[Novel therapies in neurometabolic diseases: the importance of early intervention]. / Terapias novedosas en enfermedades neurometabolicas: importancia de una intervencion precoz.

INTRODUCTION: Individually, neurometabolic diseases are ultra rare, but for some of them there is an effective treatment. DEVELOPMENT: Several recent therapeutic advances are reviewed. Today, the possibilities of treatment for lysosomal diseases have improved. In recent years the use of enzyme replacement therapy has become more widely extended to treat mucopolysaccharidosis type IVA (Morquio A), mucopolysaccharidosis type VII (Sly syndrome), lysosomal acid lipase deficiency and alpha-mannosidosis. It has been proven that very early treatment of mucopolysaccharidoses can change their natural course. Intrathecal enzyme replacement therapy is being tried in some mucopolysaccharidoses with cognitive involvement, in an attempt to halt neurodegeneration. Very positive results have been obtained with genetically modified autotransplants in late-onset infantile metachromatic leukodystrophy and research is being conducted on other pathologies (mucopolysaccharidosis type III, X-linked adrenoleukodystrophy). Novel outcomes are also being achieved in the treatment of some encephalopathies that are sensitive to vitamins or cofactors: triple therapy in pyridoxine dependency, treatment with thiamine for some subacute encephalopathies with involvement of the basal ganglia, treatment with folinic acid for children with cerebral folate deficiency, or treatment with cyclic pyranopterin monophosphate in molybdenum cofactor deficiency type A. CONCLUSIONS: As neuropaediatricians we must update our knowledge, especially in the case of treatable neurometabolic pathologies, since early treatment can change their prognosis significantly.

TITLE: Terapias novedosas en enfermedades neurometabolicas: importancia de una intervencion precoz.Introduccion. Las enfermedades neurometabolicas son individualmente ultrarraras, pero algunas de ellas tienen un tratamiento eficaz. Desarrollo. Se revisan algunas novedades terapeuticas. Las enfermedades lisosomales tienen actualmente mejores posibilidades de tratamiento. En los ultimos años se ha extendido el uso de la terapia enzimatica sustitutiva a la mucopolisacaridosis tipo IVA (Morquio A), a la mucopolisacaridosis tipo VII (enfermedad de Sly), al deficit de lipasa acida lisosomal y a la alfa-manosidosis. Se ha constatado que un tratamiento muy precoz de las mucopolisacaridosis puede cambiar su historia natural. Se esta probando la terapia enzimatica sustitutiva intratecal en algunas mucopolisacaridosis con afectacion cognitiva, en el intento de frenar la neurodegeneracion. Se han obtenido resultados muy positivos con autotrasplante modificado geneticamente en leucodistrofia metacromatica infantil tardia y se esta trabajando en otras patologias (mucopolisacaridosis tipo III, adrenoleucodistrofia ligada a X). Tambien hay novedades en la terapia de algunas encefalopatias sensibles a vitaminas o cofactores: la triple terapia en la dependencia de piridoxina, el tratamiento con tiamina de algunas encefalopatias subagudas con afectacion de ganglios basales, el tratamiento con acido folinico de niños con deficiencia de folato cerebral, o el tratamiento con monofosfato de piranopterina ciclico en los defectos de cofactor de molibdeno de tipo A. Conclusiones. Los neuropediatras debemos actualizar nuestro conocimiento especialmente en aquellas patologias neurometabolicas tratables, dado que una terapia precoz puede cambiar de forma significativa su pronostico.

Neuronopathic lysosomal storage disorders: Approaches to treat the central nervous system.

Pharmacological research has always focused on developing new therapeutic strategies capable of modifying a disease's natural history and improving patients' quality of life. Despite recent advances within the fields of medicine and biology, some diseases still represent a major challenge for successful therapy. Neuronopathic lysosomal storage disorders, in particular, have high rates of morbidity and mortality and a devastating socio-economic effect. Many of the available therapies, such as enzyme replacement therapy, can reverse the natural history of the disease in peripheral organs but, unfortunately, are still unable to reach the central nervous system effectively because they cannot cross the blood-brain barrier that surrounds and protects the brain. Moreover, many lysosomal storage disorders are characterized by a number of blood-brain barrier dysfunctions, which may further contribute to disease neuropathology and accelerate neuronal cell death. These issues, and their context in the development of new therapeutic strategies, will be discussed in detail in this chapter.

Blood-brain barrier structure and function and the challenges for CNS drug delivery.

