The Scottish Invasive Species Initiative is a 8-year partnership project working with communities and volunteers to control invasive non-native species along rivers in northern Scotland. Funded by the Scottish Government's Nature Restoration Fund. Visit our website – www.invasivespecies.scot – or email us at: sisi@nature.scot
Adam Lovell, Seasonal Project Officer, SISI Project, published February 2025
We asked Adam Lovell, Seasonal Project Officer for the Dee and Don catchments, about his experiences working with volunteer groups to tackle Himalayan balsam last summer.
As I sit down to write this blog in mid-October, I find myself reflecting on the busy summer just passed and the culmination of my time as a seasonal Project Officer for the Scottish Invasive Species Initiative in the Dee and Don catchments. The season dedicated to tackling Himalayan balsam (Impatiens glandulifera) has come to an end, and what an educational journey it has been! Witnessing the extent of this invasive plant’s impact first hand has been eye-opening, especially when considering the positive effects of careful management and treatment undertaken in previous seasons.
Volunteers help tackle a large patch of Himalayan balsam at Goals in Aberdeen
One of the most rewarding aspects of this project has been the collaboration with a diverse range of volunteers. Each group brings its own unique perspectives and knowledge to our shared goal of managing Himalayan balsam. From corporate teams to local youth groups and community groups like ‘Bolland’s Balsam Bashers’, it has been inspiring to see everyone come together to form an impressive coordinated and united effort. The synergy created by these differing groups is remarkable; each person contributes not just their physical labour but also fresh ideas and spirit, which only enhances the project.
Project volunteers Rick, Donald and Alan tackle Himalayan balsam at Ardoe in the Dee catchment
Managing Himalayan balsam presents its own set of challenges as this plant can dominate environments where it takes root. Introduced to the UK in 1839, it has become an established invasive species, particularly flourishing along riverbanks and in disturbed soils. Its ability to thrive in low light and outcompete native vegetation can significantly disrupt habitats and biodiversity, leading to the decline of other plant species. Not only does it change ecosystems, but it can also have detrimental non-biotic effects, like reducing waterflow and/or leading to potential flooding and bank erosion, which can have knock-on effects for freshwater ecosystems.
Volunteers from Oil Spill Response joined us for a Conservation Volunteer Day in July in Deeside
Employee groups help to provide extra people power to tackle balsam monocultures
What makes managing Himalayan balsam even more satisfying is that control work is a manual endeavour. Unlike many invasive species, where chemical control is generally needed to be effective (requiring training, specialised equipment and expertise), working with Himalayan balsam needs only a bit of elbow grease (sometimes lots of it), making it an accessible task to everyone who is physically able. Armed with our scythes, gloves, and a can-do spirit, it’s a great way for people with varied abilities and experience to get involved in invasive plant control. It’s been a joy to see volunteers discover how impactful ordinary tools and dedicated teamwork can be in removing this plant effectively and in making a difference to each control location.
Himalayan balsam can be controlled by pulling the plant out by the roots and piling them up to help prevent rerooting
Himalayan balsam flowers are strikingly beautiful, producing clusters of purplish-pink blooms that attract bees and provide a good source of nectar. This might all sound rather positive and beneficial but it is not quite as straightforward as that unfortunately! There are significant downsides to Himalayan balsam, for example, bees will often visit Himalayan balsam in preference to native plants meaning that native plants may not be pollinated as effectively when Himalayan balsam is present. This can impact the ability of native species to produce seed and maintain viable populations and ecosystems. Think of it like using a big burger chain to buy lunch instead of a small local independent place.
Himalayan balsam flowers may look pretty…
… but this invasive plant has significant detrimental impacts on native vegetation and ecosystems
Once pollinated, each Himalayan balsam plant can produce up to 800 seeds, with pods that explosively launch these seeds up to 7 meters away. Great tactics for spreading and reproducing but unfortunately this means that, once established it can rapidly spread, often aided by human activities and water currents, and form dense monocultures which outcompete native plants.
Throughout the 2024 season we collectively managed to pull, cut, and control the spread of Himalayan balsam, sharing in the triumphs and the inevitable frustrations along the way as we tucked into an essential Tunnocks Tea Cake and coffee. The community spirit has been inspiring! Volunteers have bonded over our common goal, exchanged stories from past seasons with us and other projects, learned from each other and ultimately had fun and a good laugh—whether they were seasoned conservationists or trying their hand at practical ecological management for the first time.
