Frank the Fish made me an Environmental Scientist

Guest post by Neda Ejbari, MEnvSc

Children are intelligent, autonomous human beings, and although they lack experience in many things, that does not make their thoughts, feelings, and values invalid. Children are some of the most compassionate people you will meet and influencing them in a positive way early on in their development is crucial for the sake of a brighter future for humankind.

A lot of this positive influence must come from science. Understanding our planet’s functions and learning the structure and behavior of the physical and natural world is crucial to ensure that we can protect it. However, to do this, we as scientists need to be experts at communicating science. We need to pass down what we learn in a way that is understandable, not just for new-coming scientists, but for those without the background as well.

Science communication can be discouraging for many. The fear of “dumbing down” one’s work until it is no longer factual or legitimate is always a concern among scientists. In addition to this, many scientists simply do not have the background to effectively communicate their science. They might lack the training or the resources to do so. Just having the public’s attention long enough to get one’s point across can be extremely difficult to do. If someone told you there was going to be a talk about eutrophication in the Great Lakes, would you go? If you were scrolling down Twitter or Facebook, would you stop long enough to understand what that table or graph you were seeing meant?

Let’s do a little experiment. 

What graph is easier to understand?

Taken from Twitter to discuss climate change, a graph obtained from John O'Sullivan & Norm Kalmanovich’s news article: What Michael Mann’s ‘Hockey Stick’ Graph Gave To UN Climate Fraud, which was taken from Michael Mann’s 1999 paper showed a confusing analysis that is hard to interpret without some background knowledge in climate change.

Also taken from Twitter, an easy to understand tweet from Peter Gleick about climate change and what it means.

The issue with science communication is that it's a double-edged sword. You need to make your information enticing to the audience, but you need the resources and the proper training in order to do so. And the only way to get that support is through the interest and push from the public. It’s a vicious cycle; like a student being told they need experience for a job —but needing that job for the experience. The fact of the matter is; most scientists don’t have those resources or training to communicate their research to a wide audience, which makes it difficult to get the public to care for their cause and push for better science communication in the first place.

Now imagine taking that fear and doubling it as you try to communicate to children, the future of our planet’s well-being.

In a study completed by Andrea Bou - Vinals and Silvia Prock, scientists admitted to having many fears when trying to communicate with children. In Bou-Vinals and Proc’s study, scientists were made to run a workshop and roleplay with children ages 9 to 13 with the goal of engaging them in scientific activities. The consensus of this experiment was that scientists were afraid that they were boring the children or that they wouldn’t be able to get their scientific knowledge across. On the children’s end, their interpretation of the experiment was that the scientists were there to “please children, because children are the future” and “having fun with knowledge transfer.” It shows that children are aware of their importance, and the importance of learning from scientists.

So, what can we do?

We as scientists need to understand that proper, easily comprehensible communication is key to getting people to care. Scientific literature often sounds extremely unbiased and un-opinionated. The issue with this is that most people are not trained to read scientific literature. There is jargon and difficult words that many will not understand because they will never have the context for it. To communicate effectively a scientist, there must be a compromise in the language to get your point across. Sometimes, you must sacrifice the language entirely and use other means for communication, i.e., videos, infographics or applied/interactive experiments.

We as the public also need to understand that science is important. We need to improve our scientific literacy and look for answers to questions that might strike us on a day-to-day basis. We need to encourage ourselves to take the first step and seek knowledge, and in turn, pass that behaviour on to our children as well. We must expose our children to the knowledge we have, and trust that they can understand what is being presented to them. We as the public need to support our scientists and push for their information to become easily accessible and comprehensible to us, as it is the masses that often influence the choices of policy makers.

