Macroorchidism and fragile X in mentally retarded males

Summary One hundred and seventy eight males resident in an institution for the mentally retarded were screened clinically for the presence of macroorchidism, using the standard orchidometer. In this way 52 males with a testicular volume of 25 ml and over were found. Of these, 11 had pronounced macroorchidism (above 25 ml). All 52 males were examined cytogenetically for the fragile X. Two patients with pronounced macroorchidism showed this abnormality. Although the other nine patients with pronounced macroorchidism were reexamined with FUdR-addition to blood cultures, no further cases positive for the fragile X were found. Also, the thyroid function as well as the prolactin level in serum were investigated in all 52 males. No significant abnormalities were found. The high incidence of macroorchidism in mentally retarded males is underlined; however, it is suggested that the definition of macroorchidism should take into account several parameters.     

Frequency of the fragile X syndrome in Japanese mentally retarded males

Summary Among 243 institutionalized mentally retarded males in Japan, 13 patients (5.3%) with the fre(X)(q27) from nine families were detected. These 13 patients accounted for 8.6% of 152 male inmates with unknown causes of mental retardation in the population. One out of nine pedigrees had an apparently unaffected male transmitter of this disorder. Our data agree with the frequencies of the fra(X) syndrome in various retarded populations, most of which were Caucasians, suggesting that the prevalence of the fra(X) syndrome in Japanese is not significantly different from those in Causasians.     

Frequency of the fragile X syndrome in institutionalized mentally retarded females in Japan

Summary The fragile X [fra(X)] syndrome was screened on 190 Japanese institutionalized females with moderate to severe mental retardation. Two inmates with severe mental retardation (IQ 20) had the fra(X) chromosome in 26% and 15% of the cells examined, indicating that the prevalence of the fra(X) syndrome was about 1% in all female inmates and was about 3.27% in severely mentally retarded females with known causes. However, no female with fra(X) syndrome was found in 35 moderately retarded females. Both had brothers with the fra(X) syndrome and the prevalence was 10% in females with a family history of mental retardation. In addition, the replication study of the fra(X) chromosome in the patients supported the proposal that an excess of the early replicated fra(X) chromosome is related to the mental capacity in heterozygous females. Therefore, the fra(X) syndrome should not be ignored even in severely mentally retarded females with a family history, though the heterozygotes are commonly normal to subnormal in their mental development. in addition, the replication study of the fra(X) chromosome may help to estimate mental development in the carrier children.     

Screening for fragile X syndrome among Brazilian mentally retarded male patients using PCR from buccal cell DNA

Fragile X syndrome is one of the most frequent causes of mental retardation. Since the phenotype in this syndrome is quite variable, clinical diagnosis is not easy and molecular laboratory diagnosis is necessary. Usually DNA from blood cells is used in molecular tests to detect the fragile X mutation which is characterized by an unstable expansion of a CGG repeat in the fragile X mental retardation gene (FMR1). In the present study, blood and buccal cells of 53 mentally retarded patients were molecularly analyzed for FMR1 mutation by PCR. Our data revealed that DNA extraction from buccal cells is a useful noninvasive alternative in the screening of the FMR1 mutation among mentally retarded males.     

A PCR-based test suitable for screening for fragile X syndrome among mentally retarded males

Ever since the identification of the genetic cause of fragile X syndrome as the expansion of an unstable trinucleotide sequence, several diagnostic strategies have evolved from molecular studies. However, we still lack a simple test suitable for population screening. We have therefore developed a nonisotopic polymerase chain reaction (PCR)-based technique for the identification of fragile X full mutations among men, with easy visualization of the PCR products on silver-stained polyacrylamide gels. The technique consists of PCR amplification with primers that flank the trinucleotide repeats, with a product of 557 bp for the (CGG)₂₉ allele. Conditions were established such that full mutations failed to amplify and were thus identified with 98% sensitivity compared with Southern blot analysis. To produce an indispensable internal control we added to the reaction a third primer, internal to this fragment, allowing the multiplex amplification of a monomorphic band corresponding to a CG-rich stretch 147 bp upstream of the polymorphic region. In trials involving 41 patients and 74 controls, the PCR-based test here described showed specificity of more than 98.6%, accuracy of 99% and a sensitivity of 98%. Thus, although not suitable for medical diagnosis, it constitutes a useful tool for screening for the fragile X syndrome in populations of mentally retarded males. Received: 31 May 1995 / Revised: 4 October 1995     

