Over the last nine years scientists have made significant progress in identifying aspects of insect-plant host relationships that play important roles in determining how much damage an introduced, non-native pest is likely to cause within forest ecosystems in the United States. Predicting which introductions will probably cause the greatest damage is vitally important because scientists, phytosanitary officials, and resource managers cannot address all the hundreds of established insects, much less the thousands which might be introduced. This shortfall increases with each surge in import volumes (see my previous blogs about wood packaging by scrolling down the website below the “Archives” to “Categories”, then find “SWPM”), proliferation of goods types and source areas, and cutbacks in funding.
I hope USDA APHIS and Forest Service are adjusting their procedures to apply the scientists’ path-breaking findings.
Their progress will help protect our forests. I apologize if I seem ungrateful — but we need similar progress in managing plant pathogens. Consider the damage caused by chestnut blight, white pine blister rust, Dutch elm disease, sudden oak death, beech leaf disease … (All these and other pathogens are described briefly here.) Understanding the universe of introduced fungi, water molds, nematodes, viruses, etc., is per se much more challenging. Ashley Schulz points out that among the complications are pathogens’ complex life cycles, and possible new relationships with vectors.
Undertaking this analysis will be set back decades if agencies’ resources – funds and staffs – are decimated during the current “downsizing” of government. We must speak up!!
At least regarding non-native insects that attack North American tree species, scientists’ analyses promise a new ability to set priorities. This should improve the efficacy of phytosanitary programs – if government downsizing is not allowed to destroy USDA’s scientific, regulatory, and resource management programs.
We must speak up!!
What science tells us now
Schulz et al. (2025) summarize current findings. (Full citation to all references appear at the end of the blog.)
Earlier, scientists sought to find commonalities associated with introduced insects that caused high impacts on North American conifer trees [Mech et al. (2019)] and hardwoods (angiosperms) [Schulz et al. (2021)] (Full citations at the end of the blog; earlier blogs posted here and here.) Both studies found that the time elapsed since tree species in North America diverged from the host plants of the insects in their native range (i.e., host evolutionary history) is a diagnostic factor. This factor best predicted non-native insect impact compared to the other factors that were significant for conifer and hardwood specialists. For conifers, the other significant factors included the shade and drought tolerance of the North American host plants and whether there was a related insect native to North America on the same hosts that the non-native insect impacted. For hardwoods, another important factor explaining a specialist insect’s impact is if the insect is a wood borer, especially a scolytine beetle. The wood density of the North American host plant was also considered a significant factor when predicting impact of the non-native insect.
In 2022, Uden et al. applied the divergence time method to insect species not yet introduced to North America that might attack conifer species. They hoped to identify both insects posing the greatest hazard and tree species most vulnerable to introduced pests.
Now, a new team again led by Ashley Schulz and Angela Mech (see Schulz et al. 2025) has applied a similar approach to a more comprehensive range of pest-host relationships, including the pests that specialize on host plants and pests that feed on a broader array of hosts. Some feed on both conifers and hardwoods. They found that:
- It is possible to quantify insect host breadth and identify the cutoff where “specialists” and “generalists” diverge. Specifically, the split occurs around 2,250 cumulative million years, where insects that feed on hosts that add up to less than that have narrow host breadth (i.e., “specialists”) and insects that feed on hosts that add up to more than that have broad host breadth (i.e., “generalists”). This technique also helps categorize insects that fall within the middle range of host breadth and are traditionally difficult to classify as either specialists or generalists based on differing qualitative definitions of the terms.
- Insects that use more hosts in their native range also tend to use more hosts in the introduced range (North America). However, many of these insects utilized fewer hosts in the introduced range compared to the native range. This shrinkage was not universal, however; about 30% of insects increased their host breadth in the introduced range. Most of these fed on a single species in their native range but attacked additional species in the same family in North America. The corresponding i-Tree Pest Predictor tool uses the list of hosts in the insect’s native range and these models to determine the insect’s likelihood that it would cause high impact, as well as each North American tree species’ susceptibility to the insect entered into the tool.
- Certain feeding guilds had – on average — a significantly narrower host breadth in North America than in their native ranges. These were gall makers (13 species analyzed); sap feeders (120 species); and wood borers (35 species). In contrast, host ranges did not differ for folivores (68 species), reproductive feeders (7 species), and root feeders (5 species). Still, we know that wood borers, as a group, have caused enormous damage to a range of North American tree taxa (see emerald ash borer, redbay ambrosia beetle, invasive shot hole borers (all described briefly here). Again, the i-Tree Pest Predictor tool can help identify the threat to particular tree species.