Before at Ardoe: project volunteer Sandra clears a clump of Himalayan balsam
After at Ardoe
As the season winds down and my time with the Initiative comes to an end, I am filled with gratitude and admiration for the dedicated volunteers who have helped this year, the invaluable experiences we have gained, and the hope that our joint efforts will lead to healthier ecosystems in the Dee and Don catchments for the future. We have laid and continued to build solid foundations, and, although the battle with Himalayan balsam is ongoing, I am optimistic for the future. Thank you for being a part of this journey with me – your passion and enthusiasm have made a world of difference!
To find out more about the Scottish Invasive Species Initiative and how to get involved, you can visit our website, follow us on social media or contact us on sisi@nature.scot
Connor Wood, Seasonal Project Officer and PhD Student with the University of the West of Scotland, January 2025
Introduction
We know that invasive non-native species are a major threat to biodiversity, but the danger they pose to our ecosystems can often be hard to see. Picture a sewer pumping sludge into a river or a forest being cleared and replaced with concrete—those are obvious, visible threats. But when an ecosystem is taken over by a non-native species, the damage can be much harder to recognize. Unless you can identify which species are native and which are non-native and invasive, the problem might not stand out. An understanding of why these invaders are a threat requires knowledge of their subtle differences from similar native species and how these differences can disrupt the balance of the ecosystem.
At first glance, some invasive non-native species don’t seem all that different from their closely related native counterparts. Take the invasive giant hogweed (Heracleum mantegazzianum) and the native common hogweed (Heracleum sphondylium) — sure, the invader stands much taller than its British relative, but they appear to function quite similarly overall. Or consider the Eurasian otter (Lutra lutra) and American mink (Neovison vison): the otter may be noticeably larger, but both are semi-aquatic predators from the weasel family, swimming through the same rivers. So, why is one a valued part of our ecosystem and the other a serious biodiversity threat?
Connor (left) took a break from his PhD research this summer to join us in the Spey catchment and help tackle invasive non-native species like American mink and giant hogweed
Connor sets up a mink trap on a floating raft
The answer isn’t just blind favouritism for native species. The danger posed by invasive species is very real, and it often comes down to small, crucial details – differences in biological traits (for example, size or fecundity) and how these traits shape their interactions with other species.
This is the focus of my ongoing PhD research, where I compare the traits of a native freshwater shrimp (Gammarus pulex) with two closely related invasive species (the killer- and demon shrimp, Dikerogammarus species) to understand how these differences play out. In this blog, I’ll focus on the traits that give invasive species like giant hogweed and American mink their destructive edge over native species.
Case Study 1: Giant Hogweed vs Common Hogweed
Giant hogweed, a member of the carrot family from the Caucasus Mountains, is closely related to common hogweed which is native to the UK. In fact, they’re so closely related they’re even capable of producing the occasional hybrid offspring [14]. Despite these similarities, their ecological roles differ dramatically. Here are some of the key differences between them which can explain why giant hogweed is considered a high-impact invader.
Common hogweed (above) is a native species which is very similar to the invasive giant hogweed (right). Photo credit: Rasbak, Wikimedia Commons.
There are key biological differences which make giant hogweed (above) a high impact invader.
Growth and Light Competition Giant hogweed can grow up to 5 meters tall, dwarfing the smaller common hogweed which grows to a maximum of only 2 metres. The leaves of giant hogweed are similarly oversized, spanning 1.5 to 3 metres in width compared to the much smaller 55cm length leaves of the common hogweed. This size, when combined with rapid vegetative growth, allows giant hogweed to form dense leaf canopies that block out sunlight for smaller native plants. Competition for light is one of the major drivers of plant community composition [21], and the giant hogweed has a clear advantage in this contest.
