World’s oldest meal offers food for thought

Professor Jochen Brocks (left) and Dr Ilya Bobrovskiy
Photo Credit: ANU

The contents of the last meal consumed by the earliest animals known to inhabit Earth more than 550 million years ago has unearthed new clues about the physiology of our earliest animal ancestors, according to scientists from The Australian National University (ANU).

Ediacara biota are the world's oldest large organisms and were first discovered in the Ediacara Hills in South Australia's Flinders Ranges. They date back 575 million years.

ANU researchers found the animals ate bacteria and algae that was sourced from the ocean floor. The findings, published in Current Biology, reveal more about these strange creatures, including how they were able to consume and digest food.

The scientists analyzed ancient fossils containing preserved phytosterol molecules -- a type of fat found in plants -- that remained from the animals' last meal. By examining the molecular remains of what the animals ate, the researchers were able to confirm the slug-like organism, known as Kimberella, had a mouth and a gut and digested food the same way modern animals do. The researchers say it was likely one of the most advanced creatures of the Ediacarans.

Most young people’s well-being falls sharply in first years of secondary school

Most young people in the UK experience a sharp decline in their subjective well-being during their first years at secondary school, regardless of their circumstances or background, new research shows.

Academics from the Universities of Cambridge and Manchester analyzed the well-being and self-esteem of more than 11,000 young people from across the UK, using data collected when they were 11, and again when they were 14.

The adolescents’ overall ‘subjective well-being’ – their satisfaction with different aspects of life (such as friends, school and family) – dropped significantly during the intervening years.

It is widely accepted that young people’s well-being and mental health are influenced by factors such as economic circumstances and family life. The research shows that notwithstanding this, well-being tends to fall steeply and across the board during early adolescence.

That decline is probably linked to the transition to secondary school at age 11. The study identified that the particular aspects of well-being which changed in early adolescence were typically related to school and peer relationships, suggesting a close connection with shifts in these young people’s academic and social lives.

New Omicron subvariant BQ.1.1 resistant to all therapeutic antibodies

The Omicron subvariants BA.1, BA.4, BA.5 as well as Q.1.1 have a high number of mutations in the spike protein. Some of these mutations are escape mutations that allow the virus to escape neutralization by antibodies. In addition, resistance to biotechnologically produced antibodies, which are administered to high-risk patients as a preventive measure or as therapy for a diagnosed SARS-CoV-2 infection, is also developing. Omicron sub-lineage BQ.1.1 is the first variant resistant to all antibody therapies currently approved by the EMA (European Medicines Agency) and/or FDA (US Food and Drug Administration).
Figure Credit: Markus Hoffmann, German Primate Center – Leibniz Institute for Primate Research.

Are the currently approved antibody therapies used to treat individuals at increased risk for severe COVID-19 disease also effective against currently circulating viral variants? A recent study by researchers at the German Primate Center (DPZ) – Leibniz Institute for Primate Research and Friedrich-Alexander University Erlangen-Nürnberg shows that the Omicron sub-lineage BQ.1.1, currently on the rise worldwide, is resistant to all approved antibody therapies. published in the journal Lancet Infectious Diseases.

Alzheimer’s risk gene undermines insulation of brain’s “wiring”

A new study shows how carrying the biggest genetic risk factor for Alzheimer's disease, the APOE4 gene variant, contributes to disease pathology. Here, black gold staining in postmortem brain tissue shows people with two copies of the APOE3 variant have much more myelin insulation of their neurons than people (bottom row) with a copy of APOE4.
Resized Image using AI by SFLORG
Image Credit: Tsai Lab/The Picower Institute

It’s well-known that carrying one copy of the APOE4 gene variant increases one’s risk for Alzheimer’s disease threefold and two copies about tenfold, but the fundamental reasons why, and what can be done to help patients, remain largely unknown. A study published by an MIT-based team in the journal Nature provides some new answers as part of a broader line of research that has demonstrated APOE4’s consequences, cell-type-by-cell-type, in the brain.

The new study combines evidence from postmortem human brains, lab-based human brain cell cultures, and Alzheimer’s model mice to show that when people have one or two copies of APOE4, rather than the more common and risk-neutral APOE3 version, cells called oligodendrocytes mismanage cholesterol, failing to transport the fat molecule to wrap the long vine-like axon “wiring” that neurons project to make brain circuit connections. Deficiency of this fatty insulation, called myelin, may be a significant contributor to the pathology and symptoms of Alzheimer’s disease because without proper myelination, communications among neurons are degraded.

