New methods to improve super-resolution imaging techniques are giving biologists a clearer and more complete view of the inner workings of living cells.

The enzymes polyketide synthases and nonribosomal peptide synthetases can shuffle their parts, allowing them to produce new chemicals. To help scientists design these enzymes, researchers have improved ClusterCAD. This tool helps users modify these enzymes for synthetic biology applications. New improvements include an expanded database, powerful search tools, and helpful new features within the interface.

The Svalbard reindeer have gotten fatter, not thinner, the past 28 years of climate change.

Microbiome engineering is a promising area of synthetic biology, with applications ranging from human therapeutics to environmental bioremediation. However, designing systems to transfer genes across complex microbial communities is a major challenge. Scientists from Spain have now developed a plasmid pMATING, which can effectively enable conjugal DNA between multiple species ranging from bacteria to yeast. The system has the potential to be a tremendous asset for the spread of beneficial traits across various environmental microbiomes.

Rhizobacteria colonize plant roots and have a significant impact on their growth and sustenance. Engineering genetic circuits in these bacteria can be used to indirectly improve plant stress resilience. Now, researchers from Stanford University have explored key synthetic biology tools and methods for designing effective rhizobacterial genetic circuits through a ‘design-build-test-learn’ cycle. They have also emphasized how the resultant next-generation plants with improved root architecture could address food security and sustainability challenges.

University of Queensland scientists have developed a model that gives soccer players their best chance of kicking a penalty goal.