Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C0025362 (
mental retardation
)
15,878
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
X-linked hereditary spastic paraplegias (HSP) present with two distinct phenotypes, pure and complicated. The pure form is characterized by spasticity and gait difficulties but lacks the additional features (nystagmus, dysarthria,
mental retardation
) present in the complicated form. The complicated form is heterogeneous, caused by mutations of the L1CAM gene at Xq28 (SPG1) or the PLP gene at Xq22 (SPG2) that is allelic to Pelizaeus-Merzbacher disease (PMD). Since in one kindred (K313) the pure form of HSP was also mapped to Xq22, this raises the issue as to whether a pure form of HSP exists that is allelic to X-linked complicated HSP (SPG2) and PMD. To answer this question, we carried out linkage analysis in a new pedigree with pure HSP (K101) and refined linkage in pedigree K313. The PLP gene was also screened for mutation by direct sequencing and reverse-transcriptase polymerase chain reaction (RT-PCR). In both families, the disease locus mapped to Xq22 with Lod scores at zero recombination of 5.3 for
COL4A5
2B6 in K313 and 2.4 for DXS101 in K101. A T to C transition in exon 5 of the PLP gene was identified from affected individuals of K313. This transition causes a Ser to Pro mutation in the major extracellular loop of PLP/DM20. This finding demonstrates that a form of X-linked pure spastic paraplegia, X-linked complicated HSP (SPG2) and PMD are allelic disorders. There was no evidence of mutations in either coding sequences or the intron/exon junctions of PLP in pedigree K101, suggesting that the disease-producing mutation may be in the noncoding portions of PLP or in a nearby gene.
...
PMID:Refined genetic mapping and proteolipid protein mutation analysis in X-linked pure hereditary spastic paraplegia. 878 Jan 1
We observed a family in which two boys were diagnosed with Alport syndrome, elliptocytosis, and
mental retardation
and carried a large deletion of the Xq22.3-q23 region, encompassing the
COL4A5
gene. This suggests the possibility of a new contiguous gene syndrome. In an attempt to characterize the genes contributing to this complex phenotype, we have isolated a gene encoding a new long-chain acyl-CoA synthetase (FACL4 or LACS4) from the region deleted in these patients. Among several ESTs identified by searching the human gene map database maintained at the National Center for Biotechnology Information, using the map position as a query, only one was deleted in the patients. RACE products containing the entire ORF were subsequently generated. Northern blot analysis showed a 5-kb mRNA expressed in several tissues except for liver and lung. Brain shows a longer transcript, possibly reflecting the use of a brain-specific upstream ATG start codon. FACL4 encodes a predicted protein product of 670 amino acids (711 in brain), with a remarkable level of conservation compared to the rat acyl-CoA synthetases ACS4 and brain-specific ACS3 protein sequences. We are investigating the possibility that the absence of this enzyme may play a role in the development of
mental retardation
or other signs associated with Alport syndrome in the family.
...
PMID:FACL4, a new gene encoding long-chain acyl-CoA synthetase 4, is deleted in a family with Alport syndrome, elliptocytosis, and mental retardation. 948 Jul 48
We describe a family with four members, a mother, two sons, and a daughter, who show clinical features consistent with X linked Alport syndrome. The two males presented with additional features including
mental retardation
, dysmorphic facies with marked midface hypoplasia, and elliptocytosis. The elliptocytosis was not associated with any detectable abnormalities in red cell membrane proteins; red cell membrane stability and rigidity was normal on ektacytometry. Molecular characterisation suggests a submicroscopic X chromosome deletion encompassing the entire
COL4A5
gene. We propose that the additional abnormalities found in the affected males of this family are attributable to deletion or disruption of X linked recessive genes adjacent to the
COL4A5
gene and that this constellation of findings may represent a new X linked contiguous gene deletion syndrome.
...
PMID:Alport syndrome, mental retardation, midface hypoplasia, and elliptocytosis: a new X linked contiguous gene deletion syndrome? 959 18
We recently described a novel contiguous gene deletion syndrome (AMME) in Xq22.3 that includes Alport syndrome (A),
mental retardation
(M), midface hypoplasia (M), and elliptocytosis (E). While the Alport syndrome is due to deletion of the
COL4A5
gene, no other genes are known in the region with the exception of our recent finding of the FACL4 gene. In our effort to isolate additional genes from the deleted region, we have identified the gene named AMMECR1 (Alport syndrome,
mental retardation
, midface hypoplasia, and elliptocytosis chromosomal region gene 1). RACE experiments and screening of cDNA libraries enabled us to obtain the entire ORF of the gene (1002 bp) followed by about 2 kb of 3'UTR. AMMECR1 is composed of six exons, shows a ubiquitous 6.5-kb transcript, and codes for a protein with a molecular mass of 35.5 kDa. Sequence analysis revealed that this gene is conserved in several species ranging from Caenorhabditis elegans and yeast to micro-organisms. Exon 2 of AMMECR1 encodes a domain consisting of six amino acids identically conserved throughout the course of evolution and whose function is as yet unknown. Analysis of the predicted protein product using ExPAsy tools raises the possibility that the gene may code for a regulatory factor potentially involved in the development of AMME contiguous gene deletion syndrome.
