Wei Zhao introduces CRISPR idea for flu at symposium

An international team led by ETH Zurich and including researchers in Japan has used a new high‑resolution imaging technique to watch, live, as influenza viruses penetrate human cells. The work shows that cells actively engage with the virus, helping to draw it inside in a process that resembles surfing along the cell membrane, and could inform the development of targeted antiviral therapies.

18. helmikuuta 2026 Raportoinut AI Faktatarkistettu

Researchers at the University of California San Diego report they have developed a second-generation CRISPR-based “Pro-Active Genetics” system, called pPro-MobV, that is designed to spread between bacteria and disable antibiotic-resistance genes, including inside hard-to-treat biofilms.

Health economics specialist Martin Morgenstern stated in an interview that genetic editing will transform medical treatments in the coming decades. According to him, technologies like CRISPR will allow altering specific genes to combat conditions like high cholesterol. This approach promises to be more precise than traditional medications, though it carries inherent risks.

11. tammikuuta 2026 Raportoinut AI

Researchers at Cold Spring Harbor Laboratory have employed CRISPR gene-editing to create more compact goldenberry plants, reducing their size by about 35 percent to simplify cultivation. This innovation targets the fruit's unruly growth while preserving its nutritious, sweet-tart flavor. The approach aims to enable large-scale farming and enhance crop resilience amid climate challenges.

Researchers at ChristianaCare’s Gene Editing Institute report that disabling the NRF2 gene with CRISPR restored chemotherapy sensitivity in models of squamous non‑small cell lung cancer and slowed tumor growth, with benefits seen even when only a fraction of tumor cells were edited. The work was published online November 13, 2025 in Molecular Therapy Oncology.

15. joulukuuta 2025 Raportoinut AI Faktatarkistettu

Scientists at Washington State University used artificial intelligence and molecular simulations to identify a crucial amino acid interaction in a herpes virus fusion protein that is required for cell invasion. When they engineered a mutation at this site, the virus could no longer fuse with or enter cells, according to a study published in Nanoscale.