Extra-muscular manifestations in GNE myopathy patients: A nationwide repository questionnaire survey in Japan

Beyond sialylation: Exploring the multifaceted role of GNE in GNE myopathy

Defects in sialic acid metabolism disrupt the sialylation of glycoproteins and glycolipids, contributing to a spectrum of diseases, including GNE myopathy (GNEM). This rare disorder is caused by mutations in the GNE gene that encodes for a bifunctional enzyme required for sialic acid biosynthesis, resulting in progressive muscle atrophy and weakness. There is no approved treatment for GNEM, and the number of affected individuals is underestimated. Although hyposialylation is considered the hallmark of GNEM, evidence showed lack of consistent correlation with GNEM severity and unveiled additional roles of GNE that contribute to the onset and/or progression of GNEM. Recent findings indicate that these mechanisms extend beyond glycosylation, encompassing cytoskeletal dynamics, oxidative stress, and muscle regeneration pathways. Understanding how GNE mutations result in a cascade of cellular and molecular dysregulations is crucial for developing targeted therapies aimed at improving the quality of life of patients. This review comprehensively examines GNEM's pathophysiology, clinical presentation, and therapeutic strategies, highlighting key findings on non-canonical GNE functions that account to GNEM clinical outcomes and emerging therapeutic targets. We propose future research directions to explore alternative target pathways that can ultimately support clinical development.

Ultra-Orphan drug development for GNE Myopathy: A synthetic literature review and meta-analysis

GNE myopathy is an autosomal recessive hereditary muscle disorder that has the following clinical characteristics: develops in early adulthood, gradually progresses from the distal muscles, and is relatively sparing of quadriceps until the advanced stages of the disease. With further progression, patients become non-ambulatory and need a wheelchair. There is growing concern about extra-muscular presentations such as thrombocytopenia, respiratory dysfunction, and sleep apnea syndrome. Pathologically, rimmed vacuoles and tubulofilamentous inclusions are observed in affected muscles. The cause of the disease is thought to be a sialic acid deficiency due to mutations of the GNE gene required for in vivo sialic acid biosynthesis. Sialic acid supplementation to a presymptomatic GNE myopathy mouse model was effective in preventing the development of the disease. Several clinical studies have been conducted to evaluate the safety and efficacy of sialic acid supplementation in humans. Based on the favorable results of these studies, an extended-release aceneuramic acid formulation was approved for treatment of GNE myopathy in Japan in March 2024. It is anticipated that it will be a significant step in the development of an effective treatment for GNE myopathy and other ultra-orphan diseases.

Novel biallelic GNE variants identified in a patient with chronic thrombocytopenia without any symptoms of myopathy

GNE encodes a rate-limiting enzyme that regulates the biosynthesis of a sialic acid precursor. As sialic acids are critical for the platelet membrane and muscle fibers, GNE variants cause GNE-related thrombocytopenia and GNE-related myopathy. Here, we report a neonate with thrombocytopenia that initially met the criteria for neonatal allo-immune thrombocytopenia (NAIT) but was resistant to treatments and then revealed novel biallelic heterozygous GNE variants without any symptoms of myopathy when diagnosed. NAIT was initially diagnosed due to alloantibodies against HPA5 and its mismatch between the patient and his mother. However, intravenous immunoglobulin therapy and platelet transfusions showed minimal improvement in the platelet count. Platelet counts remained around 60 × 109/L, suggesting congenital thrombocytopenia. Gene panel sequencing at the age of 13 identified biallelic pathogenic variants of GNE. The patient did not exhibit any symptoms of muscular weakness, suggesting GNE-related myopathy. We demonstrated a GNE-related thrombocytopenia patient with novel biallelic heterozygous GNE variants. Clinical trials have involved the use of sialic acids or their precursors, as well as gene therapy, to treat GNE-related myopathy, which may slow or halt the progression of the disease. Therefore, early diagnosis of this disease may significantly impact its clinical course.

Preserved Forearm and Hand Muscles and Diaphragm with Mild Cardiac and Respiratory Involvement in a Patient with GNE Myopathy Harboring Homozygous Variants in GNE (c.1807G>C, p.V603L) over Four Decades after the Onset

We encountered a 67-year-old Japanese man with GNE myopathy and homozygous variants (c.1807G>C, p.V603L) of the GNE gene. The patient developed weakness in the left foot at 24 years old and could only move his wrist joints and hands 43 years after the onset. This genotype is the most common variant and causes severe muscle involvement; however, the distal upper extremities are preserved until the end-stage of the disease. Although severe heart failure is rare in GNE myopathy, mild cardiac dysfunction (ejection fraction 46.1%) was observed. Furthermore, respiratory dysfunction was noted with a preserved diaphragm.

