The Rise of Pelagic Fungi and their Crucial Role in Oceanic Ecosystems

Federico Baltar and Eva Breyer in front of their research vessel in Antarctica during a sampling expedition
Photo Credit: Federico Baltar

Mycoplankton plays an active role in the degradation of organic matter and the cycling of nutrients

Fungi plays a vital and previously neglected role in the complex tapestry of marine ecosystems, a study by Eva Breyer and Federico Baltar of the University of Vienna reveals. The results have now been published in the journal Trends in Ecology & Evolution.

Traditionally overlooked and underestimated, recent findings have put the spotlight on the profound importance of pelagic fungi (mycoplankton) as valuable members of oceanic pelagic ecosystems. Thanks to recent technological advances, the scientific community can now harness cutting-edge tools to uncover, characterize, and understand the abundance, diversity, and functional roles played by pelagic fungal taxa and communities within the oceanic realm.

Saving moths may be just as important as saving the bees

More moths were found to be carrying pollen than previously thought, and visiting more types of plant and fruit crops than previously identified
Photo Credit: EyeCandyDesignz

Night-time pollinators such as moths need protecting as effectively as bees, as new research found they could be less resilient to the pressures of urbanization

Night-time pollinators such as moths may visit just as many plants as bees, and should also be the focus of conservation and protection efforts, a new study from the University of Sheffield suggests.

The study found that moths under pressure from urbanization may also be less resilient than bees, due to their more complex life cycle and more specific plant requirements.

It also revealed that despite this threat, moths play a crucial role in supporting urban plant communities, accounting for a third of all pollination in flowering plants, crops and trees.

The researchers suggest that when planning or redeveloping urban areas, supporting the introduction of plant species that are beneficial for moths, as well as bees, will become increasingly important for the health of urban ecosystems.

Fossil of mosasaur with bizarre “screwdriver teeth” found in Morocco

The strange ridges on the teeth indicate a specialised feeding strategy, however its diet remains a mystery.
Photo Credit: Dr Nick Longrich

Scientists have discovered a new species of mosasaur, a sea-dwelling lizard from the age of the dinosaurs, with strange, ridged teeth unlike those of any known reptile. Along with other recent finds from Africa, it suggests that mosasaurs and other marine reptiles were evolving rapidly up until 66 million years ago, when they were wiped out by an asteroid along with the dinosaurs and around 90% of all species on Earth.

The new species, Stelladens mysterious, comes from the Late Cretaceous of Morocco and was around twice the size of a dolphin.

It had a unique tooth arrangement with blade-like ridges running down the teeth, arranged in a star-shaped pattern, reminiscent of a cross-head screwdriver.

Most mosasaurs had two bladelike, serrated ridges on the front and back of the tooth to help cut prey, however Stelladens had anywhere from four to six of these blades running down the tooth.

“It’s a surprise,” said Dr Nick Longrich from the Milner Centre for Evolution at the University of Bath, who led the study. “It’s not like any mosasaur, or any reptile, even any vertebrate we’ve seen before.”

Past climate change to blame for Antarctica’s giant underwater landslides

Dr Jenny Gales (right) and Professor Rob McKay examine the half-section of a core recovered from the Antarctic seabed
Photo Credit: Justin Dodd

Scientists have discovered the cause of giant underwater landslides in Antarctica which they believe could have generated tsunami waves that stretched across the Southern Ocean.

An international team of researchers, led by Dr Jenny Gales from the University of Plymouth, uncovered layers of weak, fossilized and biologically-rich sediments hundreds of meters beneath the seafloor.

These formed beneath extensive areas of underwater landslides, many of which cut more than 100 meters into the seabed.

Writing in Nature Communications, the scientists say these weak layers – made up of historic biological material – made the area susceptible to failure in the face of earthquakes and other seismic activity.

They also highlight that the layers formed at a time when temperatures in Antarctica were up to 3°C warmer than they are today, when sea levels were higher and ice sheets much smaller than at present.

Researchers identify 10 pesticides toxic to neurons involved in Parkinson’s

Photo Credit: Rosyid Arifin

Researchers at UCLA Health and Harvard have identified 10 pesticides that significantly damaged neurons implicated in the development of Parkinson’s disease, providing new clues about environmental toxins’ role in the disease.

While environmental factors such as pesticide exposure have long been linked to Parkinson’s, it has been harder to pinpoint which pesticides may raise risk for the neurodegenerative disorder. Just in California, the nation’s largest agricultural producer and exporter, there are nearly 14,000 pesticide products with over 1,000 active ingredients registered for use.

Through a novel pairing of epidemiology and toxicity screening that leveraged California’s extensive pesticide use database, UCLA and Harvard researchers were able to identify 10 pesticides that were directly toxic to dopaminergic neurons. The neurons play a key role in voluntary movement, and the death of these neurons is a hallmark of Parkinson’s.

Further, the researchers found that co-exposure of pesticides that are typically used in combinations in cotton farming were more toxic than any single pesticide in that group.

