Myopathy is the main adverse effect of the widely prescribed statin drug class. Statins exert their beneficial effect by inhibiting HMG CoA-reductase, the rate-controlling enzyme of the mevalonate pathway. The mechanism of statin myopathy is yet to be resolved, and its treatment is insufficient. Through homozygosity mapping and whole exome sequencing, followed by functional analysis using confocal microscopy and biochemical and biophysical methods, we demonstrate that a distinct form of human limb girdle muscular disease is caused by a pathogenic homozygous loss-of-function missense mutation in HMG CoA reductase ( HMGCR ), encoding HMG CoA-reductase . We biochemically synthesized and purified mevalonolactone, never administered to human patients before, and establish the safety of its oral administration in mice. We then show that its oral administration is effective in treating a human patient with no significant adverse effects. Furthermore, we demonstrate that oral mevalonolactone resolved statin-induced myopathy in mice. We conclude that HMGCR mutation causes a late-onset severe progressive muscular disease, which shows similar features to statin-induced myopathy. Our findings indicate that mevalonolactone is effective both in the treatment of hereditary HMGCR myopathy and in a murine model of statin myopathy. Further large clinical trials are in place to enable the clinical use of mevalonolactone both in the rare orphan disease and in the more common statin myopathy.
A congenital disorder of glycosylation due to biallelic mutations in B4GALT1 has been previously reported in only three patients with two different mutations. Through homozygosity mapping followed by segregation analysis in an extended pedigree, we identified three additional patients homozygous for a novel mutation in B4GALT1, expanding the phenotypic spectrum of the disease. The patients showed a uniform clinical presentation with intellectual disability, marked pancytopenia requiring chronic management, and novel features including pulmonary hypertension and nephrotic syndrome. Notably, affected individuals exhibited a moderate elevation of Man3GlcNAc4Fuc1 on serum N-glycan analysis, yet two of the patients had a normal pattern of transferrin glycosylation in repeated analysis. The novel mutation is the third disease-causing variant described in B4GALT1, and the first one within its transmembrane domain. K E Y W O R D S cholestasis, congenital disorders of glycosylation, nephrotic syndrome, persistent pulmonary hypertension of the newborn, seizures, thrombocytopenia Orna Staretz-Chacham and Iris Noyman and Ohad Wormser contributed equally to this study.
Proteasome 26S, the eukaryotic proteasome, serves as the machinery for cellular protein degradation. It is composed of the 20S core particle and one or two 19S regulatory particles, composed of a base and a lid. To date, several human diseases have been associated with mutations within the 26S proteasome subunits; only one of them affects a base subunit. We now delineate an autosomal recessive syndrome of failure to thrive, severe developmental delay and intellectual disability, spastic tetraplegia with central hypotonia, chorea, hearing loss, micropenis and undescended testes, as well as mild elevation of liver enzymes. None of the affected individuals achieved verbal communication or ambulation. Ventriculomegaly was evident on MRI. Homozygosity mapping combined with exome sequencing revealed a disease‐associated p.I328T PSMC1 variant. Protein modeling demonstrated that the PSMC1 variant is located at the highly conserved putative ATP binding and hydrolysis domain, and is suggested to interrupt a hydrophobic core within the protein. Fruit flies in which we silenced the Drosophila ortholog Rpt2 specifically in the eye exhibited an apparent phenotype that was highly rescued by the human wild‐type PSMC1, yet only partly by the mutant PSMC1, proving the functional effect of the p.I328T disease‐causing variant.
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