Yale School of Medicine (YSM) researchers have made key breakthroughs in understanding how to treat fibrotic diseases such as scleroderma and graft-versus-host disease.

Fibrotic diseases are a group of conditions—often autoimmune—characterized by excessive tissue scarring. They can drastically hinder patients’ quality of life, and in some cases, they can be life-threatening— fibrosis contributes to approximately 45% of all deaths in developed nations. However, there are no effective treatments.

Now, in a study published in Blood, researchers have developed a monoclonal antibody that is showing promise as a new therapy for patients. And in a Nature Communications study, the same team discovered a signaling pathway that may be mediating fibrosis and could be a target for future therapies.

EMBL scientists have improved a protein analysis technique, significantly expanding its use and making it 100 times faster.

Swedish chemist Jöns Jacob Berzelius, in a letter to a fellow chemist, first suggested the name “proteins” for a particular class of biological substances, deriving it from the Greek word proteios, meaning “primary” or “of first importance.” Although scientists in the 1830s knew very little about proteins, it was already clear how essential they were to living organisms.

Long-known as the “workhorses of the cell,” proteins are responsible for powering nearly every function in the body. Often critical to this is their interactions with other small molecules known as ligands. In a new study published in Nature Structural and Molecular Biology, EMBL researchers introduce HT-PELSA, a high-throughput adaptation of an earlier tool that detects these interactions. This new tool can process samples at an unprecedented scale, a breakthrough that promises to accelerate drug discovery and our understanding of fundamental biological processes.