Management of adrenoleukodystrophy: From pre-clinical studies to the development of new therapies

Cerebral adrenoleukodystrophy presenting as status epilepticus: Unveiling the neurological maze

We describe the case of a 7-year-old boy who had repeated episodes of prolonged seizures without recovery of consciousness when he arrived at a rural tertiary care teaching institute hospital in Wardha, India. Detailed history of the patient revealed that the child's symptoms began with left exotropia and visual acuity changes, progressing over 6 months to cognitive decline, hearing impairment, pseudobulbar affect, and motor issues, eventually leading to school dropout. Social isolation and difficulty walking also developed as the disease advanced. MRI brain revealed diffuse white matter lesions bilaterally with raised serum ACTH levels of 5 times the normal range associated with raised levels of tetracosanoic acid (C24) and hexacosanoic acid (C26), along with elevated C24/C22 and C26/C22 ratios. The patient was provisionally diagnosed as X linked cerebral adrenoleukodystrophy. Post treatment and stabilization, the patient was seizure-free on antiepileptic medications, however, patient developed blindness, lost mobility, became bedridden, and progressed to a vegetative state within 6 months. Adrenoleukodystrophy (ALD) is a rare X-linked genetic disorder that primarily affects men. It is caused by mutations in the ABCD 1 gene and is characterized by an abnormal build-up of very long-chain fatty acids (VLCFA) in various body tissues, which affect the spinal cord, white matter, and adrenal glands, causing progressive damage and dysfunction at each location. This case highlights the importance of early diagnosis and intervention to slow down disease progression in order to improve outcome. Also, increased awareness among healthcare professionals to help early detect the signs of this disease is of great importance.

Inherited metabolic epilepsies-established diseases, new approaches

Inherited metabolic epilepsies (IMEs) represent the inherited metabolic disorders (IMDs) in which epilepsy is a prevailing component, often determining other neurodevelopmental outcomes associated with the disorder. The different metabolic pathways affected by individual IMEs are the basis of their rarity and heterogeneity. These characteristics make it particularly challenging to establish their targeted therapies, and many of the IMEs are treated nowadays only symptomatically and supportively. However, owing to immense molecular and genetic progress in the last decades, important features of their pathomechanisms have been elucidated. This has led to advancements in the development of novel diagnostic approaches and specific therapies for a considerable number of these unique disorders. This review provides an overview of the broad approach to the diagnosis and management of IMEs, along with their eminent and new individual treatment options, ranging from dietary therapies and vitamins to enzyme and gene replacement therapies. PLAIN LANGUAGE SUMMARY: Inherited metabolic disorders (IMDs) in which epilepsy is a main symptom are considered inherited metabolic epilepsies (IMEs). It is challenging to develop targeted therapies for IMEs since they are rare and individually different in characteristics. Therefore, many of the IMEs are currently treated only symptomatically. However, scientific progress in the last decades led to the creation of specific treatments for many of these unique disorders. This review provides an overview of the approach to the diagnosis and management of IMEs, including the available newer therapeutic modalities.

Intracisternal AAV9-MAG-hABCD1 Vector Reverses Motor Deficits in Adult Adrenomyeloneuropathy Mice

Worldwide, thousands of male patients who carry ATP Binding Cassette Subfamily D Member 1 (ABCD1) mutations develop adrenomyeloneuropathy (AMN) in mid-adulthood, a debilitating axonopathy of the spinal cord. Today AAV gene therapy brings the most hope for this orphan disease. We previously reported that an AAV9-MAG-hABCD1 vector injected intravenously in the neonatal period prevented the disease in 2-year-old Abcd1-/- mice, the AMN mouse model. In the current study, the same vector was injected intracisternally at 18 months of age, when about half of Abcd1-/- mice start losing balance and motricity. As soon as 1-3 months after vector injection, motor tests have evolved differently in treated and untreated (UT) mice. Six months after vector, treated mice (n = 24) had near-normal motor performances, whereas neurological state had deteriorated in UT mice (n = 34). In five white matter regions of the cervical spinal cord, hABCD1 expression at 24 months of age was present in 22% (18-27) of oligodendrocytes (OLs) and 22% (17-26) of astrocytes and not detected in neurons or microglia. Abundant hABCD1 expression was also observed in OLs and astrocytes in the cerebellum and brainstem and, to a lesser level, in the lower spinal cord, not in the dorsal root ganglia or brain cortex. In conclusion, the effect of the AAV9-MAG-hABCD1 vector at an early symptomatic stage of the Abcd1-/- mouse model paves a new oligotropic way for the gene therapy of AMN.

