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Category: genetics

X-ray snapshots reveal how viral shells change shape as they dry out

When viruses travel through the air in tiny droplets, they can quickly start to dry out. Yet many viruses remain infectious after rehydration—something that is still not fully understood. Now, an international team of researchers has directly observed at the European XFEL how the protein shells of viruses can change shape during dehydration, offering new clues to viral resilience and opening new possibilities for virology research. The results, published in Light: Science & Applications, lay the groundwork for potential applications in virology and public health and can, for instance, help develop antiviral strategies.

At the SPB/SFX instrument of the European XFEL, Abhishek Mall from the Max Planck Institute for the Structure and Dynamics of Matter in Hamburg (MPSD) and his colleagues explored the structural dynamics of the protein shells—called capsids—that enclose the genetic material of viruses. Specifically, they examined the behavior of capsids of the bacteriophage MS2 under conditions of dehydration. MS2 is an icosahedral, i.e., shaped by 20 triangular surfaces that form a sphere, single-stranded RNA virus that infects the bacterium Escherichia coli and is widely used as a model system in virology.

The capsid’s design is critical for protecting the viral genome and helping the virus interact with host cells. However, viruses are often confronted with environments that challenge their structural integrity, for example through dehydration. Theoretical studies have long suggested that capsids may undergo low-energy “buckling transitions”—sudden changes in shape—to adapt to such stresses, but direct experimental evidence has been lacking.

Out of darkness, blind Mexican cavefish illuminate brain evolution

Deep within the dark caves of northeastern Mexico lives a fish that has spent hundreds of thousands of years adapting to a world without light. The blind Mexican cavefish (Astyanax mexicanus) has evolved in perpetual darkness, losing its eyes and pigmentation while developing remarkable adaptations that help it survive in nutrient-poor environments.

Now, scientists are using this extraordinary species to uncover how evolution rewires the brain and shapes behavior. Because Astyanax exists both as sighted surface fish and as more than 30 independently evolved cave populations, researchers can directly compare how life in darkness alters sensory systems, neural circuits and behavior.

With new genetic tools and advanced imaging technologies that allow scientists to watch brain activity in real time, this unique fish is providing unprecedented insights into how animals adapt to extreme environments—and how evolution transforms the brain itself.

Synthetic DNA toolkit expands scientists’ ability to recognize genetic targets

A new method for recognizing and targeting DNA that dramatically expands the range of genetic sequences scientists can identify has been developed by experts at the University of Portsmouth. Published this week in Nature Communications, the research opens new possibilities for gene-targeting technologies, molecular diagnostics and DNA nanotechnology.

Dr. David Rusling, associate professor in bioengineering from the University of Portsmouth’s School of Medicine, Pharmacy and Biomedical Sciences, said, Our lab develops synthetic molecules that can recognize and bind to unique gene sequences. By introducing synthetic DNA bases into these molecules, we’ve been able to significantly improve how they recognize their targets.

I’ve worked in this area for around 20 years, and this is the first time we’ve had a system that combines strong recognition under physiological conditions with building blocks that are commercially available to other researchers.

An AAV variant selected through NHP screens robustly transduces the brain and drives secreted protein expression in NHPs and mice

Tecedor et al. used directed evolution to engineer AAVs with enhanced ependymal and brain delivery after injection into the cerebrospinal fluid. I think it would be interesting to try lumbar puncture delivery of these AAVs as well to see if they maintain decent biodistribution. (See my other post about Hinderer et al.’s paper: https://doi.org/10.1016/j.omtm.2020.04.012).

AAV capsid variants enriched for transduction of ventricular lining cells and brain parenchyma reduce the dose required for gene therapy to the CNS.

Specific cognitive abilities are highly heritable independent of general intelligence

A massive new meta-analysis reveals that individual cognitive abilities, like reading and math, rely on inherited DNA just as much as overall intelligence, suggesting people possess heavily customized genetic cognitive profiles independent of general smarts.

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