A spark of evolution: When differences in coexistence create new species

University of Bern

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

A male threespine stickleback guarding eggs in his nest.

 

view more 

Credit: Photo credit: Marius Roesti

It has long been assumed that adaptation to different habitats plays an important role in the evolution of new species. Yet how important this influence truly is – particularly during the initial stages of the speciation process – and which ecological differences are most critical remain major questions in evolutionary research.

For the current study, the research team studied populations of threespine stickleback – small fish about the size of a finger – from lakes in western Canada. These lakes formed after glaciers from the last ice age melted less than 12,000 years ago and were then colonized by sticklebacks from the sea. While many of these lakes are environmentally similar, they differ in one aspect: in some, another fish species, the prickly sculpin, lives alongside sticklebacks, while in other lakes sculpins are absent. This seemingly simple ecological difference – living with or without sculpins – has repeatedly pushed sticklebacks down distinct evolutionary paths: in lakes with sculpins, sticklebacks have evolved into slimmer open-water forms, while in sculpin-free lakes they have become stockier bottom-feeding specialists. “Our study sheds light on how new species form and on the role ecological differences play in initiating this process,” says Dr. Marius Roesti from the Institute of Ecology and Evolution at the University of Bern. Roesti is the first author of the study, which has just been published in the scientific journal PNAS. He initiated the research project during his postdoctoral work at the University of British Columbia in Canada, which was supported by the Swiss National Science Foundation (SNSF), and completed it at the University of Bern.

Mating isolation as a decisive step on the way to new species

To test whether the ecological differences between sticklebacks from these different lake types have triggered the evolution of new species, the researchers caught several hundred sticklebacks from multiple lakes with and without sculpins and introduced them into large experimental ponds. A genetic parentage analysis of over 400 offspring revealed that the fish tended to mate with partners from the same lake type. In some cases, this mate preference was so strong that populations from different lake types separated completely. Roesti explains: “Being able to witness the emergence of new species was only possible through our experimental approach. By bringing these evolutionarily young populations from distinct lakes together in the same ponds, we could directly test whether they remained reproductively isolated – and indeed, sticklebacks from different lake types partially did so despite ample mating opportunities – a decisive step on the path toward becoming new species.”

Interaction with a single, ecologically similar species crucial for evolution

The study further shows that the degree of isolation was not random but depended on how much populations had adapted, in both body shape and the genome, to the presence of sculpins. Put simply, the more populations differed in shape and genes between lakes with and without sculpins, the less willing they were to mate. “Remarkably, sculpins and sticklebacks hardly interact directly. Instead, they compete for similar prey and share some of the same predators, influencing each other mainly indirectly through these ecological links,” explains Roesti. Close, direct relationships between species, such as between hosts and parasites or plants and pollinators, have long been seen as powerful engines of speciation. “Our results suggest that indirect interactions between ecologically similar species can also ignite this evolutionary process,” says Roesti.

More broadly, the results show that adaptation to different ecological conditions can, even between geographically isolated populations, be an important driver of speciation. Although geographic isolation is often viewed as a prerequisite for speciation to begin, the importance of ecological adaptation at these early stages remains controversial. “Our study shows that even in geographically isolated populations, speciation does not necessarily unfold slowly or by chance – adaptation to subtle ecological differences can be enough to trigger the process in surprisingly little time,” says Roesti.

Delicate evolutionary balance between interacting species

The study makes clear that even small ecological differences have the potential to shape the course of evolution. It also highlights how sensitive interactions between species are for biodiversity as a whole: depending on which and how such interactions change, new species can form or existing ones can disappear. “We recently learned that one of the stickleback populations we studied has gone extinct after a predatory, non-native fish species was introduced into its lake. This is a sad example showing how human interventions can alter species coexistence and thereby profoundly influence natural evolutionary processes,” says Roesti.

The researchers are continuing their investigations into the formation of species – including in waters in Central Europe, such as in the Lake Constance region, where sticklebacks have also adapted to different habitats. A continuing focus remains the use of field experiments to better understand the mechanisms of speciation under natural conditions. By combining such experiments with high-resolution laboratory analyses, the researchers hope to gain further insights into the evolutionary mechanisms underlying biological diversity.

Institute of Ecology & Evolution / Department of Biology The Institute of Ecology and Evolution at the University of Bern is devoted to research and teaching in all aspects of ecology and evolution and aims to provide a scientific basis for understanding and preserving our living world. We study the mechanisms by which organisms respond to and interact with their environment, including phenotypic responses at the individual level, changes in gene frequencies at the population level, shifts in species composition and abundance at the community level, and the functioning of entire ecosystems. More information

Prickly sculpin – here photographed in its natural habitat – 

plays a key role in the evolution of stickleback towards new species.

Credit

Photo credit: Marius Roesti

The experimental pond facility at the University of British Columbia (Vancouver), where the "speciation test" was carried out. Left: bird's eye view of the entire facility. Right: Close-up of one experimental pond.