'Charge Density Wave' Linked to Atomic Distortions in Would-be Superconductor

This image shows the positions of atoms (blue spheres) that make up the crystal lattice of a copper-oxide superconductor, superimposed on a map of electronic charge distribution (yellow is high charge density, dark spots are low) in charge-ordered states. Normally, the atoms can vibrate side-to-side (shadows represent average locations when vibrating). But when cooled to the point where the ladder-like charge density wave appears, the atomic positions shift along the "rungs" and the vibrations cease, locking the atoms in place. Understanding these charge-ordered states may help scientists unlock other interactions that trigger superconductivity at lower temperatures.
Illustration Credit: Courtesy of Brookhaven National Laboratory

Precision measurements reveal connection between electron density and atomic arrangements in charge-ordered states of a superconducting copper-oxide material

What makes some materials carry current with no resistance? Scientists are trying to unravel the complex characteristics. Harnessing this property, known as superconductivity, could lead to perfectly efficient power lines, ultrafast computers, and a range of energy-saving advances. Understanding these materials when they aren’t superconducting is a key part of the quest to unlock that potential.

“To solve the problem, we need to understand the many phases of these materials,” said Kazuhiro Fujita, a physicist in the Condensed Matter Physics & Materials Science Department of the U.S. Department of Energy’s Brookhaven National Laboratory. In a new study just published in Physical Review X, Fujita and his colleagues sought to find an explanation for an oddity observed in a phase that coexists with the superconducting phase of a copper-oxide superconductor.

Scientists unearth forgotten children of the past

One of the team of scientists analyzing hair under the microscope
Photo Credit: Courtesy of University of York

Scientists have unearthed a story of forgotten children of the past, providing the first direct evidence of the lives of early nineteenth-century ‘pauper apprentices'.

A team from the University of York in collaboration with Durham University and volunteer researchers at Washburn Heritage Centre, examined human remains from a rural churchyard cemetery in the village of Fewston, North Yorkshire. 

Analysis

The analysis discovered the skeletal remains of over 150 individuals, including an unusually large proportion of children aged between eight and 20 years. 

Early analysis immediately identified the children as being distinctive from the locals, showing signs of stunted growth and malnutrition, as well as evidence of diseases associated with hazardous labor. 

The team of scientists, working together with local historians, have been able to piece together the story of these forgotten children, transported from workhouses in London and indentured to work long hours in the mills of the North of England. They were used as an expendable and cheap source of labor.

Adult Friendships Can Triumph Over Childhood Trauma, Even in Baboons

Members of a baboon group in Amboseli, Kenya, relax and groom together, a baboon's way of social bonding.
Photo Credit: Susan C. Alberts, Duke University

Decades of research show that experiencing traumatic things as a child -- such as having an alcoholic parent or growing up in a tumultuous home -- puts you at risk for poorer health and survival later in life.

But mounting evidence suggests that forging strong social relationships can help mitigate these effects. And not just for people, but for our primate cousins, too.

Drawing on 36 years of data, a new study of nearly 200 baboons in southern Kenya finds that adversity early in life can take years off their lifespan, but strong social bonds with other baboons in adulthood can help get them back.

“It’s like the saying from the King James Apocrypha, ‘a faithful friend is the medicine of life,’” said senior author Susan Alberts, professor of biology and evolutionary anthropology at Duke University.

Baboons who had challenging childhoods were able to reclaim two years of life expectancy by forming strong friendships.

The findings were published May 17 in the journal Science Advances.

New study explains how a common virus can cause multiple sclerosis

Olivia Thomas and Mattias Bronge
Photo Credit: Erik Holmgren

Researchers at Karolinska Institutet have found further evidence for how the Epstein-Barr virus can trigger multiple sclerosis or drive disease progression. A study published in Science Advances shows that some individuals have antibodies against the virus that mistakenly attacks a protein in the brain and spinal cord.

The Epstein-Barr virus (EBV) infects most people early in life and then remains in the body, usually without causing symptoms. The link between EBV and the neurological disease multiple sclerosis (MS) was discovered many years ago and has puzzled researchers ever since. Increasing evidence, including two papers published in Science and Nature last year, suggests that EBV infection precedes MS and that antibodies against the virus may be involved. However, the molecular mechanisms seem to vary between patients and remain largely unknown.

“MS is an incredibly complex disease, but our study provides an important piece in the puzzle and could explain why some people develop the disease,” says Olivia Thomas, postdoctoral researcher at the Department of Clinical Neuroscience, Karolinska Institutet and shared first author of the paper. “We have discovered that certain antibodies against the Epstein-Barr virus, which would normally fight the infection, can mistakenly target the brain and spinal cord and cause damage.”

How Breast Cancer Arises

Breast cancer: polyploid giant cancer cell (PGCC)
Image Credit: National Cancer Institute

In what may turn out to be a long-missing piece in the puzzle of breast cancer, Harvard Medical School researchers have identified the molecular sparkplug that ignites cases of the disease currently unexplained by the classical model of breast-cancer development.

A report on the team’s work is published May 17 in Nature.

“We have identified what we believe is the original molecular trigger that initiates a cascade culminating in breast tumor development in a subset of breast cancers that are driven by estrogen,” said study senior investigator Peter Park, professor of Biomedical Informatics in the Blavatnik Institute at HMS.

The researchers said as many as one-third of breast cancer cases may arise through the newly identified mechanism.

The study also shows that the sex hormone estrogen is the culprit behind this molecular dysfunction because it directly alters a cell’s DNA.

Most, though not all, breast cancers are fueled by hormonal fluctuations. The prevailing view of estrogen’s role in breast cancer is that it acts as a catalyst for cancer growth because it stimulates the division and proliferation of breast tissue, a process that carries the risk for cancer-causing mutations. The new work, however, shows that estrogen causes mischief in a far more direct manner.