Durable reprogramming of human T cells may now be possible thanks to a new technique based on the CRISPRoff and CRISPRon methodology. Researchers from the Arc Institute, Gladstone Institutes, and the University of California San Francisco have stably silenced or activated genes in this type of immune cell without cutting or altering its DNA, making T cells more resistant, active, and effective against tumors.

Durable reprogramming of human T cells may now be possible thanks to a new technique based on the CRISPRoff and CRISPRon methodology. Researchers from the Arc Institute, Gladstone Institutes, and the University of California San Francisco (UCSF) have stably silenced or activated genes in this type of immune cell without cutting or altering its DNA, making T cells more resistant, active, and effective against tumors.

Current treatments for Alzheimer’s disease have limited effects. While they can slow cognitive decline or alleviate symptoms, they do not reverse this complex neurodegenerative condition caused by multiple factors. Researchers from the Gladstone Institutes and the University of California, San Francisco (UCSF) have screened FDA-approved drugs in search of agents that could potentially modify the disease.

At first blush, the brain’s extracellular matrix (ECM) seems like the opposite of synaptic plasticity. Plasticity is the ability to change; the ECM is stable, to the point that it is often described as a scaffold – something to lend stability. “ECM proteins have some of the longest lifetimes of any protein in the brain,” Anna Molofsky told her audience at the XVII Meeting on Glial Cells in Health and Disease, which is being held in Marseille this week.

At first blush, the brain’s extracellular matrix (ECM) seems like the opposite of synaptic plasticity. Plasticity is the ability to change; the ECM is stable, to the point that it is often described as a scaffold – something to lend stability. “ECM proteins have some of the longest lifetimes of any protein in the brain,” Anna Molofsky told her audience at the XVII Meeting on Glial Cells in Health and Disease, which is being held in Marseille this week.

Too much of a good thing, it turns out, is a concept that applies to oxygen. And researchers at the University of California at San Francisco are working on a small molecule, Hypoxystat, that can lower tissue oxygen levels and prevent damage when oxygen levels are too high. When administered to mice with the rare mitochondrial disorder Leigh syndrome, the molecule more than tripled their average lifespan.

Researchers at the University of California at San Francisco have identified an RNA-binding protein that increased the translation of Myc mRNA. The authors wrote that their work, which was published online in Nature Cell Biology on Feb. 4, 2025, “transforms the understanding of the translational code in cancer and illuminates therapeutic openings to target the expression of oncogenes.”

Researchers at the University of California at San Francisco have identified an RNA-binding protein that increased the translation of Myc mRNA. The authors wrote that their work, which was published online in Nature Cell Biology on Feb. 4, 2025, “transforms the understanding of the translational code in cancer and illuminates therapeutic openings to target the expression of oncogenes.” Myc is a transcription factor that regulates multiple cellular growth factors. Its overexpression is a driver event in many solid tumors, including pancreatic cancer. Drugging Myc, though, has so far proved challenging.

The way the brain ages is not the same in women and men. A study in mice has observed differences in the expression of the maternal and paternal X chromosomes that could explain variation in brain aging between the sexes and a faster deterioration in some women. Another study has discovered different survival strategies in the microglial cells of females and males. Both studies highlight sex differences that could have implications for several age-related neurological disorders, such as Alzheimer’s or Parkinson’s.

Researchers from the University of California San Francisco (UCSF) have successfully replicated the design of regulatory T cells, achieving local targeted immune suppression and protection from CAR T-cell cytotoxicity. Many of the treatments used so far in the context of inflammatory and autoimmune disorders lead to systemic immunosuppression. In this sense, limiting immunosuppression locally to targeted tissues may help overcome systemic toxicity.