 

Credit

Photo credit: Marius Roesti

Journal

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2506625122 

Method of Research

Experimental study

Subject of Research

Animals

Article Title

A species interaction kick-starts ecological speciation in allopatry

Article Publication Date

13-Oct-2025

 

Two Artificial Intelligence methodologies are validated to improve wind speed predictions for wind farms

University of Córdoba

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Image of the team that carried out the research

view more 

Credit: University of Córdoba

Last year, wind energy accounted for 23.2% of all energy injected into the Spanish electricity system, according to data published by Red Eléctrica in its latest 2024 report. Although wind power leads national energy production, its dependence on weather conditions and its inherently intermittent nature present challenges. Therefore, fine-tuning wind speed prediction data for these infrastructures is a key task to optimize the management and performance of wind turbines.

This is precisely what the AYRNA group at the University of Córdoba (UCO) has proposed, using Artificial Intelligence to help fill the sails of wind power, as it were. The team has confirmed two methodologies trained on over 13 years of data, capable of predicting extreme speeds with greater accuracy than traditional methods, using variables such as wind components at different altitudes, pressures, and air temperatures.

Both systems are based on artificial neural networks, inspired by the human brain, and ordinal classification systems, which categorize wind speeds from lowest to highest intensity, rather than predicting specific speeds.

As explained by researcher Antonio Gómez, with the Department of Computer Science and Artificial Intelligence at the UCO, both methodologies have been trained to forecast four different wind speed ranges—low, moderate, high, and extreme—with time horizons of 1, 4, and 8 hours. Each of these categories is associated with not only a specific wind speed range, but also an estimated range of wind energy production.

While the first model performs similarly across all four wind classes, the second excels with more severe events, notes David Guijo, another author of the study. In fact, for gusts exceeding 20 meters per second, which fall into the extreme wind category, the system outperforms traditional methods and can predict speeds with over 94% accuracy. This is particularly valuable for anticipating extreme wind events, allowing turbines to be shut down to prevent damage or collapse.

"Energy companies must periodically estimate the energy they will put on the grid, which underscores the need to refine forecasts for optimal predictions," emphasizes researcher Pedro Antonio Gutiérrez. He notes that while both systems can be extrapolated to different wind farms with relative ease, the models were trained on a specific farm featuring particular conditions. Therefore, applying them to other settings would require retraining and validation.

This work, conducted in collaboration with researchers in the Department of Signal Theory and Communications at the University of Alcalá, is part of the national NEXO research project. The project aims to develop Artificial Intelligence models for applications to renewable energy, various meteorological events, and the field of medicine.

---

Journal

Energy and AI

DOI

10.1016/j.egyai.2025.100596. 

Article Title

Enhancing wind speed prediction in wind farms through ordinal classification

Climate change taking toll on teen mental health, study finds

Nationwide survey led by Athabasca University researchers finds 37% of Canadian youth felt climate change has impacted their mental health

Athabasca University

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

video: 

Dr. Gina Martin, an assistant professor at the Faculty of Health Disciplines at Athabasca University, is studying how young people are experiencing climate change and its impact on their mental well-being.

view more 

Credit: Athabasca University

More than a third of Canadian teens say climate change is impacting their mental health, according to a national study led by Athabasca University researchers.

A survey of 800 Canadian youth aged 13 to 18 found that 37% reported their mental health was impacting their mental health to some extent. Teens indicated climate change has led to feelings of anxiety, stress, and worry, and fuels concerns and uncertainty for the future.

“We’re seeing a lot of increased attention around how young people are feeling around climate change. A lot of that is around their mental health and terms like climate anxiety, or eco anxiety,” explained study co-author Dr. Gina Martin, an associate professor in AU’s Faculty of Health Disciplines.

“We wanted to be able to better understand, from young people’s own perspectives and using their own language, how they feel that climate change is impacting their mental health.”

 

Climate anxiety, fear, and concerns for the future

The study, led by AU postdoctoral researcher Dr. Ishwar Tiwari, used a polling firm to engage youth from coast to coast to coast. After answering the initial question about whether climate change affects their mental health, participants were then asked a series of questions to understand specific concerns.

Researchers were able to identify four main themes, including how climate change affects participants’ emotionally and psychologically with responses related to anxiety, stress, worry, depression, sadness and fear. Other themes focused on teens’ concerns for their own futures, worries for the future of the environment, humanity, and wildlife, but also how climate change affects their ability to lead normal lives.

Concerns about their own future included feelings of hopelessness, worries about the potential loss of homes and livelihoods due to climate change and extreme weather events. Some even reported concerns about becoming a parent and raising children in a world that “will keep getting worse for them,” as one youth wrote.

For some youth, climate change is already having an impact on their ability to function with reports of difficulties sleeping at night and issues related to breathing, headaches, and weakness experienced during wildfire season when air quality is poor due to smoke.

