Great Barrier Reef fish evidence suggests shifts in major global biodiversity patterns

Life on the Great Barrier Reef is undergoing big changes in the face of climate change and other human-caused pressures, a new study reveals

Peer-Reviewed Publication

Lancaster University

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A group of parrotfish swimming in a reef composed of branching, table and massive corals in the Great Barrier Reef 

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Credit: the Long Term Monitoring Program (LTMP) from the Australian Institute of Marine Science (AIMS)

Life on the Great Barrier Reef is undergoing big changes in the face of climate change and other human-caused pressures, a new study reveals.  

From food security to controlling seaweed and even making sand for beaches, reef fish are a hugely important part of marine ecosystems providing a range of benefits to humans and coral reef ecosystems.

New research from an international team of marine scientists from the UK and Australia and led by researchers at Lancaster University, published today in the journal Nature Communications, reveals significant transformations in fish communities on the Great Barrier Reef, the World’s largest coral reef ecosystem.

Their findings show Great Barrier Reef fish communities differ substantially from those of the 1990s, and the pace of change has increased.  The findings raise questions around how long-known patterns of how life is spread across the Earth seem to be shifting.

And importantly, researchers discovered that coral diversity rather than the amount of coral on a reef plays the most crucial role in driving the diversity of fish that depend upon it.

The Great Barrier Reef ecosystem faces many pressures with some, such as coral bleaching and cyclones, becoming more intense and frequent in recent decades. Extreme heat stress resulted in six mass coral bleaching events on the Great Barrier Reef from 1998 to 2022, and another recently in 2024 after this study was completed. This is compounded by other pressures, such as tropical storms, water pollution and outbreaks of crown-of-thorns starfish. These pressures have huge effects on the coral reefs – impacting the amount of coral, the composition of coral assemblages and the diversity of fish that live on coral reefs.

The research team analysed data from the Australian Institute of Marine Science’s (AIMS) Long-Term Monitoring Program, which surveys fish and coral stretching back three decades between 1995 and 2022. The AIMS surveys span more than 1,200 km (from 14°S to 24°S) along the Great Barrier Reef.

One of the most documented patterns of life on Earth is how the number of species (also known as species richness) increases as you get closer to the Equator. This pattern is known as the 'latitudinal diversity gradient'. A key result from this study is showing how this pattern has undergone significant fluctuations.

Latitudinal patterns of diversity are thought to have been relatively stable over long geological timescales, with these patterns also found in fossil records. The study’s results show that although this pattern remains broadly in line with what we expect for the Great Barrier Reef, there are signs the gradient may be shifting as a result of the increasing pressures.

In the northernmost parts of the Great Barrier Reef, which are closest to the equator, the number of different fish species, in particular species of omnivores, plankton feeders and herbivores, have reduced. In contrast, these trophic groups increased in the southernmost sectors of the Great Barrier Reef, raising questions about other potential consequences on the functioning of this ecosystem.

 

In the southern part of the Great Barrier Reef, reef fish species richness has experienced big fluctuations – flipping from periods with high numbers of different species, and periods where that richness has been very low.

But the researchers not only show how the number of fish species has changed, they also looked at how the composition of fish communities has changed. They found that fish communities have continuously changed as fish species replace others particularly in response to disturbances. And as disturbances become more common so too do these changes in fish communities.

Javier González-Barrios, lead author of the study and PhD researcher at Lancaster University, said: “Our findings show how long-term and persistent changes are occurring in the biodiversity of the Great Barrier Reef with increasing disturbance from factors such as climate change. We reveal that the fish communities that make their home on the Great Barrier Reef have changed substantially from the beginning of monitoring in the 1990s, both in the number of species and their composition, and continue to change as pressures on the reef system increase.

“We have seen changes in the number and composition of fish species throughout the reef system as well as species turnover – when one species replaces another - are accelerating in recent years, without any sign of stabilisation.

“These changes provide valuable insights into classic geographic patterns, such as the latitudinal diversity gradient, and opens questions as to whether these patterns are decoupling from their original underlying drivers.”

Another key finding from the study is that changes to the composition of coral species is a better predictor of altered fish patterns than simply the percentage cover of hard corals – a widely-used metric to evaluate coral reef condition.