Children are important because they are easily impressionable. I speak from personal experience when I say that the most conservation-driven choices I make today stemmed from early education and youthful experience. For example, a habit that I formed when I was young was letting the tap water run while brushing my teeth. Although turning it off seems like the obvious thing to do, it was more convenient for me to let it run until I was finished. The implications behind why this was bad to do was not apparent until I watched a commercial from Sesame Street. It made the reason behind why I should conserve water very obvious and very clear to me at a young age, and I still think about it to this day.

https://www.youtube.com/watch?v=gtcZbN0Z08c

The video still holds impact. The animation is clear, the audio is crisp, and the message is still extremely relevant. What’s interesting is that the majority of the comments on the video reflected my exact thoughts and feelings. The video stuck with me after several years and is always the first thing that comes to mind when I think about conserving water, or conserving anything, for that matter. Even now, sitting in a graduate level Conservation Biology class, when we discuss the impact of human activity on the natural world, I automatically imagine Frank the Fish stuck in his dried-up pond. 

So why was this video so hard to forget? Why did it have such a clear impact on me and several others?

As a seven-year-old living on the 6^th floor of an apartment complex, I didn’t have a backyard to begin with, and yet the message was clear. Because I had seen a natural environment before, I understood that my actions were indirectly impacting that area of nature I had once seen. And because I was able to relate it to that, I was able to empathize with the commercial and change my behaviour as a result.

This video was an effective tool of science communication. As environmental scientists, we all know that running water does not directly drain a pond in your backyard. There’s a lot of complicated architect, engineering and science that goes behind how we get our clean water from the environment; and yet the public —and children especially— needed none of those small details to understand the big picture.

It was an effective tool of science communication because it showed me, and people like me, the direct impact of my behaviour in the grand scheme of things. The video influenced me as a child and encouraged me to pursue a field of biology and environmental science as a result. And now, this video will be passed down because it has been presented and saved in a form of media that can be spread and shared with a simple click of a button.

Our goal as members of the human race should be to constantly ask the question: do I understand this? Would I be able to explain this to my children so that they can understand it? Truthfully, we won’t always be able to. But if we support our scientists and give them the tools and support they need to effectively present their work to us, and trust that our children are clever enough to understand what they are being told, great things can happen.

To learn more about the importance of science communication, check out the following links:

What is Science Communication? - The EU Guide to Science Communication

English Communication for Scientists

Science Communication Breakdown

Young Scientist Series

References

Merzagora, M., & Jenkins, T. (2013). Listening and Empowering Children in Science Communication. Jcom Journal of Science Communication, 12(3).

Mann, M. E., Bradley, R. S., & Hughes, M. K. (1999). Northern hemisphere temperatures during the past millennium: Inferences, uncertainties, and limitations. Geophysical research letters, 26(6), 759-762.

Don't forget the details! Trait ecology and generality

The search for generality is perhaps the greatest driver of modern ecology and probably also the greatest source of ecological angst. Though ecological trends frequently reflect the newest, brightest hope for generality, the search for generality (perhaps by definition) encourages us to ignored details and complexities. Maybe this means that some areas of study won't develop fully until they've fallen out of fashion. And maybe this means that the most interesting science happens when the pressure to 'save community ecology' is gone. A great example of the kind of post-hype, thoughtful approach for trait-based ecology comes from Reynolds et al. (2017) in Tree Physiology. They do a really nice job of highlighting some of the details that must inform trait-based ecology. Here, Reynolds et al. take a broad comparative approach across species, but incorporate important details that have at times been overlooked - especially the role of the environment, recognizing and measuring both constitutive and plastic traits, captures that there are multiple paths (or trait combinations) that can result in similar functioning.

The authors look at four conspecific tree species (Brachychiton spp.) with different average positions along an observed moisture gradient (CMD or climate moisture deficit). Two species occupied drier areas of Australia ('xeric species'), while the other two were found in more moderate areas ('mesic species'). The authors assumed that the different distributions of these species reflect different hydraulic niches. Were species' hydraulic niches associate meaningfully with their traits, specifically those trait associated with drought stress responses. Though these species are closely related--and so huge divergences in form and function might not be expected--the costs and benefits of drought resistance should differ among the species. In dry environments, drought resistance strategies should be more important, and may select for particular traits or sets of traits. Trait states associated with drought conditions include "reduced leaf area, enhanced stomatal control, safer or more efficient xylem, increased tissue water capacitance...and/or deeper root systems " may all be selected for. On the other hand, investment in these traits when water is not limited is often costly, reducing growth and competition. This suggests a meaningful selective regime associated with the CMD gradient and trait values might exist.