Researchers use blockchain to increase electric grid resiliency

A team led by Raymond Borges Hink has developed a method using blockchain to protect communications between electronic devices in the electric grid, preventing cyberattacks and cascading blackouts.
Photo Credit: Genevieve Martin/ORNL, U.S. Dept. of Energy

Although blockchain is best known for securing digital currency payments, researchers at the Department of Energy’s Oak Ridge National Laboratory are using it to track a different kind of exchange: It’s the first time blockchain has ever been used to validate communication among devices on the electric grid.

The project is part of the ORNL-led Darknet initiative, funded by the DOE Office of Electricity, to secure the nation’s electricity infrastructure by shifting its communications to increasingly secure methods.

Cyber risks have increased with two-way communication between grid power electronics equipment and new edge devices ranging from solar panels to electric car chargers and intelligent home electronics. By providing a trust framework for communication among electrical devices, an ORNL research team led by Raymond Borges Hink is increasing the resilience of the electric grid. The team developed a framework to detect unusual activity, including data manipulation, spoofing and illicit changes to device settings. These activities could trigger cascading power outages as breakers are tripped by protection devices.

A growing trend of antibody evasion by new omicron subvariants

Scanning electron micrograph of a cell (purple) infected with the omicron strain of SARS-CoV-2 virus particles (orange), isolated from a patient sample and colorized.
Image Credit: NIAID/NIH

Three currently circulating omicron subvariants of SARS-CoV-2 – including two that currently make up almost 50% of reported COVID-19 infections in the U.S. – are better at evading vaccine- and infection-generated neutralizing antibodies than earlier versions of omicron, new research suggests.

Scientists tested neutralizing antibodies in blood serum samples from vaccinated and once-boosted or recently infected health care professionals against several subvariants in circulation. Three subvariants stood out for their resistance to the antibody immune response: BQ.1, BQ.1.1 and BA.2.75.2.

BQ.1 and BQ.1.1 are subvariants of the BA.4/5 omicron variants that have been dominating the last few months in the U.S., and each now accounts for about a quarter of current infections, according to the Centers for Disease Control and Prevention (CDC). BA.2.75.2, a mutant of the BA.2 omicron variant, was the best of all variants tested at evading neutralizing antibodies, but currently accounts for only a very small proportion of reported illnesses in the United States.

“In general, the subvariants BQ.1 and BQ.1.1 are much better compared to prior variants at evading the booster-mediated antibody response – the neutralizing antibody titers are clearly much lower. And those two variants are becoming dominant,” said Shan-Lu Liu, senior author the study and a virology professor in the Department of Veterinary Biosciences at The Ohio State University.

Researchers working to improve and simplify models for how PFAS flows through the ground

Will Gnesda demonstrates a PFAS flow lab experiment. Gnesda is graduate student in the UW–Madison Department of Geosciences and lead author of a new study modeling PFAS flow through the ground. The experiment is designed to build on the modeling study.
Photo Credit: Will Cushman

As a growing number of communities are forced to confront PFAS contamination in their groundwater, a key hurdle in addressing this harmful group of chemicals lies in unraveling how they move through a region of the environment called the unsaturated zone — a jumble of soil, rock and water sandwiched between the ground’s surface and the water table below.

A new study by University of Wisconsin­–Madison researchers offers a simplified new way of understanding PFAS movement through this zone.

PFAS is an abbreviation for perfluoroalkyl and polyfluoroalkyl substances. The synthetic chemicals have been used for decades in products ranging from nonstick cookware to firefighting foams. Some PFAS chemicals are associated with health risks and can persist in the environment indefinitely. Modeling their flow through the unsaturated zone — also known as the vadose zone — is important because the chemicals can linger there for years or decades, all the while slowly leaching into aquifers many communities use to provide drinking water.

Researchers find decrease in crucial trace element preceded ancient mass extinction

The research group collecting samples.
Photo Credit Ben Gill

A decline in the element molybdenum across the planet’s oceans preceded a significant extinction event approximately 183 million years ago, new research from Florida State University shows.