“The Great Barrier Reef has undergone major fluctuations, with hard coral cover on many reefs declining and then recovering in response to large disturbances,” said Dr Mike Emslie of AIMS. “However, just looking at coral cover can mask the underlying changes in the composition of coral species. Corals build the three-dimensional habitat structure that support other organisms such as fish, and the diversity of corals present can greatly influence the extent of that 3-D structure. The recovery of some corals might not provide the same level of habitat complexity resulting in changes to the fish communities that rely on that complexity.

“Our study shows that changes in fish diversity on the Great Barrier Reef were strongly correlated with shifts in coral composition, and to a lesser extent with fluctuations in coral cover, highlighting the vital importance of a diverse coral assemblage for reef fish communities.”

Professor Nick Graham, of Lancaster University said: “Reef fish are important to a range of ecosystem processes, such as controlling seaweed so it doesn’t overgrow and take over areas of the seabed, to producing the sand we sunbathe on in tropical locations. Reef fish are also important to fisheries and are a vital source of food for millions of people. With disturbances becoming more frequent and severe, the patterns in fish diversity and abundance we have come to expect are changing, and this will alter the benefits the fish provide for the ecosystem and for people.  It’s important that we improve our understanding of how patterns of biodiversity are changing on coral reefs, and the ecological and social implications of this change.”

The study’s findings are outlined in the paper ‘Emergent patterns of reef fish diversity correlate with coral assemblage shifts along the Great Barrier Reef’ published in Nature Communications.

The paper’s authors are Javier González-Barrios, Sally Keith and Nick Graham of Lancaster University, Michael Emslie and Daniela Ceccarelli of AIMS, and Gareth Williams of Bangor University.

The Australian Institute of Marine Science (AIMS) is an Australian government science agency and provides funding for the Long-Term Monitoring Program. Javier González-Barrios was funded by a Natural Environment Research Council (NERC) studentship with the Envision Doctoral Training Centre.

A diverse fish community living in a coral reef with high coral cover and habitat complexity in the Great Barrier Reef 

A small group of tiny fish swimming among bleached and dead corals in the Great Barrier Reef 

Credit

the Long Term Monitoring Program (LTMP) from the Australian Institute of Marine Science (AIMS)

Journal

Nature Communications

DOI

10.1038/s41467-024-55128-7 

Method of Research

Data/statistical analysis

Subject of Research

Animals

Article Title

Emergent patterns of reef fish diversity correlate with coral assemblage shifts along the Great Barrier Reef

Article Publication Date

13-Jan-2025

 

Big firms, big impact: How major exporters drive trade volatility

The world's largest exporters are the hidden culprits behind significant fluctuations in international trade, according to research from the University of Surrey, in collaboration with the Bank of France

University of Surrey

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The world's largest exporters are the hidden culprits behind significant fluctuations in international trade, according to research from the University of Surrey, in collaboration with the Bank of France.  

Their study, published in the Journal of International Economics, shows that when these corporate giants falter, it sends shockwaves through the global economy, resulting in catastrophic declines in exports during crises such as the 2008 financial meltdown and the Covid-19 pandemic. 

Using data covering firm-level exports and imports from France between 1993 and 2020, the team analysed the monthly performance of thousands of exporters. The research revealed four critical insights:  

• Variations in the export performance of large firms account for a staggering 40% of aggregate export fluctuations 

• These firms are particularly sensitive to macroeconomic shocks 

• During major crises, the top 1% of exporters experience an overwhelming impact on their export volumes 

• Their sensitivity is primarily linked to how they respond to large demand shocks, not just their involvement in global supply chains. 

Lead author of the study, Juan Carluccio, Professor in International Trade at the University of Surrey, said: 

"Our findings highlight the disproportionate influence of large exporters on overall trade dynamics. We commonly think as large firms as being more resilient and bringing stability to the economy. But our data shows the opposite: very large firms are actually more sensitive to global shocks, and they are actually a source of volatility.  Understanding their reactions to economic shocks can help policymakers formulate better strategies to mitigate the effects of future crises." 

