Marine mammals in zoos and aquariums now live 2-3 times longer than in the wild

Photo Credit: Los Muertos Crew

A new study provides compelling evidence that animal care and management practices at zoos and aquariums have significantly improved over time. The study, led by Species360 and University of Southern Denmark Research Scientist Dr. Morgane Tidière in collaboration with 41 co-authors from academic, governmental, and zoological institutions around the world, is the first to examine life expectancy and lifespan equality together as a proxy of population welfare in marine mammal species.

The study also found that marine mammal species live longer in zoological institutions than in the wild as a result of advances in animal care practices centered on animal welfare. The results have been published in Proceedings of the Royal Society B: Biological Sciences.

From SDU the following researchers contributed: Fernando Colchero, Johanna Staerk, Ditte H. Andersen, Kirstin Anderson Hansen and Dalia A. Conde.

The animals in the study
The four species in this study (harbor seal, sea lion, polar bear and bottlenose dolphin) were selected because they represent 63,4% of all marine mammals, registered in the global Species360 Zoological Information Management System (ZIMS).

Critical step made for managing brushtail possums

Researchers say mapping the genetic code of the brushtail possum will benefit those working to both conserve and control the animal.

In a five-year long study, just published in Nature Communications, an international group of researchers led by the University of Otago, has assembled the entire genetic code of the marsupial mammal.

The work also uncovered where and when their genes are expressed, and revealed surprising details about their population diversity, reproduction, and origins.

Study lead Associate Professor Tim Hore, of Otago’s Department of Anatomy, describes possums as “a fascinating animal that is loved in one country and a cause of concern in another”.

“They are hunted in Aotearoa New Zealand for their fur, and controlled for conservation, but treasured and protected in Australia. Having their full genetic code is important for both countries as efforts to manage their respective populations are being held back by the lack of this knowledge,” he says.

UCLA-led team finds a stem-cell derived mechanism that could lead to regenerative therapies for heart damage

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A UCLA-led team has identified an essential internal control mechanism that can promote the maturation of human stem cell-derived heart muscle cells, offering a deeper understanding of how heart muscle cells develop from their immature fetal stage to their mature adult form.

The findings, published in the peer-reviewed journal Circulation, could lead to new therapies for heart disease and cardiac damage.

The collaborative effort with Duke-NUS Medical School in Singapore and other institutions identified an RNA splicing regulator named RBFox1, which was considerably more prevalent in adult heart cells than in newborns, based on a preclinical model. The sharp rise in RBFox1 during the maturation of heart cells was also confirmed through analyses of existing single-cell data.

“This is the first piece of evidence suggesting that RNA splicing control plays a vital role in postnatal heart cell maturation,” said study lead Jijun Huang, who conducted this research during his postdoctoral training in anesthesiology at UCLA. “While RBFox1 alone may not be sufficient to push mature fetal heart muscle cells all the way to fully matured adult cells, our findings uncover a new RNA-based internal network that can substantially drive this maturation process beyond other available approaches.”

New patterns in Sun’s layers could help scientists solve solar mystery

In this image, the fine-structure of the quiet Sun is observed at its surface or photosphere.
Image Credit: NSF/AURA/NSO

Astronomers are one step closer to understanding one of the most enduring solar mysteries, having captured unprecedented data from the Sun’s magnetic field.

New research from an international team may explain one of the biggest conundrums in astrophysics – why the outermost layer of the Sun’s atmosphere is hotter than the surface

Groundbreaking data collected from the world's most powerful solar telescopes shows a snake-like pattern in the Sun’s magnetic fields that could contribute to the heating of the Sun’s outermost atmosphere

The project, which includes scientists across a wide range of institutions on both sides of the Atlantic Ocean, has opened new avenues in solar physics

Astronomers are one step closer to understanding one of the most enduring solar mysteries, having captured unprecedented data from the Sun’s magnetic field.

New Research Suggests Why Males and Females Respond Differently to Social Stress

Emily Wright, researcher, in a UC Davis lab.
Photo Credit: Jerry Tsai

Women are nearly twice as likely as men to be diagnosed with an anxiety disorder, but among boys and girls the likelihood is the same. New University of California, Davis, research has identified changes in the brain during puberty that may account for differences in how women and men respond to stress.

A team of psychologists has found that testosterone is the key hormone that drives gender-based differences in responses to social stress. The study encompassed six separate experiments with mice to isolate what changes in the brain drive these differences between males and females. The study was published in the Proceedings of the National Academy of Sciences, or PNAS, today.

“This research shows how the body’s hormones shape the complex interplay between the brain’s circuitry and behavioral responses to stress,” said Brian Trainor, a professor of psychology in the College of Letters and Science at UC Davis and the study’s corresponding author.

Germicidal UV lights could be producing indoor air pollutants

Image Credit: José-Luis Olivares, MIT; iStock
(CC BY-NC-ND 3.0 DEED)

Many efforts to reduce transmission of diseases like Covid-19 and the flu have focused on measures such as masking and isolation, but another useful approach is reducing the load of airborne pathogens through filtration or germicidal ultraviolet light. Conventional UV sources can be harmful to eyes and skin, but newer sources that emit at a different wavelength, 222 nanometers, are considered safe.

