A multilevel screening pipeline in zebrafish identifies therapeutic drugs for GAN.

Giant axonal neuropathy (GAN) is a fatal neurodegenerative disorder for which there is currently no treatment. Affecting the nervous system, GAN starts in infancy with motor deficits that rapidly evolve toward total loss of ambulation. Using the gan zebrafish model that reproduces the loss of motility as seen in patients, we conducted the first pharmacological screening for the GAN pathology. Here, we established a multilevel pipeline to identify small molecules restoring both the physiological and the cellular deficits in GAN. We combined behavioral, in silico, and high-content imaging analyses to refine our Hits to five drugs restoring locomotion, axonal outgrowth, and stabilizing neuromuscular junctions in the gan zebrafish. The postsynaptic nature of the drug's cellular targets provides direct evidence for the pivotal role the neuromuscular junction holds in the restoration of motility. Our results identify the first drug candidates that can now be integrated in a repositioning approach to fasten therapy for the GAN disease. Moreover, we anticipate both our methodological development and the identified hits to be of benefit to other neuromuscular diseases.

Expanding the genetic spectrum of giant axonal neuropathy: Two novel variants in Iranian families.

BACKGROUND: Giant axonal neuropathy (GAN) is a progressive childhood hereditary polyneuropathy that affects both the peripheral and central nervous systems. Disease-causing variants in the gigaxonin gene (GAN) cause autosomal recessive giant axonal neuropathy. Facial weakness, nystagmus, scoliosis, kinky or curly hair, pyramidal and cerebellar signs, and sensory and motor axonal neuropathy are the main symptoms of this disorder. Here, we report two novel variants in the GAN gene from two unrelated Iranian families. METHODS: Clinical and imaging data of patients were recorded and evaluated, retrospectively. Whole-exome sequencing (WES) was undertaken in order to detect disease-causing variants in participants. Confirmation of a causative variant in all three patients and their parents was carried out using Sanger sequencing and segregation analysis. In addition, for comparing to our cases, we reviewed all relevant clinical data of previously published cases of GAN between the years 2013-2020. RESULTS: Three patients from two unrelated families were included. Using WES, we identified a novel nonsense variant [NM_022041.3:c.1162del (p.Leu388Ter)], in a 7-year-old boy of family 1, and a likely pathogenic missense variant [NM_022041.3:c.370T>A (p.Phe124Ile)], in two affected siblings of the family 2. Clinical examination revealed typical features of GAN-1 in all three patients, including walking difficulties, ataxic gait, kinky hair, sensory-motor polyneuropathy, and nonspecific neuroimaging abnormalities. Review of 63 previously reported cases of GAN indicated unique kinky hair, gait problem, hyporeflexia/areflexia, and sensory impairment were the most commonly reported clinical features. CONCLUSIONS: One homozygous nonsense variant and one homozygous missense variant in the GAN gene were discovered for the first time in two unrelated Iranian families that expand the mutation spectrum of GAN. Imaging findings are nonspecific, but the electrophysiological study in addition to history is helpful to achieve the diagnosis. The molecular test confirms the diagnosis.

Pelo lanoso posnatal: clave diagnóstica en la neuropatía axonal gigante / Postnatal Woolly Hair: A Key to Diagnosis in Giant Axonal Neuropathy

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Giant axonal neuropathy: A differential diagnosis of consideration.

Edem P, Karakaya M, Wirth B, Okur TD, Yis U. Giant axonal neuropathy: A differential diagnosis of consideration. Turk J Pediatr 2019; 61: 275-278. Giant axonal neuropathy (GAN) is a rare neurodegenerative disorder affecting both the central and peripheral nervous systems progressively. The recessive mutations of the GAN gene are responsible for the disease. Although some clinical aspects, like coarse and kinky hair, are suggestive, other diseases may interfere with diagnosis. We describe a case who previously had been diagnosed with and treated for chronic inflammatory demyelinating polyradiculoneuropathy (CIDP); after re-evaluation, genetic testing was received, and the patient was diagnosed with GAN.