One important, but oft-overlooked aspect of trait ecology is that trait values depend on both genes and the environment. Reynold et al. incorporate this fact this by manipulating water availability between drought and control treatments. They measured both constitutive components of trait values – those driven by genetics and expressed regardless of environments – and the plastic or environment-dependent components. For instance, in the presence of prolonged drought, trees might increase root production or change leaf characteristics. In addition to manipulating water availability between treatments, the authors measured nine traits related to morphology and allocation.

From Reynolds et al. 

Given the expectation that trait values reflect the complex interaction of genetics and the environment in different species, is it possible to even make simple predictions about trait-environment relationships? The authors find that "These complex relationships illustrate that assuming that individual traits (often measured on individuals under a single set of environmental conditions) reflect drought resistance is likely to be overly simplistic and may be erroneous for many species. However, our results do suggest that generalization may be possible, provided multiple traits are measured to explore specific integrated drought strategies."

Indeed, some results are relatively predictable relationships: under well-watered control conditions, the allocation of biomass matched the expectation: xeric species had higher investment in below-ground biomass and in transport tissues than the mesic species (both characteristic of a water-conserving species).

On the other hand, leaf traits such as SLA did not show any trend related to species' assumed drought tolerance, either for constitutive or plastic trait components. Sometimes traits associated with the leaf economic spectrum such as SLA are assumed to indicate stress tolerance, but this was not the case.

By far the most interesting result was the observation that the xeric species had the highest assimilation and stomatal conductance rate and the lowest water use efficiency under well-watered conditions. Only by also examining these species under drought conditions was it possible to observe that they are highly plastic with regards to water use efficiency. In fact, they show a feast or famine approach to water usage - "where high photosynthetic rates per unit leaf area and high investment in root and stem tissue even in well-watered conditions are achieved through profligate water use during rare periods of water availability, in order to establish a root system and stem storage tissues necessary to survive long periods of water stress." Under drought conditions, these species show reduced root tissue investment; in contrast, mesic species follow expected patterns and plastically increase root tissue investment.

This paper is a reminder that the details are also fascinating and informative. As humans, we may have a simplistic understanding of the realized environment sometimes. To us perhaps all water stress is similar, but for each species in this study, the long term selective pressures may be meaningfully different - in timing, duration, and life stage. This creates the potential for complex differences between species which may best be reflected via life history strategies involving multiple traits. That may still imply some degree of generality is possible, but it is multi-dimensional.

Works cited:
Victoria A Reynolds, Leander D L Anderegg, Xingwen Loy, Janneke HilleRisLambers, Margaret M Mayfield; Unexpected drought resistance strategies in seedlings of four Brachychiton species, Tree Physiology, https://doi.org/10.1093/treephys/tpx143

Life in Plastic Ain’t so Fantastic

Guest post by Louis Vassos, MEnvSci Candidate in the Professional Masters of Environmental Science program at the University of Toronto-Scarborough

Much like the Buggles’ 1980 debut album, our material preferences are well within the age of plastic. Thanks to its light weight, durability, inertness, and low manufacturing costs, our use of plastics has increased dramatically since the mid-20^th century. From bottles and toys to car parts and electronics, there is seemingly no application beyond its reach. Despite its uses and benefits, it has come under increasing scrutiny by environmentalists in recent years. In this regard, we tend to think of larger-scale and more visible environmental impacts, such as accumulation in landfills and petrochemical use in manufacturing. There has also been a significant amount of research on plastic in marine environments, usually focused on larger debris known as macroplastics. Over the past decade, however, there has been increasing concern about a new type of plastic debris in our oceans. Though its presence was first highlighted in the 1970s, we are only just beginning to realize the impact of fragments known as microplastics. As their name would suggest, they are small pieces of plastic, typically measuring less than 5mm in diameter and sorted into two distinct classifications.

