ABSTRACT
Abstract Classical galactosemia is caused by the genetic deficiency of galactose-1-phosphate-urydyl-transferase resulting in clinical symptoms development during the first weeks of life including jaundice, hypotonia, lethargy, emesis, hepatomegaly, among others. Currently, dietary restriction of galactose is considered the standard for classical galactosemia management. For several years, severe dietary galactose restriction was considered necessary, implying restriction not only of dairy products, but also fruits, vegetables, legumes, and viscera. Such management failed to improve or prevent the appearance of long-term complications, by contrast, such restrictive approach may lead to nutritional deficiencies development. Thus, the last consensus suggests guidelines that are more flexible. In addition, the lack of knowledge regarding the physiopathology of the disease, and the toxicity threshold of the metabolites accumulated, make even more difficult to propose novel and more effective therapeutic approaches. This review summarizes the current state of knowledge regarding classical galactosemia in terms of physiopathology, long-term complications, newborn screening and genetic variants and their implications on galactosemia treatment, summed to the challenges that researchers working on this disease must address in future studies including the analysis of galactose content in foods, galactose tolerance threshold and search for novel therapeutic targets.
ABSTRACT
The utility of low-resolution 1H-NMR analysis for the identification of biomarkers provided evidence for rapid biochemical diagnoses of organic acidemia and aminoacidopathy. 1H-NMR, with a sensitivity expected for a field strength of 400 MHz at 64 scans was used to establish the metabolomic urine sample profiles of an infant population diagnosed with small molecule Inborn Errors of Metabolism (smIEM) compared to unaffected individuals. A qualitative differentiation of the 1H-NMR spectral profiles of urine samples obtained from individuals affected by different organic acidemias and aminoacidopathies was achieved in combination with GC-MS. The smIEM disorders investigated in this study included phenylalanine metabolism; isovaleric, propionic, 3-methylglutaconicm and glutaric type I acidemia; and deficiencies in medium chain acyl-coenzyme and holocarboxylase synthase. The observed metabolites were comparable and similar to those reported in the literature, as well as to those detected with higher-resolution NMR. In this study, diagnostic marker metabolites were identified for the smIEM disorders. In some cases, changes in metabolite profiles differentiated post-treatments and follow-ups while allowing for the establishment of different clinical states of a biochemical disorder. In addition, for the first time, a 1H-NMR-based biomarker profile was established for holocarboxylase synthase deficiency spectrum.
ABSTRACT
BACKGROUND: Mucopolysaccharidoses (MPS) are a group of inherited metabolic diseases caused by impaired function or absence of lysosomal enzymes involved in degradation of glycosaminoglycans. Clinically, MPS are skeletal dysplasias, characterized by cartilage abnormalities and disturbances in the process of endochondral ossification. Histologic abnormalities of growth cartilage have been reported at advanced stages of the disease, but information regarding growth plate pathology progression either in humans or in animal models, as well as its pathophysiology, is limited. METHODS: Histological analyses of distal femur growth plates of wild type (WT) and mucopolysaccharidosis type VI (MPS VI) rats at different stages of development were performed, including quantitative data. Experimental findings were then analyzed in a theoretical scenario. RESULTS: Histological evaluation showed a progressive loss of histological architecture within the growth plate. Furthermore, in silico simulation suggest the abnormal cell distribution in the tissue may lead to alterations in biochemical gradients, which may be one of the factors contributing to the growth plate abnormalities observed, highlighting aspects that must be the focus of future experimental works. CONCLUSION: The results presented shed some light on the progression of growth plate alterations observed in MPS VI and evidence the potentiality of combined theoretical and experimental approaches to better understand pathological scenarios, which is a necessary step to improve the search for novel therapeutic approaches.
ABSTRACT
Introducción. Los trastornos de la biogénesis de los peroxisomas se deben a mutaciones en los genes PEX, que codifican peroxinas requeridas para la biogénesis peroxisómica. Clínicamente se expresan como un espectro del síndrome de Zellweger, y hay una amplia variedad fenotípica. Su diagnóstico se realiza bioquímicamente y la confirmación es molecular. El objetivo de este caso ilustrativo es resaltar la importancia de la clínica y de las pruebas bioquímicas en el abordaje de una enfermedad peroxisómica. Caso clínico. Niño de 3 años con hipotonía neonatal, retraso global del desarrollo y fallo de medro, con un patrón en resonancia cerebral de leucodistrofia hipomielinizante, en quien se había sospechado un trastorno de la biogénesis de los peroxisomas por encontrarse una variante de significado incierto en PEX5, pero su clínica, los estudios bioquímicos y el análisis crítico de las pruebas moleculares hacían improbable este diagnóstico. Se hace énfasis en el abordaje que debería tenerse cuando se sospecha un trastorno del espectro del síndrome de Zellweger. Conclusión. En el caso descrito se sospechó un trastorno de la biogénesis de los peroxisomas por una secuenciación exómica que, al analizarse críticamente junto con la clínica y los hallazgos bioquímicos, hacía muy poco probable una enfermedad peroxisómica. Cuando se tiene sospecha clínica y por neuroimágenes, el abordaje diagnóstico principal debe partir del análisis bioquímico. Aunque la confirmación es molecular, estas pruebas deben interpretarse con precaución
Introduction. Peroxisomal biogenesis disorders are due to mutations in the PEX genes, which code for peroxins that are required for peroxisomal biogenesis. Clinically, they are expressed as a Zellweger syndrome spectrum, and there is a wide phenotypic variety. They are diagnosed biochemically, and confirmation is molecular. The aim of this illustrative case is to highlight the importance of the clinical features and biochemical testing in the management of a peroxisomal disease. Case report. A 3-year-old boy with neonatal hypotonia, overall developmental delay and failure to thrive and a pattern of hypomyelinating leukodystrophy in brain resonance. The suspected diagnosis was a disorder affecting the biogenesis of the peroxisomes due to having found a variant with an uncertain meaning in PEX5. The clinical features, the biochemical studies and critical analysis, however, made this diagnosis unlikely. Emphasis is placed on the management that must be applied when a Zellweger syndrome spectrum is suspected. Conclusion. In the case reported here, a peroxisomal biogenesis disorder was suspected owing to an exome sequencing which, on being critically analysed together with the clinical features and the biochemical findings, made a peroxisomal disease very unlikely. In cases of clinical suspicion, backed up by neuroimaging, the main diagnostic management must be based on the biochemistry analysis. Although confirmation is molecular, these tests must be interpreted with caution