Unusual X chromosome inactivation in a mentally retarded girl with an interstitial deletion Xq27: implications for the fragile X syndrome

Summary A de novo interstitial deletion (X)(q27.1q27.3), between the loci DXS 105 and F8, has been found in a mentally retarded female. The deleted X chromosome is preferentially early replicating in fibroblasts, B cells and T cells, suggesting that the missing region plays a role in inactivation of the X chromosome. None of the available DNA probes except DXS 98 maps to the deleted region of about 10000kb. The locus FRAXA is either included in the deletion, or located close to the distal break point.     

Partial 1p monosomy in a physically and mentally retarded boy

An 8-year-old boy is reported with marked mental and physical retardation, microcephaly, hypertelorism, mongoloid palpebral fissures, hypoplasia of the maxillary portion of the face, and other discrete anomalies. Deletion of the distal portion of the short arm of the chromosome 1 and the karyotype 46,XY, del(1)(p33----pter) was detected.     

Understanding fragile X syndrome: insights from retarded flies

Fragile X syndrome, the most common form of inherited mental retardation, is caused by loss-of-function mutations in the fragile X mental retardation 1 (fmr1) gene. FMR1 is an RNA binding protein that is highly expressed in neurons of the central nervous system. Recent studies in Drosophila indicate that FMR1 plays an important role in synaptogenesis and axonal arborization, which may underlie the observed deficits in flight ability and circadian behavior of fmr1 mutant flies. The relevance of these studies to our understanding of fragile X syndrome is discussed.     

X monosomy and 21 trisomy in a sibship

Summary The case of a sibship of 4, 2 members of which present aneuploïdy (45,X and 47,XX,21+) is reported. The paternal grandfather and grandmother are first cousins and there is a large number of centromeric associations in the father.     

X monosomy and 21 trisomy in a sibship.

The case of a sibship of 4, 2 members of which present aneuplo?dy (45,X and 47,XX,21+) is reported. The paternal grandfather and grandmother are first cousins and there is a large number of centromeric associations in the father.     

Screening and diagnosis for the fragile X syndrome among the mentally retarded: an epidemiological and psychological survey. Collaborative Fragile X Study Group.

The fragile X syndrome is an X-linked mental retardation disorder caused by an expanded CGG repeat in the first exon of the fragile X mental retardation (FMR1) gene. Its frequency, X-linked inheritance, and consequences for relatives all prompt for diagnosis of this disorder on a large scale in all affected individuals. A screening for the fragile X syndrome has been conducted in a representative sample of 3,352 individuals in schools and institutes for the mentally retarded in the southwestern Netherlands, by use of a brief physical examination and the DNA test. The attitudes and reactions of (non)consenting parents/guardians were studied by (pre- and posttest) questionnaires. A total of 2,189 individuals (65%) were eligible for testing, since they had no valid diagnosis, cerebral palsy, or a previous test for the FMR1 gene mutation. Seventy percent (1,531/2,189) of the parents/guardians consented to testing. Besides 32 previously diagnosed fragile X patients, 11 new patients (9 males and 2 females) were diagnosed. Scoring of physical features was effective in preselection, especially for males (sensitivity .91 and specificity .92). Major motives to participate in the screening were the wish to obtain a diagnosis (82%), the hereditary implications (80%), and the support of research into mental retardation (81%). Thirty-four percent of the parents/guardians will seek additional diagnostic workup after exclusion of the fragile X syndrome. The prevalence of the fragile X syndrome was estimated at 1/ 6,045 for males (95% confidence interval 1/9,981-1/ 3,851). On the basis of the actual number of diagnosed cases in the Netherlands, it is estimated that >50% of the fragile X cases are undiagnosed at present.     