The decrease may have contributed to the mass extinction, in which up to 90% of species in the oceans perished, and it suggests that much more organic carbon was buried in the extinction event than had been previously estimated. The work is published in AGU Advances.

“This research tells us more about what was happening with molybdenum during this extinction event, but we also take it a step further,” said Jeremy Owens, an associate professor in FSU’s Department of Earth, Ocean and Atmospheric Science and a paper co-author. “Our findings help us understand how much carbon was cycling through the system, and it’s much larger than previously thought — potentially on the scale of modern atmospheric and oceanic increases due to human activities.”

Previous research showed decreases in molybdenum during the main phase of the ancient mass extinction, but it was unclear how widespread the decrease was, how early it started or how long it lasted.

Webb Reveals an Exoplanet Atmosphere as Never Seen Before

The atmospheric composition of the hot gas giant exoplanet WASP-39 b has been revealed by the NASA/ESA/CSA James Webb Space Telescope. This graphic shows four transmission spectra from three of Webb’s instruments operated in four instrument modes. All are plotted on a common scale extending from 0.5 to 5.5 microns.  A transmission spectrum is made by comparing starlight filtered through a planet’s atmosphere as it moves in front of the star, to the unfiltered starlight detected when the planet is beside the star. Each of the data points (white circles) on these graphs represents the amount of a specific wavelength of light that is blocked by the planet and absorbed by its atmosphere. Wavelengths that are preferentially absorbed by the atmosphere appear as peaks in the transmission spectrum.  The blue line is a best-fit model that takes into account the data, the known properties of WASP-39 b and its star (e.g., size, mass, temperature), and assumed characteristics of the atmosphere. Researchers can vary the parameters in the model – changing unknown characteristics like cloud height in the atmosphere and abundances of various gases – to get a better fit and further understand what the atmosphere is really like.  At upper left, data from NIRISS shows fingerprints of potassium (K), water (H2O), and carbon monoxide (CO). At upper right, data from NIRCam shows a prominent water signature. At lower left, data from NIRSpec indicates water, sulfur dioxide (SO2), carbon dioxide (CO2), and carbon monoxide (CO). At lower right, additional NIRSpec data reveals all of these molecules as well as sodium (Na). 
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Credit: NASA, ESA, CSA, J. Olmsted (STScI)

The NASA/ESA/CSA James Webb Space Telescope just scored another first: a molecular and chemical portrait of a distant world’s skies. While Webb and other space telescopes, including the NASA/ESA Hubble Space Telescope, have previously revealed isolated ingredients of this heated planet’s atmosphere, the new readings provide a full menu of atoms, molecules, and even signs of active chemistry and clouds. The latest data also give a hint of how these clouds might look up close: broken up rather than as a single, uniform blanket over the planet.

The telescope’s array of highly sensitive instruments was trained on the atmosphere of WASP-39 b, a “hot Saturn” (a planet about as massive as Saturn but in an orbit tighter than Mercury) orbiting a star some 700 light-years away. This Saturn-sized exoplanet was one of the first examined by the NASA/ESA/CSA James Webb Space Telescope when it began regular science operations. The results have excited the exoplanet science community. Webb’s exquisitely sensitive instruments have provided a profile of WASP-39 b’s atmospheric constituents and identified a plethora of contents, including water, sulfur dioxide, carbon monoxide, sodium and potassium.

New study reveals high rates of iron deficiency in women during late-stage pregnancy

Photo Credit: Juan Encalada

Pregnant women may need to take more supplemental iron than current Health Canada guidelines recommend, after two UBC researchers found high rates of iron deficiency in a recent study.

The research investigated iron deficiency prevalence among 60 pregnant women in Metro Vancouver and found that over 80 per cent of them were likely iron-deficient in late pregnancy despite taking daily prenatal supplements that provided 100 per cent of the daily iron recommendation in pregnancy.

“This was much higher than I expected to see, which worries us because a woman who is iron-deficient in pregnancy is at higher risk for having an infant with iron deficiency,” said faculty of land and food systems professor Dr. Crystal Karakochuk (she/her), the study’s principal investigator.

Iron is an important nutrient during pregnancy and infancy as it supports optimal growth and development for the fetus and, eventually, the baby.

Kelsey Cochrane (she/her), a PhD candidate in the faculty of land and food systems and the study’s first author, explains that, for the first six months of their lives, babies rely on iron stores they built throughout gestation.