A novel, patient-derived RyR1 mutation impairs muscle function and calcium homeostasis in mice

Benucci, Sofia; Ruiz, Alexis; Franchini, Martina; Ruggiero, Lucia; Zoppi, Dario; Sitsapesan, Rebecca; Lindsay, Chris; Pelczar, Pawel; Pietrangelo, Laura; Protasi, Feliciano; Treves, Susan; Zorzato, Francesco

doi:10.1085/jgp.202313486

Cited by 2 publications

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

Compound heterozygous RYR1‐RM mouse model reveals disease pathomechanisms and muscle adaptations to promote postnatal survival

Liang,

Malik,

et al. 2024

The FASEB Journal

View full text Add to dashboard Cite

Pathogenic variants in the type I ryanodine receptor (RYR1) result in a wide range of muscle disorders referred to as RYR1‐related myopathies (RYR1‐RM). We developed the first RYR1‐RM mouse model resulting from co‐inheritance of two different RYR1 missense alleles (Ryr1TM/SC‐ΔL mice). Ryr1TM/SC‐ΔL mice exhibit a severe, early onset myopathy characterized by decreased body/muscle mass, muscle weakness, hypotrophy, reduced RYR1 expression, and unexpectedly, incomplete postnatal lethality with a plateau survival of ~50% at 12 weeks of age. Ryr1TM/SC‐ΔL mice display reduced respiratory function, locomotor activity, and in vivo muscle strength. Extensor digitorum longus muscles from Ryr1TM/SC‐ΔL mice exhibit decreased cross‐sectional area of type IIb and type IIx fibers, as well as a reduction in number of type IIb fibers. Ex vivo functional analyses revealed reduced Ca2+ release and specific force production during electrically‐evoked twitch stimulation. In spite of a ~threefold reduction in RYR1 expression in single muscle fibers from Ryr1TM/SC‐ΔL mice at 4 weeks and 12 weeks of age, RYR1 Ca2+ leak was not different from that of fibers from control mice at either age. Proteomic analyses revealed alterations in protein synthesis, folding, and degradation pathways in the muscle of 4‐ and 12‐week‐old Ryr1TM/SC‐ΔL mice, while proteins involved in the extracellular matrix, dystrophin‐associated glycoprotein complex, and fatty acid metabolism were upregulated in Ryr1TM/SC‐ΔL mice that survive to 12 weeks of age. These findings suggest that adaptations that optimize RYR1 expression/Ca2+ leak balance, sarcolemmal stability, and fatty acid biosynthesis provide Ryr1TM/SC‐ΔL mice with an increased survival advantage during postnatal development.

show abstract

Compound heterozygous RYR1‐RM mouse model reveals disease pathomechanisms and muscle adaptations to promote postnatal survival

Liang,

Malik,

et al. 2024

The FASEB Journal

View full text Add to dashboard Cite

show abstract

Massive reduction of RyR1 in muscle spindles of mice carrying recessiveRyr1mutations alters proprioception and causes scoliosis

Ruiz,

Benucci,

Meier

et al. 2024

Preprint

View full text Add to dashboard Cite

Muscle spindles are stretch receptors lying deep within the muscle belly involved in detecting changes in muscle length and playing a fundamental role in motor control, posture and synchronized gait. They are made up of an external capsule surrounding 3-5 intrafusal muscle fibers and a nuclear bag complex. Dysfunction of muscle spindles leads to abnormal proprioceptor function, which has been linked to aberrant bone and cartilage development, scoliosis, kyphosis and joint contractures.RYR1, the gene encoding the calcium release channel of the sarcoplasmic reticulum, is the most common target of mutations linked to human congenital myopathies, a condition often accompanied by skeleton alterations and joint contractures. So far, the link betweenRYR1mutations, altered muscle spindles and skeletal defects has not been investigated. To this end, we investigated heterozygous mice carrying recessiveRyr1mutations isogenic to those present in a severely affected child. Here we show that: (i) the RyR1 protein localizes to the polar regions of intrafusal fibers and exhibits a doubled row distribution pattern, typical for junctional sarcoplasmic reticulum proteins; (ii) muscle spindles of compound heterozygous mice show structural defects; (iii) RyR1 content in intrafusal muscle fibers from dHT mice is reduced by 54%. Such a massive reduction of mutant RyR1 in intrafusal muscle fibers leads to altered expression of intrafusal fiber proteins, severe scoliosis, alteration of gait and inter limb coordination. These results support the hypothesis thatRYR1mutations not only affect the function of extrafusal muscles, but might also affect that of intrafusal muscles. The latter may be one of the underlying causes of skeletal abnormalities seen in patients affected by recessiveRYR1mutations.

show abstract

A novel, patient-derived RyR1 mutation impairs muscle function and calcium homeostasis in mice

Cited by 2 publications

References 66 publications

Compound heterozygous RYR1‐RM mouse model reveals disease pathomechanisms and muscle adaptations to promote postnatal survival

Compound heterozygous RYR1‐RM mouse model reveals disease pathomechanisms and muscle adaptations to promote postnatal survival

Massive reduction of RyR1 in muscle spindles of mice carrying recessiveRyr1mutations alters proprioception and causes scoliosis

Contact Info

Product

Resources

About