Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0025362 (mental retardation)
15,878 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We describe a three-generation family in which X-linked mental retardation (XLMR) is associated with minor facial anomalies and brachydactyly. Two brothers and four nephews have "coarse" facial appearance, brachydactyly with widening of the distal phalanges, short stature, and moderate mental retardation. The three obligate carrier women have normal intelligence and normal physical findings. The results of linkage analysis carried out in 1988 using restriction fragment length polymorphisms (RFLPs) were suggestive of linkage to DXYS1 and DXS101 in proximal Xq (Zmax = 1.63 at straight thetamax = 0.0) [Carpenter et al., 1988: Am J Med Genet 43:A139]. The family was restudied with 16 microsatellite loci from Xp11.4 through Xq24. Linkage analysis demonstrated significant linkage to DXS1003, ALAS2, AR, DXS986, DXS990, DXS454, DXS1106, DXS1105, and DXS1220 from Xp11.3 to Xq23 (Zmax = 2.53 at straight thetamax = 0.0). Recombinations detected between MAOB and DXS1055 and between DXS1220 and DXS1001 place the disease locus between Xp11.3 and Xq23. Among the genes known to map to this region is the XNP gene for the alpha-thalassemia/mental retardation syndrome (ATR-X). This fact, along with the phenotypic similarity between our patients and ATR-X males, led us to consider XNP as a candidate gene for this family. X-inactivation studies provided further evidence for the involvement of XNP by showing completely skewed X-inactivation patterns in the three obligate carrier females, a pattern characteristic of carriers of XNP mutations.
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PMID:X-linked mental retardation syndrome with characteristic "coarse" facial appearance, brachydactyly, and short stature maps to proximal Xq. 1039 34

We report the characterization of a new Caenorhabditis elegans gene, xnp-1, that encodes the closest known non-mammalian relative of the human XNP/ATR-X protein. Mutations in the corresponding gene lead to mental retardation in humans. The nematode gene is composed of 10 exons, and we show that a 4.3kb transcript is produced from the xnp-1 locus. The 1359 residue XNP-1 protein is 33.6% identical and 52.2% similar to the human XNP/ATR-X protein. In two regions of more than 250 amino acids, the proteins display 70% identity. The human and nematode proteins are putative DNA helicases and contain the seven characteristic domains of this family of proteins. In addition to the fact that similar proteins are encoded by the nematode and human gene, they share a partially identical genomic structure. These data indicate that xnp-1 and XNP/ATR-X have diverged from the same ancestral DNA helicase gene and may therefore have conserved similar functions at the cellular level.
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PMID:Characterization of xnp-1, a Caenorhabditis elegans gene similar to the human XNP/ATR-X gene. 1043 61

We have identified two females who are mosaic for an ATRX mutation. One case, in whom the mutation was undetectable in peripheral blood and buccal cells, has two affected sons and is therefore presumed to be a germline mosaic. In another case, the ATRX mutation is weakly detectable in the peripheral blood but only one of her three children who share the disease-associated haplotype carries the mutation and therefore it is concluded that she is a gonosomal mosaic. These cases provide the first molecular evidence for the occurrence of post-zygotic mutation in X-linked alpha thalassaemia mental retardation syndrome. The possibility of germline mosaicism must therefore be considered in the genetic counselling of ATR-X families.
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PMID:Germline and gonosomal mosaicism in the ATR-X syndrome. 1060 70

In the search for genetic causes of mental retardation, we have studied a five-generation family that includes 10 individuals in generations IV and V who are affected with mild-to-moderate mental retardation and mild, nonspecific dysmorphic features. The disease is inherited in a seemingly autosomal dominant fashion with reduced penetrance. The pedigree is unusual because of (1) its size and (2) the fact that individuals with the disease appear only in the last two generations, which is suggestive of anticipation. Standard clinical and laboratory screening protocols and extended cytogenetic analysis, including the use of high-resolution karyotyping and multiplex FISH (M-FISH), could not reveal the cause of the mental retardation. Therefore, a whole-genome scan was performed, by linkage analysis, with microsatellite markers. The phenotype was linked to chromosome 16p13.3, and, unexpectedly, a deletion of a part of 16pter was demonstrated in patients, similar to the deletion observed in patients with ATR-16 syndrome. Subsequent FISH analysis demonstrated that patients inherited a duplication of terminal 3q in addition to the deletion of 16p. FISH analysis of obligate carriers revealed that a balanced translocation between the terminal parts of 16p and 3q segregated in this family. This case reinforces the role of cryptic (cytogenetically invisible) subtelomeric translocations in mental retardation, which is estimated by others to be implicated in 5%-10% of cases.
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PMID:Familial mental retardation syndrome ATR-16 due to an inherited cryptic subtelomeric translocation, t(3;16)(q29;p13.3). 1063 Nov 33

