Severe Respiratory and Swallowing Disorders in Infantile-Onset Multisystem Neurologic, Endocrine, and Pancreatic Disease Type 1: Two Cases.

Objectives: The objective of this study was to expand the phenotypic spectrum of infantile-onset multisystem neurologic, endocrine, and pancreatic disease type 1 (IMNEPD1) and highlight the importance of analyzing the PTRH2 gene in patients with neuropathy presenting with pancreatic lipomatosis. Methods: Two sisters, aged 73 and 71 years, respectively, presented a severe, length-dependent sensorimotor axonal neuropathy, associated with deafness and intellectual deficiency. Results: They both needed a wheelchair from the fourth decade. They developed a severe respiratory dysfunction, requiring nocturnal noninvasive ventilation from around 50 years of age. The younger sister developed severe dysphagia complicated by aspiration pneumonia. A muscle biopsy of the younger sister was suggestive of mitochondrial myopathy. The youngest presented a complete pancreatic lipomatosis. A biallelic novel likely pathogenic variant within PTRH2, c.254A>G (p.Gln85Arg), was evidenced in both patients. Discussion: IMNEPD1 is a rare autosomal recessive disorder caused by sequence variant in the PTRH2 gene and characterized by a peripheral neuropathy, cerebellar atrophy, intellectual disability, hearing loss, pancreatic insufficiency, hypothyroidism, and dysmorphic features. In addition to these classic manifestations of the disorder, severe dysphagia and respiratory insufficiency may develop over the course of the disease and should be systematically screened. PTRH2 gene should be considered in patients with pancreatic lipomatosis and neuropathy.

Generation of iPSC lines from three Laing distal myopathy patients with a recurrent MYH7 p.Lys1617del variant.

Variants in MYH7 cause cardiomyopathies as well as myosin storage myopathy and Laing early-onset distal myopathy (MPD1). MPD1 is characterized by muscle weakness and atrophy usually beginning in the lower legs. Here, we generated iPSC lines from lymphoblastoid cells of three unrelated individuals heterozygous for the most common MPD1-causing variant; p.Lys1617del. iPSC lines showed typical morphology, expressed pluripotency markers, demonstrated trilineage differentiation potential, and had a normal karyotype. These lines represent the first iPSCs derived from MPD1 patients and complement existing MPD1 animal models. They can provide in vitro platforms to better understand and model MPD1 pathomechanisms and test therapies.

Generation of two iPSC lines from patients with inherited central core disease and concurrent malignant hyperthermia caused by dominant missense variants in the RYR1 gene.

RYR1 variants are the most common genetic cause of congenital myopathies, and typically cause central core disease (CCD) and/or malignant hyperthermia (MH). Here, we generated iPSC lines from two patients with CCD and MH caused by dominant RYR1 variants within the central region of the protein (p.Val2168Met and p.Arg2508Cys). Both lines displayed typical iPSC morphology, uniform expression of pluripotency markers, trilineage differentiation potential, and had normal karyotypes. These are the first RYR1 iPSC lines from patients with both CCD and MH. As these are common CCD/MH variants, these lines should be useful to study these conditions and test therapeutics.

Pathogenic DPAGT1 variants in limb-girdle congenital myasthenic syndrome (LG-CMS) associated with tubular aggregates and ORAI1 hypoglycosylation.

AIMS: Limb-girdle congenital myasthenic syndrome (LG-CMS) is a genetically heterogeneous disorder characterized by muscle weakness and fatigability. The LG-CMS gene DPAGT1 codes for an essential enzyme of the glycosylation pathway, a posttranslational modification mechanism shaping the structure and function of proteins. In DPAGT1-related LG-CMS, reduced glycosylation of the acetylcholine receptor (AChR) reduces its localization at the neuromuscular junction (NMJ), and results in diminished neuromuscular transmission. LG-CMS patients also show tubular aggregates on muscle biopsy, but the origin and potential contribution of the aggregates to disease development are not understood. Here, we describe two LG-CMS patients with the aim of providing a molecular diagnosis and to shed light on the pathways implicated in tubular aggregate formation. METHODS: Following clinical examination of the patients, we performed next-generation sequencing (NGS) to identify the genetic causes, analysed the biopsies at the histological and ultrastructural levels, investigated the composition of the tubular aggregates, and performed experiments on protein glycosylation. RESULTS: We identified novel pathogenic DPAGT1 variants in both patients, and pyridostigmine treatment quantitatively improved muscle force and function. The tubular aggregates contained proteins of the sarcoplasmic reticulum (SR) and structurally conformed to the aggregates observed in tubular aggregate myopathy (TAM). TAM arises from overactivation of the plasma membrane calcium channel ORAI1, and functional studies on muscle extracts from our LG-CMS patients evidenced abnormal ORAI1 glycosylation. CONCLUSIONS: We expand the genetic variant spectrum of LG-CMS and provide a genotype/phenotype correlation for pathogenic DPAGT1 variants. The discovery of ORAI1 hypoglycosylation in our patients highlights a physiopathological link between LG-CMS and TAM.