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Non-syndromic Mental Retardation (non-syndromic + mental_retardation)

Distribution by Scientific Domains
Life Sciences80%

Selected Abstracts

The four mammalian splice variants encoded by the p21-activated kinase 3 gene have different biological properties

JOURNAL OF NEUROCHEMISTRY, Issue 3 2008
Patricia Kreis
Abstract The p21-activated kinases (PAK1), PAK2, and PAK3 are members of the PAK group I and share high sequence identity and common biochemical properties. PAK3 is specifically implicated in neuronal plasticity and also regulates cell cycle progression, neuronal migration, and apoptosis. Loss of function of PAK3 is responsible for X-linked non-syndromic mental retardation whereas gain of PAK3 function is associated with cancer. To understand the functional specificities of PAK3, we analyzed the structure of PAK3 gene products. We report here the characterization of a new alternatively spliced exon called c located upstream of the previously identified exon b. Exon b is detected in all tetrapods and not in fish, exon c is only present in mammals. Mammalian PAK3 genes encode four splice variants and the corresponding proteins were detected with specific antibodies in brain extracts. All PAK3 transcripts are specifically expressed in brain and in particular in neurons. The presence of the exons b and c renders the kinase constitutively active and decreases interaction with GTPases. The expression of the new splice variants in COS7 cells alters cell morphology and modifies the structure of focal adhesions. We propose that the appearance of new alternatively spliced exons during evolution and the resulting increase of complexity of PAK3 gene products may confer new functions to this kinase and contribute to its specific roles in neuronal signaling. [source]

Nonsyndromic mental retardation and cryptogenic epilepsy in women with Doublecortin gene mutations

ANNALS OF NEUROLOGY, Issue 1 2003
Renzo Guerrini MD
DCX mutations cause mental retardation in male subjects with lissencephalypachygyria and in female subjects with subcortical band heterotopia (SBH). We observed four families in which carrier women had normal brain magnetic resonance imaging (MRI) and mild mental retardation, with or without epilepsy. Affected male subjects had SBH or pachygyria-SBH. In two families, the phenotype was mild in both genders. In the first family, we found a tyr138his mutation that is predicted to result in abnormal folding in the small hinge region. In the second family, we found an arg178cys mutation at the initial portion of R2, in the putative ,-sheet structure. Carrier female subjects with normal MRI showed no somatic mosaicism or altered X-inactivation in lymphocytes, suggesting a correlation between mild mutations and phenotypes. In the two other families, with severely affected boys, we found arg76ser and arg56gly mutations within the R1 region that are predicted to affect DCX folding, severely modifying its activity. Both carrier mothers showed skewed X-inactivation, possibly explaining their mild phenotypes. Missense DCX mutations may manifest as non-syndromic mental retardation with cryptogenic epilepsy in female subjects and SBH in boys. Mutation analysis in mothers of affected children is mandatory, even when brain MRI is normal. Ann Neurol 2003 [source]

De novo duplication of MECP2 in a girl with mental retardation and no obvious dysmorphic features

CLINICAL GENETICS, Issue 2 2010
P Makrythanasis
Makrythanasis P, Moix I, Gimelli S, Fluss J, Aliferis K, Antonarakis SE, Morris MA, Béna F, Bottani A. De novo duplication of MECP2 in a girl with mental retardation and no obvious dysmorphic features. Loss-of-function mutations of MECP2 are responsible for Rett syndrome (RTT), an X-linked neurodevelopmental disorder affecting mainly girls. The availability of MECP2 testing has led to the identification of such mutations in girls with atypical RTT features and the recognition of milder forms. Furthermore, duplication of the entire gene has recently been described in boys with mental retardation and recurrent infections. We describe a girl with a heterozygous de novo MECP2 duplication. The patient, at the age of 19, has mental retardation with no autistic features. She is friendly but gets frequently anxious. She has neither dysmorphic features nor malformations. Her motor development was delayed with walking at 20 months. Speech is fluid with good pronunciation but is simple and repetitive. Diagnosis was made after single-strand conformation analysis (SSCA) and multiplex ligation-dependent probe amplification (MLPA) analysis of MECP2. Array comparative genomic hybridization (aCGH) analysis showed a duplication of 29 kb including MECP2 and part of IRAK1. Fluorescent in situ hybridization (FISH) has revealed that the duplicated region is inserted near the telomere of the short arm of chromosome 10. X-chromosome inactivation in leukocyte DNA was not skewed. We conclude that it is likely that this MECP2 duplication is responsible for the mental retardation in this patient. This case broadens the phenotypic spectrum of MECP2 abnormalities with consequent implication in diagnosis and genetic counselling of girls with non-syndromic mental retardation. [source]

Genetics of autosomal recessive non-syndromic mental retardation: recent advances

CLINICAL GENETICS, Issue 3 2007
L Basel-Vanagaite
The identification of the genes mutated in autosomal recessive non-syndromic mental retardation (ARNSMR) has been very active recently. This report presents an overview of the current knowledge on clinical data in ARNSMR and progress in research. To date, 12 ARNSMR loci have been mapped, and three genes identified. Mutations in known ARNSMR genes have been detected so far in only a small number of families; their contribution to mental retardation in the general population might be limited. The ARNSMR-causing genes belong to different protein families, including serine proteases, Adenosine 5,-triphosphate-dependent Lon proteases and calcium-regulated transcriptional repressors. All of the mutations in the ARNSMR-causing genes are protein truncating, indicating a putative severe loss-of-function effect. The future objective will be the development of diagnostic kits for molecular diagnosis in mentally retarded individuals in order to offer at-risk families pre-natal diagnosis to detect affected offspring. [source]