Calorie restriction in humans builds strong muscle and stimulates healthy aging genes

NIH study suggests a small reduction in daily calories is beneficial for wellness.
Photo Credit: rawpixel

Reducing overall calorie intake may rejuvenate your muscles and activate biological pathways important for good health, according to researchers at the National Institutes of Health and their colleagues. Decreasing calories without depriving the body of essential vitamins and minerals, known as calorie restriction, has long been known to delay the progression of age-related diseases in animal models. This new study, published in Aging Cell, suggests the same biological mechanisms may also apply to humans.

Researchers analyzed data from participants in the Comprehensive Assessment of Long-Term Effects of Reducing Intake of Energy (CALERIE), a study supported by the National Institute on Aging (NIA) that examined whether moderate calorie restriction conveys the same health benefits seen in animal studies. They found that during a two-year span, the goal for participants was to reduce their daily caloric intake by 25%, but the highest the group was able to reach was a 12% reduction. Even so, this slight reduction in calories was enough to activate most of the biological pathways that are important in healthy aging.

Negative attitudes towards breastfeeding in public still an issue

Photo Credit: seeseehundhund

International law supports women’s right to breastfeed in public. However, women report having been subjected to negative responses and judgmental looks when breastfeeding outside the home. This is according to a new study from Lund University in Sweden, based on surveys answered by women living in Sweden, Ireland and Australia.

The researchers behind the study say that societies everywhere need to give clearer, explicit support for breastfeeding in public – and that society needs to welcome breastfeeding, regardless of the setting.

“Women and children lack access to public spaces. This affects opportunities to breastfeed when children need it, which in turn has a negative effect on both women and children,” says Charlotta Dykes, doctoral student and pediatric nurse.

She illustrates that point with one of many similar statements from women in their study: “Just how hungry is my child, will they be okay until I get home? Is there a better spot close by? Can I easily turn to face the other direction?”

Over 40 percent of Antarctica’s ice shelves are smaller

Photo Credit: Derek Oyen

71 of the 162 ice shelves that surround Antarctica have reduced in volume over 25 years from 1997 to 2021, with a net release of 7.5 trillion tons of meltwater into the oceans, say scientists.

They found that almost all the ice shelves on the western side of Antarctica experienced ice loss. In contrast, most of the ice shelves on the eastern side stayed the same or increased in volume. 

Over the 25 years, the scientists calculated almost 67 trillion tons of ice was exported to the ocean, which was offset by 59 trillion tons of ice being added to the ice shelves, giving a net loss of 7.5 trillion tons. 

Dr Benjamin Davison, a research fellow at the University of Leeds who led the study, said: “There is a mixed picture of ice-shelf deterioration, and this is to do with the ocean temperature and ocean currents around Antarctica. 

“The western half is exposed to warm water, which can rapidly erode the ice shelves from below, whereas much of East Antarctica is currently protected from nearby warm water by a band of cold water at the coast.” 

FSU scientists find oxygen levels increased during boom in ancient marine life

Postdoctoral fellow Anders Lindskog examined limestone samples from modern-day Scandinavia to unravel why marine life boomed during the Ordovician Period roughly 487 to 443 million years ago.
 Photo Credit: Seth Young

Florida State University scientists have uncovered answers to a conundrum in Earth’s history: Why did marine life experience an extraordinary boom millions of years ago?

Scientists have long been puzzled about what triggered this explosion of life and a remarkable increase in the diversity of marine species during the Ordovician Period roughly 487 to 443 million years ago. A new study led by FSU Associate Professor of Geology Seth Young and postdoctoral fellow Anders Lindskog has provided insights into this ancient ecological transformation and the role oxygen played in it. Their study was published in Nature Geoscience.

To unravel the ancient mystery, Lindskog and Young embarked on a mission with colleagues at FSU and Lund University in Sweden to understand the environmental conditions, particularly the oxygen levels in the ancient seas, of the Ordovician Period. Oxygen is essential for the development of higher organisms, so it’s a key player in the evolution of marine life.

“By better understanding the backdrop to these changes, we can better understand the mechanisms that drive large-scale and long-term evolution — basically, how life became what it is today,” said Lindskog, who is now at Lund University.

Whaling wiped out far more fin whales than previously thought

The study found current conservation efforts should be enough to help the Eastern North Pacific fin whale population rebound without becoming inbred.
Photo Credit: Aqqa Rosing-Asvid
(CC BY 4.0 DEED)

A new genomic study by UCLA biologists shows that whaling in the 20th century destroyed 99% of the Eastern North Pacific fin whale breeding, or “effective,” population — 29% more than previously thought.

But there is also some good news: Genes among members of this endangered species are still diverse enough that current conservation measures should be be enough to help the population rebound without becoming inbred. The study also found that the health of this group is essential for the survival of highly isolated, genetically distinct fin whales in the Gulf of California.

The study, published in Nature Communications, is among the first to use whole genome information to get a picture of the size and genetic diversity of today’s population. Previous studies had to rely on whaling records or mitochondrial DNA, which is inherited only from the mother, providing limited genetic information.

In the 19th century, whaling decimated most whale species around the world but left the largest ones — blue and fin whales — largely untouched. That changed with the advent of industrial whaling in the 20th century. By midcentury, close to a million fin whales worldwide had been slaughtered, at least 75,000 of these in the Eastern North Pacific.

