The type I interferon (IFN-I) response is a critical component of the immune defense against various viral pathogens, triggering the expression of hundreds of interferon-stimulated genes (ISGs). These ISGs encode proteins with diverse antiviral functions, targeting various stages of viral replication and restricting infection spread. Beyond their antiviral functions, ISGs and associated immune metabolites have emerged as promising broad-spectrum biomarkers that can differentiate viral infections from other conditions. This review provides an overview of the diagnostic potential of ISGs at transcript and protein levels, as well as their immune metabolites. We focus on their clinical applications and the sensitivity and specificity of these biomarkers through receiver operating characteristic (ROC) analysis.

Loss of the Y chromosome in both tumor and immune cells may hamper immune protections and lead to poorer outcomes for men with different types of cancer.

Researchers in the United States have built a technology that boosts the performance of electron microscopes. Berkeley Lab and UC Berkeley physicists’ new technique offers detailed images of the small molecules and cell structures that are crucial to understanding biology and disease.

They have adapted the phase-contrast technique to cryo-electron microscopy (cryo-EM), which has about 10,000 times the magnification of light microscopy. Their laser-based phase plate produces sharp images of molecules that today’s cutting-edge cryo-EM systems struggle to capture.

The research team revealed that the new technology was brought to fruition by more than 15 years of theoretical and experimental work by leading microscopy scientists, collaboration with expert machinists, and support from Biohub.