Advances in AAV-mediated gene replacement therapy for pediatric monogenic neurological disorders

Pediatric monogenetic diseases encompass a spectrum of debilitating neurological disorders that affect infants and children, often resulting in profound cognitive and motor impairments. Gene replacement therapy holds immense promise in addressing the underlying genetic defects responsible for these conditions. Adeno-associated virus (AAV) vectors have emerged as a leading platform for delivering therapeutic genes due to their safety profile and ability to transduce various cell types, including neurons. This review highlights recent advancements in AAV-mediated gene replacement therapy for pediatric monogenetic diseases, focusing on key preclinical and clinical studies. We discuss various strategies to enhance transduction efficiency, target specificity, and safety. Furthermore, we explore challenges such as immune responses, along with innovative approaches to overcome these obstacles. Moreover, we examine the clinical outcomes and safety profiles of AAV-based gene therapies in pediatric patients, providing insights into the feasibility and efficacy of these interventions. Finally, we discuss future directions and potential avenues for further research to optimize the therapeutic potential of AAV-delivered gene replacement therapy for pediatric encephalopathies, ultimately aiming to improve the quality of life for affected individuals and their families.

From gene to therapy: a review of deciphering the role of ABCD1 in combating X-Linked adrenoleukodystrophy

X-linked adrenoleukodystrophy (X-ALD) is a severe genetic disorder caused by ABCD1 mutations, resulting in the buildup of very-long-chain fatty acids, leading to significant neurological decline and adrenal insufficiency. Despite advancements in understanding the mechanisms of X-ALD, its pathophysiology remains incompletely understood, complicating the development of effective treatments. This review provides a comprehensive overview of X-ALD, with a focus on the genetic and biochemical roles of ABCD1 and the impacts of its mutations. Current therapeutic approaches are evaluated, discussing their limitations, and emphasizing the need to fully elucidate the pathogenesis of X-ALD. Additionally, this review highlights the importance of international collaboration to enhance systematic data collection and advance biomarker discovery, ultimately improving patient outcomes with X-ALD.

Terra incognita of glial cell dynamics in the etiology of leukodystrophies: Broadening disease and therapeutic perspectives

Neuroglial cells, also known as glia, are primarily characterized as auxiliary cells within the central nervous system (CNS). The recent findings have shed light on their significance in numerous physiological processes and their involvement in various neurological disorders. Leukodystrophies encompass an array of rare and hereditary neurodegenerative conditions that were initially characterized by the deficiency, aberration, or degradation of myelin sheath within CNS. The primary cellular populations that experience significant alterations are astrocytes, oligodendrocytes and microglia. These glial cells are either structurally or metabolically impaired due to inherent cellular dysfunction. Alternatively, they may fall victim to the accumulation of harmful by-products resulting from metabolic disturbances. In either situation, the possible replacement of glial cells through the utilization of implanted tissue or stem cell-derived human neural or glial progenitor cells hold great promise as a therapeutic strategy for both the restoration of structural integrity through remyelination and the amelioration of metabolic deficiencies. Various emerging treatment strategies like stem cell therapy, ex-vivo gene therapy, infusion of adeno-associated virus vectors, emerging RNA-based therapies as well as long-term therapies have demonstrated success in pre-clinical studies and show promise for rapid clinical translation. Here, we addressed various leukodystrophies in a comprehensive and detailed manner as well as provide prospective therapeutic interventions that are being considered for clinical trials. Further, we aim to emphasize the crucial role of different glial cells in the pathogenesis of leukodystrophies. By doing so, we hope to advance our understanding of the disease, elucidate underlying mechanisms, and facilitate the development of potential treatment interventions.

Phase I clinical trial of intracerebral injection of lentiviral-ABCD1 for the treatment of cerebral adrenoleukodystrophy