Two novel mutations in the GAN gene causing giant axonal neuropathy.

BACKGROUND: Giant axonal neuropathy (GAN) is a rare neurodegenerative disease transmitted in an autosomal recessive mode. This disorder presents motor and sensitive symptoms with an onset in early childhood. Progressive neurodegeneration makes the patients wheelchair dependent by the end of the second decade of life. Affected individuals do not survive beyond the third decade of life. Molecular analysis has identified mutations in the gene GAN in patients with this disorder. This gene produces a protein called gigaxonin which is presumably involved in protein degradation via the ubiquitin-proteasome system. However, the underlying molecular mechanism is not clearly understood yet. METHODS: Here we present the first patient from Mexico with clinical data suggesting GAN. Sequencing of the GAN gene was carried out. Changes in the nucleotide sequence were investigated for their possible impact on protein function and structure using the publicly available prediction tools PolyPhen-2 and PANTHER. RESULTS: The patient is a compound heterozygous carrying two novel mutations in the GAN gene. The sequence analysis revealed two missense mutations in the Kelch repeats domain. In one allele, a C>T transition was found in exon 9 at the nucleotide position 55393 (g.55393C>T). In the other allele, a transversion G>T in exon 11 at the nucleotide position 67471 (g.67471G>T) was observed. Both of the bioinformatic tools predicted that these amino acid substitutions would have a negative impact on gigaxonin's function. CONCLUSION: This work provides useful information for health professionals and expands the spectrum of disease-causing mutations in the GAN gene and it is the first documented case in Mexican population.

Giant axonal neuropathy-like disease in an Alexandrine parrot (Psittacula eupatria).

A chronic progressive neurological condition in an Alexandrine parrot (Psittacula eupatria) was manifest as intention tremors, incoordination, and seizure activity. Histology revealed large eosinophilic bodies throughout the central nervous system, and electron microscopy demonstrated that these bodies were greatly expanded axons distended by short filamentous structures that aggregated to form long strands. The presence of periodic acid-Schiff-positive material within the neuronal bodies of Purkinje cells and ganglionic neurons is another distinctive feature of this disease. The histological features of this case display some features consistent with giant axonal neuropathy as reported in humans and dogs. Based on investigation of the lineage in this case, an underlying inherited defect is suspected, but some additional factor appears to have altered the specific disease presentation in this bird.

Giant axonal neuropathy.

Giant axonal neuropathy is an autosomal recessive disorder of childhood with distinct morphological features. An 8-year-old boy presented with progressive walking difficulty and recurrent falls. Evaluation showed frizzy hair, characteristic facies, sensory motor neuropathy, and ataxia. Magnetic resonance imaging (MRI) showed bilateral symmetric white matter signal changes in the cerebellum and periventricular regions along with involvement of the posterior limb of the internal capsule. Sural nerve biopsy demonstrated giant axons with neurofilament accumulation. The clinicopathologic manifestations of giant axonal neuropathy are discussed along with the clinical and histologic differential diagnoses.

Measuring disease progression in giant axonal neuropathy: implications for clinical trial design.

As part of a natural history study of giant axonal neuropathy, we hypothesized that the Friedreich Ataxia Rating Scale and the Gross Motor Function Measure would show a significant change over 6 months, reflecting subjects' decline in motor function. The Friedreich Ataxia Rating Scale was performed on 11 subjects and the Gross Motor Function Measure was performed on 10 subjects twice with a six-month interval. A paired two-tailed t-test was used to assess the difference in each subject's score. Significant changes were found over six months of 11.7 ± 11.0 (P = 0.006) for the Friedreich Ataxia Rating Scale and -10.0 ± 13.5 (P = 0.043) for the Gross Motor Function Measure, reflecting subjects' decline in motor function on examination and by report. These standardized assessments of clinical function are the first to be validated in giant axonal neuropathy and will be used in an upcoming gene therapy clinical trial.