...
PMID:Identification and characterization of a highly conserved protein absent in the Alport syndrome (A), mental retardation (M), midface hypoplasia (M), and elliptocytosis (E) contiguous gene deletion syndrome (AMME). 1004 89
A map has been assembled that extends from the XY homology region in Xq21.3 to proximal Xq24, approximately 20 Mb, formatted with 200 STSs that include 25 dinucleotide repeat polymorphic markers and more than 80 expressed sequences including 30 genes. New genes HTRP5, CAPN6, STPK, 14-3-3PKR, and CALM1 and previously known genes including BTK, DDP, GLA, PLP,
COL4A5
, COL4A6, PAK3, and DCX are localized; candidate loci for other disorders for which genes have not yet been identified, including DFN-2, POF, megalocornea, and syndromic and nonsyndromic
mental retardation
, are also mapped in the region. The telomeric end of the contig overlaps a yeast artificial chromosome (YAC) contig from Xq24-q26 and with other previously published contigs provides complete sequence-tagged site (STS)/YAC-based coverage of the long arm of the X chromosome. The order of published landmark loci in genetic and radiation hybrid maps is in general agreement. Combined with high-density STS landmarks, the multiple YAC clone coverage and integrated genetic, radiation hybrid, and transcript map provide resources to further disease gene searches and sequencing.
...
PMID:Integrated STS/YAC physical, genetic, and transcript map of human Xq21.3 to q23/q24 (DXS1203-DXS1059). 1036 51
The contiguous gene deletion syndrome AMME is characterized by Alport syndrome, midface hypoplasia,
mental retardation
and elliptocytosis and is caused by a deletion in Xq22.3, comprising several genes including
COL4A5
, FACL4 and AMMECR1. We have now cloned the murine Facl4 and Ammecr1 genes and have mapped both novel murine genes to mouse chromosome X band F1-F3. The murine and human orthologs show 96.5% (FACL4) and 95.2% (AMMECR1) identity at the amino acid level, with conservation of the respective putative subcellular localization signals. Our results show that Facl4 and Ammecr1 are the true murine orthologs of the human genes. Furthermore, the mapping of Facl4 and Ammecr1 to MmuXF1-F3 suggests that this subinterval is orthologous, at least for a portion of Xq22. 3.
...
PMID:Identification and characterization of mouse orthologs of the AMMECR1 and FACL4 genes deleted in AMME syndrome: orthology of Xq22.3 and MmuXF1-F3. 1082 4
To investigate whether submicroscopic chromosomal deletions or duplications can be causative of unclear syndromic nephropathies, we analyzed ten patients with congenital abnormalities of the kidney and urinary tract or glomerulopathies combined with important extrarenal anomalies by whole-genome array-based comparative genomic hybridization. In a 14-year-old girl presenting with hematuria, proteinuria,
mental retardation
(MR), sensorineural hearing loss, dysmorphisms, and epilepsy, we detected a microdeletion in chromosome Xq22.3-q23. This deletion was verified and characterized by fluorescence in situ hybridization and multiplex ligation-dependent probe amplification analyses, found to be de novo, uniallelic and 3.3 Mb in size. Electron microscopy of a kidney biopsy showed glomerular basement membrane thinning and segmental splitting of the lamina densa compatible with Alport syndrome. Cranial magnetic resonance and diffusion tensor imaging detected a severe neuronal migration disorder with double cortex formation and pronounced reduction of the fronto-occipital tract system. Thus, in one of ten patients with unclear syndromic nephropathies we identified a previously undescribed contiguous gene syndrome at Xq22.3-q23. The microdeletion contains the X-linked Alport syndrome gene
COL4A5
, the MR genes FACL4 and PAK3, and parts of the X-chromosomal lissencephaly gene DCX associated with double cortex formation in girls, MR, and epilepsy. The phenotype in our patient combines features of the Alport-MR contiguous gene syndrome with lissencephaly.
...
PMID:Array-CGH in unclear syndromic nephropathies identifies a microdeletion in Xq22.3-q23. 1944 85
