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Category: biotech/medical

How cells fight infection from the inside: Newly identified ADX pathway may broaden understanding of immunity

When thinking of the immune system, most people imagine white blood cells putting up a fight against invading germs in the bloodstream. But now, in research published in Molecular Cell, scientists detail a separate but equally important route by which our bodies fight infection—directly inside already infected cells.

In the report, the authors define a previously undescribed method of germ resistance they coin “antibody-directed xenophagy” (ADX), where cells can digest bacteria and viruses that cross the cell membrane, including Salmonella and adenoviruses.

“People have talked about viral xenophagy before as a sort of concept, but if you look in literature, there aren’t any good examples where people have shown this operating to potently block infection,” says Leo James of the MRC Laboratory of Molecular Biology.

Novel synthetic biomolecule degrades disease-related proteins

Northwestern Medicine scientists have developed a novel synthetic biomolecular condensate that can degrade intracellular disease-causing proteins, providing a framework for new therapeutic approaches for a wide range of diseases, as detailed in a recent study published in Nature Communications.

Shana Kelley, Ph.D., the Neena B. Schwartz Professor of Chemistry, Biomedical Engineering, and Biochemistry and Molecular Genetics and the president of the Chan Zuckerberg Biohub Chicago, was senior author of the study.

Targeted protein degradation is an emerging therapeutic strategy that harnesses cells’ own degradation machinery to clear disease-causing proteins. However, achieving this degradation process across different cell types has remained a challenge due to subtle variations in protein structure.

Alzheimer’s gene map expands to 91 loci, revealing 16 previously unknown risk regions

An international collaboration of genetic researchers has identified more than 90 genetic regions associated with the risk of Alzheimer’s disease and related dementias. The large-scale meta-analysis reveals new biological insights into the disease, highlighting the important roles of immune processes, beta-amyloid and tau biology, and lipid metabolism.

Alzheimer’s disease is the most common cause of dementia worldwide, and its development is influenced by a complex interplay of genetic and environmental factors. Understanding the genetic architecture of the disease is essential for improving diagnosis, risk prediction, and the development of targeted therapies.

In this study, researchers combined genome-wide association data from nearly a million individuals of European ancestry, including over 128,000 Alzheimer’s disease cases and nearly 850,000 controls.

Autism risk framework tracks genes, maternal factors and environment across 18,000 families

A new statistical framework developed by researchers at the Johns Hopkins Bloomberg School of Public Health, Johns Hopkins University School of Medicine, and Kaiser Permanente Northern California offers improved understanding of how genetics and environment contribute to autism risk.

Large-scale genetic studies have led to the development of genetic risk scores that estimate a person’s predisposition to diseases and health conditions based on their DNA profiles. The new framework allows researchers and clinicians to analyze these scores using family data and characterize the risk of conditions such as autism and other developmental conditions in children based on their own DNA, parental factors, and environmental influences such as maternal diet and lifestyle.

For their study published in Nature Genetics, the researchers analyzed more than 18,000 case-parent trios —autistic children and their parents—across diverse ancestral populations in the Simons Foundation Powering Autism Research for Knowledge consortium and the Genes and Environment Autism Research Study.

Biohybrid microrobots repair spinal cord by combining stem cells with magnetoelectric nanoparticles

Spinal cord injuries can have devastating consequences for those affected. Nerve cells in the spinal cord rarely regenerate naturally, while scarring often prevents the regrowth of nerve fibers. Modern therapies attempt to influence implanted stem cells using electrical stimulation to promote the growth of new nerve cells. This approach has several drawbacks: it requires implanted electrodes, and the transplanted cells do not always survive or integrate properly into the existing tissue.

Researchers in Zurich are pursuing a new approach, which they have published in the journal Nature Materials. This involves combining therapeutic stem cells with magnetoelectric nanoparticles in such a way that the cells can be guided magnetically to the precise site of an injury and stimulate the stem cells to accelerate repair.

To achieve this, the researchers created a biohybrid microrobot, which combines living neural progenitor cells (NPCs) with a technical component in the form of specially engineered nanoparticles.

Experimental Brain ‘Pacemakers’ May Rewire Circuits Linked to Depression

Every year, more than 2 million people in the United States are diagnosed with treatment-resistant depression.

Desperate for solutions, some brave patients are now volunteering to undergo surgery to place experimental ‘pacemakers’ into their brains.

These implanted electrodes are part of a treatment known as deep brain stimulation, which is currently used to address some cases of Parkinson’s disease and epilepsy.

Munk Debate on Gene Editing

On April 21, the Munk Debates convened a special debate about gene editing in Deerfield, Massachusetts for 650 students at Deerfield Academy.

Motion: Be it Resolved, let’s engineer better human beings.

About the Debate:
New powerful engineering technology is already being used to edit human embryos, curing diseases and repairing defective genes before a child is even born. Some welcome this new science as a powerful tool to enhance human intelligence, memory, appearance and physical health. Why wouldn’t we embrace a science that allows people to live longer, healthier, and happier lives? Others warn that this new technology will be used to create designer babies and a new class of genetically “enhanced” elites. It will undermine human dignity and autonomy, and risk unleashing new diseases into the human gene pool. Playing G-d with human nature, critics argue, will result in a dystopian nightmare of our own making.

About the Debaters:
Arguing in favour of the motion was the biophysicist, best-selling author, biotechnology entrepreneur, and the former director of the Program on Medicine, Technology and Society at UCLA School of Medicine, Gregory Stock. His debate partner was the internationally acclaimed strategic philosopher and pioneering transhumanist Max More. Arguing against the motion was the prominent American bioethicist Ezekiel Emanuel, Special Advisor to the Director General of the WHO and a former founding chair of the Department of Bioethics at the NIH. His debate partner was the award-winning educator, author, and Professor of Reproductive Science at University College London, Joyce Harper.

Brain circuit links memory to hearing, revealing how learned sounds guide behavior

Short-term memories are thought to be formed deep within the brain in structures such as the hippocampus, but little is known about how and where memory-related information is kept in the brain or the process of drawing on this information. A good example is the sound of a car horn—most of us recognize it as a warning and know how to respond, even though not all horns sound the same and the circumstances in which we might hear a horn are different each time.

New research led by Professor Lucy Palmer from The Florey’s Neural Network Group has uncovered new insights into how and where memory-related information is stored and how these memory banks are used. These findings improve our fundamental understanding of how the brain works, providing a springboard for other scientists to make further, disease-specific discoveries. The paper is published in the journal Science Advances.

“Using mice that we trained to respond to similar, but slightly altered sounds, we identified a long-range cortical circuit that links memory and sensory systems,” Professor Palmer said. “Our findings provide valuable insights into the cellular and network mechanisms that support learning and memory-guided sensory behavior.

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