Giant axonal neuropathy: a rare inherited neuropathy with simple clinical clues.

Giant axonal neuropathy (GAN) is a rare hereditary neurodegenerative disorder characterised by accumulation of excess neurofilaments in the axons of peripheral and central nervous systems, which hampers signal transmission. It usually manifests in infancy and early childhood and is slowly progressive. Those affected with GAN have characteristic curly kinky hair, everted feet and a crouched gait, which suggest the diagnosis in most cases. We describe twin children who presented with difficulty in walking and an abnormal gait since they began walking; clinical clues such as hair changes led us to the final diagnosis.

Ultrasound differentiation of axonal and demyelinating neuropathies.

INTRODUCTION: Ultrasound can be used to visualize peripheral nerve abnormality. Our objective in this study was to prove whether nerve ultrasound can differentiate between axonal and demyelinating polyneuropathies (PNPs). METHODS: Systematic ultrasound measurements of peripheral nerves were performed in 53 patients (25 with demyelinating, 20 with axonal, 8 with mixed neuropathy) and 8 healthy controls. Nerve conduction studies of corresponding nerves were undertaken. RESULTS: Analysis of variance revealed significant differences between the groups with regard to motor conduction velocity, compound muscle action potential amplitude, and cross-sectional area (CSA) of different nerves at different locations. Receiver operating characteristic curve analysis revealed CSA measurements to be well suited for detection of demyelinating neuropathies, and boundary values of peripheral nerve CSA could be defined. CONCLUSIONS: Systematic ultrasound CSA measurement in different nerves helped detect demyelination, which is an additional cue in the etiological diagnosis of PNP, along with nerve conduction studies and nerve biopsy.

Heterogeneity of axonal pathology in Chinese patients with giant axonal neuropathy.

INTRODUCTION: Giant axonal neuropathy (GAN) is a rare autosomal recessive neurodegenerative disorder caused by mutations in the GAN gene. Herein we report ultrastructural changes in Chinese patients with GAN. METHODS: General clinical assessment, sural nerve biopsy, and genetic analysis were performed. RESULTS: Sural biopsy revealed giant axons in 3 patients, 2 with a mild phenotype and 1 with a classical phenotype. Ultrastructurally, all patients had giant axons filled with closely packed neurofilaments. In addition, the classical patient had some axons containing irregular tubular-like structures. GAN mutation analysis revealed novel compound heterozygous c.98A>C and c.158C>T mutations in the BTB domain in 1 mild patient, a novel homozygous c.371T>G mutation in the BACK domain in another mild patient, and a novel c.1342G>T homozygous mutation in the Kelch domain in the classical patient. CONCLUSION: Closely packed neurofilaments in giant axons are common pathological changes in Chinese patients with GAN, whereas irregular tubular-like structures appear in the classical type of this neuropathy.

Giant axonal neuropathy diagnosed on skin biopsy.

Evaluation of hereditary axonal neuropathy in childhood is complex. Often, the child has to be subjected to general anaesthesia for a nerve biopsy to guide further genetic testing, which may or may not be readily available. We describe a toddler with clinical features suggesting giant axonal neuropathy (GAN), whose diagnosis was confirmed by minimally invasive skin biopsy and corroborated by the finding of compound heterozygous mutations involving the GAN gene, including a novel interstitial microdeletion at 16q23.2 detected by microarray and a point mutation detected by direct sequencing.

The absence of curly hair is associated with a milder phenotype in Giant Axonal Neuropathy.

