Annette K. Taylor

Elevated Levels of FMR1 mRNA in Carrier Males: A New Mechanism of Involvement in the Fragile-X Syndrome

Fragile-X syndrome is a trinucleotide-repeat-expansion disorder in which the clinical phenotype is believed to result from transcriptional silencing of the fragile-X mental retardation 1 (FMR1) gene as the number of CGG repeats exceeds approximately 200. For premutation alleles ( approximately 55-200 repeats), no abnormalities in FMR1-gene expression have been described, despite growing evidence of clinical involvement in premutation carriers. To address this (apparent) paradox, we have determined, for 16 carrier males (55-192 repeats), the relative levels of leukocyte FMR1 mRNA, by use of automated fluorescence-detection reverse transcriptase-PCR, and the percent of lymphocytes that are immunoreactive for FMR1 protein (FMRP). For some alleles with>100 repeats, there was a reduction in the number of FMRP-positive cells. Unexpectedly, FMR1 mRNA levels were elevated at least fivefold within this same range. No significant increase in FMR1 mRNA stability was observed in a lymphoblastoid cell line (160 repeats) derived from one of the carrier males, suggesting that the increased message levels are due to an increased rate of transcription. Current results support a mechanism of involvement in premutation carriers, in which reduced translational efficiency is at least partially compensated through increased transcriptional activity. Thus, diminished translational efficiency may be important throughout much of the premutation range, with a mechanistic switch occurring in the full-mutation range as the FMR1 gene is silenced.

Electrodermal responses to sensory stimuli in individuals with fragile X syndrome: a preliminary report.

The fragile X mutation and fragile X syndrome are associated with hyperarousal, hyperactivity, aggression, and anxiety. These may be related to strong reactions to auditory, tactile, visual, and olfactory stimuli [Hagerman, 1996b; Hagerman and Cronister, 1996]. However, almost no data exist describing hyperarousal and sensory sensitivity in individuals with the fragile X mutation. This study establishes a reliable laboratory paradigm for examining reactions to sensory stimuli. We found the pattern of electrodermal responses (EDRs) to stimulation in one sensory modality predicted the pattern of EDRs in four other sensory systems. In addition, the EDR pattern of individuals with the fragile X mutation was related to their FMR-protein expression. Finally, EDRs in individuals with fragile X syndrome were significantly different from those of normal controls, demonstrating greater magnitude, more responses per stimulation, responses on a greater proportion of trials, and lower rates of habituation. The findings support the theory that individuals with fragile X syndrome have a physiologically based enhancement of reactions to sensations. Because electrodermal activity indexes sympathetic nervous system activity, the data suggest that the over-arousal to sensation may involve the sympathetic system.

A Rapid Polymerase Chain Reaction-Based Screening Method for Identification of All Expanded Alleles of the Fragile X (FMR1) Gene in Newborn and High-Risk Populations

Fragile X syndrome, the most common inherited cause of intellectual impairment and the most common single gene associated with autism, generally occurs for fragile X mental retardation 1 (FMR1) alleles that exceed 200 CGG repeats (full-mutation range). Currently, there are no unbiased estimates of the number of full-mutation FMR1 alleles in the general population; a major obstacle is the lack of an effective screening tool for expanded FMR1 alleles in large populations. We have developed a rapid polymerase chain reaction (PCR)-based screening tool for expanded FMR1 alleles. The method utilizes a chimeric PCR primer that targets randomly within the expanded CGG region, such that the presence of a broad distribution of PCR products represents a positive result for an expanded allele. The method is applicable for screening both males and females and for allele sizes throughout the premutation (55 to 200 CGG repeats) and full-mutation ranges. Furthermore, the method is capable of rapid detection of expanded alleles using as little as 1% of the DNA from a single dried blood spot. The methodology presented in this work is suitable for screening large populations of newborn or those at high risk (eg, autism, premature ovarian failure, ataxia, dementia) for expanded FMR1 alleles. The test described herein costs less than

FMRP expression as a potential prognostic indicator in fragile X syndrome

5 per sample for materials; with suitable scale-up and automation, the cost should approach

Clinical involvement and protein expression in individuals with the FMR1 premutation

1 per sample.

Molecular-clinical correlations in males with an expanded FMR1 mutation

Absence or deficit of FMR1 protein (FMRP) resulting from methylation of full mutation genes is the fundamental defect in fragile X syndrome. We used FMRP immunocytochemistry and detailed phenotypic assessment to investigate the relationship between degree of FMRP expression and the broad clinical spectrum of impairment in 80 individuals affected with fragile X syndrome. FMRP expression correlated with IQ in mosaic males (P=0.043), males with a partially methylated full mutation (P=0.0005), and females with a full mutation (P=0.046). In the females, FMRP expression also correlated with the number of fragile X physical features (P=0.0003). Even modest deficits in FMRP result in some manifestations of fragile X syndrome. In this initial study of 53 males, FMRP expression testing had a very high positive predictive value (100%, confidence interval of 29-100%) for a nonretarded IQ among males with expression of FMRP in > or = 50% of lymphocytes (3 males), suggesting that FMRP expression may have potential as a prognostic indicator in males with fragile X syndrome.