Mutations in the X-encoded gene ATRX are known to give rise to profound syndromal mental retardation (MR). Here, we describe a pedigree, including 4 affected family members with a 324C-->T nonsense mutation in the ATRX gene. Although 2 patients have moderate to profound MR and the typical facial features of ATR-X syndrome, the other 2 patients presented with mild MR and epilepsy but without the characteristic facial dysmorphism. Mutations in the ATRX gene should be considered as a cause of mild MR in male patients lacking specific diagnostic features.
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PMID:A nonsense mutation of the ATRX gene causing mild mental retardation and epilepsy. 1063 11

SOX proteins are transcription factors that are characterized by a common DNA-binding motif known as the HMG domain. We describe the 5. 4-kb human SOX8 gene that codes for a 446-amino-acid protein and that is expressed strongly in brain and less abundantly in other tissues. SOX8 shows an overall identity of 47% to SOX9 and SOX10. The latter two possess a C-terminal transactivation domain, whereas in SOX8, this domain is located in the central part of the protein. We have mapped SOX8 within 700 kb of the telomeric repeats of band 16p13.3. Hemizygosity for 1 Mb from this region causes the ATR-16 syndrome characterized by alpha-thalassemia and mental retardation. We show that SOX8 is deleted in an ATR-16 patient, and from its location, we deduce that it should be deleted in all previously described cases. Thus, SOX8 is a good candidate gene contributing to the mental retardation phenotype seen in ATR-16 patients.
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PMID:The SOX8 gene is located within 700 kb of the tip of chromosome 16p and is deleted in a patient with ATR-16 syndrome. 1066 50

SOX proteins form a large family of transcription factors related by a DNA-binding domain known as the HMG box. Some 30 Sox genes have been identified in mammals and orthologues have been found in a wide range of other metazoans. Sox genes are highly conserved and are known to play important roles in embryonic development, including roles in gonadal, central nervous system, neural crest and skeletal development. Several SOX genes have been implicated in human congenital diseases. We report here the isolation of Sox8 and its characterisation in mice and humans. This gene has a remarkably similar primary structure and genomic organisation to the campomelic dysplasia gene SOX9 and the Waardenburg-Shah syndrome gene SOX10. SOX8 protein is able to bind to canonical SOX target DNA sequences and activate transcription in vitro through two separate trans -activation regions. Further, Sox8 is expressed in the central nervous system, limbs, kidneys, gonads and craniofacial structures during mouse embryo development. Sox8 maps to the t complex on mouse chromosome 17 and to human chromosome 16p13.3, a region associated with the microphthalmia-cataract syndrome CATM and the alpha-thalassemia/mental retardation syndrome ATR-16.
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PMID:Cloning and characterisation of the Sry-related transcription factor gene Sox8. 1068 44

Mutations in the ATRX gene are associated with an X-linked mental retardation (XLMR) syndrome most often accompanied by alpha-thalassaemia (ATR-X syndrome). The ATRX gene encodes a predicted protein of 280 kDa featuring a PHD zinc finger motif and an ATPase/helicase domain of the SWI/SNF type; the vast majority of mutations in the ATRX gene fall within these two motifs. Although these domains are suggestive of a role for ATRX in transcriptional regulation by affecting chromatin structure and/or function, the precise cellular role of the ATRX protein remains undefined. Using indirect immunofluorescence and biochemical fractionation, we demonstrate that the ATRX protein has a punctate nuclear staining pattern and that it is tightly associated with the nuclear matrix at interphase. At the onset of M phase, the ATRX protein was associated mainly with condensed chromatin. The association of the ATRX protein with chromosomes at mitosis is concomitant with phosphorylation of the protein and its association with heterochromatin protein 1alpha (HP1alpha). The phosphorylation-dependent changes in localization between the nuclear matrix and condensed chromatin are consistent with a dual role for ATRX, possibly involving gene regulation at interphase and chromosomal segregation at mitosis.
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PMID:Cell cycle-dependent phosphorylation of the ATRX protein correlates with changes in nuclear matrix and chromatin association. 1069 77