Giant Axonal Neuropathy is a pediatric neurodegenerative disorder caused by autosomal recessive mutations in the GAN gene on chromosome 16q24.1. Mutations in the GAN gene lead to functional impairment of the cytoskeletal protein gigaxonin and a generalized disorder of intermediate filaments, including neurofilaments in axons. Tightly curled hair is a common but not universal feature of Giant Axonal Neuropathy. The pathogenesis of curly hair is unknown, although disruption of keratin architecture is thought to play a role. As part of a broader natural history study of Giant Axonal Neuropathy, we found that the absence of curly hair is correlated with superior motor function (p=0.013) when controlling for age, as measured by the Gross Motor Function Measure. Theoretically, higher levels of functional gigaxonin protein or compensatory mechanisms could produce fewer abnormalities of neurofilaments and keratin, accounting for this phenotype. We suggest that straight-haired patients with Giant Axonal Neuropathy are potentially underdiagnosed due to their divergence from the classic phenotype of the disease. Due to their non-specific features of an axonal neuropathy, these patients may be misdiagnosed with Charcot-Marie-Tooth Disease type 2. Genetic testing for Giant Axonal Neuropathy should be considered in relevant cases of Charcot-Marie-Tooth Disease type 2.

Giant axonal neuropathy.

Giant axonal neuropathy (GAN) is a rare hereditary autosomal recessive neurodegenerative disease affecting both the peripheral and the central nervous system. Clinically it is characterized by an age of onset during the first decade, progressive and severe motor sensory neuropathy followed, in some patients, by the occurrence of various central nervous system signs such as cerebellar syndrome, upper motor neuron signs, or epilepsy. Although kinky hairs are reported in the majority of patients, it is not a constant finding. The prognosis is usually severe with death occurring during the second or third decade; nevertheless a less severe course is reported in some patients. The presence of a variable number of giant axons filled with neurofilaments in the nerve biopsy represents the pathological feature of the disease and it is usually associated to a variable degree with axonal loss and demyelization. Giant axons are also found in the central nervous system associated with Rosenthal fibers and a variable degree of involvement of white matter and neuronal loss. The disease is caused by mutation in the GAN gene encoding for gigaxonin, a member of BTB-Kelch. Up to now 37 mutations in the GAN gene have been reported. These mutations are scattered over the 11 exons of the gene without a clear genotype-phenotype correlation. These mutations resulting in gigaxonin deficiency lead to a slow down in ubiquitin-mediated protein degradation and possibly of other unidentified proteins. GAN represents a good model of a neurodegenerative disorder in which there is a primary defect of the ubiquitin proteasome system and its network with neurofilaments. The clarification of molecular mechanisms involved in GAN can help in understanding other frequent neurodegenerative diseases such as amyotrophic lateral sclerosis (ALS) and Parkinson disease.

Involvement of the globus pallidus in giant axonal neuropathy.

Giant axonal neuropathy is a rare autosomal recessive disorder commonly characterized by chronic, progressive dysfunction in the peripheral nervous system. Lesions also can occur in the central nervous system, especially in the brainstem and cerebellum. We present cranial magnetic resonance imaging and magnetic resonance spectroscopy findings in a 5-year-old Turkish girl with giant axonal neuropathy. This study is the second to describe involvement of the globus pallidus on T(2)-weighted imaging in giant axonal neuropathy. Magnetic resonance spectroscopy of cerebellar white matter lesions and globus pallidus revealed metabolic changes, including increased choline/creatine ratios, increased lactate, and reduced N-acetyl aspartate/creatine ratios. Thus, magnetic resonance spectroscopy did not produce findings specific to giant axonal neuropathy, but indicated progressive neuronal loss, demyelination, and gliosis in the cerebellar white matter.

Application of autologous bone marrow stem cells in giant axonal neuropathy.

Giant axonal neuropathy is a rare disorder of autosomal recessive inheritance, morphologically characterized by accumulation of neurofilaments in enlargements of preterminal regions of central and peripheral axons. We present a 7-year-old girl with thick and tightly curled lackluster hair suffering from giant axonal neuropathy. The diagnosis was confirmed on the brain MRI which showed white matter abnormalities in the anterior and posterior periventricular regions as well as the cerebellar white matter. In view of the same, the patient was given intrathecal autologous bone marrow-derived stem cell therapy as part of the neuroregenerative rehabilitation therapy protocol. The patient showed functional improvements in her disability after receiving the therapy. A detailed case report is presented here with.