13q deletion syndrome in an adult mentally retarded patient.

Clinical features of the 13q deletion syndrome are difficult to define and include retinoblastoma, mental and growth retardation, craniofacial abnormalities, brain, gastrointestinal, renal and heart malformations, anal atresia and limb and digit malformations. The critical region for development of major organ systems has been defined in 13q32 between the proximal marker 13S132 and distal marker D13S147. We report a severely mentally retarded male patient with a deletion of the distal part of chromosome 13 (13q32.3-->qter) without major organ malformations.     

A study of FRAXE in mentally retarded individuals referred for fragile X syndrome (FRAXA) testing in the United Kingdom.

The folate-sensitive fragile site FRAXE is located in proximal Xq28 of the human X chromosome and lies approximately 600 kb distal to the fragile X syndrome (FRAXA) fragile site at Xq27.3. The cytogenetic expression of FRAXE is thought to be associated with mental handicap, but this is usually mild compared to that of the more common fragile X syndrome that is associated with the expression of the FRAXA fragile site. The exact incidence of FRAXE mental retardation is uncertain. We describe here the results of a U.K. survey designed to assess the frequency of FRAXE in a population of individuals referred for fragile X syndrome testing and found to be negative for expansion events at the FRAXA locus. No FRAXE expansion events were found in 362 cytogenetically negative males studied, and one expansion event was identified in a sample of 534 males for whom cytogenetic analyses were either unrecorded or not performed. Further FRAXE expansion events were detected in two related females known to be cytogenetically positive for a fragile site in Xq27.3-28. To gain insight into the FRAXE phenotype, the clinical details of the identified FRAXE male plus three other FRAXE individuals identified through previous referrals for fragile X syndrome testing are presented. For the population studied, we conclude that FRAXE mental retardation is a relatively rare but significant form of mental retardation for which genetic diagnosis would be appropriate.     

Prenatal diagnosis in a mentally retarded woman with mosaic ring chromosome 18

We present a pregnant woman with mental retardation and mosaic for ring 18 referred for prenatal diagnosis. Major clinical features included short stature with clinodactyly in feet, foot deformity and club feet, hypotonia, kyphosis, and absence of breast development, low set ears, high arched palate, dental decay and speech disorder. Prenatal diagnosis was carried. Using amniocentesis. The fetus had a normal karyotype described as 46,XX. The fetus was evaluated for clinical features after delivery; she was healthy with no abnormal clinical characterizations.     

A cytogenetic study of mentally retarded school children in taiwan with special reference to the fragile X chromosome

Summary A cytogenetic study was made on 341 mentally retarded children in the Provincial Nantou Rehabilitation Center for the Mentally Retarded and the St. Raphael Opportunity Center in Tainan. Of the 89 mentally retarded children with chromosomal abnormalities, 63 had Down syndrome, 13 had the fragile X [fra(X)] syndrome, and the remaining had other aneuploid constitutions. Family studies were possible for 2 of the 13 fra(X) probands. The results of this study illustrate the contribution of chromosomal abnormalities to the pathogenesis of mental retardation in children.     

Primary amenorrhoea in a patient with mosaicism for monosomy X and a derivative X-chromosome

Primary amenorrhoea is defined as the absence of menstruation in phenotypic women aged 16 years or older, if secondary sexual characteristics are present. X chromosome abnormalities probably comprise about one half of all cases, including Turner syndrome and X chromosome rearrangements. Conventional banding cytogenetic methods might miss the accurate detection of structural chromosome abnormalities. The fluorescence in situ hybridization (FISH) and multicolor FISH techniques are required to interpret specific chromosomal rearrangement. As far as we know, we report the first case with chromosome mosaicism for monosomy X and terminal deletion of Xq26 with duplication of Xp11-->pter. In spite of the fact that a 45,X karyotype was detected in 46% of lymphocytes, she was tall and her secondary sexual characteristics were moderately developed, including breast, pubic and axillary hair stages. Cytogenetic and FISH analyses should be considered for patients presenting primary amenorrhoea even if there are no other clinical features suggestive of chromosome abnormality.