The research broke down aggregate export growth into two components: the average growth rate of all exporters and a "granular residual" that captures the impact of larger firms. By focusing on the largest exporters, the researchers were able to demonstrate that these firms react unfavourably to macroeconomic changes, with repercussions that re felt throughout the economy, leading to a significant decline in overall trade volumes. 

Professor Carluccio continued: 

“Our study sheds light on the crucial role that large exporters play in shaping the global trade landscape. As economies navigate the ongoing challenges posed by global crises, it becomes vital to recognise that support for these major players can lead to a more stable trade environment. Policymakers are urged to consider strategies that bolster the resilience of large exporters, ensuring they can weather economic storms without jeopardising global trade.” 

“In an era where international trade is more volatile than ever, our research underscores the importance of focusing on the performance of large firms to help stabilise the global economy. By supporting the very firms that drive our economy, we can create a more resilient trade ecosystem that benefits everyone." 

 

[ENDS] 

Note to Editors

• Professor Carluccio is available for interview, please contact mediarelations@surrey.ac.uk to arrange.   

• The full paper is available in the Journal of International Economics 

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Journal

Journal of International Economics

DOI

10.1016/j.jinteco.2024.104037 

Article Title

From macro to micro: Large exporters coping with global crises

 

Stop burning the biomass to protect your lungs

Institute of Physical Chemistry of the Polish Academy of Sciences

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Are you burning garbage? Stop doing it. When you burn garbage, you produce 4-nitrocatechol and levoglucosan, which disrupt biological membranes and enter our first line of defense against volatile compounds - damaging our lung cells. Acknowledgements to Cardinal Stefan Wyszyński University in Warsaw for providing the facility for the photo shoot.  Photo courtesy: Grzegorz Krzyżewski

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Credit: Source: IPC PAS, Grzegorz Krzyzewski

The air over urban sites have much more complex chemical composition than we think. The complexity arises from the presence of air-suspended solid or liquid particles and other organic or inorganic pollutants that interact with each other under solar radiation. These processes make the Earth’s lower atmosphere a real “toxic cocktail” that shape our lives and well-being at places we dwell in. The recent research demonstrated by researchers from the Institute of Physical Chemistry Polish Academy of Sciences in collaboration with foreign partners explains the effect of biomass burning products, namely 4-nitro­catechol and levoglucosan on the behavior of epithelial human lung cells that are the first barrier between the bloodstream and harmful compounds that are present in the air. This work emphasizes the urgent need to extend air quality networks across the European Union by monitoring the concentrations of key biomass burning markers (i.e., 4-nitrocatechol and levoglucosan) in PM2.5 aerosol. Why? The research firmly proved their cytotoxic nature and capacity to severely demolish mitochondrial regions of human lung cells.

 

Our lungs are in danger. This is due to the presence of toxic organic compounds bound to the suspended solid or liquid matter, denoted as aerosol particles, which are present at elevated concentrations in the lower atmosphere over urbanized places. The important sources of aerosol particles are geological processes, volcanic activities, sea sprays but also wild fires that severely annihilates Earth’s ecosystems in drought regions around the world.

 

However, far more relevant for the atmospheric aerosol budget are particles formed through complex chemical processes of volatile pollutants that enter the atmosphere due to human activities or living vegetations. These volatiles play a key role in plant self-defence systems plant/animal communication and vegetations, but importantly can be released by man-made activities such as biomass burning for household heating or biowaste incineration. Once all these compounds get to the lower atmosphere, they immediately enter complex reaction networks with ozone, free radicals and other gaseous pollutants, such as nitrogen and sulfur oxides (NOx, SO2) and… here the whole story begins.

 

Solid particles of a nanoscale range that exist in the lower atmosphere, such as mineral dust, rock grains, plant debris and bacteria residues serve as a platform for condensation of products from aforementioned reactions. This is the onset of the organic aerosol particle growth. It is worth stressing that the resulting thin films of trapped reaction products undergo further chemical modifications that result in aged aerosol particles, which we breath in while exposed to polluted air. Surely, it is not beneficial to our health, and especially to our lung’s cells, which stand on the front line of defense.

