MECP2 mutation in male patients with non-specific X-linked mental retardation

In contrast to the preponderance of affected males in families with X-linked mental retardation, Rett syndrome (RTT) is a neurological disorder occurring almost exclusively in females. The near complete absence of affected males in RTT families has been explained by the lethal effect of an X-linked gene mutation in hemizygous affected males. We report here on a novel mutation (A140V) in the MECP2 gene detected in one female with mild mental retardation. In a family study, the A140V mutation was found to segregate in the affected daughter and in four adult sons with severe mental retardation. These results indicate that MECP2 mutations are not necessarily lethal in males and that they can be causative of non-specific X-linked mental retardation.     

Renpenning syndrome maps to Xp11.

Mutations in genes on the X chromosome are believed to be responsible for the excess of males among individuals with mental retardation. Such genes are numerous, certainly >100, and cause both syndromal and nonsyndromal types of mental retardation. Clinical and molecular studies have been conducted on the Mennonite family with X-linked mental retardation (XLMR) reported, in 1962, by Renpenning et al. The clinical phenotype includes severe mental retardation, microcephaly, up-slanting palpebral fissures, small testes, and stature shorter than that of nonaffected males. Major malformations, neuromuscular abnormalities, and behavioral disturbances were not seen. Longevity is not impaired. Carrier females do not show heterozygote manifestations. The syndrome maps to Xp11.2-p11.4, with a maximum LOD score of 3.21 (recombination fraction 0) for markers between DXS1039 and DXS1068. Renpenning syndrome (also known as "MRXS8"; gene RENS1, MIM 309500) shares phenotypic manifestations with several other XLMR syndromes, notably the Sutherland-Haan syndrome. In none of these entities has the responsible gene been isolated; hence, the possibility that two or more of them may be allelic cannot be excluded at present.     

Allan-Herndon syndrome. I. Clinical studies.

A large family with X-linked mental retardation, originally reported in 1944 by Allan, Herndon, and Dudley, has been reinvestigated. Twenty-nine males have been affected in seven generations. Clinical features include severe mental retardation, dysarthria, ataxia, athetoid movements, muscle hypoplasia, and spastic paraplegia with hyperreflexia, clonus, and Babinski reflexes. The facies appear elongated with normal head circumference, bitemporal narrowing, and large, simple ears. Contractures develop at both small and large joint. Statural growth is normal and macroorchidism does not occur. Longevity is not impaired. High-resolution chromosomes, serum creatine kinase, and amino acids are normal. This condition, termed the Allan-Herndon syndrome, appears distinct from other X-linked disorders having mental retardation, muscle hypoplasia, and spastic paraplegia.     

Monogenic causes of X-linked mental retardation

Mutations in X-linked genes are likely to account for the observation that more males than females are affected by mental retardation. Causative mutations have recently been identified in both syndromic X-linked mental retardation (XLMR) and in the genetically heterogeneous 'nonspecific' forms of XLMR, for which cognitive impairment is the only defining clinical feature. Proteins that function in chromatin remodelling are affected in three important syndromic forms of XLMR. In nonspecific forms of the disorder, defects have been found in signal-transduction pathways that are believed to function during neuronal maturation. These findings provide important insights into the molecular and cellular defects that underlie mental retardation.     

Further delineation of X-linked mental retardation

Summary Chromosomal, clinical, and psychological data are presented on members of six families with X-linked mental retardation. Affected males in three of these families express the fra(X)(q28) marker, while the retarded males in the other three do not. Similar variable physical and psychological charateristics, such as lop ears, large testes, and perseverative speech, are present in affected males in all six families. Preliminary analysis of the psychological data also shows that males with and without marker expression cannot be differentiated with certainty. On this basis we suggest that there is a type of X-linked mental retardation with many phenotypic features of marker-X mental retardation but without expression of the X chromosome fragile site.     

A mutation in the rett syndrome gene, MECP2, causes X-linked mental retardation and progressive spasticity in males

Heterozygous mutations in the X-linked MECP2 gene cause Rett syndrome, a severe neurodevelopmental disorder of young females. Only one male presenting an MECP2 mutation has been reported; he survived only to age 1 year, suggesting that mutations in MECP2 are male lethal. Here we report a three-generation family in which two affected males showed severe mental retardation and progressive spasticity, previously mapped in Xq27.2-qter. Two obligate carrier females showed either normal or borderline intelligence, simulating an X-linked recessive trait. The two males and the two obligate carrier females presented a mutation in the MECP2 gene, demonstrating that, in males, MECP2 can be responsible for severe mental retardation associated with neurological disorders.     

