The constantly evolving spectrum of phenotypes in titinopathies - will it ever stop?

Familial childhood onset, slowly progressive myopathy plus cardiomyopathy expands the phenotype related to variants in the TTN gene

This report describes a novel TTN -related phenotype in two brothers, both affected by a childhood onset, very slowly progressive myopathy with cores, associated with dilated cardiomyopathy only in their late disease stages. Clinical exome sequencing documented in both siblings the heterozygous c.2089A>T and c.19426+2T>A variants in TTN. The c.2089A>T, classified in ClinVar as possibly pathogenic, introduces a premature stop codon in exon 14, whereas the c.19426+2T>A affects TTN alternative splicing. The unfeasibility of segregation studies prevented us from establishing the inheritance mode of the muscle disease in this family, although the lack of any reported muscle or heart symptoms in both parents might support an autosomal recessive transmission. In this view, the occurrence of cardiomyopathy in both probands might be related to the c.2089A>T truncating variant in exon 14, and the childhood onset, slowly progressive myopathy to the c.19426+2T>A splicing variant, possibly allowing translation of an almost full length TTN protein.

Successful heart transplant in a child with congenital core myopathy and delayed-onset restrictive cardiomyopathy due to recessive mutations in the titin (TTN) gene

BACKGROUND

Mutations in the TTN gene, encoding the muscle filament titin, are a major cause of inherited dilated cardiomyopathy. Early-onset skeletal muscle disorders due to recessive TTN mutations have recently been described, sometimes associated with cardiomyopathies.

CASE DESCRIPTION

We report the case of a boy with congenital core myopathy due to compound heterozygosity for TTN variants. He presented in infancy with rapidly evolving restrictive cardiomyopathy, requiring heart transplantation at the age of 5 years with favorable long-term cardiac and neuromuscular outcome.

CONCLUSION

Heart transplantation may have a role in selected patients with TTN-related congenital myopathy with disproportionally severe cardiac presentation compared to skeletal and respiratory muscle involvement.

Titin related myopathy with ophthalmoplegia. A novel phenotype

Titin-related myopathy is an emerging genetic neuromuscular disorder with a wide spectrum of clinical phenotypes. To date, there have not been reports of patients with this disease that presented with extraocular muscle involvement. Here we discuss a 19-year-old male with congenital weakness, complete ophthalmoplegia, thoracolumbar scoliosis, and obstructive sleep apnea. Muscle magnetic resonance imaging revealed severe involvement of the gluteal and anterior compartment muscles, and clear adductor sparing, while muscle biopsy of the right vastus lateralis showed distinctive cap-like structures. Trio Whole Exome Sequencing (WES) showed compound heterozygous likely pathologic variants in the TTN gene. (c.82541_82544dup (p.Arg27515Serfs*2) in exon 327 (NM_001267550.2) and c.31846+1G>A (p.?) in exon 123 (NM_001267550.2). To our knowledge, this is the first report of a TTN-related disorder associated with ophthalmoplegia.

LAMA2-Related Muscular Dystrophy: The Importance of Accurate Phenotyping and Brain Imaging in the Diagnosis of LGMD

We report three siblings from a non-consanguineous family presenting with contractural limb-girdle phenotype with intrafamilial variability. Muscle MRI showed posterior thigh and quadriceps involvement with a sandwich-like sign. Whole-exome sequencing identified two compound heterozygous missense TTN variants and one heterozygous LAMA2 variant. Brain MRI performed because of concentration difficulties in one of the siblings evidenced white-matter abnormalities, subsequently found in the others. The genetic analysis was re-oriented, revealing a novel pathogenic intronic LAMA2 variant which confirmed the LAMA2-RD diagnosis. This work highlights the importance of a thorough clinical phenotyping and the importance of brain imaging, in order to orientate and interpret the genetic analysis.

A sandwich ELISA kit reveals marked elevation of titin N‐terminal fragment levels in the urine of mdx mice

The mdx mouse is a model of Duchenne muscular dystrophy (DMD), a fatal progressive muscle wasting disease caused by dystrophin deficiency, and is used most widely in preclinical studies. Mice with dystrophin deficiency, however, show milder muscle strength phenotypes than humans. In human, the introduction of a sandwich enzyme‐linked immunosorbent assay (ELISA) kit revealed a more than 700‐fold increase in titin N‐terminal fragment levels in the urine of pediatric patients with DMD. Notably, the urinary titin level declines with aging, reflecting progression of muscle wasting. In mouse, development of a highly sensitive ELISA kit has been awaited. Here, a sandwich ELISA kit to measure titin N‐terminal fragment levels in mouse urine was developed. The developed kit showed good linearity, recovery, and repeatability in measuring recombinant or natural mouse titin N‐terminal fragment levels. The titin N‐terminal fragment concentration in the urine of mdx mice was more than 500‐fold higher than that of normal mice. Urinary titin was further analyzed by extending the collection of urine samples to both young (3–11 weeks old) and aged (56–58 weeks old) mdx mice. The concentration in the young group was significantly higher than that in the aged group. It was concluded that muscle protein breakdown is active and persistent in mdx mice even though the muscle phenotype is mild. Our results provide an opportunity to develop DMD treatments that aim to alleviate muscle protein breakdown by monitoring urinary titin levels.

Clinicopathological features of titinopathy from a Chinese neuromuscular center

Titin, one of the largest proteins in humans, is a major component of muscle sarcomeres. Pathogenic variants in the titin gene (TTN) have been reported to cause a range of skeletal muscle diseases, collectively known as titinopathy. Titinopathy is a heterogeneous group of disabling diseases characterized by muscle weakness. In our study, we aimed to establish the clinicopathological-genetic spectrum of titinopathy from a single neuromuscular center. Three patients were diagnosed as having definite titinopathy, and additional three patients were diagnosed as having possible titinopathy according to the diagnostic criteria. All the patients showed initial symptoms from age one to 40 years. Physical examination revealed that five patients had muscle weakness, and that one patient experienced behavioral changes. Muscle biopsy specimens obtained from all six patients demonstrated multiple myopathological changes, including increased fiber size variation, muscle fiber hypertrophy or atrophy, formation of centralized cell nuclei, necklace cytoplasmic bodies, and formation of rimmed vacuoles and cores. Genetic testing revealed 11 different TTN alterations, including missense (6/11), nonsense (2/11), frameshift (2/11), and splicing (1/11) mutations. Our study provides further evidence that TTN mutations are more likely to be responsible for an increasing proportion of various myopathies, such as hereditary myopathy with early respiratory failure (HMERF), core myopathy, and distal myopathy with rimmed vacuoles, than currently recognized mutations. Our findings expand the clinical, pathohistological and genetic spectrum of titinopathy.

Centronuclear myopathy due to a de novo nonsense variant and a maternally inherited splice-site variant in TTN: A case report

Next-generation sequencing has resulted in an explosion of rare de novo TTN variants. The clinical interpretation of these de novo variants in patients with recessive titinopathy is very difficult. Here, we provided a useful way to identify compound heterozygous mutations with a de novo one.