However, new research from MIT shows that these UV lights can produce potentially harmful compounds in indoor spaces. While the researchers emphasize that this doesn’t mean the new UV lights should be avoided entirely, they do say the research suggests it is important that the lights have the right strength for a given indoor situation, and that they are used along with appropriate ventilation.

The findings are reported in the journal Environmental Science and Technology, in a paper by recent MIT postdoc Victoria Barber, doctoral student Matthew Goss, Professor Jesse Kroll, and six others at MIT, Aerodyne Research, and Harvard University.

While Kroll and his team usually work on issues of outdoor air pollution, during the pandemic they became increasingly interested in indoor air quality. Usually, little photochemical reactivity happens indoors, unlike outdoors, where the air is constantly exposed to sunlight. But with the use of devices to clean indoor air using chemical methods or UV light, “all of a sudden some of this oxidation is brought indoors,” triggering a potential cascade of reactions, Kroll says.

Large swings in past ocean oxygen revealed

GEOTRACES researchers prepare to sample cobalt and more.
Photo Credit: Bill Schmoker, PolarTREC

As the climate warms, there is major concern that Earth’s oceans will lose oxygen. A study published by oceanographers at the University of Hawaiʻi at Mānoa revealed that locked in ancient deep-sea sediments is evidence for oxygen loss in the world’s ocean during past glacial periods.

Scientists first measured oxygen in the oceans in the 1960s. Since then, they have observed decreasing levels in the mid-depths of the ocean—a phenomenon that can be explained in part by the fact that warmer waters hold less oxygen. Less oxygen in the water can lead to habitat loss for fish and other marine species that need oxygen to breathe. If the naturally-occurring low-oxygen regions in the Eastern Pacific expand in a warmer climate, Pacific Island fisheries could be significantly impacted.

The study also indicates that widespread oxygen loss with current climate change may not be permanent, if Pacific Ocean currents rearrange in the future.

AI Models Identify Biodiversity in Tropical Rainforests

The Banded Ground Cocoo (Neomorphus radiolosus, left) and the Purple Chested Hummingbird (Polyerata rosenbergi) are among the birds recorded in tropical reforestation plots in Ecuador.
Photo Credits: John Rogers / Martin Schaefer)

Animal sounds are a very good indicator of biodiversity in tropical reforestation areas. Researchers led by Würzburg Professor Jörg Müller demonstrate this by using sound recordings and AI models.

Tropical forests are among the most important habitats on our planet. They are characterized by extremely high species diversity and play an eminent role in the global carbon cycle and the world climate. However, many tropical forest areas have been deforested and overexploitation continues day by day.

Reforested areas in the tropics are therefore becoming increasingly important for the climate and biodiversity. How well biodiversity develops on such areas can be monitored very well with an automated analysis of animal sounds. This was reported by researchers in the journal Nature Communications.

The world may have crossed solar power ‘tipping point’

Photo Credit: American Public Power Association

The world may have crossed a “tipping point” that will inevitably make solar power our main source of energy, new research suggests.

The study, based on a data-driven model of technology and economics, finds that solar PV (photovoltaics) is likely to become the dominant power source before 2050 – even without support from more ambitious climate policies.

However, it warns four “barriers” could hamper this: creation of stable power grids, financing solar in developing economies, capacity of supply chains, and political resistance from regions that lose jobs.

The researchers say policies resolving these barriers may be more effective than price instruments such as carbon taxes in accelerating the clean energy transition.

The study, led by the University of Exeter and University College London, is part of the Economics of Energy Innovation and System Transition (EEIST) project, funded by the UK Government’s Department for Energy Security and Net Zero and the Children’s Investment Fund Foundation (CIFF).

“The recent progress of renewables means that fossil fuel-dominated projections are no longer realistic,” Dr Femke Nijsse, from Exeter’s Global Systems Institute.

Unlocking the secrets of cell behavior on soft substrates: A paradigm shift in mechanobiology

Figure showing cancer cells (Osteosarcoma cells) on a printed protein spot. Scale bar: 50 μm.
Photo Credit: Turku Bioscience Centre / James Conway and Hellyeh Hamid

A research group from the University of Turku and Turku Bioscience Centre together with Misvik Biology Ltd in Finland have develop a new method for studying how cancer cells function in softer and stiffer tissue environments. This insight challenges the existing paradigm, opening up new possibilities for research in cancer biology and tissue engineering.

A longstanding belief has been that cells outside the body prefer to spread and grow on stiffer surfaces. This is similar to when we walk on a concrete sidewalk (very stiff) and find it preferable to walking in mud (very soft). For this reason, cells, including stem cells, are continuously cultured on very stiff plastic or glass for research purposes. This idea also resonates with cancer cells thriving within a hard lump they form in tissues. Usually, the stiffer the tumor, the poorer the patients’ prognosis. However, the stiffness of the tissues in our body (e.g., bone versus brain) is not the same. In fact, some cells like neurons and fat cells grow and function effectively in very soft surroundings.

The research group from the University of Turku and Turku Bioscience Centre collaborated with Misvik Biology Ltd, a biotechnology company based in Turku, Finland, to understand how cells function in softer environments and how these could be better modelled outside the human body. They used computational modelling and a large array of growth conditions to meticulously compare cell behavior on soft and stiff surfaces at an unprecedented resolution.