Fragile X males with unmethylated, full mutation trinucleotide repeat expansions have elevated levels of FMR1 messenger RNA

Most individuals with the fragile X premutation are clinically unaffected; however, some show clinical manifestations, including learning difficulties, emotional problems, or even mental retardation. The basis of clinical involvement in these individuals is unknown. Premutation alleles are reportedly associated with normal levels of mRNA and protein (FMRP). To examine this issue in more detail, we studied six individuals with a premutation. We are reporting these cases to demonstrate a spectrum of phenotypic involvement which can be seen clinically. These cases include one individual with the premutation who has no evidence of FMR1 gene dysfunction but has mental retardation from other causes. Other cases presented here show varying degrees of FMR1 gene dysfunction as assessed by FMRP and FMR1 mRNA levels and various clinical features of fragile X. In two cases we observed a significant reduction in FMRP expression and an elevated FMR1 mRNA expression level associated with moderate cognitive deficit. Thus, the utilization of FMRP measures can be helpful in understanding for which premutation patients clinical involvement is caused by dysfunction of the FMR1 gene.

Molecular and cognitive predictors of the continuum of autistic behaviours in fragile X

Fragile X syndrome is caused by an expansion of a CGG repeat in the FMR1 gene. The CGG repeat number of the FMR1 mutation and the percentage of cells with methylation of the gene were studied in 218 male patients. Physical and cognitive measurements were also performed. Patients were divided into three groups; those with full mutation and complete methylation (n = 160), those with full mutation and partial methylation (n = 12), and those with a mosaic pattern (n = 46). Statistical comparisons were made between males with the fully methylated full mutation and those with a mosaic pattern. Males having full mutation with complete methylation had the lowest IQ scores and greatest physical involvement. These significant differences were seen only in ages after puberty. CGG repeat length did not correlate with IQ or the physical index score in any group. These findings suggest that a partial production of FMR1 protein may predict milder clinical involvement in some males with fragile X syndrome.

Profile of cognitive functioning in women with the fragile X mutation.

Fragile X syndrome normally arises as a consequence of large expansions (n >200) of a (CGG)(n) trinucleotide repeat in the promoter region of the FMR1 gene. The clinical phenotype is thought to result from hypermethylation of the repeat and adjacent upstream elements, with consequent down-regulation of transcription (transcriptional silencing). However, the relationship between repeat expansion and transcription has not been defined in the full mutation range. Using the method of quantitative (fluorescence) reverse transcriptase polymerase chain reaction, we demonstrated previously that FMR1 mRNA levels are substantially elevated in premutation (55 </= n < 200) male carriers. In the current work, we report that in fragile X males with unmethylated alleles in the full mutation range (n > 200), FMR1 mRNA levels remain significantly elevated (mean 3.5-fold elevation; P = 6.7 x 10(-3)) relative to normal controls, even for alleles exceeding 300 repeats. This conclusion is independent of any assumption regarding the transcriptional activity of methylated alleles. However, if it were assumed that all methylated alleles were transcriptionally silent, the FMR1 mRNA levels for cells with unmethylated alleles would be even higher (mean 4.5-fold elevation; P = 2.1 x 10(-4)). These observations show that the full-mutation CGG expansion per se is not a strong impediment to transcription and that the apparent up-regulation of the FMR1 locus remains active in at least some cells with full-mutation alleles.

Molecular/clinical correlations in females with fragile X

The distributions of scores for autistic behaviours obtained from the Autism Diagnostic Observation Scale-Generic (ADOS-G) were investigated in 147 males and females affected with the full mutation in the fragile X mental retardation 1 (FMR1) gene, in 59 individuals with the premutation, and in 42 non-fragile X relatives, aged 4-70 years. The scores representing communication and social interaction were continuously distributed across the two fragile X groups, and they were significantly elevated compared with the non-fragile X controls. Strong relationships were found between both these scores and FMRP deficits, but they became insignificant for social interaction, and the sum of social interaction and communication scores, when FSIQ was included as another predictor of autism scores. Other significant predictors of these scores in both sexes were those executive skills which related to verbal fluency, and to the regulation and control of motor behaviour. Overall, our data have shown that cognitive impairment, especially of verbal skills, best explains the comorbidity of autism and fragile X. This implies some more fundamental perturbations of specific neural connections which are essential for both specific behaviours and cognition. We also emphasize that FXS offers a unique molecular model for autism since FMRP regulates the translation of many other genes involved in synaptic formation and plasticity which should be natural targets for further exploration.