The neurons of the central nervous system (CNS) require precise control of their bathing microenvironment for optimal function, and an important element in this control is the blood-brain barrier (BBB). The BBB is formed by the endothelial cells lining the brain microvessels, under the inductive influence of neighbouring cell types within the 'neurovascular unit' (NVU) including astrocytes and pericytes. The endothelium forms the major interface between the blood and the CNS, and by a combination of low passive permeability and presence of specific transport systems, enzymes and receptors regulates molecular and cellular traffic across the barrier layer. A number of methods and models are available for examining BBB permeation in vivo and in vitro, and can give valuable information on the mechanisms by which therapeutic agents and constructs permeate, ways to optimize permeation, and implications for drug discovery, delivery and toxicity. For treating lysosomal storage diseases (LSDs), models can be included that mimic aspects of the disease, including genetically-modified animals, and in vitro models can be used to examine the effects of cells of the NVU on the BBB under pathological conditions. For testing CNS drug delivery, several in vitro models now provide reliable prediction of penetration of drugs including large molecules and artificial constructs with promising potential in treating LSDs. For many of these diseases it is still not clear how best to deliver appropriate drugs to the CNS, and a concerted approach using a variety of models and methods can give critical insights and indicate practical solutions.

Dietary modifications in patients receiving miglustat.

Weight loss and gastrointestinal disturbances are often seen during miglustat therapy for lysosomal storage diseases. A retrospective analysis of data from a mixed group of patients treated with miglustat at two UK centres was performed to evaluate the effect of two different dietary interventions on body weight and gastrointestinal tolerability during the initial 6 months of miglustat therapy. Neurological outcomes in these patients are not discussed herein. Data were analysed from a total of 29 patients with varied neurolipidoses (21 children/adolescents; 8 adults). Negative mean changes in body weight were seen in children/adolescents on an unmodified diet (-8.1%), and in adults (-4.1%) and children/adolescents (-5.2%) on a low-lactose diet. Patients on the low-disaccharide diet showed a positive mean change in body weight (+2.0%), although there was high variability in this group. Non-parametric sub-analysis of median body-weight change in children/adolescents also showed high variability both within and between diet groups, with no statistically significant difference between the effects of different diets on body weight (p = 0.062). The low-lactose diet reduced gastrointestinal disturbances; single small doses of loperamide were required in some patients. Patients on the low-disaccharide diet showed the lowest frequency of gastrointestinal effects. In conclusion, simple dietary modifications allowed the maintenance of body-weight gain in line with normal growth potential during miglustat therapy in young patients with lysosomal storage diseases, and reduced gastrointestinal disturbances.

ER and oxidative stresses are common mediators of apoptosis in both neurodegenerative and non-neurodegenerative lysosomal storage disorders and are alleviated by chemical chaperones.

It is estimated that more than 40 different lysosomal storage disorders (LSDs) cumulatively affect one in 5000 live births, and in the majority of the LSDs, neurodegeneration is a prominent feature. Neuronal ceroid lipofuscinoses (NCLs), as a group, represent one of the most common (one in 12,500 births) neurodegenerative LSDs. The infantile NCL (INCL) is the most devastating neurodegenerative LSD, which is caused by inactivating mutations in the palmitoyl-protein thioesterase-1 (PPT1) gene. We previously reported that neuronal death by apoptosis in INCL, and in the PPT1-knockout (PPT1-KO) mice that mimic INCL, is at least in part caused by endoplasmic reticulum (ER) and oxidative stresses. In the present study, we sought to determine whether ER and oxidative stresses are unique manifestations of INCL or they are common to both neurodegenerative and non-neurodegenerative LSDs. Unexpectedly, we found that ER and oxidative stresses are common manifestations in cells from both neurodegenerative and non-neurodegenerative LSDs. Moreover, all LSD cells studied show extraordinary sensitivity to brefeldin-A-induced apoptosis, which suggests pre-existing ER stress conditions. Further, we uncovered that chemical disruption of lysosomal homeostasis in normal cells causes ER stress, suggesting a cross-talk between the lysosomes and the ER. Most importantly, we found that chemical chaperones that alleviate ER and oxidative stresses are also cytoprotective in all forms of LSDs studied. We propose that ER and oxidative stresses are common mediators of apoptosis in both neurodegenerative and non-neurodegenerative LSDs and suggest that the beneficial effects of chemical/pharmacological chaperones are exerted, at least in part, by alleviating these stress conditions.