Alexander Disease

Neuroglia in leukodystrophies

Leukodystrophies are a heterogeneous group of rare genetic neurologic disorders characterized by white matter degeneration resulting from mutations affecting glial cells. This review focuses on the primary subtypes-astroglial, oligodendroglial, and microglial leukodystrophies-offering a detailed description of their neuropathologic features and clinical manifestations. It delves into key aspects of the pathogenesis, emphasizing the distinct cellular mechanisms that drive white matter damage. Advances in disease modeling, including the development of animal models with pathologic gene expressions and patient-derived iPS-cell models, have significantly enhanced our understanding of these rare disorders. Insights into the roles of different glial cell types highlight the complexity of leukodystrophies and provide a foundation for the development of targeted therapeutic strategies.

Morphological Characteristics and Extracellular Matrix Abnormalities in Astrocytes Derived From iPSCs of Children With Alexander Disease

AIMS

Alexander disease (AxD) is a leukodystrophy caused by mutations in the astrocytic filament gene GFAP. There are currently no effective treatments for AxD. Previous studies have rarely established AxD models with the patient's original GFAP mutations. In this study, we aimed to explore the morphological and transcriptomic characteristics of GFAP-mutant astrocytes via induced pluripotent stem cell (iPSC) models of AxD.

METHODS

Fibroblasts from three AxD children were reprogrammed into iPSCs. Wild-type (WT) and AxD-iPSCs were differentiated into astrocytes. We compared the morphological and transcriptomic differences between WT- and AxD iPSC-derived astrocytes.

RESULTS

Astrocytes induced from AxD-derived iPSCs exhibited the Rosenthal fibers (RFs), the main pathological phenotype of AxD. Compared with WT astrocytes, AxD astrocytes had shorter processes, more branches, and larger cell bodies. Transcriptomic analysis revealed that extracellular matrix (ECM) components, particularly chondroitin sulfate proteoglycans (CSPGs), were upregulated, and ECM-degrading enzymes were generally downregulated. These changes may lead to abnormalities in neurons and myelination.

CONCLUSIONS

We explored the morphological characteristics of AxD astrocytes via iPSC models and revealed the ECM, previously unexplored for AxD, may be an important new pathogenic mechanism of this disease.

Leukodystrophy with Macrocephaly, Refractory Epilepsy, and Severe Hyponatremia-The Neonatal Type of Alexander Disease

INTRODUCTION

Alexander disease (AxD) is a rare neurodegenerative condition that represents the group of leukodystrophies. The disease is caused by GFAP mutation. Symptoms usually occur in the infantile age with macrocephaly, developmental deterioration, progressive quadriparesis, and seizures as the most characteristic features. In this case report, we provide a detailed clinical description of the neonatal type of AxD.

METHOD

Next-Generation Sequencing (NGS), including a panel of 49 genes related to Early Infantile Epileptic Encephalopathy (EIEE), was carried out, and then Whole Exome Sequencing (WES) was performed on the proband's DNA extracted from blood.

CASE DESCRIPTION

In the first weeks of life, the child presented with signs of increased intracranial pressure, which led to ventriculoperitoneal shunt implementation. Recurrent focal-onset motor seizures with secondary generalization occurred despite phenobarbital treatment. Therapy was modified with multiple anti-seizure medications. In MRI contrast-enhanced lesions in basal ganglia, midbrain and cortico-spinal tracts were observed. During the diagnostic process, GLUT-1 deficiency, lysosomal storage disorders, organic acidurias, and fatty acid oxidation defects were excluded. The NGS panel of EIEE revealed no abnormalities. In WES analysis, GFAP missense heterozygous variant NM_002055.5: c.1187C>T, p.(Thr396Ile) was detected, confirming the diagnosis of AxD.

CONCLUSION

AxD should be considered in the differential diagnosis in all neonates with progressive, intractable seizures accompanied by macrocephaly.

Identification of association fibers using ex vivo diffusion tractography in Alexander disease brains

BACKGROUND AND PURPOSE

Alexander disease (AxD) is a neurodegenerative disorder caused by heterozygous Glial Fibrillary Acidic Protein mutation. The characteristic structural findings of AxD, such as leukodystrophic features, are well known, while association fibers of AxD remain uninvestigated. The aim of this study was to explore global and subcortical fibers in four brains with AxD using ex vivo diffusion tractography METHODS: High-angular-resolution diffusion magnetic resonance imaging (HARDI) tractography and diffusion-tensor imaging (DTI) tractography were used to evaluate long and short association fibers and compared to histological findings in brain specimens obtained from four donors with AxD and two donors without neurological disorders RESULTS: AxD brains showed impairment of long association fibers, except for the arcuate fasciculus and cingulum bundle, and abnormal trajectories of the inferior longitudinal and fronto-occipital fasciculi on HARDI tractography and loss of multidirectionality in subcortical fibers on DTI tractography. In histological studies, AxD brains showed diffuse low density on Klüver-Barrera and neurofilament staining and sporadic Rosenthal fibers on hematoxylin and eosin staining CONCLUSIONS: This study describes the spatial distribution of degenerations of short and long association fibers in AxD brains using combined tractography and pathological findings.