Seed production and Emergence High reproductive output is one of the most commonly reoccurring traits in successful and high impact invasive species [17]. Looking at the hogweed species, we can see a major difference between the two. Both species take around three years to reach the flowering stage. However, the reproductive potential of giant hogweed far outstrips its native counterpart. While common hogweed produces about 850 seeds per flowering season and usually flowers two to three times during its lifespan [16], giant hogweed can produce anywhere from 20,000 to a staggering 100,000 seeds in a single season. These seeds also germinate more frequently and emerge earlier in the season, giving the giant hogweed a big head start on outgrowing the competition [15]. What’s more, the seeds can remain viable in the soil for up to 15 years.
The reason for this difference lies in the giant hogweeds evolutionary history – the high seed production is a vital adaptation to survive the extreme cold and nutrient poor soil of the mountains in its native range. This reproductive advantage means that once giant hogweed takes hold, it is difficult to eradicate, allowing it to spread rapidly and persistently.
The oversized leaves of giant hogweed form dense canopies which block out light while it’s high reproductive output allows it to spread rapidly in new environments
Brown seedheads from the previous summer are visible among a dense covering of giant hogweed leaves
Toxic sap Giant hogweed is notorious for its highly toxic sap, which can cause painful, long-lasting burns due to a chemical compound called furocoumarin. While common hogweed also contains furocoumarin and can cause skin irritation, its effects are far milder because the chemical is present in significantly lower quantities. Whether giant hogweed’s toxic sap provides an ecological advantage over common hogweed or other native plants remains unclear—it may deter some herbivores [20], but our sheep trials have shown that certain livestock are unaffected. However, the difference in impact on human health is undeniable, with giant hogweed posing a far greater threat.
Insects and Pollination Common hogweed is a vital part of the local insect food web, attracting a broad variety of pollinators such as bumblebees, butterflies, hoverflies, and beetles. These pollinators play an important role in maintaining biodiversity. Giant hogweed, on the other hand, attracts a much narrower range of insects. Studies have shown that areas dominated by giant hogweed experience a decrease in pollinator diversity [13], which can have ripple effects throughout the entire ecosystem. The loss of specialist insect species in areas overtaken by giant hogweed is particularly concerning, as it impacts the broader insect community and the health of native plants that rely on these pollinators [19].
Common hogweed attracts a variety of native pollinators, providing a food source for bees, butterflies, hoverflies and beetles. Photo credit: Anne Burgess, Wikimedia Commons.
Summary Giant hogweed’s size, reproductive capacity and highly toxic defence strategies have made it a highly successful and destructive invader. As they overtake and dominate plant communities, the abundance and diversity of both native plant species and specialist insect species declines in turn. Without this native biodiversity and the ecosystem services it provides – pollination, nutrient cycling and habitat creation – the ecosystem suffers as a whole.
Case Study 2: American Mink vs. Native Otter
Background The American mink and the European otter are both top predators, members of the weasel family and share similar wetland and river habitats across the UK. Despite these overlaps, these two species have sharply different ecological impacts. The American mink poses a significant threat to native species, particularly causing dramatic declines in water vole and ground-nesting bird populations [1], whereas the otter is often regarded a keystone species crucial in maintaining ecosystem health. These are some of the trait differences that make mink a danger when compared to the otter.
The European otter (above) and American mink (right) are both semi-aquatic mustelids which inhabit rivers, wetlands and coastlines in Scotland. Photo credit: Peter Trimming, Wikimedia Commons
Despite their similarities, the invasive American mink (above) has a very different ecological impact compared to the native European otter (left). Photo credit: NatureScot
Size Differences and Competitive Advantage One key difference between the two species is size. Quite the opposite from the giant- and common hogweed, in this case the native otter is the larger animal. Otters can grow up to 130 cm in length, while mink are much smaller, ranging from 42 to 65 cm. Given the significant size difference, otters would be expected to hold a dominant competitive advantage over mink, enabling them to essentially bully them out of their territories or away from their food sources [4] [12]. Unfortunately, this is frequently not the case – many sites in the UK show a coexistence of otters and mink rather than competitive exclusion (we’ll discuss why later). All to say, the negative environmental impacts of American mink aren’t seen through direct competitive interaction with otters, rather through the direct predatory impacts on a variety of prey species.
