Hemizygosity of delta-catenin (CTNND2) is associated with severe mental retardation in cri-du-chat syndrome

Delta-catenin is an adherens junction protein involved in cell motility and expressed early in neuronal development. It was discovered as an interactor with presenilin-1. The genomic structure of the human delta-catenin gene (Human Gene Nomenclature Committee-approved symbol CTNND2) was determined and mapped to 5p15.2. A deletion of this chromosomal region has been associated with the cri-du-chat syndrome (CDCS), a segmental aneusomy syndrome of 5p that is associated with an unusual high-pitched cry at birth, facial dysmorphology, poor growth, and severe mental retardation. delta-catenin maps to a specific region in 5p15.2 that has been implicated in the mental retardation phenotype. The breakpoints in patients with 5p terminal deletions were characterized with respect to the severity of mental retardation and the physical location of the delta-catenin gene. A strong correlation was found between the hemizygous loss of delta-catenin and severe mental retardation. These findings and the properties of delta-catenin as a neuronal-specific protein, expressed early in development and involved in cell motility, support its role in the mental retardation of CDCS when present in only one copy.     

Determination of the gene structure of human oligophrenin-1 and identification of three novel polymorphisms by screening of DNA from 164 patients with non-specific X-linked mental retardation

We have recently shown that mutations in oligophrenin-1 (OPHN1) are responsible for non-specific X-linked mental retardation (MRX). The structure of the gene encoding the OPHN1 protein was determined by isolation of genomic DNA clones from the human cosmid library. Genomic fragments containing exons were sequenced, and the sequences of the exons and flanking introns were defined. Knowledge of the genomic structure of the OPHN1 gene, which spans at least 500 kb and consists of 25 exons, will facilitate the search for additional mutations in OPHN1. OPHN1 was screened for mutations in 164 subjects with non-specific mental retardation. Three nucleotide substitutions were identified, one of which was a silent mutation in the codon threonine 301 at position 903 (G-->C). The other substitutions were located in exon 2, a G-->A substitution at position 133 (A45T), and in exon 10, a C-->T substitution at position 902 (T301M), but these are common polymorphisms rather than disease-causing mutations.     

The potassium channel gene HK1 maps to human chromosome 11p14.1, close to the FSHB gene

Transiently activating (A-type) potassium (K) channels are important regulators of action potential and action potential firing frequencies. HK1 designates the first human cDNA that is highly homologous to the rat RCK4 cDNA that codes for an A-type K-channel. The HK1 channel is expressed in heart. By somatic cell hybrid analysis, the HK1 gene has been assigned to human chromosome 11p13-p14, the WAGR deletion region (Wilms tumor, aniridia, genito-urinary abnormalities and mental retardation). Subsequent pulsed field gel (PFG) analysis and comparison with the well-established PFG map of this region localized the gene to 11p14, 200–600kb telomeric to the FSHB gene.     

Cloning and Mapping of the cDNA for Human Sarcosine Dehydrogenase, a Flavoenzyme Defective in Patients with Sarcosinemia

Sarcosine dehydrogenase is a liver mitochondrial matrix flavoenzyme that is defective in patients with sarcosinemia, a rare autosomal metabolic defect characterized by elevated levels of sarcosine in blood and urine. Some patients also exhibit mental retardation and growth failure. A full-length cDNA for human sarcosine dehydrogenase was isolated from an adult liver cDNA library. The first 22 residues in the deduced amino acid sequence exhibit features expected for a mitochondrial targeting sequence. The predicted mass of the mature human liver sarcosine dehydrogenase (99,505 Da) is in good agreement with that observed for rat liver sarcosine dehydrogenase ( approximately 100,000 Da). Human sarcosine dehydrogenase exhibits 89% identity with rat liver sarcosine dehydrogenase and strong homology ( approximately 35% identity) with rat liver dimethylglycine dehydrogenase, a sarcosine dehydrogenase-related protein from Rhodobacter capsulatus, and the regulatory subunit from bovine pyruvate dehydrogenase phosphatase. The human sarcosine dehydrogenase gene is at least 75.3 kb long and located on chromosome 9q34. The adult human liver clone is assembled from 21 exons (1-6, 7a, 8a, 9-21). Two smaller cDNA clones, isolated from adult liver and infant brain libraries, were assembled from the same sarcosine dehydrogenase gene by the use of alternate polyadenylation and splice sites. This is the first report of the genomic structure of the sarcosine dehydrogenase gene in any species. The observed chromosomal location is consistent with genetic studies with a mouse model for sarcosinemia that map the mouse gene to a region of mouse chromosome 2 syntenic with human 9q33-q34. The availability of the SDH gene sequence will enable characterization of the genotypes of sarcosinemia patients with different phenotypes.     