Primary microplastics are manufactured to be microscopically sized and are typically used in air blasting as a paint and rust remover, as well as in personal care products as an exfoliating scrubber. This latter use has risen sharply in cosmetics and facial cleansers since the 1980s, with plastic “microbeads” replacing natural materials such as pumice and ground almonds. Regardless of application they usually enter water bodies through drainage systems, and are easily able to pass through filtration systems at sewage treatment plants due to their small size.

Microbeads in toothpaste. Retrieved from: https://blog.nationalgeographic.org/2016/04/04/pesky-plastic-the-true-harm-of-microplastics-in-the-oceans/

Secondary microplastics arise from the breakdown of larger pieces of plastic debris on both land and in water. Larger debris will typically enter marine ecosystems directly or indirectly through careless waste disposal, often being transported through river systems. Sources of transfer include coastal tourism, extreme weather events, fishing, other marine industries, and accidental spillage during transportation. Over time, a culmination of processes such as exposure to UV radiation can reduce the debris’ structural integrity, causing brittleness, cracking, and yellowing. This in turn can lead to fragmentation through abrasion and waves, and fragments will gradually become smaller over time before reaching microplastic size (Cole et al, 2011).

As Eriksen et al (2014) have estimated, there is a minimum of 5.25 trillion plastic particles weighing 268,940 tons in the world’s oceans. Microplastics account for 92.4% of this mass, and their reach has been substantial. Because of their buoyancy and durability, they have the ability to travel long distances without degrading for years. Denser plastics (such as PVC) will sink and have the potential to reach coastal sediment (Andray, 2011). Other marine microplastics will end up trapped in ocean current systems known as gyres, the most famous grouping of which is the “Great Pacific Garbage Patch” in the North Pacific Gyre. Despite what the name would suggest, it is not an island-like mass of floating debris, but is more akin to an extensive “soup” of debris difficult to see with the naked eye. At a density of 334,271 pieces/km², microplastic mass in the area was found to be 6 times that of plankton (Moore et al, 2001). 

Potential microplastic transport pathways (From Wright et al, 2013)

Densities such as this increase potential microplastic ingestion by various marine organisms, especially filter feeders, plankton, and suspension feeders. These species may mistake debris for prey based on size or colour, or passively ingest them without being selective (Wright et al, 2013). In Farrell and Nelson’s (2013) study of mussel-eating crabs, they found that it is possible for microplastics to be transferred to individuals at a higher trophic level. The large surface area to volume ratio of microplastics makes them susceptible to water-borne pollutant contamination, and can cause toxic plastic additives such as BPA and PCB to leach into the water. This debris can also act as a dispersal vector for microbial communities, including potentially pathogenic species (Jiang et al, 2018). While the ingested debris can accumulate within individuals and be transferred up the food chain, the exact effects of this are not entirely known at this point in time (Avio et al, 2017). A recent study by Lei et al (2018), however, found that microplastics can cause oxidative stress and intestinal damage in zebrafish and nematodes, and that their toxicity is closely dependent on particle size.

Intestinal damage in zebrafish caused by exposure to 1.0 mg L^-1 of different microplastic types and sizes. Photograph A shows control (top), survival (middle), and dead after exposure (bottom) zebrafish (From Jiang et al, 2018)

Fluorescent microspheres on a crab’s gill lamella transferred from ingesting mussels, each measuring 5 micrometres in diameter (From Farrell and Nelson, 2013)

          What does the future hold for microplastics? Because their effects on both marine life and humans is relatively unknown, it is important to try and prevent them from entering and accumulating within marine environments. Properly dispose of larger plastic items to prevent them from entering waterways and breaking down into secondary microplastics, and be conscious about the presence of primary microplastics in other products. Make informed decisions when buying cosmetics, and choose ones that use natural exfoliating materials. Microbead bans have already begun to be enacted in several countries, including the UK, US, Canada and New Zealand (Pfeifer, 2018). There is also the potential for future studies on topics such as the health effects of microplastic ingestion and leached additives, debris behavior within the water column, and new standardized techniques for detection and sampling (Cole et al, 2011). It is hard to say what will happen next, but the removal of these 5.25 trillion particles from our oceans will prove to be a very difficult challenge without the development of novel extraction methods.

