Muscles make up nearly 40% of the human body and power every move we make, from a child’s first steps to recovery after injury. For some, however, muscle development goes awry, leading to weakness, delayed motor milestones or lifelong disabilities. New research from the University of Georgia is shedding light on why.

UGA researchers have created a first-of-its-kind CRISPR screening platform for human muscle cells, identifying hundreds of genes critical to skeletal muscle formation and uncovering the potential cause of a rare genetic disorder. The findings come from two companion papers published in Nature Communications, one describing the large-scale screen and a second digging into a particular gene’s role in muscle development.

Together, the studies provide a comprehensive genetic map of how human muscle fibers are built and lend insights into the effects of genetic mutations on developmental muscle defects. By linking specific genes to the muscle-building process, this genetic roadmap gives clinicians a practical shortlist to more quickly pinpoint the likely genetic causes of a patient’s muscle-development disorder. It also provides researchers with clear targets to prioritize future drug or gene therapy approaches.

Using single-cell epigenomic profiling of immune cells from 110 individuals, researchers show that genetic variation and environmental exposures shape the human immune system through distinct DNA methylation mechanisms. Genetic effects concentrate within gene bodies of memory cells, while environmental exposures primarily remodel regulatory regions in naive immune cells.

Scientists analyzing ancient DNA from a 12,000-year-old double burial in southern Italy uncovered genetic evidence of a rare inherited growth disorder in two closely related prehistoric individuals. A team led by researchers at the University of Vienna and Liège University Hospital Centre has tra

Scientists mapped every possible mutation in a key genetic hotspot, revealing how distinct mutations drive tumor growth differently, which could influence anticancer therapy success.

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Mapping diverse mutations within a cancer hotspot revealed that distinct variants drive tumor growth to different extents, which could guide anticancer therapies.

Here, Miguel Verbitsky & team analyze urine from 325 participants in the Randomized Intervention for Children with Vesicoureteral Reflux study (RIVUR study), revealing genetic variations influence bacterial composition of urine in children with recurrent urinary infections and vesicoureteral reflux:

The image shows cytokeratin 5 and smooth muscle actin labeling after UTI in mouse bladder, which increases expression of Cxcl12 and Cxcr4.

³Department of Dermatology; and.

⁴Center for Precision Medicine and Genomics, Columbia University, New York, New York, USA.

⁵Department of Neurology, Heersink School of Medicine, University of Alabama at Birmingham, Birmingham, Alabama, USA.