Scientists engineer probiotic bacteria to target mouse tumors

Researchers at the University of Waterloo have developed engineered bacteria designed to invade and eat solid tumors from the inside out. The approach uses microbes that thrive in oxygen-free environments, targeting the low-oxygen cores of tumors. A genetic modification allows the bacteria to survive near oxygenated edges, controlled by a quorum-sensing mechanism.

February 01, 2026 Ti AI ṣe iroyin Ti ṣayẹwo fun ododo

Researchers report that small doses of the antibiotic cephaloridine can prompt certain gut bacteria to increase production of colanic acid, a microbial polysaccharide previously tied to longer lifespan in laboratory animals. In experiments, treated roundworms lived longer and mice showed shifts in cholesterol or insulin measures associated with aging, with the team arguing the approach works by acting in the gut rather than throughout the body.

Scientists at Oregon State University say they have engineered an iron-based nanomaterial that exploits acidic, peroxide-rich conditions inside tumors to generate two types of reactive oxygen species and kill cancer cells while largely sparing healthy cells. In mouse tests using human breast-cancer tumors, the team reports complete tumor regression without observable adverse effects, though the work remains preclinical.

February 16, 2026 Ti AI ṣe iroyin

Researchers at the University of California San Diego have discovered the enzyme N4BP2, which triggers chromothripsis, a chaotic genetic event in cancer cells. This process allows tumors to rapidly evolve and resist treatments. The findings, published in Science, suggest blocking N4BP2 could limit cancer's genomic instability.

Researchers report that Enterococcus faecalis—a bacterium often found in chronic wounds—can hinder skin repair by generating hydrogen peroxide through a metabolic pathway, triggering stress responses that stop key skin cells from migrating. In laboratory experiments, breaking down the peroxide with the antioxidant enzyme catalase helped restore cell movement, suggesting a potential treatment approach that does not rely on antibiotics.

January 04, 2026 Ti AI ṣe iroyin

Scientists at Flinders University have developed the first database tracking beneficial microbes and natural compounds that support human health. The 'Database of Salutogenic Potential' highlights how exposure to diverse environmental microbiomes can boost immune strength and reduce stress. This work challenges the traditional focus on pathogens and promotes a balanced view of microbial biodiversity.