 

Luckily, human cells are selective and have evolved biochemical mechanisms to defeat tiny intruders. They activate enzymes that alter the polarity of chemical intruders (xenobiotics) through oxidation processes, ultimately breaking them down to less harmful products, like carbon dioxide and water. However, the smaller the particle size is, the more easily they can diffuse into cells of other tissues, causing inflammation and oxidative stress processes that explain many adverse human health effects. A comprehensive study led by a research team from the IPC PAS (Dr. Faria Khan, Dr. Karina Kwapiszewska, Dr. Krzysztof Rudzinski and Prof. Rafał Szmigielski) in cooperation with the University of North Carolina at Chapel Hill (Prof. Jason Surratt) and Príncipe Felipe Research Center in Spain (Dr. Alicia M. Romero, Dr. Domingo Gil-Casanova) aimed at understanding whether aerosol particles originated from biomass burning are inert to human lung cells or may cause health risks. In other words, they approached the problem from a cell side: are the biomass burning products toxic to a lung cell, and if so, what are symptoms and consequences at a biochemical level?

 

Since the chemical composition of particulates from biomass burning are complex, each biomass burning product shows some toxicity to cellular processes, from cellular respiration to metabolic pathways, which is dependent on its concentrations (doses) and exposition time. Based on our previous studies, the composition of biomass burning aerosol is by far dominated by two end products – levoglucosan and 4-nitrocatechnol. Biomass burning is a process where polysaccharide-based polymers undergo thermal degradation (pyrolysis) leading to both polyhydroxylated derivatives and aromatic compounds. Levoglucosan, as a glucose anhydride, is a product of a glucose pyrolysis, in which a chain breaks down and released monomeric units easily dehydrate. On the other hand, 4-nitrocatechol is a phenolic compound derived from the pyrolysis of cellulose and hemicellulose in the presence of nitrogen oxides that form in situ in a high temperature. As a result, NOx released modify the structure of catechol, resulting in the formation of 4-nitrocatechol.

 

The goal of the researchers from the IPC PAS and foreign colleagues was to investigate how levoglucosan and 4-nitrocatechol affect BEAS-2B bronchial epithelial cells cultured from human lung epithelial cells and alveolar epithelial adenocarcinoma cell lines, such as A549, for which respiration cycles no longer follow the same path through the Warburg effect. Their findings confirmed that the exposure to 4-nitrocatechol disrupt the H+ ions concentration gradient between sides of the mitochondrial membrane, affecting the ADP-ATP biosynthesis. Researchers have shown that the presence of 4-nitrocatechol in the cytoplasm triggers oxidative stress responses, hypoxia induction, and disruption of mitochondrial membrane potential that affect mitochondria As a result, cells begin to behave completely differently in presence of 4-nitrocatechol and levoclucosan in cytoplasm, cellular respiration processes are disrupted. In turn, the disrupted respiration leads to cell apoptosis.

 

"Biomass burning-derived aerosol (BBA) emissions are one of the largest sources of fine carbonaceous aerosol in the troposphere and the second-largest source of trace organic gases worldwide. The inhalation, ingestion, or direct contact with organic volatiles that are released during biomass burning may result in acute and/or chronic exposures and pose serious health threats, including reactive oxygen species (ROS) increase, mutagenesis, DNA damage, hypersensitivity, and systematic or localized (pulmonary) inflammatory responses". - says Prof. Rafał Szmigielski of ICP PAS.

 

Examining the effects of both biomass burning products, 4-nitrocatechol had a very low inhibitory concentration-50 (IC50) value. This explains the increased cytotoxicity and reactive oxygen species (ROS) buildup in the exposed cells. This effect may be due to the higher acidity of 4-nitrocatechnol. Nevertheless, levoglucosan also accelerates the deformation of the phosphor-lipid bilayer but with different rate. Studies clearly show the toxicity of both biomass burning products in both BEAS-2B and A549 cell lines. This is not indifferent to humans, as these aromatic compounds cause strong cell dysfunction leading to a cell death. In order to estimate the magnitude of cellular processes, fluorescence techniques combined with biochemical assays allowed to assess what actually happens in the mitochondria under the exposure of the cell to the aforementioned biomass burning products. Apoptosis occurred in both healthy and cancer cells within just a few hours after exposure with levoglucosan showing the same toxicity at slightly higher doses than 4-nitrocatechol.