SOURCES

Anadrady, A.L. 2011. Microplastics in the marine environment. Marine Pollution Bulletin 62:1596 – 1605

Avio, C.G., S. Gorbi, and F. Regoli. 2017. Plastics and microplastics in oceans: from emerging pollutants to emerged threat. Environmental Research 128: 2 – 11

Cole, M., P. Lindeque, C. Halsband, and T.S. Galloway. 2011. Microplastics as contaminants in the marine environment: a review. Marine Pollution Bulletin 62:2588 – 2597

Eriksen, M., L.C.M. Lebreton, H.S. Carson, M. Thiel, C.J. Moore, J.C. Borerro. F. Galgani, P.G. Ryan, and J. Reisser. 2014. Plastic pollution in the world’s oceans: more than 5 trillion plastic pieces weighing over 250,000 tons afloat at sea. PLOS One

Farrell, P., and K. Nelson. 2013. Trophic level transfer of microplastic: Mytilus edulis (L.) to Carcinus maenas (L.). Environmental Pollution 177:1 – 3

Jiang, P., S. Zhao, L. Zhu, and L. Daoji. 2018. Microplastic-associated bacterial assemblages in the intertidal zone of the Yangtze Estuary. Science of the Total Environment 624:48 – 54

Lei, L., S. Wu, S. Lu, M. Liu, Y. Song, Z. Fu, H Shi, K. Raley-Susman, and D. He. 2018. Microplastic particles cause intestinal damage and other adverse effects in zebrafish Danio rerio and nematode Caenorhabditis elegans. Science of the Total Environment 619:1 – 8

Moore, C.J., S.L. Moore, M.K. Leecaster, and S.B. Weisberg. 2001. A comparison of plastic and plankton in the North Pacific Central Gyre. Marine Pollution Bulletin 42:1297 – 1300

Pfeifer, H. 2018. The UK now has one of the world’s toughest microbead bans. CNN. Retrieved from: https://www.cnn.com/2018/01/09/health/microbead-ban-uk-intl/index.html

Wright, S.L., R.C. Thompson, and T.S. Galloway. 2013. The physical impacts of microplastics on marine organisms: a review. Environmental Pollution 178:483 – 492

The problematic charismatics: Are loveable invasives getting a free pass?

Guest post by Will Brown, MEnvSci Candidate in the Professional Masters of Environmental Science program at the University of Toronto-Scarborough

In the world of animal conservation, charismatic wildlife - those loveable, huggable species like giant pandas or koalas - take centre stage. They’re the kinds of animals you see dominating news stories, books, and movies, with less-attractive species often falling by the wayside. The concept of charismatic species is tied closely to animal conservation and protection. And the public’s love and adoration for charismatic creatures plays an essential role in the success of conservation and awareness campaigns. As flagship species they become ambassadors and icons, rallying support and focusing the public’s attention (and money) on an environmental cause or conservation program.

Figure 1 A famous example of a charismatic species used as a flagship species for a conservation group, the World Wildlife Fund (WWF). (Source)

For many years, a societal bias for charismatics has been important for protecting and conserving rare and imperilled species. But what happens when a charismatic species, rather than requiring protection, is considered an invasive pest? And how does this affect the proper implementation of invasive species management and threat abatement?

A perfect example of a charismatic species as an invasive pest is wild horses, known as brumbies, in Australia. First introduced for farm work in 1788, there are now over 400 000 brumbies throughout the country. As an invasive this species causes erosion and damages vegetation with their hard hooves and overgrazing. They damage and foul waterholes and spread weeds through seeds carried in their dung, manes, and tails. As competitors with native species, they can force wildlife from favoured habitats and dominate food and water sources. There is a significant portion of the public, however, that see the brumby as an iconic Australian species that is  ’a unique equine and epitomizes the spirit of freedom’.

