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Category: biotech/medical – Page 237

‘Jumping gene’ caught in the act: Advanced imaging provides new insights into retrotransposons

An arms race is unfolding in our cells: Transposons, also known as jumping genes or mobile genetic elements as they can replicate and reinsert themselves in the genome, threaten the cell’s genome integrity by triggering DNA rearrangements and causing mutations. Host cells, in turn, protect their genome using intricate defense mechanisms that stop transposons from jumping.

Now, for the first time, a retrotransposon has been caught in action inside a cell: Refining cryo-Electron Tomography (cryo-ET) techniques, scientists imaged the retrotransposon copia in the egg chambers of the fruitfly Drosophila melanogaster at sub-nanometer resolution. The paper is published in the journal Cell.

Among the international team of scientists achieving this detailed visualization are three scientists with Vienna BioCenter ties: Sven Klumpe, currently in the laboratory of Jürgen Plitzko at the Max Planck Institute of Biochemistry in Martinsried, will join IMBA and IMP to build a group as a Joint Fellow; Julius Brennecke, a Senior Group Leader at IMBA, the Institute of Molecular Biotechnology of the Austrian Academy of Sciences; and Kirsten Senti, staff scientist in the Brennecke group. Also involved in this collaboration is the group of Martin Beck at the Max Planck Institute of Biophysics in Frankfurt.

New gene switch activates with simple skin patch and could help treat diabetes

ETH researchers have developed a new gene switch that can be activated using a commercially available nitroglycerine patch applied to the skin. One day, researchers want to use switches of this kind to trigger cell therapies for various metabolic diseases.

The body regulates its metabolism precisely and continuously, with specialized cells in the pancreas constantly monitoring the amount of sugar in the blood, for example. When this blood sugar level increases after a meal, the body sets a signal cascade in motion in order to bring it back down.

In people suffering from diabetes, this regulatory mechanism no longer works exactly as it should. Those affected therefore have too much sugar in their blood and need to measure their blood sugar level and inject themselves with insulin in order to regulate it. This is a relatively imprecise approach compared to the body’s own mechanism.

Scientists Successfully Rejuvenate a 53-Year-Old Woman’s Skin Cells by 30 Years

The fields of regenerative medicine and cellular biology are advancing rapidly, demonstrating that some aging-related processes may be more reversible than previously thought.

Recent research has shown that it is possible to rejuvenate the skin cells of a 53-year-old woman by 30 years, a groundbreaking scientific achievement that could redefine modern approaches to treating age-related diseases.

Cellular aging is a complex process marked by gradual changes in cell structure and function. Over time, alterations in gene expression, DNA damage accumulation, and reduced tissue regeneration capacity occur.

Biological Age, Age At Menopause, And Longevity (4 Studies)

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Scientists Just Discovered an RNA That Repairs DNA Damage — And It’s a Game-Changer

Genome Instability and Disease Risk

Every time a cell divides, its DNA is at risk of damage. To complete division, the cell must copy its entire genetic code — billions of letters long — which can lead to occasional errors. But cell division isn’t the only threat. Over time, exposure to factors like sunlight, alcohol, and cigarette smoke can also harm DNA, increasing the risk of cancer and other diseases.

Fortunately, cells have built-in repair systems to counteract this damage. This process, known as the DNA damage response (DDR), activates specific signaling pathways that detect and fix errors. These mechanisms help maintain genetic stability and ensure the cell’s survival.

From classical to quantum: Navier–Stokes equations adapted for 1D quantum liquids

Although Navier–Stokes equations are the foundation of modern hydrodynamics, adapting them to quantum systems has so far been a major challenge. Researchers from the Faculty of Physics at the University of Warsaw, Maciej Łebek, M.Sc. and Miłosz Panfil, Ph.D., Prof., have shown that these equations can be generalized to quantum systems, specifically quantum liquids, in which the motion of particles is restricted to one dimension.

This discovery opens up new avenues for research into transport in one-dimensional quantum systems. The resulting paper, published in Physical Review Letters, was awarded an Editors’ Suggestion.

Liquids are among the basic states of matter and play a key role in nature and technology. The equations of hydrodynamics, known as the Navier–Stokes equations, describe their motion and interactions with the environment. Solutions to these equations allow us to predict the behavior of fluids under various conditions, from the and the in blood vessels, to the dynamics of quark-gluon plasma on subatomic scales.

Inflammation identified as a potential cause of multiple sclerosis progression

For the first time, researchers have identified that inflammation—long associated with multiple sclerosis (MS)—appears to cause increased mutations linked to MS progression.

MS is a progressive neurological disease that affects 33,000 Australians and three million people worldwide. About one-third of people living with MS have progressive disease, which current treatments do not address effectively.

The researchers studied MS brain lesions, visible as spots on MRI scans, which are areas of past or ongoing brain inflammation. They found located in MS brain lesions have a that is two-and-a-half times faster than in normal neurons.

Seeing the Invisible World

Two-photon vision is an emerging technique with significant potential for the future of ophthalmic diagnostics. While it offers many advantages, certain aspects still require refinement. Scientists at ICTER have advanced this technology, enhancing its capabilities and expanding its potential applications in ocular medicine.

Imagine looking through a kaleidoscope that reveals a spectrum of colors beyond human vision, where invisible light is brought into focus. In conventional sight, photons—the fleeting messengers of light—typically appear alone. However, in the phenomenon of two-photon vision, they work in pairs, allowing the human eye to perceive infrared laser pulses instead of visible light, unlocking access to an otherwise invisible world.

A crucial aspect of understanding two-photon vision is measuring the brightness of these stimuli. Until now, this was only possible for visible light. Scientists at the International Centre for Eye Research (ICTER) have achieved a groundbreaking milestone by determining the luminance value of infrared light using photometric units (cd/m²). This discovery has enabled them to connect the brightness of two-photon stimuli to a newly defined physical quantity: two-photon retinal illumination, a key factor in understanding perceived brightness.