Stress in adolescence causes lasting brain changes, suggests a study with mice

Stressful situations experienced during adolescence tend to cause deeper and more lasting changes to the brain than those ...
Nanowerk

Living fungi as factories for self-assembling functional materials

Living fungi weave conductive nanoparticles into their own growing networks, amplifying bioelectric signals 9-fold and ...
News-Medical.Net

Gut microbiota regulates intestinal epithelial cell function and plasticity

A research team led by scientists from the State University of Campinas (UNICAMP) in São Paulo, Brazil, has made significant ...

Cysteine pathways help T cells choose between multiplying and attacking tumors

A research team from the Johns Hopkins Kimmel Cancer Center, its Bloomberg~Kimmel Institute for Cancer Immunotherapy and the ...

Cell 'snowball' may be answer to large-scale tissue engineering

Cell cultures—single layers of cells grown in a small dish—have enabled researchers to study biological growth, develop or ...

Scientists Discover New Way To Eliminate “Zombie Cells” Driving Aging

Scientists uncover a metabolic vulnerability in aging cells that could be key to restoring resilience and combating ...
Johns Hopkins Medicine

Single Nutrient Fuels Cancer-Fighting Power of T Cells

Using a variety of laboratory and animal models, the team found that cysteine fuels the production of the antioxidant ...

Location matters: How one fat molecule can help trigger both cell limbo and cell death

When cells experience enough chronic stress, they can stop dividing permanently. In this state of cellular limbo, known as replicative senescence, cells remain alive but no longer proliferate.
News-Medical.Net

How the nutrient cysteine controls cancer-fighting power of T cells

A research team from the Johns Hopkins Kimmel Cancer Center, its Bloomberg~Kimmel Institute for Cancer Immunotherapy and the ...
Kaleido Scope

Welner develops new laboratory method to study the functions of immune cells

The study, “Integration of phospho-signaling and transcriptomics in single cells reveals distinct Th17 cell fates,” was published in Cell Reports. In the study, first author Seth Fortmann, M.D., Ph.D.