Alba Tristán-Noguero scite author profile

Autism is a severe neurodevelopmental disorder, the aetiology of which remains mainly unknown. Family and twin studies provide strong evidence that genetic factors have a major role in the aetiology of this disease. Recently, whole exome sequencing (WES) efforts have focused mainly on rare de novo variants in singleton families. Although these studies have provided pioneering insights, de novo variants probably explain only a small proportion of the autism risk variance. In this study, we performed exome sequencing of 10 autism multiplex families with the aim of investigating the role of rare variants that are coinherited in the affected sibs. The pool of variants selected in our study is enriched with genes involved in neuronal functions or previously reported in psychiatric disorders, as shown by Gene Ontology analysis and by browsing the Neurocarta database. Our data suggest that rare truncating heterozygous variants have a predominant role in the aetiology of autism. Using a multiple linear regression model, we found that the burden of truncating mutations correlates with a lower non-verbal intelligence quotient (NVIQ). Also, the number of truncating mutations that were transmitted to the affected sibs was significantly higher (twofold) than those not transmitted. Protein-protein interaction analysis performed with our list of mutated genes revealed that the postsynaptic YWHAZ is the most interconnected node of the network. Among the genes found disrupted in our study, there is evidence suggesting that YWHAZ and also the X-linked DRP2 may be considered as novel autism candidate genes.

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Diseases of the Synaptic Vesicle: A Potential New Group of Neurometabolic Disorders Affecting Neurotransmission

Cortès‐Saladelafont

Tristán-Noguero

Artuch

et al. 2016

Seminars in Pediatric Neurology

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Synaptic metabolism: a new approach to inborn errors of neurotransmission

Tristán-Noguero¹,

García‐Cazorla²

2018

J of Inher Metab Disea

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To date, inborn errors of neurotransmitters have been defined based on the classic concept of inborn error of metabolism (IEM), and they include defects in synthesis, catabolism, and transport pathways. However, the omics era is bringing insights into new diseases and is leading to an extended definition of IEM including new categories and mechanisms. Neurotransmission takes place at the synapse, the most specialized tight junction in the brain. The concept of "synaptic metabolism" would point to the specific chemical composition and metabolic functions of the synapse. Based on these specialized functions, we aim to provide a tentative overview about the major categories of IEM susceptible to affect neurotransmission. Small molecule defects (biogenic amines and amino acids) and energy defects are amongst the most prevalent diseases reported to disturb the concentration of CSF neurotransmitters. In these IEM, the neurological phenotypes have been largely described. Disorders of complex molecules are not typically considered as diseases affecting neurotransmission. However, most of them have been recently discovered and are involved in intracellular vesiculation, trafficking, processing, and quality control mechanisms. In this large group, neurotransmission is affected in disorders of chaperones and autophagy, disorders of the synaptic vesicle, and diseases affecting pre-synaptic membranes (synthesis and remodeling of complex lipids, defects of glycosylation). Disorders of the vesicle pools, receptor trafficking, and the chronobiology of neurotransmission are potentially emerging new categories. Finally, although not considered as IEM, channelopathies are a large group of diseases disturbing neurotransmitter homeostasis. New CSF biomarkers will probably contribute to improve the diagnosis of these disorders and find new therapeutic targets.

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Study of a fetal brain affected by a severe form of tyrosine hydroxylase deficiency, a rare cause of early parkinsonism

et al. 2015

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Tyrosine hydroxylase (TH) deficiency is an inborn error of dopamine synthesis. Two clinical phenotypes have been described. The THD "B" phenotype produces a severe encephalopathy of early-onset with sub-optimal L-Dopa response, whereas the "A" phenotype has a better L-Dopa response and outcome. The objective of the study is to describe the expression of key synaptic proteins and neurodevelopmental markers in a fetal brain of THD "B" phenotype. The brain of a 16-week-old miscarried human fetus was dissected in different brain areas and frozen until the analysis. TH gene study revealed the p.R328W/p.T399M mutations, the same mutations that produced a B phenotype in her sister. After protein extraction, western blot analyses were performed to assess protein expression. The results were compared to an age-matched control. We observed a decreased expression in TH and in other dopaminergic proteins, such as VMAT 1 and 2 and dopamine receptors, especially D2DR. GABAergic and glutamatergic proteins such as GABA VT, NMDAR1 and calbindin were also altered. Developmental markers for synapses, axons and dendrites were decreased whereas markers of neuronal volume were preserved. Although this is an isolated case, this brain sample is unique and corresponds to the first reported study of a THD brain. It provides interesting information about the influence of dopamine as a regulator of other neurotransmitter systems, brain development and movement disorders with origin at the embryological state. This study could also contribute to a better understanding of the pathophysiology of THD at early fetal stages.

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