This was a single-arm, multicenter, open-label phase I trial. Lentiviral vectors (LV) carrying the ABCD1 gene (LV-ABCD1) was directly injected into the brain of patients with childhood cerebral adrenoleukodystrophy (CCALD), and multi-site injection was performed. The injection dose increased from 200 to 1600 μL (vector titer: 1×109 transduction units per mL (TU/mL)), and the average dose per kilogram body weight ranges from 8 to 63.6 μL/kg. The primary endpoint was safety, dose-exploration and immunogenicity and the secondary endpoint was initial evaluation of efficacy and the expression of ABCD1 protein. A total of 7 patients participated in this phase I study and were followed for 1 year. No injection-related serious adverse event or death occurred. Common adverse events associated with the injection were irritability (71%, 5/7) and fever (37.2-38.5 ℃, 57%, 4/7). Adverse events were mild and self-limited, or resolved within 3 d of symptomatic treatment. The maximal tolerable dose is 1600 μL. In 5 cases (83.3%, 5/6), no lentivirus associated antibodies were detected. The overall survival at 1-year was 100%. The ABCD1 protein expression was detected in neutrophils, monocytes and lymphocytes. This study suggests that the intracerebral injection of LV-ABCD1 for CCALD is safe and can achieve successful LV transduction in vivo; even the maximal dose did not increase the risk of adverse events. Furthermore, the direct LV-ABCD1 injection displayed low immunogenicity. In addition, the effectiveness of intracerebral LV-ABCD1 injection has been preliminarily demonstrated while further investigation is needed. This study has been registered in the Chinese Clinical Trial Registry (https://www.chictr.org.cn/, registration number: ChiCTR1900026649).

Preimplantation Genetic Testing Inhibits the Transmission of Pathogenic Variants Associated With Cerebral White Matter Disease

Hereditary white matter disease is a series of progressive genetic diseases that mainly affect the white matter of the central nervous system. The development of molecular genetics enables the clinical diagnosis, carrier detection, and prenatal diagnosis of hereditary white matter disease. Here, we block the transmission of pathogenic variants in ABCD1 and NOTCH3 in a family with cerebral white matter disease via preimplantation genetic testing (PGT). Pathogenic genes were identified based on clinical manifestations, genetic background, and the results of targeted gene capture sequencing. A blastocyst biopsy was performed, and multiple annealing and looping-based amplification (MALBAC), next-generation sequencing (NGS), and single nucleotide polymorphism (SNP) arrays were used to analyze ploidy and the state of the gene mutations. The proband (III:1) had hemizygous mutations in ABCD1 (c.323C>A (p.Ser108 *) and c.775C>T (p.Arg259Trp)) and heterozygous mutations in NOTCH3 (c.1630C>T (p.Arg544Cys)), which were maternally inherited (II:2). After genetic analysis, a euploid blastocyst without ABCD1 and NOTCH3 variations was transferred. A healthy male baby was born at full term, and the results of prenatal diagnosis by amniocentesis in the second trimester verified the results of PGT. To our knowledge, this is the first report of simultaneously blocking the transmission of pathogenic variants in ABCD1 and NOTCH3 via PGT. This report highlights the feasibility and effectiveness of PGT in preventing cerebral adrenoleukodystrophy (cALD) and cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) and provides valuable insights for the diagnosis and treatment of similar cases.

Emerging Role of ABC Transporters in Glia Cells in Health and Diseases of the Central Nervous System

ATP-binding cassette (ABC) transporters play a crucial role for the efflux of a wide range of substrates across different cellular membranes. In the central nervous system (CNS), ABC transporters have recently gathered significant attention due to their pivotal involvement in brain physiology and neurodegenerative disorders, such as Alzheimer's disease (AD). Glial cells are fundamental for normal CNS function and engage with several ABC transporters in different ways. Here, we specifically highlight ABC transporters involved in the maintenance of brain homeostasis and their implications in its metabolic regulation. We also show new aspects related to ABC transporter function found in less recognized diseases, such as Huntington's disease (HD) and experimental autoimmune encephalomyelitis (EAE), as a model for multiple sclerosis (MS). Understanding both their impact on the physiological regulation of the CNS and their roles in brain diseases holds promise for uncovering new therapeutic options. Further investigations and preclinical studies are warranted to elucidate the complex interplay between glial ABC transporters and physiological brain functions, potentially leading to effective therapeutic interventions also for rare CNS disorders.

Overview of drugs approved by the FDA in 2022

The aim of the work is to conduct a review of medications approved by the FDA in 2022.

Materials and methods. In searching for the materials to write this review article, bibliographic databases including PubMed, Google Scholar and e-library.ru were utilized. The search was conducted for the publications spanning the period from 2008 to 2023. Herewith, the following keywords and word combinations were used: new drug approval, NDA, drug authorization, approval package, breakthrough medicine.