Large phenotypic diversity by genotype in patients with GNE myopathy: 10 years after the establishment of a national registry in Japan

BACKGROUND

GNE myopathy is an ultra-rare autosomal recessive distal myopathy caused by pathogenic variants of the GNE gene, which encodes a key enzyme in sialic acid biosynthesis. The present study aimed to examine the long-term progression of GNE myopathy, genotype-phenotype correlations, and complications to provide useful information for predicting patient progression and designing clinical trials using a large collection of registry data over a 10-year period.

METHODS

We analyzed 220 Japanese patients with GNE myopathy from a national registry in Japan. Diagnoses were confirmed by genetic curators based on genetic analysis reports. We analyzed registration sheets and annually updated items completed by attending physicians.

RESULTS

In total, 197 of 220 participants (89.5%) carried p.D207V or p.V603L in at least one allele. The median disease duration to loss of ambulation was estimated to be 10 years in p.V603L homozygotes (n = 48), whereas more than 90% of p.D207V/p.V603L compound heterozygotes were estimated to be ambulatory even 20 years after disease onset according to Kaplan-Meier analysis (p < 0.001). Moreover, participants with a younger age of onset lost ambulation earlier regardless of genotype. A decline in respiratory function was observed as the disease progressed, particularly in p.V603L homozygotes, whereas none of the p.D207V/p.V603L compound heterozygotes showed a decline.

CONCLUSIONS

The present study demonstrated large differences in disease progression and respiratory function between genotypes. Moreover, age of onset was found to be an indicator of disease severity regardless of genotype in GNE myopathy patients. These results may help stratify patients in clinical trials and predict disease progression.

Hereditary thrombocytopenia with platelet sialic acid deficiency and mutations in the GNE genes

BACKGROUND

The inherited macrothrombocytopenias are rare disorders and the underlying cause can be identified in many cases but in some, this can remain enigmatic. Platelet transfusions are often administered during hemorrhagic events.

METHODS

A patient with previously unexplained inherited macrothrombocytopenia with a platelet count between 3-20 × 10⁹ /L is described in which studies were performed using exome sequencing (ES) and platelet flow cytometry.

RESULTS

Both the hemoglobin and white cell counts were normal. ES revealed two suspicious variants, one likely pathogenic and one a variant of uncertain significance, in the UDP-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase (GNE) gene, and flow cytometry showed diminished expression of surface platelet sialic acid (about 5%) but normal red cell sialic acid. The Thrombopoietin (TPO) level was low, and the patient responded to TPO-mimetic treatment with an increase in the platelet count.

CONCLUSION

Two variants in the GNE gene were able to be upgraded to pathogenic with apparently restricted expression to the megakaryocyte lineage. Platelet transfusion may be avoided in these patients with TPO-mimetic treatment.

Development of Assays to Measure GNE Gene Potency and Gene Replacement in Skeletal Muscle

BACKGROUND

GNE myopathy (GNEM) is a severe muscle disease caused by mutations in the UDP-GlcNAc-2-epimerase/ManNAc-6-kinase (GNE) gene, which encodes a bifunctional enzyme required for sialic acid (Sia) biosynthesis.

OBJECTIVE

To develop assays to demonstrate the potency of AAV gene therapy vectors in making Sia and to define the dose required for replacement of endogenous mouse Gne gene expression with human GNE in skeletal muscles.

METHODS

A MyoD-inducible Gne-deficient cell line, Lec3MyoDI, and a GNE-deficient human muscle cell line, were made and tested to define the potency of various AAV vectors to increase binding of Sia-specific lectins, including MAA and SNA. qPCR and qRT-PCR methods were used to quantify AAV biodistribution and GNE gene expression after intravenous delivery of AAV vectors designed with different promoters in wild-type mice.

RESULTS

Lec3 cells showed a strong deficit in MAA binding, while GNE-/-MB135 cells did not. Overexpressing GNE in Lec3 and Lec3MyoDI cells by AAV infection stimulated MAA binding in a dose-dependent manner. Use of a constitutive promoter, CMV, showed higher induction of MAA binding than use of muscle-specific promoters (MCK, MHCK7). rAAVrh74.CMV.GNE stimulated human GNE expression in muscles at levels equivalent to endogenous mouse Gne at a dose of 1×1013vg/kg, while AAVs with muscle-specific promoters required higher doses. AAV biodistribution in skeletal muscles trended higher when CMV was used as the promoter, and this correlated with increased sialylation of its viral capsid.