A Case Report of Adult-Onset Alexander Disease with a Tumor-Like Lesion in the Lateral Ventricle

Adult-onset Alexander disease (AOAD) is an autosomal dominant progressive astrogliopathy caused by pathogenic variants in glial fibrillary acidic protein (GFAP). Individuals with this disorder often present with a typical neuroradiologic pattern, including frontal white matter abnormality with contrast enhancement, atrophy and signal intensity changes of the medulla oblongata and upper cervical cord on MRI. Focal lesions are rarely seen in AOAD, which causes concern for primary malignancies. This study aimed to present the case of a 37-year-old male patient initially diagnosed with an astrocytoma in the lateral ventricle that was later identified as GFAP mutation-confirmed AOAD. GFAP sequencing revealed a heterogeneous missense mutation point c.236G>A. Hence, AOAD should be considered in patients with tumor-like lesion brain lesion in association with atrophy of medulla oblongata and upper cervical spinal cord, and frontal white matter abnormality with contrast enhancement.

GFAP variants leading to infantile Alexander disease: Phenotype and genotype analysis of 135 cases and report of a de novo variant

OBJECTIVES

Alexander disease (AxD) is a rare autosomal dominant disorder due to GFAP mutations; infantile AxD is the most common severe form which usually results in death. In this study, phenotype and genotype analysis of all reported cases with IAxD are reported as well as a de novo variant.

METHODS

We conduct a comprehensive review on all reported Infantile AxD due to GFAP mutation. Clinical data and genetics of the reported patients were analyzed. Clinical evaluations, pedigree drawing, MRI and sequencing of GFAP were performed.

RESULTS

135 patients clinically diagnosed with IAxD had GFAP mutations. A total of fifty three variants of GFAP were determined; 19 of them were located at 1A domain. The four common prevalent variants (c 0.715C>T, c 0.236G˃A, c 0.716G˃A, and c 0.235C˃T) were responsible for 64/135 (47.4%) of the patients. Seizure was the dominant clinical symptom (62.3%) followed by macrocephaly (41%), developmental delay (23.9%) and spasticity (23.9%). A de novo variant c 0.715C˃T was found in the presented Iranian case.

DISCUSSION

The majority of GFAP variant are located in a specific domain of the protein. Seizure as the most common symptom of IAxD could be considered. This study highlighted the role of genetic testing for diagnosing AxD.

Imaging pitfalls in paediatric posterior fossa neoplastic and non-neoplastic lesions

Paediatric posterior fossa lesions can have much overlap in their clinical and radiological presentation. There are, however, a number of key imaging features that can help the reading radiologist to distinguish tumours from important tumour mimics which are often inflammatory or metabolic entities. This pictorial review provides a number of important cases that proved challenging on imaging and illustrates some common pitfalls when interpreting lesions in the posterior fossa in children. Not everything that is abnormal will be a tumour, but often other causes are overlooked and misinterpreted as tumours, leading to great morbidity for that child. This article highlights some lesions that were mistaken as tumours and will introduce the reader to less commonly seen pathologies which are important to consider on a differential list for this location.

Alexander disease: an astrocytopathy that produces a leukodystrophy

Alexander Disease (AxD) is a degenerative disorder caused by mutations in the GFAP gene, which encodes the major intermediate filament of astrocytes. As other cells in the CNS do not express GFAP, AxD is a primary astrocyte disease. Astrocytes acquire a large number of pathological features, including changes in morphology, the loss or diminution of a number of critical astrocyte functions and the activation of cell stress and inflammatory pathways. AxD is also characterized by white matter degeneration, a pathology that has led it to be included in the "leukodystrophies." Furthermore, variable degrees of neuronal loss take place. Thus, the astrocyte pathology triggers alterations in other cell types. Here, we will review the neuropathology of AxD and discuss how a disease of astrocytes can lead to severe pathologies in non-astrocytic cells. Our knowledge of the pathophysiology of AxD will also lead to a better understanding of how astrocytes interact with other CNS cells and how astrocytes in the gliosis that accompanies many neurological disorders can damage the function and survival of other cells.

Histopathological proof of the pathogenicity of a rare GFAP mutation in a patient with flaccid paraparesis

Infantile Alexander disease is a rare progressive leukodystrophy caused by autosomal dominant mutations in the (GFAP) gene typically presenting with psychomotor retardation, progressive macrocephaly and refractory epilepsy. Neuroradiological hallmarks are extensive white matter lesions with frontal preponderance as well as signal intensity changes of basal ganglia and medulla oblongata with variable contrast enhancement. Here, we report an atypical manifestation in a 21-month-old boy presenting with flaccid paraparesis and areflexia. Cognitive, visual as well as fine motor skills and muscular strength of the upper extremities were appropriate for age. Weight and height as well as head circumference were within normal range. Clinical or electroencephalographic signs of seizures were absent. Cranial MRI demonstrated bifrontal cystic tumorous lesions with partial contrast rims, as well as space-occupying focal lesions of the caudate nuclei. Spinal MRI revealed swelling of the lumbar and cervical spinal cord. CSF and blood chemistry showed normal results. Histopathology of a subcortical lesion showed large amounts of Rosenthal fibers and protein droplets characteristic of Alexander disease. Sequencing detected a heterozygous mutation of the GFAP gene (c.205G > A; p.(Glu69Lys)) that has been reported before as probably pathogenetic in another case of lower spinal involvement. This well documented case draws attention to atypical spinal manifestations of Alexander disease and gives histopathological proof of the pathogenetic role of a rare GFAP mutation with marked spinal involvement.