应用PCR快速筛查脆性X综合征患儿

目的应用PCR快速筛查脆性X综合征患儿。方法采用PCR和聚丙烯酰胺凝胶电泳技术,对24例不明原因智力低下患儿的脆性X基因（CGG）n重复序列进行检测。结果在24例不明原因智力低下患儿中,筛查出1例脆性X综合征患者。结沦采用PCR技术扩增脆性X基因的（CGG）n重复序列,可对脆性X综合征患者进行快速筛查。     

The frequency of the fragile X chromosome among schoolchildren in Coventry.

A population study has been carried out among schoolchildren in the City of Coventry in order to ascertain the frequency of mental retardation associated with the fragile X chromosome. The prevalence of the fragile X mental retardation syndrome in the 11 to 16 year age group (the age of greatest ascertainment) was about 1.0 per 1,000 and therefore indicates that the syndrome is a major cause of mental retardation.     

A novel polymorphism in the FMR1 gene: implications for clinical testing of fragile X syndrome

Fragile X syndrome is the most common cause of inherited mental retardation among males. In most cases, the molecular basis of fragile X syndrome is the expansion and subsequent methylation of a CGG trinucleotide repeat in the 5' untranslated region of the fragile X mental retardation 1 (FMR1) gene. Laboratory diagnosis usually relies on a combination of Southern blot and polymerase chain reaction analyses. In this case report we describe an unusual Southern blot result in a patient who presented with developmental delay and had a normal CGG repeat number by polymerase chain reaction analysis. Further investigation revealed a novel G3310C transversion in the FMR1 gene resulting in a new recognition site for the BssHII restriction enzyme. This novel restriction site could potentially mimic a partial deletion of the FMR1 gene on Southern blot analysis and thus represents a possible pitfall in the diagnosis of fragile X syndrome.     

Molecular screening for fragile X syndrome in mentally handicapped children in Korea.

Fragile X syndrome is one of the most common forms of inherited mental retardation and is caused by the expansion of the CGG trinucleotide repeats in the FMR-1 gene. This study was aimed to facilitate the molecular screening of fragile X syndrome in Korean children with mental retardation of unknown etiology. The subjects were tested by Expand Long Template PCR system in the presence of 7-deaza-dGTP, and then by Southern blot analysis. The PCR method provided rapid and reliable results for the identification of fragile X negative and positive patients. One hundred one mentally retarded children (78 males and 23 females) were screened by PCR amplification, which detected only one abnormal sample. The PCR-positive case was confirmed by the CGG repeat expansion on Southern blot analysis with a positive cytogenetic result. In conclusion, Expand Long Template PCR may be used as the first screening test for detecting the fragile X syndrome.     

脆性X综合征分子诊断研究进展

脆性X智力低下1基因(fragile X mental retardation l gene,FMRI)是脆性X综合征的致病基因,其产物脆性X智力低下蛋白(fragile X mental retardation protein,FMRP)与大脑神经元的发育密切相关.自FMR1基因被鉴定以来,以PCR和Southern印迹杂交为主的分子诊断方法已成为脆性X综合征实验室诊断的主流技术.本文就脆性X综合征分子诊断方法的最新研究进展作一综述.     

Four sisters compound heterozygotes for the pre- and full mutation in fragile X syndrome and a complete inactivation of X-functional chromosome: implications for genetic counseling

Fragile X syndrome (FXS) is a neurodevelopmental disorder and a leading monogenic form of cognitive impairment and autism. It is the most common form of inherited mental retardation in males and a significant cause of mental retardation in females. It is caused by the instability and subsequent expansion of the CGG repeat in the promoter region of the FMR1 (fragile X mental retardation 1) gene at Xq27.3. We describe a double consanguineous family with four sisters compound heterozygotes for the full and pre-mutation CGG repeat size. The index case shows clinical features of the affected males with profound mental retardation; the other three sisters also suffer from mental retardation, ranging from mild to severe. Molecular analysis reveals very similar ranges for the CGG expansions for both chromosomes in all four sisters. The phenotypic differences observed in the index case and her sisters are the total inactivation of X premutated chromosome and the total absence of FMRP (fragile X mental retardation protein). This family case raises important issues for genetic counseling in families with consanguinity and with cases of idiopathic mental retardation.     