 

Figure 2 Feral horses threaten fragile ecosystems in Kosciusko National Park. (Source)

To manage the impacts of brumbies in Kosciuszko National Park, a plan was released in 2016 to reduce the number of wild horses by 90% over a 20-year period. The cull was to be carried out using humane control methods including trapping, fertility control and ground shooting rather than aerial shooting and roping. The management plan sparked angry protests and fierce opposition, despite warnings from scientists about the impacts of brumbies in the region. Even though government scientists declared that the horse population in the region severely degrade natural waterways and threaten fragile native alpine wildlife, hundreds of people protested the cull in Sydney and support groups downplayed the adverse effects brumbies have had on the environment. Lisa Caldwell of the Snowy Mountain Horse Riding Association was reported as saying ‘You've got to remember that the national park is 6,900 square kilometres…horses are not going to have a huge impact on those wetlands’ (www.abc.net.au).

Now almost 2 years on, backlash to the draft legislation has halted any form of management and a new amended management plan is in the works. It is reported that the amended plan includes less aggressive reduction of wild horses, with culling more likely to reduce the numbers to several thousand rather than just 600. To overcome Australia’s environment laws that require a more complete removal of wild horses, a ‘brumbies bill’ is being put forward to give recognition to the horses’ ‘cultural significance’, providing them with legal protection to remain in the park.

Now consider how an uncharismatic species is treated in a similar situation. The feral pig, generally perceived as dirty, disease-ridden and hated by farmers, also roams through Kosciuszko National Park and has very similar impacts on the environment. Feral pigs degrade natural areas through rooting up soils, grasslands and forest litter as they feed on native plants. They also spread a number of diseases and predate on a host of native animals including insects, frogs, snakes and small ground-nesting birds. Unlike brumbies however, their numbers are managed within in the park with almost no opposition.

 

Figure 3 Feral pigs populations are controlled in Australia with minimal public opposition. (Source)

In both cases there are two species found in the same location, negatively impacting the ecosystem in a similar way. For the uncharismatic species, management plans are carried out promptly and effectively. But for the charismatic species, it seems clear that societal bias can lead to strong resistance from the public and as a result, management efforts can be delayed or watered down.

And this pattern isn’t restricted to Australia. In Canada, introduced feral cats are the No.1 killer of birds, responsible for over 100 million bird deaths per year. Even with this information available, there is no widescale control programs for managing feral cat populations. In British Columbia, an exploding European rabbit population at the University of Victoria was responsible for extensive damage to fields, lawns and mature trees. When the university tried to implement a removal program, public outcry delayed efforts and the university ended up committing to using non-lethal methods for controlling the rabbit population. Meanwhile, less cute and fluffy invasive species such as America bullfrogs in BC have active population control programs with almost no objection from the public.

Based on these examples, it is clear there is a degree of favouritism when it comes to how invasive species are perceived and subsequently managed. With an obvious bias towards charismatic species, the power of public opinion can have significant impacts on invasive species control. This in turn has the potential to result in severe ecological consequences. Unfortunately, due to the complexity of the issue there is likely no single solution. The most impactful approach may be to increase the public’s awareness of the negative impacts of invasives with a focus on how these species may be damaging native wildlife. A more controversial approach may be to simply provide government scientists with greater decision-making power when it comes to wildlife management, especially for federally and state-owned lands. Adding to the complexity of the issue is how valuable are the cultural ecosystem services provided by charismatic invasives. Are the cultural benefits of invasive species as important as those provided by native species? This is an important question that should be addressed in evaluating the overall impacts caused by invasive species. Biases present in invasion biology are rarely discussed but the issues are clear. For the effective management of all invasive species, whether huggable or ugly, these biases should be recognised and carefully considered.