Genes contain the essential building instructions for life, guiding cells on which amino acids to assemble in what sequence to produce specific proteins. The human genome codes for about 20,000 such ...

Bodybuilders and cellular mechanisms agree generating protein is a heavy lift. To complete the task, cells rely on complexes called spliceosomes. These molecular machines snip extra bits out of our ...

The modulation of RNA splicing by small molecules has emerged as a promising strategy for treating pathogenic infections, human genetic diseases, and cancer; however, the principles by which splicing ...

Alternative Splicing is an extraordinarily complex process that requires the coordinated action of multiple proteins, each specialised in very specific functions. These proteins are assembled and ...

To carry out all of life’s functions, proteins must be produced from instructions carried by genes within DNA and delivered to the cell’s protein-making machinery by messenger RNA. However, to ...

CSHL’s Krainer lab used a technique called live-cell fluorescence imaging to observe the DDX23 enzyme (above, in green) in action. Together with the critical regulator protein SRSF1, DDX23 helps set ...

Scientists have created a model to study the role of RNA splicing defects in Alzheimer's disease, revealing degeneration and toxicity caused by neuron hyperexcitability. Researchers have puzzled over ...

The protein complex cohesin is fundamental to the cell division process, as it holds sister chromatids tightly together in a ringlike structure before a cell physically splits. But now researchers at ...

Researchers at the Centre for Genomic Regulation (CRG) have created the first blueprint of the human spliceosome, the complex molecular machine that edits genetic messages transcribed from DNA, ...