment is required (Owusu 1999). Furthermore, for many trees, little is known of their physiology and genetics (Owusu 1999;Valenzuela et al 2006), and in many cases, tree species generate interspecific hybrids (e.g., Quercus, Populus and Eucalyptus) (Barbour et al 2003;Ubukata 2003;Brooker 2000). Their pollen and seed dispersal distances are not well-known, and unforeseen acceptors of GM pollen undoubtedly exist around the plantation area.…”

Section: Treesmentioning

confidence: 99%

Recent progress on environmental biosafety assessment of genetically modified trees and floricultural plants in Japan

Kikuchi

Watanabe

Tanaka

et al. 2008

Plant Biotechnology

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A broad spectrum of living modified organisms (LMOs) have been developed and commercial production of them have already been started. It is the global requirement to conduct environmental biosafety after the implementation of Cartagena Protocol on Biosafety. Environmental biosafety assessment is of cardinal importance even in confined field trials and at the deliberate release to an environment for practical uses. It is necessary to collect various categories of data prior to fields; not only about the morphological and physiological traits of the LMOs in some confined experimental facilities, but also about characteristics of host organisms in the natural habitat and field for intended releases. Environmental release of LMOs is possible only after collected information is examined systematically and comprehensively in a scientifically-sound manner, and target end-points of such uses are well-identified. Environmental biosafety assessments principally require case-by-case evaluation. Gene-flow, allelopathy and invasiveness are three key aspects in GM plants. In Japan, many crop species do not have their wild relatives due to their historical introduction from overseas. Furthermore, crops grow properly only under agricultural practices, and invasive weediness of these plants is very likely low. In contrast, floricultural plants and trees have related native species located around the fields that can cross with the transgenic counterparts in many cases. In this review, we examine the environmental biosafety assessment of LMO floricultural plants and trees enumerating the example of field trials in Japan, and describe concepts that should be noted for the commercial cultivation and environmental release of these species.

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Gene flow between introduced and native Eucalyptus species: exotic hybrids are establishing in the wild

Cited by 34 publications

References 38 publications

Assessing a Bayesian Approach for Detecting Exotic Hybrids between Plantation and Native Eucalypts

Assessing a Bayesian Approach for Detecting Exotic Hybrids between Plantation and Native Eucalypts

Managing Australia’s eucalypt gene pools: assessing the risk of exotic gene flow

Recent progress on environmental biosafety assessment of genetically modified trees and floricultural plants in Japan

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