New light-tuned chemical tools control processes in living cells

Jun Zhang, Laura Herzog and Yaowen Wu have found a way to control proteins in living cells.
Photo Credit: Shuang Li

A research group at Umeå University has developed new advanced light-controlled tools that enable precise control of proteins in real time in living cells. This groundbreaking research opens doors to new methods for studying complex processes in cells and could pave the way for significant advances in medicine and synthetic biology.

In our experiments, we were able to demonstrate precise control over several processes in the cell

“Cellular processes are complex and constantly change depending on when and where in the cell they occur. Our new chemical tool with light switches will make it easier to control processes in the cell and study how cells function in real time. We can also determine where we make such regulation with a resolution of micrometres within a cell or tissue”, says Yaowen Wu, professor at the Department of Chemistry and SciLifeLab Group leader at Umeå University.

The intricate choreography of what happens in a cell is based on the precise distribution and interaction of proteins over time and space. Controlling protein or gene function is a cornerstone of modern biological research. However, traditional genetic techniques such as CRISPR-Cas9 often operate on a longer time scale, which risks causing cells to adapt. In addition, the techniques lack the spatial and temporal precision required to study highly dynamic cellular processes.

Mount Rainier White-Tailed Ptarmigan Finally Receives a ‘Threatened’ Species Designation

An adult Mount Rainier white-tailed ptarmigan in brown summer plumage. Its feathers change seasonally—white in the winter, white and brown in the spring. Its tail remains white year-round.
Photo Credit: Pete Plage/USFWS

In July, the Mount Rainier white-tailed ptarmigan was officially listed as threatened by the U.S. Fish and Wildlife Service (FWS) under the Endangered Species Act (ESA), 14 years after the Center for Biological Diversity first petitioned for its listing. This designation is meant to help preserve the bird, whose survival depends on the glaciers of the Cascade Mountains of Washington State and British Columbia. It also reflects the complex challenges that alpine-adapted birds face in a warming world.

With its feathered, snowshoe-like feet that allow it to walk on high mountain terrain and its seasonal plumage that provides camouflage year-round, Mount Rainier white-tailed ptarmigans are adapted to high elevation regions above the treeline. They are frequently spotted in areas with mixed rock, snow and alpine plants. Their diet consists of twigs, leaves, buds and seeds of alpine tundra vegetation that only grow in treeless, cold and dry mountainous regions that receive critical moisture from spring snowmelt and summer glacier runoff.

Warming temperatures are accelerating glacier retreat and endangering the bird’s habitat: glaciers in the North Cascades shrunk 56 percent between 1900 and 2009. Mauri Pelto, director of the North Cascade Glacier Climate Project, told GlacierHub that ptarmigans are often spotted along the Shuksan and Ptarmigan Ridges near Mount Baker. In a study, Pelto found that seven of the 13 glaciers along those ridges have disappeared since the mid-1980s. Retreating glaciers risk reduced soil water availability for tundra vegetation and long-term habitat loss associated with warming temperatures.

Life cycles of some insects adapt well to a changing climate. Others, not so much.

A grasshopper, Melanoplus boulderensis, typical of the Colorado Rocky Mountains.
Photo Credit: ©Thomas Naef, 2022

As insect populations decrease worldwide in what some have called an “insect apocalypse,” biologists are desperate to determine how the six-legged creatures are responding to a warming world and to predict the long-term winners and losers.

A new study of Colorado grasshoppers shows that, while the answers are complicated, biologists have much of the knowledge they need to make these predictions and prepare for the consequences.

The findings, published in the journal PLOS Biology, come thanks to the serendipitous discovery of 13,000 grasshoppers collected from the same Colorado mountain site between 1958 and 1960 by a biologist at the University of Colorado Boulder (CU Boulder). After that scientist’s untimely death in 1973, the collection was rescued by his son and donated to the CU Museum, where it languished until 2005, when César Nufio, then a postdoctoral fellow, rediscovered it. Nufio set about curating the collection and initiated a resurvey of the same sites to collect more grasshoppers.

Better digital memories with the help of noble gases

Adding the noble gas xenon when manufacturing digital memories enables a more even material coating even in small cavities.
Photo Credit: Olov Planthaber

The electronics of the future can be made even smaller and more efficient by getting more memory cells to fit in less space. One way to achieve this is by adding the noble gas xenon when manufacturing digital memories. This has been demonstrated by researchers at Linköping University in a study published in Nature Communications. This technology enables a more even material coating even in small cavities.

Twenty-five years ago, a camera memory card could hold 64 megabytes of information. Today, the same physical size memory card can hold 4 terabytes – over 60,000 times more information.

An electronic storage space, such as a memory card, is created by alternating hundreds of thin layers of an electrically conductive and an insulating material. A multitude of very small holes are then etched through the layers. Finally, the holes are filled with a conductive material. This is done by using a technique in which vapors of various substances are used to create thin material layers.

Carbon capture from constructed wetlands declines as they age

Protecting wetland ecosystems is essential as they provide critical environmental benefits to our planet.
Photo Credit: Herbert Aust

Constructed wetlands do a good job in their early years of capturing carbon in the environment that contributes to climate change – but that ability does diminish with time as the wetlands mature, a new study suggests.

Researchers examined soil core samples taken from two constructed freshwater wetlands and compared them to data from previous studies of the same wetlands over 29 years to determine how well human-made wetlands sequester — or capture and store — carbon as they age. 

Findings showed both wetlands captured similar amounts of carbon over the decades, but neither has shown a net gain or loss since year 15.

But their value in sequestering carbon is remarkable, the researchers said.

