Researchers have identified a lipid-driven biophysical mechanism that allows tuberculosis-causing mycobacteria to survive inside human immune cells, a discovery that could inform novel ...

A recent study by the University of Bonn and University Hospital Bonn and the University of Freiburg shows that the ...

The powerhouse of the cells – known as mitochondria – appear to be able to influence the number of lipid droplets in the cell ...

Cells were long believed to safeguard nuclear contents, releasing them only during cell death. Extracellular DNA was thought ...

The human body is a dynamic place. Blood pumps, spinal fluid flows, oxygen comes in and carbon dioxide goes out. Deeper still, charged molecules pass through cell walls, quietly keeping the body's ...

Over the years, cell biology has built a detailed picture of how cells compartmentalize their internal functions. Central to this organization is the nucleus, which houses the genetic material and is ...

A surprising new function of essential hearing proteins may explain why some genetic mutations and common antibiotics lead to permanent deafness.

Explore how tuberculosis bacteria survive within human cells, revealing potential paths for new treatments against this ...

Researchers have identified a previously unknown mechanism that drives the death of inner ear hair cells, the tiny sensory structures responsible for converting sound into brain signals. The discovery ...

Proteins long known to be essential for hearing have been hiding a talent: they also act as gatekeepers that shuffle fatty molecules across cell membranes.

Researchers at the National Institute on Deafness and Other Communication Disorders have identified a previously unknown mechanism that destroys the sensory hair cells of the inner ear, a discovery ...

Researchers discover that hearing-essential proteins (TMC1/TMC2) also regulate cell membranes, and their malfunction is a primary cause of permanent hearing loss.