Roughly eight in every million children are born with a particularly severe form of muscle weakness known as LAMA2-related muscular dystrophy. In Switzerland, 18 cases are currently known. This rare hereditary disease is still incurable. The muscles of affected children gradually become weaker, including the respiratory musculature. In many cases, the children do not reach adulthood.
LAMA2-related muscular dystrophy caused by genetic defect
The disease is caused by a genetic defect that prevents cells in the human body from producing the protein laminin-α2. In skeletal muscle, this protein is part of the extracellular matrix that surrounds muscle fibers and helps to maintain their structural integrity. Without laminin-α2, even normal muscle use causes damage, leading to progressive muscle loss.
Together with researchers from the Jagiellonian University in Kraków, Prof. Markus Rüegg’s team at the Biozentrum, University of Basel, has now discovered that laminin-α2 also has an important influence on muscle stem cells, which are essential to generate new muscle fibers after muscle injury. Their study has recently been published in “Nature Communications”.
Impaired repair of damaged muscles
Muscle stem cells reside dormant in specialized niches between muscle fibers. When muscle injuries occur, they become activated, start dividing, and differentiate to form new muscle fibers. In healthy muscle, these stem cells also produce laminin-α2 themselves and release it into their environment to support their proliferation.
“We were surprised to see that muscle stem cells actually rely on their own laminin-α2 to efficiently generate new muscle fibers,” says Timothy McGowan, the study’s first author. “In diseased mice lacking laminin-α2, muscle stem cells proliferate much more slowly and muscle repair after injury is severely impaired.” In other words, the muscles degenerate faster than they can regenerate.
In experiments with human cells, the researchers confirmed these findings. “Human muscle stem cells also produce laminin-α2, and preventing them from doing so impairs their proliferation”, explains McGowan. Laminin-α2 produced by stem cells therefore plays a crucial role in regenerating damaged muscles.
Muscle stem cells as a target for therapy
The study reveals that laminin-α2 is not only important for the structural integrity and stability of skeletal muscle fibers but also serves as a signal for muscle stem cells to multiply after injury.
“So far, laminin-α2 has been recognized primarily for its role in stabilizing muscle fibers,” says Rüegg. “Our findings now demonstrate that this protein is also crucial for the regenerative capacity of muscle stem cells. Based on our data, the best strategy for future therapies to mitigate symptoms of muscular dystrophy and slow disease progression will be to target both muscle fibers and muscle stem cells.”
Publication:
Timothy J. McGowan, Judith R. Reinhard, Nicolas Lewerenz, Marta Białobrzeska, Shuo Lin, Jacek Stępniewski, Krzysztof Szade, Józef Dulak, Markus A. Rüegg. Loss of cell-autonomously secreted laminin-α2 drives muscle stem cell dysfunction in LAMA2-related muscular dystrophy. Nature Communications, published online 27 November 2025
Contact: Communications, Katrin Bühler