CONCLUSIONS

Lec3 and Lec3MyoDI cells work well to assay the potency of AAV vectors in making Sia. Systemic delivery of rAAVrh74.CMV.GNE can deliver GNE gene replacement to skeletal muscles at doses that do not overwhelm non-muscle tissues, suggesting that AAV vectors that drive constitutive organ expression could be used to treat GNEM.

Genetic and Clinical Spectrum of GNE Myopathy in Russia

GNE myopathy (GNEM) is a rare hereditary disease, but at the same time, it is the most common distal myopathy in several countries due to a founder effect of some pathogenic variants in the GNE gene. We collected the largest cohort of patients with GNEM from Russia and analyzed their mutational spectrum and clinical data. In our cohort, 10 novel variants were found, including 2 frameshift variants and 2 large deletions. One novel missense variant c.169_170delGCinsTT (p.(Ala57Phe)) was detected in 4 families in a homozygous state and in 3 unrelated patients in a compound heterozygous state. It was the second most frequent variant in our cohort. All families with this novel frequent variant were non-consanguineous and originated from the 3 neighboring areas in the European part of Russia. The clinical picture of the patients carrying this novel variant was typical, but the severity of clinical manifestation differed significantly. In our study, we reported two atypical cases expanding the phenotypic spectrum of GNEM. One female patient had severe quadriceps atrophy, hand joint contractures, keloid scars, and non-classical pattern on leg muscle magnetic resonance imaging, which was more similar to atypical collagenopathy rather than GNEM. Another patient initially had been observed with spinal muscular atrophy due to asymmetric atrophy of hand muscles and results of electromyography. The peculiar pattern of muscle involvement on magnetic resonance imaging consisted of pronounced changes in the posterior thigh muscle group with relatively spared muscles of the lower legs, apart from the soleus muscles. Different variants in the GNE gene were found in both atypical cases. Thus, our data expand the mutational and clinical spectrum of GNEM.

Recent advances in establishing a cure for GNE myopathy

PURPOSE OF REVIEW

GNE myopathy is a rare autosomal recessive disease caused by biallelic variants in the GNE gene, which encodes an enzyme involved in sialic acid biosynthesis. No drugs are approved for the treatment of GNE myopathy. Following proof-of-concept of sialic acid supplementation efficacy in mouse models, multiple clinical trials have been conducted. Here, we review clinical trials of sialic acid supplementation therapies and provide new insights into the additional clinical features of GNE myopathy.

RECENT FINDINGS

Clinical trials of sialic acid supplementation have been conducted in Europe, the USA, Japan, and South Korea. Some clinical trials of NeuAc-extended release tablets demonstrated amelioration of decline in upper extremity muscle strength; however, no significant improvement was observed in phase 3 trials in Europe and USA. A phase 2 trial of ManNAc showed slowed decline of both upper and lower extremity strength. GNE myopathy patient registries have been established in Europe and Japan, and have provided information on extramuscular manifestations such as thrombocytopenia, respiratory dysfunction, and sleep apnea syndrome. Sensitive and reliable biomarkers, and a disease-specific functional activity scale, have also been investigated.

SUMMARY

We discuss recent advances in establishing a GNE myopathy cure, and discuss other prospective therapeutic options, including gene therapy.

The role of amyloid β in the pathological mechanism of GNE myopathy

GNE myopathy is a hereditary muscle disorder characterized by muscle atrophy and weakness initially involving the lower distal extremities. The treatment of GNE myopathy mainly focuses on a sialic acid deficiency caused by a mutation in the GNE gene, but it has not achieved the expected effect. The main pathological features of GNE myopathy are myofiber atrophy and rimmed vacuoles, including accumulation of amyloid β, which is mainly found in atrophic muscle fibers. Although the role of amyloid β and other misfolded proteins on the nervous system has been widely recognized, the cause and process of the formation of amyloid β in the pathological process of GNE myopathy are unclear. In addition, amyloid β has been reported to be linked to quality control mechanisms of proteins, such as molecular chaperones, the ubiquitin–proteasome system, and the autophagy-lysosome system. Herein, we summarize the possible reasons for amyloid β deposition and illustrate amyloid β-mediated events in the cells and their role in muscle atrophy in GNE myopathy. This review represents an overview of amyloid β and GNE myopathy that could help identify a potential mechanism and thereby a plausible therapeutic for the disease.