Fragile site X chromosomes and X-linked mental retardation in severely retarded boys in a northern Swedish county. A prevalence study

In an unselected series of 96 severely mentally retarded boys (IQ < 50) born 1959–70 in a northern Swedish county, six had a fragile site on the distal end of the X chromosome (FraXq 28). The prevalence of the fragile X syndrome in severely retarded boys was 6 %. Next to trisomy 21, this fragile X syndrome appears to be the most common single cause of severe mental retardation in boys.     

Frequency of the fragile X syndrome in Chinese mentally retarded populations is similar to that in Caucasians.

Fragile X syndrome is recognized as the most common inherited cause of mental retardation in western countries. The prevalence of the fragile X syndrome in Asian populations is uncertain. We report a multi-institutional collaborative study of molecular screening for the fragile X syndrome from 1,127 Chinese mentally retarded (MR) individuals. We found that 2.8% of the Chinese MR population screened by DNA analysis had the fragile X full mutation. Our screening indicated that the fragile X syndrome prevalence was very close to that of Caucasian subjects. In addition, we found that 62.5% of fragile X chromosomes had a single haplotype for DXS548-FRAXAC1 (21-18 repeats) which was present in only 9.7% of controls. This unique distribution of microsatellite markers flanking the FMR1 CGG repeats suggests that the fragile X syndrome in Chinese populations, as in the Caucasian, may also be derived from founder chromosomes.     

A 15-item checklist for screening mentally retarded males for the fragile X syndrome

A 15-item checklist, including physical and behavioral features frequently observed in fragile X syndrome, was used in a prospective study of 188 mentally retarded males in order to identify males at risk for this syndrome. Of the 188 males, 19 were found to have the fragile X syndrome, while the remaining 169 males had no recognizable cause of their mental retardation, including normal chromosomes. Significant differences (p less than 0.01) were found between mentally retarded males with and without the fragile X syndrome with increased hyperactivity; shorter attention span; more tactile defensiveness, hand-flapping, perseverative speech, and hyperextensibility; large ears and testes; higher frequency of simian creases or Sydney lines and plantar creases; and more positive family histories of mental retardation in the fragile X syndrome males. Multiple regression and discriminant analyses of the 188 males indicated several physical features were useful predictors for inclusion in the fragile X syndrome group. An overall correct classification rate of 93% was achieved based on 6 variables (plantar crease, simian crease, hyperflexibility, large testes, large ears, and a positive family history of mental retardation) that were entered into the discriminant equation. Therefore, our experience with a 15-item checklist suggests the potential of screening for the fragile X syndrome in mentally retarded males and that 6 of the 15 variables were particularly good predictors of this syndrome.     

Fragile X syndrome in mildly mentally retarded children in a Northern Swedish county. A prevalence study

In an extensive etiological study of an unselected series of mildly mentally retarded children (MMR) (IQ 50–70) born 1959–1970 in a northern Swedish county, 5 of 110 boys (4.5%) and none of 61 girls had a fragile site on the distal end of the X-chromosome (Fra Xq 28). Consequently fragile X was seen in 2.9% of the total series of 171 children. In a combined series of severe and mild mental retardation, the incidence of the fragile X syndrome was calculated to be 1:3000 in the county of Vasterbotten. Next to trisomy 21 the fragile X syndrome was the most common single identified cause of MMR in boys. A cytogenetic investigation using special cultural conditions and banding techniques should be performed in cases of mental retardation of unclear etiology and in possible female carriers.     

Longer brainstem auditory evoked response latencies of individuals with fragile X syndrome related to sedation

Brainstem auditory evoked response latencies were studied in 75 males (13 with fragile X syndrome, 18 with mental retardation due to other causes, and 44 with no disability). Latency values were obtained for each ear for the positive deflections of waves I (P1), III (P3), and V (P5). Some individuals with mental retardation required sedation. Contrary to previous report, latencies obtained for individuals with fragile X did not differ from those obtained for persons without mental retardation. Persons receiving sedation, whether or not their retardation was due to fragile X, had longer latencies for wave P5 than persons who did not receive sedation. This effect of sedation may also explain the previously reported increased latencies for persons with fragile X. Am. J. Med. Genet. 74:167–171, 1997. © 1997 Wiley-Liss, Inc.     