“Wetlands are generally thought of as the kidneys of our world because they can clean water naturally and sequester carbon well,” said Jay Martin, a distinguished professor in food, agricultural and biological engineering at The Ohio State University and a co-author of the study. “As we try to combat climate change, they also provide habitat for many species that are important to us.”

New study could help tackle hidden hunger in Malawi

Fields in Blantyre, Malawi
Photo Credit: Dr Charlotte Hall

Growing fruit trees on farms in rural Malawi could directly improve people’s diets, according to new study by a University of Stirling researcher.

 Around 20% of the population of the African country are undernourished and far more suffer from hidden hunger, meaning they consume enough calories but lack essential micronutrients, such as iron, zinc and vitamin A.

Around 80% of Malawians are involved in smallholder agriculture and a large proportion of the food they consume comes from their own production.

However, conventional agri-food policies continue to promote the increased production of staple cereal crops, and very rarely promote the benefits of fruit trees.

This Multiferroic Can Take the Heat - up to 160℃

Image Credit: Tohoku University

While most multiferroics are limited such that the hottest they can operate at is room temperature, a team of researchers at Tohoku University demonstrated that terbium oxide Tb2(MoO4)3 works as a multiferroic even at 160 ℃.

As one can imagine, a material that loses its functionality from a hot summer's day or simply the heat generated by the device itself has limited practical applications. This is the major Achilles heel of multiferroics - materials that possess close coupling between magnetism and ferroelectricity. This coupling makes multiferroics an attractive area to explore, despite that weakness.

In order to surmount this weakness to unleash the full potential of multiferroics, the research team investigated the candidate material Tb2(MoO4)3. It successfully showed the hallmark traits of multiferroics, and was able to manipulate electric polarization using a magnetic field, even at 160 ℃. This is a huge jump from the previous limit of approximately 20 ℃. Without that major Achilles heel, this remarkable finding means that multiferroics can meaningfully be applied to areas such as spintronics, memory devices that consume less power, and light diodes.

Spinning or not spinning?

Opening the "Gate of Truth" of puzzling superconductivity in strontium ruthenate
Image Credit: KyotoU/G Mattoni

Superconductors can carry electricity without losing energy, a superpower that makes them invaluable for a range of sought-after applications, from maglev trains to quantum computers. Generally, this comes at the price of having to keep them extremely cold, an opportunity cost that has frequently hindered widespread use.

Understanding of how superconductors work has also progressed, but there still remains a great deal about them that is unknown. For example, amongst many materials known to have superconducting properties, some do not behave according to conventional theory.

One such puzzling material is strontium ruthenate or Sr2RuO4, which has challenged scientists since it was discovered to be a superconductor in 1994. Initially, researchers thought this material had a special type of superconductivity called a "spin-triplet" state, which is notable for its spin supercurrent. But even after considerable investigation, a full understanding of its behavior has remained a mystery.

OHSU researchers identify protective properties of amniotic fluid

A multidisciplinary team of OHSU researchers collaborates to better understand the mechanism of amniotic fluid’s role in fetal development. Their goal is to identify how its properties can be harnessed to address prenatal health concerns.
Photo Credit: Christine Torres Hicks/OHSU

Researchers at Oregon Health & Science University have made new discoveries about amniotic fluid, a substance historically not well understood in medical research due to the difficulty in obtaining it during pregnancy, especially across gestation.

Amniotic fluid is the vital fluid that surrounds and protects a fetus during pregnancy. In addition to providing much-needed cushion and protection for the fetus, it also aids in development of vital organs — especially the lungs, digestive tract and skin— and stabilizes the temperature inside the womb.

The new study, published in the journal Research and Practice in Thrombosis and Haemostasis, found that the addition of amniotic fluid to plasma — the liquid portion of blood — improves the blood’s ability to thicken and clot, which is a critical and likely a protective function throughout pregnancy and during delivery for both the birthing parent and the baby.

The mechanism of amniotic fluid’s role in fetal development is not well understood and is understudied: The OHSU study is one of the first to identify how the features and properties of amniotic fluid change over time, especially those properties that play a role in thickening the blood, and how those changes can affect how maternal blood coagulates. If a pregnant person’s blood does not clot properly, it can create life-threatening complications for the fetus and birthing parent, including excessive bleeding during pregnancy and delivery.  

Cold Waves in the Rainforest: What They Mean for Wild Animals

Typical animals in the lowland rainforest of the Amazon: On the left, the palm-sized dung beetle Coprophanaeus lancifer, which appears to be sensitive to low temperatures. On the right, the Brazilian wandering spider Phoneutria boliviensis, which also grows to the size of a palm. The spider can often be seen at night, but during the cold wave it was nowhere to be seen.
Photo Credit: Kim Lea Holzmann / Universität Würzburg

It's not always cozy and warm in the Amazon rainforest: cold waves can cause temperatures to drop drastically. Würzburg researchers have investigated how animals react to this.

Anyone conducting research in the tropical rainforest does not necessarily have a winter jacket and warm socks with them. After all, this region of the world is considered to have a consistently pleasant temperature. But this is not the case, as Kim Lea Holzmann and Pedro Alonso-Alonso have found out for themselves. Both are doing their doctoral theses at the University of Würzburg's Biocentre and both spent almost the whole of 2023 in the Amazon region in southern Peru to study biodiversity.

It happened on 13 June: a cold spell caused temperatures to plummet from an average of 23.9 to 10.5 degrees Celsius. The cool period lasted almost a week. ‘A year before, we had already experienced a day when it was only 18 degrees,’ says Kim Lea Holzmann. But such severe and prolonged cold seemed strange to them. The local field assistants, on the other hand, were not really surprised. They explained to the Würzburg team that cold spells lasting several days are not that rare in the Amazon.