Evidence that a dodecamer duplication in the gene HOPA in Xq13 is not associated with mental retardation

A recent study suggested that a dodecamer duplication in exon 42 of the HOPA gene in Xq13 may be a significant factor in the etiology of X-linked mental retardation. In an effort to investigate this possibility, we determined the incidence of the dodecamer duplication in cohorts of non-fragile X males with mental retardation from three countries, cohorts of fragile X males from two countries, 43 probands from families with X-linked mental retardation and control cohorts from three countries. The duplication was found in 3.6-4.0% of male patients from two non-fragile X groups (Italy and South Carolina), in 1.2% from another non-fragile X group (South Africa), but in no male patients from families with X-linked mental retardation (South Carolina). The dodecamer duplication was also found in several white males with fragile X syndrome from France (5%) and South Africa (22.2%). Additionally, the duplication was found in 1.5% of South Carolinian newborn males, 2.5% South Carolinian male college students, 5% Italian male controls and 4.5% of the white South African controls. None of the black South African non-fragile X individuals with mental retardation, the fragile X or the control samples tested carried the duplication, suggesting that the duplication is rare in the black South African population. The incidence of the duplication was not significantly different between any of the groups in the study. Therefore, results of our studies in four different populations do not corroborate the findings of the previous study, and indicate that the HOPA dodecamer duplication does not convey an increased susceptibility to mental retardation.     

X-linked mental retardation. I. Martin-Bell syndrome (report of 18 families)

Eighteen families with X-linked mental retardation (MR) with or without macroorchidism, fragile-X positive at Xq27 (Martin-Bell syndrome) have been studied clinically and cytogenetically. All 58 affected males presented variable degrees of MR, fra(X) (q27) of their peripheral lymphocytes, macroorchidism in all adult patients with the exceptions of one with microorchidism as 47,XXY sex chromosome complement and the other with borderline testes, and characteristic facial appearance. The expression of the marker X in the heterozygotes seems to be more related to the mental development rather than the age of the individual. In two families the transmission of the syndrome through unaffected males seems probable.     

X-linked recessively inherited non-specific mental retardation. Report of a large family.

A large kindred is described in which 22 males and 3 females show non-specific mental retardation with impaired speech. An X-linked recessive is the most likely mode of inheritance of this condition. Similar families have been described in the literature, characteristic physical abnormalities are absent and performance I.Q. tends to be higher than verbal I.Q. This possible heterogenous condition may be a major individual cause of mental deficiency in males, and may account for the excess of male retardates in the population.     

X-linked mental retardation and autism are associated with a mutation in the NLGN4 gene, a member of the neuroligin family

A large French family including members affected by nonspecific X-linked mental retardation, with or without autism or pervasive developmental disorder in affected male patients, has been found to have a 2-base-pair deletion in the Neuroligin 4 gene (NLGN4) located at Xp22.33. This mutation leads to a premature stop codon in the middle of the sequence of the normal protein and is thought to suppress the transmembrane domain and sequences important for the dimerization of neuroligins that are required for proper cell-cell interaction through binding to beta-neurexins. As the neuroligins are mostly enriched at excitatory synapses, these results suggest that a defect in synaptogenesis may lead to deficits in cognitive development and communication processes. The fact that the deletion was present in both autistic and nonautistic mentally retarded males suggests that the NLGN4 gene is not only involved in autism, as previously described, but also in mental retardation, indicating that some types of autistic disorder and mental retardation may have common genetic origins.     

X-linked mental retardation. II. Renpenning syndrome and other types (report of 14 families)

Fourteen families with X-linked mental retardation (XMR) have been studied clinically and cytogenetically. All affected males failed to show a fragile site (FS) on Xq of their peripheral lymphocytes. Five families may be considered examples of Renpenning syndrome while the remaining may be divided in two groups: one of seven (type I) and one of two (type II). The seven families of type I had some physical features of the Martin-Bell syndrome but with normal to large sized testes whence the name of X-linked MR with slight macroorchidism (XMR +/- MO). The two families of type II showed unremarkable facial appearance, mild to moderate degree of MR and a certain microorchidism whence the possible name of X-linked MR with different degree of microorchidism (XMR +/- MiO).     

SLC9A6 mutations cause X-linked mental retardation, microcephaly, epilepsy, and ataxia, a phenotype mimicking Angelman syndrome

Linkage analysis and DNA sequencing in a family exhibiting an X-linked mental retardation (XLMR) syndrome, characterized by microcephaly, epilepsy, ataxia, and absent speech and resembling Angelman syndrome, identified a deletion in the SLC9A6 gene encoding the Na(+)/H(+) exchanger NHE6. Subsequently, other mutations were found in a male with mental retardation (MR) who had been investigated for Angelman syndrome and in two XLMR families with epilepsy and ataxia, including the family designated as having Christianson syndrome. Therefore, mutations in SLC9A6 cause X-linked mental retardation. Additionally, males with findings suggestive of unexplained Angelman syndrome should be considered as potential candidates for SLC9A6 mutations.     