alpha-Thalassaemias are genetic defects extremely frequent in some populations and are characterized by the decrease or complete suppression of alpha-globin polypeptide chains. The gene cluster, which codes for and controls the production of these polypeptides, maps near the telomere of the short arm of chromosome 16, within a G + C rich and early-replicating DNA region. The genes expressed during the embryonic (zeta) or fetal and adult stage (alpha 2 and alpha 1) can be modified by point mutations which affect either the processing-translation of mRNA or make the polypeptide chains extremely unstable. Much more frequent are the deletions of variable size (from approximately 3 to more than 100 kb) which remove one or both alpha genes in cis or even the whole gene cluster. Deletions of a single gene are the result of unequal pairing during meiosis, followed by reciprocal recombination. These unequal cross-overs, which produce also alpha gene triplications and quadruplications, are made possible by the high degree of homology of the two alpha genes and of their flanking sequences. Other deletions involving one or more genes are due to recombinations which have taken place within non-homologous regions (illegitimate recombinations) or in DNA segments whose homology is limited to very short sequences. Particularly interesting are the deletions which eliminate large DNA areas 5' of zeta or of both alpha genes. These deletions do not include the structural genes but, nevertheless, suppress completely their expression. Larger deletions involving the tip of the short arm of chromosome 16 by truncation, interstitial deletions or translocations result in the contiguous gene syndrome ATR-16. In this complex syndrome alpha-thalassaemia is accompanied by mental retardation and variable dismorphic features. The study of mutations of the 5' upstream flanking region has led to the discovery of a DNA sequence, localized 40 kb upstream of the zeta-globin gene, which controls the expression of the alpha genes (alpha major regulatory element or HS-40). In the acquired variant of haemoglobin H (HbH) disease found in rare individuals with myelodysplastic disorders and in the X-linked mental retardation associated with alpha-thalassaemia, a profound reduction or absence of alpha gene expression has been observed, which is not accompanied by structural alterations of the coding or controlling regions of the alpha gene complex. Most probably the acquired alpha-thalassaemia is due to the lack of soluble activators (or presence of repressors) which act in trans and affect the expression of the homologous clusters and are coded by genes not (closely) linked to the alpha genes. The ATR-X syndrome results from mutations of the XH2 gene, located on the X chromosome (Xq13.3) and coding for a transacting factor which regulates gene expression. The interaction of the different alpha-thalassaemia determinants results in three phenotypes: the alpha-thalassaemic trait, clinically silent and presenting only limited alterations of haematological parameters, HbH disease, characterized by the development of a haemolytic anaemia of variable degree, and the (lethal) Hb Bart's hydrops fetalis syndrome. The diagnosis of alpha-thalassaemia due to deletions is implemented by the electrophoretic analysis of genomic DNA digested with restriction enzymes and hybridized with specific molecular probes. Recently polymerase chain reaction (PCR) based strategies have replaced the Southern blotting methodology. The straightforward identification of point mutations is carried out by the specific amplification of the alpha 2 or alpha 1 gene by PCR followed by the localization and identification of the mutation with a variety of screening systems (denaturing gradient gel electrophoresis (DGGE), single strand conformation polymorphisms (SSCP)) and direct sequencing.
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PMID:Alpha-thalassaemia. 1087 73

X-linked alpha-thalassemia/mental retardation syndrome (ATR-X) is one of the many known X-linked mental retardation syndromes. Mutations in the ATR-X gene (ATRX) that encodes a putative global transcription factor have been identified in patients with ATR-X as well as those with other forms of X-linked mental retardation syndrome. To better understand the genetic basis of ATR-X, we investigated nine patients with the ATR-X phenotype from eight independent Japanese families for mutations in ATRX. We identified seven missense mutations, including six novel mutations, all of which were located either in the N-terminal region corresponding to the putative zinc finger domain (N179S, P190L, V194I, and R246C) or in the C-terminal region corresponding to the helicase domain (V1552F, L1645S, and Y1847C). R246C was found in two independent patients. Furthermore, we investigated the origin of the mutations in seven mothers. Five mothers were found to be carriers, and two were not, indicating de novo origin of the mutations. When we compared clinical manifestations with respective mutations, we could not find apparent phenotype-genotype correlation. Therefore, the putative zinc finger domain and the helicase domains may have similar functional significance for the function of ATRX.
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PMID:Molecular genetic study of japanese patients with X-linked alpha-thalassemia/mental retardation syndrome (ATR-X). 1099 12


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