Abstract
Bark stripping by mammals is a major problem for conifer forestry worldwide. In Australia, bark stripping in the exotic plantations of Pinus radiata is mainly caused by native marsupials. As a sustainable management option, we explored the extent to which natural variation in the susceptibility of P. radiata is under genetic control and is thus amenable to genetic improvement. Bark stripping was assessed at ages four and five years in two sister trials comprising 101 and 138 open-pollinated half-sib families. A third younger trial comprising 74 full-sib control-pollinated families was assessed at two and three years after planting. Significant additive genetic variation in bark stripping was demonstrated in all trials, with narrow-sense heritability estimates between 0.06 and 0.14. Within sites, the amount of additive genetic variation detected increased with the level of bark stripping. When strongly expressed across the two sister trials, the genetic signal was stable (i.e., there was little genotype × environment interaction). No significant non-additive effect (specific combining ability effect) on bark stripping was detected in the full-sib family trial, where it was estimated that up to 22.1% reduction in bark stripping might be achieved by selecting 20% of the less susceptible families. Physical traits that were genetically correlated, and likely influenced the amount of bark removed from the trees by the marsupials, appeared to depend upon tree age. In the older trials, these traits included bark features (presence of rough bark, rough bark height, and bark thickness), whereas in the younger trial where rough bark was not developed, it was the presence of obstructive branches or needles on the stem. In the younger trial, a positive genetic correlation between prior height and bark stripping was detected, suggesting that initially faster growing trees exhibit more bark stripping than slower growing trees but later develop rough bark faster and became less susceptible. While the presence of unexplained genetic variation after accounting for these physical factors suggests that other explanatory plant traits may be involved, such as chemical traits, overall the results indicate that selection for reduced susceptibility is possible, with potential genetic gains for deployment and breeding.
Highlights
Herbivores are important determinants of plant productivity in managed and natural plant systems [1]
Using three field-based genetic trials established with a large number of Pinus radiata families, we show the existence of additive genetic variation in susceptibility to bark stripping damage by marsupial herbivores, which, when well-expressed, appears relatively stable across sites
This paper illustrates that variation in bark stripping is under low but significant additive genetic control and, when well expressed, the genetic signal appears to be relatively stable across different environments
Summary
Herbivores are important determinants of plant productivity in managed and natural plant systems [1]. In managed conifer forests, browsing may have significant economic impacts through. The exploitation of natural resistance is, a potential strategy for managing browsing damage [5]. Natural resistance leading to variation in herbivore damage among and within populations, as well as within individuals and tissues, has been reported [6,7]. This variation, if genetically based, is key to the evolution of resistance mechanisms [8,9] and a prerequisite for genetic improvement in tree breeding and deployment populations [10,11]. Significant additive genetic variation in resistance to herbivore damage has been detected in several conifers [12,13,14]
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