How do caterpillars acquire chubby legs

Prolegs in the body of the world’s largest moth (dark color), the Atlas moth (Atticus atlas), support the caterpillar in hanging upside down on a twig. Meanwhile, the smaller thoracic legs can be used to help in food processing.
Photo Credit: Courtesy of National University of Singapore

Adult insects, including butterflies and moths, typically have only three pairs of legs. But the existence of extra legs in caterpillars – chubby abdominal appendages also known as ‘prolegs’ – has long posed an evolutionary mystery to biologists. A recent study by researchers from the National University of Singapore (NUS) linked this novel trait to crustaceans.

Caterpillars use their prolegs to grab on to twigs and leaves, while using their thoracic or ‘true’ legs to hold on to other plant parts for feeding.

“The three main theories regarding prolegs suggested that they might be modified thoracic legs, completely novel traits, or modified lobes (endites) of primitive thoracic legs,” explained Professor Antónia Monteiro, who led the team of researchers from the Department of Biological Sciences at the NUS Faculty of Science. “Our study proposes that prolegs are indeed novel traits unrelated to thoracic legs. However, they are derived from a genetic program that specifies lobes that were originally found in the proximal region of crustacean limbs, but had remained inactive in this limb region for millions of years.”

The NUS team published their findings in the scientific journal Science Advances.

Ultrahigh-sensitivity microprobe optimizes detection of molecular fingerprints

Illustration of a whispering-gallery-mode (WGM) microprobe scanning across a sample substrate to collect 2D mapping of molecular fingerprints of substances.
Illustration Credit: Yang lab

Being a good detective requires top-notch evidence gathering, going where the clues are and recognizing their meaning. The same holds true in the realm of sensing technology, where the quest for the perfect balance between ultrahigh sensitivity and a large detection area has been an ongoing challenge. These properties are crucial for a wide range of applications, from biomedical monitoring and chemical imaging to magnetic sensing and vibration detection.

Optical whispering-gallery-mode microsensors, characterized by their ability to trap light in tiny spherical cavities, have emerged as a promising platform for various sensing applications. However, they have historically struggled to achieve both ultrahigh sensitivity and a substantial detection area simultaneously.

Breaking new ground in the field, researchers working with Lan Yang, the Edwin H. & Florence G. Skinner Professor in the McKelvey School of Engineering at Washington University in St. Louis, have developed a scanning whispering-gallery-mode (WGM) microprobe. This novel device represents a shift in the world of microsensors, offering a remarkable solution to the sensitivity-detection area trade-off conundrum. The findings were published in Light: Science & Applications.

Boom in “ice ivory” trade of mammoth tusks presents new threat to elephants and environment

A new study warns the close similarities between the tusks of elephants and mammoths poses threats to conservation and environment efforts

Conservationists fear a rise in the buying and selling of mammoth tusks, known as the “ice ivory” trade, poses a new threat to elephants.

A UK-wide ban on the sale of ivory came into force in 2018, following a University of Portsmouth led investigation into the British antiques trade of the material.

Earlier this year, it was announced the Ivory Act would be extended to protect five more endangered CITES-listed species, including the hippopotamus, walrus, narwhal, orca and sperm whale.

However, a new study has warned that the sale of mammoth tusks is an unregulated aspect of the ivory trade that needs to be addressed. The species falls outside of the regulation of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES); a multi-government agreement set up to ensure the survival of animals and plant species.

Brain tumor treatment by targeting TUG1, a gene that controls replication stress

Researchers discovered the mechanism of interaction among TUG1 (red), R-loops (green),  and another protein (blue) in cancer cells, which provides a key to therapeutic applications. 
Image Credit: Yutaka Kondo, Nagoya University

A new study has unraveled a crucial link between how cancer cells cope with replication stress and the role of Taurine Upregulated Gene 1 (TUG1). By targeting TUG1 with a drug, the researchers were able to control brain tumor growth in mice, suggesting a potential strategy to combat aggressive brain tumors such as glioblastomas. 

“These findings have the potential to be translated into therapeutic applications, as TUG1 is highly expressed in glioblastoma,” said lead researcher Professor Yutaka Suzuki. “In this study, we successfully developed a therapeutic drug named TUG1-DDS, which selectively targets TUG1. It significantly suppressed tumor growth and improved survival, especially when administered in combination with the standard treatment of temozolomide. Therefore, it is a potentially effective therapeutic agent for treating glioblastoma.” 

To understand how TUG1 could potentially treat the most dangerous forms of brain cancer, it is important to understand how cancer turns the usual processes of host cells against themselves to create an environment favorable to cancer cell growth. Even essential cell processes, such as replication, are used to the cancer’s advantage.  

Adaptation to climate change impacts – action too uncoordinated worldwide

How are governments, organizations, companies, and individuals dealing with the impacts of global warming? Indeed, who are the actors, when it comes to reducing the risks of climate change, such as droughts, floods, and forest fires? What do the individual actor groups contribute? And where and how are they already working together in a systematic fashion?

A new study provides the first global analysis of actors engaged in climate adaptation and the roles they are playing. For the publication, an international team led by scientists from LMU and the University of Hamburg assessed more than 1,400 scientific studies on the subject of climate change adaptation. The results show that there are, across the globe, many gaps in distribution of roles and responsibilities for adaptation. Above all, there is a lack of adaptation that profoundly transforms societies, infrastructure, and risk management in response to the massive impacts of climate change. Further, there is a lack of comprehensive collaborations between various state and non-state actors.

“Comprehensive, fair, and forward-looking adaptation is successful when formal organizations and the various other actor group are integrated at all levels,” says Dr. Jan Petzold, geographer at LMU and lead author of the study.