On the nosology of moderate mental retardation with special attention to X-linked mental retardation. A diagnostic genetic survey of 274 institutionalized moderately mentally retarded men

In this paper we report the results of a genetic-diagnostic survey of 274 institutionalized moderately mentally retarded adult males and compare these data with those from our previous studies in the severely mentally retarded and from a comparable population of 262 institutionalized moderately mentally retarded males and females (The Borgenstein experience). Special attention is paid to the nosology of X-linked mental retardation and familial mental retardation in general.     

Some problems in the genetics of X-linked mental retardation

X-linked mental retardation has recently become one of the most interesting genetic anomalies. Studying this group of conditions has led to many insights into the mechanisms involved in normal and abnormal gene actions in humans. Since the early 1980s, the number of disease entities for which the responsible genes could be localized on the X chromosome has increased from year to year; at the Ninth International Workshop on Fragile-X-Syndrome and X-linked Mental Retardation, 199 such disease units were counted (Hamel, 1999). Conventionally, these units were subdivided into two groups: syndromal and non-syndromal types. The syndro- mal types are characterized by external features, neurological signs, and/or metabolic anomalies. The non-syndromal types do not show such specific features; here, the X-linked mode of inheritance is the only indicator. Due to the reduced reproduction of mentally severely retarded males, a relatively high fraction of new mutants among cases of a specific type must be expected. It cannot be the purpose of the present short article to review sufficiently well the entire field; this would require a complete book. Rather, it is our intention to point to some open problems and possible ways for their solution.     

Molecular screening of FRAXA and FRAXE in Indian patients with unexplained mental retardation

Fragile-X mental retardation is the commonest form of inherited mental retardation. We have studied 146 Indian patients (174 X chromosomes) with unexplained mental retardation by molecular methods. All study subjects were unrelated. Three of the 118 males were found to have the FMR1 full mutation. None of the patients tested were positive for the FMR2 full mutation. The Fragile X prevalence was 2.5% among males, which is lower than previously reported in Indian mentally retarded patients. Screening for Fragile X among patients with nonspecific mental retardation is important, even if there is no family history of mental retardation or typical behavioral or physical features associated with the Fragile-X phenotype. Identification of positive cases is also very important for the families, because of the high recurrence risk of the disease. Large multicenter screening programs with uniform criteria would be worthwhile to determine the prevalence of Fragile-X mental retardation in the Indian population.     

Mental retardation linked to fragility of chromosome X: current knowledge

The association of the fragile X chromosome with X-linked mental retardation is now well established. The main clinical features are mental retardation, typical facial dysmorphism and macroorchidism. Cytogenetically there is a fragile site in band Xq27-28 which can be demonstrated using specific techniques. The genetic studies are compatible with a X-linked dominant inheritance with an incomplete penetrance. A preliminary estimation of an overall frequency of 1: 2000 males for the fra(X)(q) condition is suggested.     

Segregation of FRAXE in a large family: clinical, psychometric, cytogenetic, and molecular data.

During an ongoing study on X-linked mental retardation, we ascertained a large family in which mild mental retardation was cosegregating with a fragile site at Xq27-28. Clinical, psychometric, cytogenetic, and molecular studies were performed. Apart from mild mental retardation, affected males and females did not show a specific clinical phenotype. Psychometric assessment of four representative affected individuals revealed low academic achievements, with verbal and performance IQs of 61-75 and 70-82, respectively. Cytogenetically the fragile site was always present in affected males and was not always present in affected females. With FISH the fragile site was located within the FRAXE region. The expanded GCC repeat of FRAXE was seen in affected males and females either as a discrete band or as a broad smear. No expansion was seen in unaffected males, whereas three unaffected females did have an enlarged GCC repeat. Maternal transmission of FRAXE may lead to expansion or contraction of the GCC repeat length, whereas in all cases of paternal transmission contraction was seen. In striking contrast to the situation in fragile X syndrome, affected males may have affected daughters. In addition, there appears to be no premutation of the FRAXE GCC repeat, since in the family studied here all males lacking the normal allele were found to be affected.     

Linkage and recombination between fragile X-linked mental retardation and the factor IX gene

Summary Linkage analysis on a family with fragile X-linked mental retardation was performed using a Taq 1 restriction fragment length polymorphism detected by a cloned human coagulation factor IX cDNA. Two affected brothers in this sibship were found to have different factor IX RFLP alleles, indicating a recombinational event occurred between the two genes. Our data therefore indicate that the gene responsible for fragile X-linked mental retardation is not as tightly linked to the factor IX gene as the previously published data may suggest.