Impact on Naïve Prey The small build of the mink actually contributes to one of their most devastating impacts – their predation on the UK’s endangered water voles [23]. The mink is small and agile enough to invade the burrows of the voles, chasing them into their dens through the underwater entrances that deter most of the voles native predators. Water voles, like many other native species, are considered “naïve prey” for the mink [22] – they have not evolved natural defences or behaviours to evade this newly introduced predator, making them easy targets. This inability to respond to new threats can have dramatic consequences for populations already weakened by habitat loss and other pressures [18]. What’s more, the aggressive prey drive of the mink leads them to kill more than they consume, which has led to the eradication of entire local vole populations.
Water voles are Britain’s most rapidly declining mammal and predation by American mink is a key contributing factor to their decline. Photo credit: Alan Ross
Diet, Habitat, and Adaptability While otters tend to have a more specialized diet focused on fish, mink are opportunistic generalist predators [6] [9]. They can hunt a wide variety of prey, including birds, amphibians, fish, rabbits, rodents, crayfish, domestic fowl and more, giving them a significant adaptive edge over otters. This dietary flexibility allows mink to thrive in diverse habitats and conditions, while otters are more limited in their prey choices. The otter needs a river with a good fish population, whereas the mink can find food just about anywhere. The specialized fish diet of the otter also makes them more susceptible to aquatic pollutants [7] [8] – if a river becomes contaminated with toxic chemicals, so too does the otter’s food source, while mink can sustain themselves on terrestrial prey and avoid the contaminant.
Reproduction and Fecundity The American mink exhibits an “r-selected” or “high output” reproductive strategy, which is typical among invasive species and contributes to their rapid population growth. Effectively this means the mink has higher fecundity (reproductive rate) compared to otters, so they can produce more offspring in a shorter time frame. While both species reproduce once a year, mink typically produce 4–6 kits per litter, compared to the otter’s 1–3 cubs. Additionally, mink can breed as early as one year old, while otters take 2–3 years to reach sexual maturity. Juvenile mortality is high for both species – as high as 50% before reaching maturity for both mink and otters, by some estimates [10] – and under these conditions the r-selected / high output reproductive strategy of the mink proves advantageous.
As well as the high fecundity, mink have a number of traits which make their reproduction adaptable to changing conditions. They’ve been shown to adjust their litter size and breeding times in response to changing population density [2] or prey availability [5]. They also have a rather unique capability for polyamorous breeding, where female mink can sire a single litter from multiple different males she has mated with [3]. These traits make the mink a particularly resilient invader as they can easily respond to changing conditions and “bounce back” after population control efforts.
American mink are opportunistic predators with high reproductive rates which makes them highly successful invaders. Their small size means they can enter burrows of vulnerable native wildlife like water voles. Photo credit: Marc Evans, Wikimedia Commons.
Summary The comparison between the American mink and the Eurasian otter gives an insight into the mink’s invasive success in the UK. Their high fecundity, adaptability, and aggressive predation make them a serious threat to native ecosystems. While both species face challenges from habitat loss and pollution, mink’s ability to thrive under these conditions compounds the pressure on vulnerable species like otters and water voles. Efforts to control mink populations must be sustained and strategic to protect native wildlife from further declines.
References
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[19] Bogusch, P., Vojtová, T., & Hadrava, J. (2023). High abundance but low diversity of floral visitors on invasive Heracleum mantegazzianum (Apiaceae). NeoBiota, 86, 193-207.
[20] Buttenschøn, R. M., & Nielsen, C. (2007). Control of Heracleum mantegazzianum by grazing. In Ecology and management of giant hogweed (Heracleum mantegazzianum) (pp. 240-254). Wallingford UK: CABI.
[21] Gioria, M., & Osborne, B. A. (2014). Resource competition in plant invasions: emerging patterns and research needs. Frontiers in Plant Science, 5, 501.
[22] Anton, A., Geraldi, N. R., Ricciardi, A., & Dick, J. T. (2020). Global determinants of prey naiveté to exotic predators. Proceedings of the Royal Society B, 287(1928), 20192978. [23] Aars, J., Lambin, X., Denny, R., & Griffin, A. C. (2001, August). Water vole in the Scottish uplands: distribution patterns of disturbed and pristine populations ahead and behind the American mink invasion front. In Animal Conservation forum (Vol. 4, No. 3, pp. 187-194). Cambridge University Press.
Scottish Invasive Species Initiative 
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