 

Scientists are explicit about the need to improve air quality assessment methods in order to have a measurable effect on human health. It is necessary not only to measure the levels of larger particulate matter in the air, such as PM10, but also the levels of PM2.5 and organic compounds from biomass burning, such as 4-nitrocatechol. They highlight that this compound is a very important marker of health effects and its monitoring is crucial.

 

The results presented by the researchers provide information on the constant measuring the levels of 4-nitrocatechol in the air as an indicator of the scale of air pollution problem and to reduce public exposure to this compound. This work is not only a guideline but also an alert for people managing the air quality monitoring system. Without rapid changes in assessing the content of certain chemicals in the inhaled air, the problem of increased incidence of civilization diseases will certainly not disappear. The introduction of 4-nitrocatechol monitoring in the air is a step forward in health care globally.

 

“Our findings are important from an atmospheric perspective as acute exposure to the BBA in case of accidental emissions, such as large-scale wildfires and wood burning, may expose human populations to higher-than-normal biomass burning aerosols (BBA) concentrations. Thus, monitoring the 4-nitrocatechol concentrations in primary and secondary BBA-impacted regions is warranted to estimate acute exposure effects within the lungs. Overall, the current BBA emission markers studied were estimated to be more toxic than other air pollution systems.“- remarks Prof. Rafał Szmigielski emphasizing the importance of the classifying 4-nitrocatechol as an important biomarker in health protection.

 

Besides leading of a research team in IPC PAS, Prof. Rafał Szmigielski is also an academic teacher in Cardinal Stefan Wyszynski University in Warsaw (UKSW), where he intensively educates the future generations on chemistry, biochemistry, air pollutions and the adverse effects of aerosol particles on human health. He also stresses the importance of the interdisciplinarity in conducting the successful research in the atmospheric chemistry. Dr. Faria Khan was a principal investigator in the project. The results obtained during the study built up a key part of her Ph.D. thesis, which she defended in honor on 24 January, 2022. Since then, as post-doctoral research she continues challenging problems of environmental and air pollution toxicology in the Heriot-Watt University, Scotland, United Kingdom (2022-2023) and the Harvard T.H. Chan School of Public Health, Boston, Massachusetts, U.S. (2023-now).

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Journal

Environmental Pollution

DOI

10.1016/j.envpol.2024.125173 

 

Ground-penetrating radar reveals new secrets under Milan's Sforza Castle

Politecnico di Milano

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Ground-penetrating radar reveals new secrets under Milan's Sforza Castle

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Credit: Politecnico di Milano

Milan, 14 January 2025  – In the context of a PhD thesis, the Politecnico di Milano carried out a cutting-edge technological investigation, working in collaboration with the Sforza Castle and with technical support from Codevintec. The survey revealed the presence of numerous passages under the Castle, in the area once covered by the "Ghirlanda" or outer wall, some of which could be linked to secret military passages, also shown in Leonardo's designs. According to historical sources, Ludovico il Moro had an underground passageway built to allow him to visit his beloved wife Beatrice d 'Este, who was buried in the Basilica of Santa Maria delle Grazie. This passageway is immortalised in Leonardo's drawings, and has long been the subject of legends and considerable speculation. But now, thanks to technology, it seems that its existence can be confirmed. However, there are many other secret passageways.

The investigation used advanced technologies, such as GPR and laser scanners, to create an accurate map of the Castle's sub-surface and the underground structures. These instruments were able to reveal underground cavities and passageways about a foot or two beneath the surface. As Franco Guzzetti, professor of Geomatics at the Politecnico di Milano, explained: "The aim is to create a digital twin of the Sforza Castle, a digital model that not only shows the current appearance of the Castle, but also allows us to explore the past, by revealing ancient structures that are no longer visible."

As well as providing a historical record, the data collected could be integrated with augmented reality to develop immersive experience projects that combine history and innovation. Francesca Biolo, researcher at the ABC Department of the Politecnico, also pointed out: "The GDR technology has added to our 3D model by providing data about well-known but inaccessible spaces, revealing unknown pathways and suggesting ideas for further research into these secret passages."

Ground-penetrating radar reveals new secrets under Milan's Sforza Castle

Credit

Politecnico di Milano

Ground-penetrating radar reveals new secrets under Milan's Sforza Castle