Dedicator of cytokinesis 8 is disrupted in two patients with mental retardation and developmental disabilities

We have identified disruptions in the dedicator of cytokinesis 8 gene, DOCK8, in two unrelated patients with mental retardation (MR). In one patient, a male with MR and no speech, we mapped a genomic deletion of approximately 230 kb in subtelomeric 9p. In the second patient, a female with mental retardation and ectodermal dysplasia and a balanced translocation, t(X;9) (q13.1;p24), we mapped the 9p24 breakpoint to a region overlapping with the centromeric end of the 230-kb subtelomeric deletion. We characterized the DOCK8 gene from the critical 9p deletion region and determined that the longest isoform of the DOCK8 gene is truncated in both patients. Furthermore, the DOCK8 gene is expressed in several human tissues, including adult and fetal brain. Recently, a role for DOCK8 in processes that affect the organization of filamentous actin has been suggested. Several genes influencing the actin cytoskeleton have been implicated in human cognitive function and thus a possibility exists that the rare mutations in the DOCK8 gene may contribute to some cases of autosomal dominant mental retardation.     

Small Deletions of SATB2 Cause Some of the Clinical Features of the 2q33.1 Microdeletion Syndrome

Recurrent deletions of 2q32q33 have recently been reported as a new microdeletion syndrome. Clinical features of this syndrome include severe mental retardation, growth retardation, dysmorphic features, thin and sparse hair, feeding difficulties and cleft or high palate. The commonly deleted region contains at least seven genes. Haploinsufficiency of one of these genes, SATB2, a DNA-binding protein that regulates gene expression, has been implicated as causative in the cleft or high palate of individuals with 2q32q33 microdeletion syndrome. In this study we describe three individuals with smaller microdeletions of this region, within 2q33.1. The deletions ranged in size from 173.1 kb to 185.2 kb and spanned part of SATB2. Review of clinical records showed similar clinical features among these individuals, including severe developmental delay and tooth abnormalities. Two of the individuals had behavioral problems. Only one of the subjects presented here had a cleft palate, suggesting reduced penetrance for this feature. Our results suggest that deletion of SATB2 is responsible for several of the clinical features associated with 2q32q33 microdeletion syndrome.     

CGG-repeat expansion in the DIP2B gene is associated with the fragile site FRA12A on chromosome 12q13.1

A high level of cytogenetic expression of the rare folate-sensitive fragile site FRA12A is significantly associated with mental retardation. Here, we identify an elongated polymorphic CGG repeat as the molecular basis of FRA12A. This repeat is in the 5' untranslated region of the gene DIP2B, which encodes a protein with a DMAP1-binding domain, which suggests a role in DNA methylation machinery. DIP2B mRNA levels were halved in two subjects with FRA12A with mental retardation in whom the repeat expansion was methylated. In two individuals without mental retardation but with an expanded and methylated repeat, DIP2B expression was reduced to approximately two-thirds of the values observed in controls. Interestingly, a carrier of an unmethylated CGG-repeat expansion showed increased levels of DIP2B mRNA, which suggests that the repeat elongation increases gene expression, as previously described for the fragile X-associated tremor/ataxia syndrome. These data suggest that deficiency of DIP2B, a brain-expressed gene, may mediate the neurocognitive problems associated with FRA12A.     

The fragile X syndromes

Fragile X syndrome is a leading cause of mental retardation worldwide, with an incidence of approximately one case in 2000 live births. It is amongst the most common of human genetic diseases, and was the first to be associated with an unstable trinucleotide (CGG) repeat sequence. It is also characterized by a chromosomal fragile site which was the first of (now) four such sites to be identified at the molecular level. Each shows very similar features suggesting that other representatives of this type of fragile site will likely involve similar sequences. As with the other unstable trinucleotide repeats, the sequence at the fragile X locus is found to be remarkably unstable upon genetic transmission, however many features differ from the other repeats. As repeat expansion at the fragile X locus results in loss of expression of the co-resident FMR1 gene, the basis for clinical features is best understood in this disorder. Two additional fragile sites in the vicinity have been identified, and at least one of these is associated with mental retardation.     