Results. The discovery and development of medications are among the most crucial scientific processes in healthcare. Developing a new drug is a highly intricate, expensive, and time-consuming process. Nowadays, the problem of costs reduction and the process of expedited discovering of new medications are particularly pertinent. To optimize the search for active compounds, virtual and high-throughput screenings, machine learning, artificial intelligence, cryo-electron microscopy, and drug repurposing are employed. Simultaneously, the search for original molecules to serve as the basis for innovative drugs continues. This article presents a review of medications approved by the FDA in 2022 for the treatment of various pathologies.

Conclusion. A drug development is a complex and resource-intensive process, with only a small fraction of candidates advancing to clinical trials. A drug design evolves in tandem with societal needs, and this review highlights some of the medications approved by the FDA in 2022. Technological advancements are expected to expedite drug development, potentially reducing the time to the market. Biotechnology, including cell therapy, holds significant prospects, and achievements in genetic mapping and chip technologies will enhance the accessibility of personalized pharmacology.

Treatment of neurometabolic epilepsies: Overview and recent advances

The rarity and heterogeneity of neurometabolic diseases make it challenging to reach evidence-based principles for their specific treatments. Indeed, current treatments for many of these diseases remain symptomatic and supportive. However, an ongoing scientific and medical revolution has led to dramatic breakthroughs in molecular sciences and genetics, revealing precise pathophysiologic mechanisms. Accordingly, this has led to significant progress in the development of novel therapeutic approaches aimed at treating epilepsy resulting from these conditions, as well as their other manifestations. We overview recent notable treatment advancements, from vitamins, trace minerals, and diets to unique medications targeting the elemental pathophysiology at a molecular or cellular level, including enzyme replacement therapy, enzyme enhancing therapy, antisense oligonucleotide therapy, stem cell transplantation, and gene therapy.

Advantages and Limitations of Gene Therapy and Gene Editing for Friedreich's Ataxia

Friedreich's ataxia (FRDA) is an inherited, multisystemic disorder predominantly caused by GAA hyper expansion in intron 1 of frataxin (FXN) gene. This expansion mutation transcriptionally represses FXN, a mitochondrial protein that is required for iron metabolism and mitochondrial homeostasis, leading to neurodegerative and cardiac dysfunction. Current therapeutic options for FRDA are focused on improving mitochondrial function and increasing frataxin expression through pharmacological interventions but are not effective in delaying or preventing the neurodegeneration in clinical trials. Recent research on in vivo and ex vivo gene therapy methods in FRDA animal and cell models showcase its promise as a one-time therapy for FRDA. In this review, we provide an overview on the current and emerging prospects of gene therapy for FRDA, with specific focus on advantages of CRISPR/Cas9-mediated gene editing of FXN as a viable option to restore endogenous frataxin expression. We also assess the potential of ex vivo gene editing in hematopoietic stem and progenitor cells as a potential autologous transplantation therapeutic option and discuss its advantages in tackling FRDA-specific safety aspects for clinical translation.

The Role of Oxidative Stress and Inflammation in X-Link Adrenoleukodystrophy

X-linked adrenoleukodystrophy (X-ALD) is an inherited disease caused by a mutation in the ABCD1 gene encoding a peroxisomal transmembrane protein. It is characterized by the accumulation of very-long-chain fatty acids (VLCFAs) in body fluids and tissues, leading to progressive demyelination and adrenal insufficiency. ALD has various phenotypes, among which the most common and severe is childhood cerebral adrenoleukodystrophy (CCALD). The pathophysiological mechanisms of ALD remain unclear, but some in vitro/in vivo research showed that VLCFA could induce oxidative stress and inflammation, leading to damage. In addition, the evidence that oxidative stress and inflammation are increased in patients with X-ALD also proves that it is a potential mechanism of brain and adrenal damage. Therefore, normalizing the redox balance becomes a critical therapeutic target. This study focuses on the possible predictors of the severity and progression of X-ALD, the potential mechanisms of pathogenesis, and the promising targeted drugs involved in oxidative stress and inflammation.

Mitochondrial developmental encephalopathy with bilateral optic neuropathy related to homozygous variants in IMMT gene

IMMT gene codes for mitofilin, a mitochondrial inner membrane protein that regulates the morphology of mitochondrial cristae. The phenotype associated with mutations in this gene has not been yet established, but functional studies carried out show that its loss causes a mitochondrial alteration, both in the morphology of the mitochondrial crests and in their function. We present two cousins from an extended highly consanguineous family with developmental encephalopathy, hypotonia, nystagmus due to optic neuropathy. The likely pathogenic homozygous c.895A>G (p.Lys299Glu) variant in the IMMT gene co-segregates with the disease and associates altered mitochondrial cristae observed by electron microscopy.