A research team at CiQUS (University of Santiago de Compostela, Spain) has unveiled an innovative molecular approach that enables anticancer drugs to reach the nucleus of tumor cells, where they can exert their therapeutic effect. The study focused on doxorubicin, a widely used chemotherapy agent. Prolonged exposure to this drug often leads to the emergence of resistant cells, a major clinical challenge that this strategy successfully overcomes while preserving the drug’s antitumor activity.

The approach builds on a simple but powerful concept: the ability of cyclic peptides —small amino acid rings— to stack and self-assemble into hollow cylindrical structures (nanotubes) on the surface of cancer cell membranes. The system, developed by the team led by Juan R. Granja, couples doxorubicin to these peptides and directs it to the cell nucleus through a delivery pathway that differs from the drug’s usual mechanism. This allows the drug to bypass the cellular resistance mechanisms that would normally deactivate it.

Compared with healthy cells, cancer cell membranes contain higher levels of negatively charged lipids. The cyclic peptides used in this study display a strong affinity for these anionic surfaces, facilitating their interaction with tumor cells. As a result, the peptide–drug conjugates enter resistant cells and travel towards the nucleus, where doxorubicin intercalates with DNA to trigger its cytotoxic effect.

For the first time, researchers have successfully fabricated and characterized a fully functional mirror-image nanopore—a molecular gateway built entirely from D-amino acids, the mirror-image forms of the natural building blocks of proteins. The work, led by Prof. Dr. Kozhinjampara R. Mahendran at the Rajiv Gandhi Center for Biotechnology (India) in collaboration with Constructor University and other partners, demonstrates not only a major milestone in nanoscience but also opens promising biomedical applications, including potential cancer therapies.

Proteins in nature are almost exclusively built from L-amino acids, while their D-amino acid counterparts usually play only minor roles. Constructing entire proteins from D-amino acids is extremely challenging, yet offers striking advantages: Such mirror-image structures are often more resistant to degradation and may interact differently with biological systems.

In this study, the team designed a synthetic stable and well-defined D-peptide pore called DpPorA. Remarkably, by modifying the charge distribution, they were able to create superior versions of these pores with enhanced conductance and selectivity under different salt conditions.

Abdominal pain is a hallmark of many digestive disorders, including inflammatory bowel disease and irritable bowel syndrome. In an effort to develop targeted treatments for gut pain, scientists have discovered a new enzyme in gut bacteria and are using nanoparticles to deliver drugs inside cells.

Currently, there are no treatments specifically for gut pain, and existing painkillers are often insufficient at managing symptoms. These drugs—including opioids, NSAIDs, and steroids—also come with side effects, some of which directly harm the digestive system.

In two new studies published in Cell Host & Microbe and Proceedings of the National Academy of Sciences, researchers focused on PAR₂, a receptor involved in pain signaling that has been shown to play a role in gastrointestinal diseases marked by inflammation and pain. Found on the lining of the gut and on pain-sensing nerves in the gut, PAR₂ is activated by certain enzymes called proteases and is a promising target for treating gut pain—in numerous ways.