Familial interstitial Xq27.3q28 duplication encompassing the FMR1 gene but not the MECP2 gene causes a new syndromic mental retardation condition

X-linked mental retardation is a common disorder that accounts for 5–10% of cases of mental retardation in males. Fragile X syndrome is the most common form resulting from a loss of expression of the FMR1 gene. On the other hand, partial duplication of the long arm of the X chromosome is uncommon. It leads to functional disomy of the corresponding genes and has been reported in several cases of mental retardation in males. In this study, we report on the clinical and genetic characterization of a new X-linked mental retardation syndrome characterized by short stature, hypogonadism and facial dysmorphism, and show that this syndrome is caused by a small Xq27.3q28 interstitial duplication encompassing the FMR1 gene. This family broadens the phenotypic spectrum of FMR1 anomalies in an unexpected manner, and we suggest that this condition may represent the fragile X syndrome «contre-type».     

脆性X智力低下蛋白与mRNAs的相互作用

脆性X智力低下蛋白(fragile mental retardation protein,FMRP)的表达缺失引起一种遗传性智力低下疾病——脆性X综合征。此蛋白是一种RNA结合蛋白,与mRNAs转运及多聚核糖体和突触的功能有关。因此,要了解脆性X综合征的发病机理,关键在于找到与FMRP蛋白结合的mRNAs,以及FMRP与这些靶mRNAs的结合对它们的代谢和翻译有何影响。     

Rapid antibody test for prenatal diagnosis of fragile X syndrome on amniotic fluid cells: a new appraisal.

Fragile X syndrome is caused by mutations in the FMR1 gene and is one of the most frequent forms of inherited mental retardation in males. Postnatal and prenatal diagnosis of fragile X syndrome is feasible by direct DNA analysis. A new approach to prenatal diagnosis of fragile X syndrome in amniotic fluid cells is described, using a rapid and simple antibody test on uncultured amniotic fluid cells. The test requires 1 ml of amniotic fluid and the results of this antibody test are available on the same day as the amniocentesis.     

The fragile X syndrome.

The fragile X syndrome is characterised by mental retardation, behavioural features, and physical features, such as a long face with large protruding ears and macro-orchidism. In 1991, after identification of the fragile X mental retardation (FMR1) gene, the cytogenetic marker (a fragile site at Xq27.3) became replaced by molecular diagnosis. The fragile X syndrome was one of the first examples of a "novel" class of disorders caused by a trinucleotide repeat expansion. In the normal population, the CGG repeat varies from six to 54 units. Affected subjects have expanded CGG repeats (>200) in the first exon of the FMR1 gene (the full mutation). Phenotypically normal carriers of the fragile X syndrome have a repeat in the 43 to 200 range (the premutation). The cloning of the FMR1 gene led to the characterisation of its protein product FMRP, encouraged further clinical studies, and opened up the possibility of more accurate family studies and fragile X screening programmes.     

The fragile X gene and its function

The fragile X syndrome represents the most common inherited cause of mental retardation worldwide. It is caused by a stretch of CGG repeats within the fragile X gene, which increases in length as it is transmitted from generation to generation. Once the repeat exceeds a threshold length, no protein is produced resulting in the fragile X phenotype. Ten years after the discovery of the gene, much has been learned about the function of the fragile X protein. Knowledge has been collected about the mutation mechanism, although still not all players that allow the destabilization of the CGG repeat are known.     

Abnormal dendritic spine characteristics in the temporal and visual cortices of patients with fragile‐X syndrome: A quantitative examination

Fragile‐X syndrome is a common form of mental retardation resulting from the inability to produce the fragile‐X mental retardation protein. Qualitative examination of human brain autopsy material has shown that fragile‐X patients exhibit abnormal dendritic spine lengths and shapes on parieto‐occipital neocortical pyramidal cells. Similar quantitative results have been obtained in fragile‐X knockout mice, that have been engineered to lack the fragile‐X mental retardation protein. Dendritic spines on layer V pyramidal cells of human temporal and visual cortices stained using the Golgi‐Kopsch method were investigated. Quantitative analysis of dendritic spine length, morphology, and number was carried out on patients with fragile‐X syndrome and normal age‐matched controls. Fragile‐X patients exhibited significantly more long dendritic spines and fewer short dendritic spines than did control subjects in both temporal and visual cortical areas. Similarly, fragile‐X patients exhibited significantly more dendritic spines with an immature morphology and fewer with a more mature type morphology in both cortical areas. In addition, fragile‐X patients had a higher density of dendritic spines than did controls on distal segments of apical and basilar dendrites in both cortical areas. Long dendritic spines with immature morphologies and elevated spine numbers are characteristic of early development or a lack of sensory experience. The fact that these characteristics are found in fragile‐X patients throughout multiple cortical areas may suggest a global failure of normal dendritic spine maturation and or pruning during development that persists throughout adulthood. © 2001 Wiley‐Liss, Inc.