A member of a gene family on Xp22.3, VCX-A, is deleted in patients with X-linked nonspecific mental retardation

X-linked nonspecific mental retardation (MRX) has a frequency of 0.15% in the male population and is caused by defects in several different genes on the human X chromosome. Genotype-phenotype correlations in male patients with a partial nullisomy of the X chromosome have suggested that at least one locus involved in MRX is on Xp22.3. Previous deletion mapping has shown that this gene resides between markers DXS1060 and DXS1139, a region encompassing approximately 1.5 Mb of DNA. Analyzing the DNA of 15 males with Xp deletions, we were able to narrow this MRX critical interval to approximately 15 kb of DNA. Only one gene, VCX-A (variably charged, X chromosome mRNA on CRI-S232A), was shown to reside in this interval. Because of a variable number of tandem 30-bp repeats in the VCX-A gene, the size of the predicted protein is 186-226 amino acids. VCX-A belongs to a gene family containing at least four nearly identical paralogues on Xp22.3 (VCX-A, -B, -B1, and -C) and two on Yq11.2 (VCY-D, VCY-E), suggesting that the X and Y copies were created by duplication events. We have found that VCX-A is retained in all patients with normal intelligence and is deleted in all patients with mental retardation. There is no correlation between the presence or absence of VCX-B1, -B, and VCX-C and mental status in our patients. These results suggest that VCX-A is sufficient to maintain normal mental development.     

Genomic organization of the human gamma adducin gene

We report the genomic structure of the human gamma adducin gene (ADD3). Adducin is a protein involved in cytoskeletal assembly and composed of alpha-beta or alpha-gamma subunits which share a high degree of homology between human and rat. Mutations in alpha subunit have been shown associated to both human and rat hypertension. The human ADD3 gene spans over 20 kb and is composed of at least 13 introns and 14 exons covering the entire coding region. The exon size ranges from 81 bp to greater than 293 bp and the intron size from 111 bp to longer than 3.2 kb. We also demonstrate the presence of an alternative splicing event around exon 13, whose sequence, position, and expression is analogous in rat Add3 gene. Moreover, human ADD3 amino acid sequence presents 91.9% of identity compared to rat sequence. Characterization of human ADD3 gene provides an important tool for mutation analysis.     

A patient with an interstitial deletion in Xp22.3 locates the gene for X-linked recessive chondrodysplasia punctata to within a one megabase interval

A male patient carrying an interstitial deletion in Xp22.3 and affected by Kallmann syndrome, X-linked ichthyosis and mental retardation, but without chondrodysplasia punctata or short stature, was investigated with molecular probes from the distal Xp22.3 region. By means of a novel probe, M115, from the relevant region, the distal deletion breakpoint was shown to be between 3.18 and 3.57 Mb from Xptel. As the patient is not affected by X-linked recessive chondrodysplasia punctata, the gene for this disease can therefore be located to within an interval of less than one megabase proximal to the pseudoautosomal boundary. If the chondrodysplasia punctata gene is associated with a CpG island, this leaves only two islands at 2760 and 3180 kb from the Xp telomere as the most promising candidate sites for this gene.     

Structure and myofiber-specific expression of the rat muscle regulatory gene MRF4.

We have cloned an 11.3-kb rat genomic DNA fragment encompassing the muscle regulatory factor 4 (MRF4) protein-coding sequence, 8.5 kb of 5'-flanking sequence, and 1.0 kb of 3'-flanking sequence. In order to study MRF4 gene expression, the rat myogenic cell line, L6J1-C, which expresses the endogenous MRF4 gene only in differentiated myofibers, was transfected stably with the full-length genomic clone and various 5' deletions. RNase protection assays demonstrated that MRF4 genes containing as little as 430 bp of 5'-flanking sequence exhibited an increase in expression as the cells differentiated into myofibers, indicating that elements responsible for fiber-specific expression are contained within this cloned DNA fragment. Similar up-regulation was observed with genes containing 1.5 kb of 5'-flanking sequence. Interestingly, MRF4 genes containing 5.0 kb and 8.5 kb of 5'-flanking sequence were up-regulated to even higher levels, suggesting that additional myofiber-specific regulatory elements located between 1.5 and 5.0 kb upstream from the coding region play a role in regulating the expression of this muscle-specific gene.