Of course, APHIS should not disregard pests with narrow host ranges; several have caused enormous damage.
Schulz et al. (2025) developed models for three groups of introduced herbivorous insects that feed on trees:
1) conifer specialists (based on analysis of 69 species);
2) hardwood specialists (based on analysis of 141 species);
3) hardwood generalists (based on analysis of 30 species).
Because of their quantification of host breadth, they defined the “specialist” group more broadly than is commonly done, e.g., an insect that feeds on the three families Betulaceae, Fagaceae, and Juglandaceae would be considered “specialists” because all three host families are in the Fagales clade.
Tree relatedness was the only significant explanatory factor for all three host breadth categories. As determined in the previous studies, North American host tree species that were too closely or distantly related to the insect’s hosts in its native range were less impacted than hosts that diverged somewhere in the middle – the “Goldilocks” range. The divergence period differs among the three pest-risk categories: 3–4 million years ago for conifer specialists, 5–9 million years ago for hardwood specialists, ~1–2 million years ago for hardwood generalists. Schulz et al. suggest that the reason why the peak probability of high impact differs among these groups is that different feeding guilds cause the most damage to the specific host category, and each feeding guild is challenged by different tree host defenses. Bark and wood boring beetles (the hardwood specialists with the greatest impact) must overcome lethal constitutive and induced tree defenses in order to survive for long periods in the cambial layer. These insects have adapted the ability to locate and select poorly defended individuals in the host population. Folivores (i.e., the generalists with the highest impact) adapt to plant chemistry and trichomes (hair-like or scale-like outgrowths), or can avoid host defenses by moving off the foliage. Sap feeders (which include many high impact conifer specialists) are usually tolerated by trees, unless they stimulate hypersensitive reactions or vector pathogens.
Of course, scientists’ estimates of how long ago tree taxa diverged from common ancestors differ. Fortunately, Uden et al. (2022) found that these differences only rarely affect the predicted impact of a non-native insect – at least in the case of the 62 European insects and 47 North American conifer species they analyzed. In only 1.37% of the 2,914 pairs analyzed did the predicted risk differ depending on which source phylogeny was used. These cases were associated with 27 conifer-specialist insects and 9 conifer hosts. The article does not tell us which pest/host pairs these are but, overall, this paper demonstrates that the estimate differences in the phylogenetic trees does not differ enough to be problematic when forecasting insect impact.
Changes Needed in the Way Agencies Set Priorities
Schulz et al. (2025) urged agencies to stop relying only on insect traits as the basis for developing models & phytosanitary regulations. The only insect trait that predicted impact is the insect’s feeding guild. Considering hardwoods, they found that wood borers pose the greatest risk among specialists to hardwoods; folivores among generalists. While sap feeders do not cause statistically higher damage on hardwood tree species, four of the seven high-impact conifer specialists are sap feeders (hemlock woolly adelgid, balsam woolly adelgid, red pine scale, and spruce aphid). Therefore, the i-Tree Pest Predictor tool incorporates consideration of whether a pest of conifers is a sap feeder.
Schulz et al. (2025) also caution agencies against relying on just the number of hosts an insect might exploit. Assessors must consider the range of underlying plant chemistry / host defenses that the insect encounters. They found that hosts that are shade tolerant are more susceptible to high impact from conifer specialists and hosts that have intermediate to no shade tolerance are more susceptible to high impact from generalists.
Uden et al. (2022) identified a possible weakness in USDA efforts to prioritize pest prevention targets. They found that APHIS’ Prioritized Offshore Pest List included only 12 conifer specialists from Europe among the 150 species listed. They go on to note that while sap feeders constitute 53% of tree pest species established in the U.S., APHIS listed none. The models applied by Uden, Schulz, and Mech do not consider whether the insect is likely to become established. Improving our understanding of the many factors influencing an insect’s likelihood of being transported to North America or becoming established requires additional research. This might eventually lead to a usable tool for predicting this aspect of bioinvasion by forest pests.
There is an urgent need for such a tool. As Uden et al. noted, they found that 66% of the insect species they analyzed fell into the “high impact” category. This is a much higher proportion than estimates based on earlier studies, so identifying which of these insects are likely to establish versus not establish in North America can provide more resolution and help identify which insects are going to be most problematic.
