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Category: chemistry

Tau mutation drives autophagy-lysosome dysfunction

The researchers studied a specific mutation in a brain protein called tau that causes the protein to become misfolded and alter its normal function. In general, when tau proteins become misfolded, they build up inside neurons and contribute to various forms of dementia, including Alzheimer’s dementia and frontotemporal dementia, a neurodegenerative disease similar to Alzheimer’s that often strikes earlier — in middle age — and typically involves significant changes in personality and behavior that precede cognitive decline.

In this new study, the researchers studied neurons that had been reprogrammed from skin cells sampled from patients with frontotemporal dementia who carried the tau mutation. In the neurons, the mutated tau proteins caused waste-recycling centers called lysosomes, which are involved in autophagy, to become dysfunctional, allowing cellular waste to accumulate in the lysosomes, which may contribute to neuronal death. The researchers found that enhancing autophagy with an analog of the chemical compound G2 improved clearance of the garbage, reduced tau levels in the lysosomes and prevented cellular toxicity and death.

G2 was discovered in 2019 via screening experiments seeking drugs that could reduce the accumulation of an aggregation-prone protein in a C. elegans model of alpha-1-antitrypsin deficiency, which can cause severe liver disease. The compound was later shown to boost autophagy function in mammalian cell model systems.

The researchers also have shown that G2 can protect brain cells from death in cells modeling Huntington’s disease, a fatal inherited neurodegenerative disease caused by a genetic mutation present at birth. In the cellular model of Huntington’s disease, the compound prevented the buildup of a harmful RNA molecule. ScienceMission sciencenewshighlights.

New research adds to growing evidence that helping brain cells break down and eliminate their own cellular waste is a promising treatment strategy for a variety of neurodegenerative diseases. In lab experiments, the researchers found that exposure to a novel compound can clear a harmful protein from human neurons modeling frontotemporal dementia — a devastating and ultimately fatal condition — and prevent those neurons from dying.

The study is published in the journal Nature Communications.

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Hydroxyl radicals in UV-exposed water reveal surprising reaction pathway

How do radicals form in aqueous solutions when exposed to UV light? This question is important for health research and environmental protection. For example, with regard to the overfertilization of water bodies by intensive agriculture. A team at BESSY II has now developed a new method of investigating hydroxyl radicals in solution. By using a clever trick, the scientists gained surprising insights into the reaction pathway. The findings are published in the Journal of the American Chemical Society.

Hydroxyl radicals (OH·) are found everywhere, from the troposphere to the cells of the human body. There, they cause oxidative stress and accelerate the aging process. They are also increasingly present in rivers and lakes, where they are formed by the photolysis of nitrogen oxides that have entered the water from over-fertilized soils. When UV radiation from sunlight strikes nitrogen oxides, hydroxyl radicals and a range of other radicals are generated. The chemistry of these radicals is extremely difficult to characterize accurately, as they react very quickly.

A team led by Professor Alexander Föhlisch of the HZB has investigated the chemistry of hydroxyl radicals formed from nitrogen oxides in water using X-ray absorption spectroscopy at the BESSY II X-ray source.

AI diffusion models tailor drug molecules to custom-fit protein targets, speeding drug development and evaluation

University of Virginia School of Medicine scientists have developed a bold new approach to drug development and discovery that could dramatically accelerate the creation of new medicines. UVA’s Nikolay V. Dokholyan, Ph.D., and colleagues have developed a suite of artificial intelligence-powered tools, called YuelDesign, YuelPocket and YuelBond, that work together to transform how new drugs are created. The centerpiece, YuelDesign, uses a cutting-edge form of AI called diffusion models to design new drug molecules tailored to fit their protein targets exactly, even accounting for the way proteins flex and shift shape during binding.

A companion tool, YuelPocket, identifies exactly where on a protein a drug can attach, while YuelBond ensures the chemical bonds in designed molecules are accurate. Together, the approach is poised to improve both how new drugs are designed and how quickly and efficiently existing drugs can be evaluated for new purposes.

“Think of it this way: Other methods try to design a key for a lock that’s sitting perfectly still, but in your body, that lock is constantly jiggling and changing shape. Our AI designs the key while the lock is moving, so the fit is much more realistic,” said Dokholyan, of UVA’s Department of Neurology. “This could make a real difference for patients with cancer, neurological disorders and many other conditions where we desperately need better drugs targeting these wiggly proteins but keep hitting dead ends.”

How surface chemistry impacts the performance of malaria nets

Insecticide-treated bed nets remain one of the most effective tools in malaria prevention, acting both as a physical barrier and as an insecticidal surface that kills or disables mosquitoes before they can transmit disease. New research by a multidisciplinary research team from the University of Liverpool and the Liverpool School of Tropical Medicine (LSTM) uses surface science to assess how well malaria nets perform.

