One of the most detailed 3D maps of how the human chromosomes are organized and folded within a cell's nucleus is published ...

A new study shows, for the first time, how the human genome folds and moves in 3D over time to control when genes turn on and ...

New 3D genome maps reveal how DNA folding controls gene activity, offering fresh clues into disease and cell function.

This article explores how single-cell multiomics and spatial transcriptomics are illuminating early pregnancy, uncovering ...

By engineering a system replicating the womb lining with high biological accuracy, researchers at the Babraham Institute and ...

In a landmark effort to understand how the physical structure of our DNA influences human biology, Northwestern investigators and the 4D Nucleome Project have unveiled the most detailed maps to date ...

SickKids researchers discovered that a long non-coding RNA, CISTR-ACT, directly regulates cell size. Using gene-editing tools ...

If stretched out, human DNA would be about 2 meters long. For this long strand to fit inside the cell nucleus, which is about ...

What keeps our cells the right size? Scientists have long puzzled over this fundamental question, since cells that are too large or too small are linked to many diseases. Until now, the genetic basis ...

A new study in the lab of Jason Stein, Ph.D., modeled brain development in a dish to identify cells and genes that influence ...

Researchers at the Netherlands Institute for Neuroscience have become the first to fully characterize cell activity from a little relay station in the center of the human brain. This aids our ...

A new chimera protein creates a potent, xeno-free fibrin scaffold with strong cell adhesion, paving the way for reproducible ...