Tree species at risk
The analysis undertaken by Uden et al. determined that three conifer species face a high level of hazard from European insects if they are introduced. They identified particularly high threats to two species, Fraser fir (Abies fraseri) and Carolina hemlock (Tsuga caroliniana). The fir is determined to be vulnerable to 17 insect species which are predicted to have high likelihood of a high impact. The hemlock is highly vulnerable to one of the insect species they sampled. They note that both of these conifers have a limited geographic range and ecological habitat, so they likely have a relatively narrow genetic pool. A third species said to be at elevated risk is red spruce (Picea rubens) – which, although more widespread, is also under attack by a non-native insect. All three species fit earlier finding by Mech et al. that conifer trees with high shade tolerance but low drought tolerance more vulnerable to non-native pests. In none of these cases do Uden et al. mention that the tree species have already been severely diminished by established non-native insects – i.e., balsam woolly adelgid on the fir (above), hemlock woolly adelgid on the Carolina hemlock. The Schulz/Mech team is working to refine methods for identifying tree species and regions at greatest risk.
Meanwhile, Uden et al. have suggested that phytosanitary authorities and forest managers apply their findings to identify the European herbivorous insects that pose the greatest threat to North American conifer species. They should identify Palearctic tree species that fall within the high-impact “Goldilocks” zone of divergence times in relation to specific North American tree species, then identify the insects that feed on those Palearctic trees. These insects would presumably pose the highest predicted hazard to those North American tree species. They suggest that species so identified should be added to the USFS’ list of species targetted by its wood borer early detection program. To address likelihood of introduction, they suggest incorporating data on insect species commonly intercepted at ports – an indication of high propagule pressure. There will always be exceptions though. For example, Ips typographus feeds on spruce and has been frequently detected at the ports, but it has not established in North America.
For those focused on identifying species or ecoregions at greatest risk, Uden et al. suggest scientists use several sources to identify vulnerable vegetation communities. Sources suggested include USFS Forest Inventory and Analysis (FIA) and NatureServe Explorer plant community descriptions) that have relatively high-value tree species predicted to be at risk from introduced species.
SOURCES
Aukema, J.E., D.G. McCullough, B. Von Holle, A.M. Liebhold, K. Britton, and S.J. Frankel. 2010. Historical Accumulation of Nonindigenous Forest Pests in the Continental United States. BioScience 60(11): 886-897. https://doi.org/10.1525/bio.2010.60.11.5
Mech, A.M., K.A. Thomas, T.D. Marsico, D.A. Herms, C.R. Allen, M.P. Ayres, K.J. K. Gandhi, J. Gurevitch, N.P. Havill, R.A. Hufbauer, A.M. Liebhold, K.F. Raffa, A.N. Schulz, D.R. Uden, & P.C. Tobin. 2019. Evolutionary history predicts high-impact invasions by herbivorous insects. Ecology and Evolution 9(21): 12216–12230. https://doi.org/10.1002/ece3.5709
Schulz, A.N., A.M. Mech, M.P. Ayres, K. J. K. Gandhi, N.P. Havill, D.A. Herms, A.M. Hoover, R.A. Hufbauer, A.M. Liebhold, T.D. Marsico, K.F. Raffa, P.C. Tobin, D.R. Uden, K.A. Thomas. 2021. Predicting non-native insect impact: focusing on the trees to see the forest. Biological Invasions 23: 3921-3936. https://doi.org/10.1007/s10530-021-02621-5
Schulz, A.N., N.P. Havill, T.D. Marsico, M.P. Ayres, K.J.K. Gandhi, D.A. Herms, A.M. Hoover, R.A. Hufbauer, A.M. Liebhold, K.F. Raffa, K.A. Thomas, P.C. Tobin, D.R. Uden, A.M. Mech. 2025. What Is a Specialist? Quantifying Host Breadth Enables Impact Prediction for Invasive Herbivores
Ecology Letters 28: e70083. https://doi.org/10.1111/ele.70083
Uden, D.R., A.M. Mech, N.P. Havill, A.N. Schulz, M.P. Ayres, D.A. Herms, A.M. Hoover, K.J.K. Gandhi, R.A. Hufbauer, A.M. Liebhold, T.D. Marsico, K.F. Raffa, K.A. Thomas, P.C. Tobin, C.R. Allen. 2022. Phylogenetic risk assessment is robust for forecasting the impact of European insects on North American conifers. Ecological Applications 33(2): e2761. https://doi.org/10.1002/eap.2761
Posted by Faith Campbell
We welcome comments that supplement or correct factual information, suggest new approaches, or promote thoughtful consideration. We post comments that disagree with us — but not those we judge to be not civil or inflammatory.
For a detailed discussion of the policies and practices that have allowed these pests to enter and spread – and that do not promote effective restoration strategies – review the Fading Forests report at https://treeimprovement.tennessee.edu/
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