Published in Science Advances, the focus of the study was the phasing out of PFAS coatings, a group of synthetic fluorinated coating chemicals that have been valued for stability and performance. However, their environmental persistence and potential health risks have made their removal an important priority. The paper is titled “Multimodal platform for ITN efficacy: Surface chemistry, bioavailability, and mosquito behavior.”

To understand the impact of removing PFAS, the team developed a novel multimodal evaluation platform combining chemical analysis, advanced surface imaging, and mosquito behavioral tracking.

Optical control of nuclear spins in molecules points to new paths for quantum technologies

Researchers at the Karlsruhe Institute of Technology (KIT) have reported important progress in quantum physics and materials science by optically initializing, controlling, and reading out nuclear spin states in a molecular material for the first time. Because of their weak interaction with the environment, nuclear spins are particularly stable quantum information carriers. The research, published in Nature Materials, shows that molecular nuclear spins could be a promising building block for future quantum technologies.

Nuclear magnetic resonance (NMR) is an established method for analyzing materials and molecules, with applications ranging from chemical analysis to quantum information processing. For a new paper, KIT researchers analyzed a molecular crystal containing europium ions. Such ions have especially narrow optical transitions that allow direct addressing of nuclear spin states. Using laser light, they were able to initialize nuclear spins in defined states and then read out those states.

In addition to optical addressing, the researchers used high-frequency fields to control the spins and protect them from interfering environmental influences. They achieved nuclear spin quantum coherence with a lifetime of up to two milliseconds, an interval during which a quantum system maintains a precisely defined quantum mechanical state.

Leather gets a power upgrade with laser-written microsupercapacitors

Researchers have developed a simple and eco-friendly way to use a laser to turn natural leather into flexible and wearable energy devices. The new approach could lay the groundwork for more sustainable wearable electronics. In a paper in Optics Letters, the researchers demonstrate the new technique by creating microsupercapacitors on leather in various patterns, including a tiger, dragon and rabbit.

“Using a laser, we directly write conductive patterns onto vegetable-tanned leather to create microsupercapacitors that can store energy and help smooth electrical signals so that wearable electronics run more reliably,” said the research team leader Dong-Dong Han from Jilin University in China.

Unlike conventional devices that rely on synthetic materials and complex, chemical-heavy processes, our approach uses a natural, skin-friendly material and a one-step fabrication method. The microsupercapacitors are well-suited for flexible and comfortable wearable electronics because they are built on soft materials and can be shaped freely and integrated directly into products.

A greener route to citrus-derived therapeutics: What a new bromination method changes

Undergraduate students at Penn State Brandywine developed an environmentally friendly and easy method to synthesize compounds from plant-derived molecules for potential use in therapeutics. Their work, conducted under the supervision of Penn State Brandywine Assistant Professor of Chemistry Anna Sigmon, was published in a special issue of the journal ACS Omega titled “Undergraduate Research as the Stimulus for Scientific Progress in the U.S.”

Co-author Maria Englert, who graduated from Penn State in 2025, became involved with Sigmon’s research on the recommendation of another mentor and said she learned far more than she expected.

“The more we worked through the reactions and discussed methodologies with each other, the more chemistry felt like an art form—something that requires creativity, intuition and a tenacious approach to problem-solving,” she said. “This experience taught me that progress in research is shaped by collaboration, careful observation and a willingness to rethink your approach.”

New hydrogen fuel cell design could unlock key clean energy technology

UNSW researchers have redesigned hydrogen fuel cells to solve a critical flaw, bringing clean energy for aviation, heavy transport and beyond closer to reality. Hydrogen fuel cells, using locally produced green hydrogen as the only fuel, have long been viewed as the ultimate clean energy source, but their commercialization has been difficult.

A multidisciplinary team from UNSW, led by Dr. Quentin Meyer and Professor Chuan Zhao from the School of Chemistry, has managed to make hydrogen fuel cells much more efficient, paving the way for their commercialization.

“Hydrogen fuel cells generate clean electricity with water as the only byproduct,” says Dr. Quentin Meyer, a Senior Research Fellow in Prof. Zhao’s team, and first author of the research published in the journal Applied Catalysis B: Environment and Energy.

Cellular reprogramming beyond pluripotency

Aging, once viewed as an irreversible process, is now considered a modifiable process. Recent advances in cellular reprogramming reveal that transient expression of reprogramming factors can reverse molecular hallmarks of aging while preserving somatic cell identity. This ‘partial reprogramming’ rejuvenates tissues, restores regenerative capacity, and, in some models, extends lifespan without the tumorigenic risks of full dedifferentiation. In this review, we summarize genetic and chemical strategies for partial reprogramming, discuss their tissue-specific effects in vivo, and evaluate their implications for tissue regeneration and age-related disease. We further examine key challenges for clinical translation, including safety, delivery strategies, and temporal control of reprogramming.

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