Structural basis of DNA crossover capture by DNA gyrase.

DNA supercoiling must be precisely regulated by topoisomerases to prevent DNA entanglement. The interaction of type IIA DNA topoisomerases with two DNA molecules, enabling the transport of one duplex through the transient double-stranded break of the other, remains elusive owing to structures derived solely from single linear duplex DNAs lacking topological constraints. Using cryo-electron microscopy, we solved the structure of DNA gyrase bound to a negatively supercoiled minicircle DNA.

Suitability of double-stranded DNA as a molecular standard for the validation of analytical ultracentrifugation instruments.

To address the current lack of validated molecular standards for analytical ultracentrifugation (AUC), we investigated the suitability of double-stranded DNA molecules. We compared the hydrodynamic properties of linear and circular DNA as a function of temperature. Negatively supercoiled, nicked, and linearized 333 and 339 bp minicircles were studied.

DNA supercoiling-induced shapes alter minicircle hydrodynamic properties.

DNA in cells is organized in negatively supercoiled loops. The resulting torsional and bending strain allows DNA to adopt a surprisingly wide variety of 3-D shapes. This interplay between negative supercoiling, looping, and shape influences how DNA is stored, replicated, transcribed, repaired, and likely every other aspect of DNA activity.

Mortality difference from vs bloodstream infections.

Members of the order Enterobacterales, including , species and species, are important pathogens in healthcare-associated infections. Higher mortality has been reported from infections due to than from , but prior studies comparing (recently renamed ) bacteraemia and complex bacteraemia have yielded conflicting results regarding whether clinical outcomes differ. We found bacteraemia with was independently associated with greater risk of 30-day mortality than bacteraemia with complex.

DNA supercoiling-induced shapes alter minicircle hydrodynamic properties.

DNA in cells is organized in negatively supercoiled loops. The resulting torsional and bending strain allows DNA to adopt a surprisingly wide variety of 3-D shapes. This interplay between negative supercoiling, looping, and shape influences how DNA is stored, replicated, transcribed, repaired, and likely every other aspect of DNA activity.