A routine experiment with a new single-cell DNA sequencing method turned into a surprising scientific twist when researchers stumbled upon a bizarre genetic code in a microscopic pond organism. Instead of following the near-universal “rules” of life, this newly identified protist rewrites how genes signal their end. This unexpected discovery challenges long-held assumptions about how genetic translation works and hints that nature may be far more flexible—and mysterious—than scientists realized.

A newly developed targeted radiopharmaceutical treatment can effectively slow tumor growth in pancreatic ductal adenocarcinoma (PDAC), according to new research published in the May issue of The Journal of Nuclear Medicine. In preclinical models, the treatment achieved complete remission of the disease, highlighting its potential to transform care for this highly aggressive cancer.

PDAC accounts for more than 90% of pancreatic cancer cases and remains one of the most lethal malignancies, with a five-year survival rate of less than 5% in patients with metastatic disease. Although surgery is the only curative approach, it is feasible only in 10%–20% of patients with localized disease.

“PDAC is very difficult to treat, and new options are urgently needed,” said Marika Nestor, professor in the Department of Immunology, Genetics and Pathology at Uppsala University in Sweden. “Our previous findings suggest a possible new targeted treatment approach for pancreatic cancer patients whose tumors express CD44v6, which may help make treatment more precise and effective.”

Variant in situ sequencing (VIS-seq) links genetic variants to cell images, revealing how variants affect molecules, subcellular structures, and cells at scale. Applied to thousands of LMNA and PTEN variants, VIS-seq illuminated how variants impacted a multidimensional phenotypic continuum that is not recapitulated by any single functional readout.