Martin said the research team did not ask youth specifically about their physical health, but teens reported those impacts on their own. “That shows us that they're making that connection themselves about the fact that their physical health is being impacted.”

 

Engaging youth from coast to coast to coast

Martin said it was important for the study to engage teens directly to understand their perspectives. The study included youth from rural, remote, and urban communities to reflect a diversity of experiences and views across Canada. It was also important to include younger teens in the sample as most research on this topic often focuses on youth between the ages of 18 and 25.

“People are going to have different direct experiences depending on where they live, but also the way that they are perceiving things and their daily life are going to be impacted by whether they're in an urban or rural community, whether they're younger or older.”

The study results give researchers, policymakers, educators, and health professionals important data to develop tools and supports to help youth understand and navigate their feelings and develop resilience, Martin added.

“We want to make sure we're protecting young people’s mental health in the context of a changing climate, so that we’re able to say, ‘OK, these things are happening, but there’s mitigation strategies that are being put in place to protect mental health.”

The study was published in September in PLOS Mental Health.

---

Journal

PLOS Mental Health

DOI

10.1371/journal.pmen.0000424 

Method of Research

Survey

Subject of Research

People

Article Title

Canadian adolescents’ perceptions of how climate change is impacting their mental health: A qualitative analysis of open-ended survey responses

Frontiers and World Economic Forum unveil top technologies to accelerate global climate and planetary health solutions

New report from the World Economic Forum and Frontiers identifies ten technologies with the potential to accelerate climate action, restore ecosystems, and drive sustainable innovation within planetary boundaries

Frontiers

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

10 Emerging Technology Solutions for Planetary Health report, co-published by Frontiers and the World Economic Forum

view more 

Credit: The World Economic Forum

The World Economic Forum and leading open science publisher Frontiers today launched the inaugural 10 Emerging Technology Solutions for Planetary Health report, a landmark publication spotlighting ten breakthrough innovations that could accelerate global efforts to tackle climate change, restore ecosystems, and build long-term resilience. These technologies offer scalable, science-based solutions to help society operate within planetary boundaries and foster a more sustainable relationship with Earth's systems. 

The ten technologies with significant transformative potential are: 

1. Precision Fermentation 

2. Green Ammonia Production 

3. Automated Food Waste Upcycling 

4. Methane Capture and Utilization 

5. Green Concrete 

6. Next-Generation Bi-Directional Charging 

7. Timely and Specific Earth Observation 

8. Modular Geothermal Energy 

9. Regenerative Desalination 

10. Soil Health Technology Convergence 

Together, these technologies provide promising pathways to cut emissions, regenerate natural systems, and enhance resilience across food, water, energy, and infrastructure. Among them: 

• Timely and specific Earth observation combines satellite and machine learning technologies for real-time climate and biodiversity monitoring 

• Modular geothermal energy delivers flexible, low-impact renewable power suited to a wide range of geographies 

• Soil health technology convergence integrates in-field sensors, microbiome engineering, and AI to boost soil resilience, carbon storage, and food system sustainability. 

A science-based response to escalating pressures 

With seven of the nine planetary boundaries already exceeded, the 10 Emerging Technology Solutions for Planetary Health report underscores the urgent need for actionable, scalable, science-backed solutions. By evaluating each technology's potential for impact, scalability, and readiness, the report serves as a practical roadmap for policymakers, innovators, and investors to accelerate the translation of breakthrough science into real-world outcomes. 

The report builds on the longstanding partnership between the World Economic Forum and Frontiers and draws on expertise from Frontiers’ global editorial network and the Frontiers Planet Prize community, including its Jury of 100 leading environmental and sustainability scientists. This new report extends the success of the annual Top 10 Emerging Technologies series, focusing for the first time on solutions aligned with the Earth's planetary boundaries.

Jeremy Jurgens, Managing Director at the World Economic Forum, said: 

“The urgent realities of climate change are clear, but what is less visible are the  technologies already available and how they can be used in new ways to deliver solutions. This research provides global leaders with the foresight they need to act at the necessary speed and scale.” 

Johan Rockström, Director of the Potsdam Institute for Climate Impact Research and Chairman of the Frontiers Planet Prize's Jury of 100, commented: 

“No single technology can solve the complex challenges we face, but emerging technologies offer new ways of transforming economies within Earth's safe operating space. From breakthroughs in clean energy and resource efficiency, to innovations in materials, agriculture and ecosystem restoration, these solutions have the potential to address and mitigate key drivers of planetary boundary transgressions.” 

Frederick Fenter, Chief Executive Editor at Frontiers, noted: 

“Open science and cross-sector partnerships are essential if we're to turn innovation into impact. This report shows that while no single technology is a silver bullet, together they can help us bend the curve towards a healthier planet and a more sustainable future for all.”