Jeanette J. A. Holden

Variation of the CGG repeat at the fragile X site results in genetic instability: Resolution of the Sherman paradox

Fragile X syndrome results from mutations in a (CGG)n repeat found in the coding sequence of the FMR-1 gene. Analysis of length variation in this region in normal individuals shows a range of allele sizes varying from a low of 6 to a high of 54 repeats. Premutations showing no phenotypic effect in fragile X families range in size from 52 to over 200 repeats. All alleles with greater than 52 repeats, including those identified in a normal family, are meiotically unstable with a mutation frequency of one, while 75 meioses of alleles of 46 repeats and below have shown no mutation. Premutation alleles are also mitotically unstable as mosaicism is observed. The risk of expansion during oogenesis to the full mutation associated with mental retardation increases with the number of repeats, and this variation in risk accounts for the Sherman paradox.

Fragile X Premutation Is a Significant Risk Factor for Premature Ovarian Failure: The International Collaborative POF in Fragile X Study—Preliminary Data

The preliminary results of an international collaborative study examining premature menopause in fragile X carriers are presented. A total of 760 women from fragile X families was surveyed about their fragile X carrier status and their menstrual and reproductive histories. Among the subjects, 395 carried a premutation, 128 carried a full mutation, and 237 were noncarriers. Sixty-three (16%) of the premutation carriers had experienced menopause prior to the age of 40 compared with none of the full mutation carriers and one (0.4%) of the controls. Based on these preliminary data, there is a significant association between fragile X premutation carrier status and premature menopause.

Disruption at the PTCHD1 locus on Xp22.11 in autism spectrum disorder and intellectual disability

Mutations of the X-linked gene PTCHD1 are associated with autism spectrum disorders and intellectual disability. A Patch in the Fabric of Autism What causes autism? This disabling disorder is characterized by severe language and social impairment and is now included under the umbrella term “autism spectrum disorder” (ASD), which also includes milder deficits in communication and social development. Numerous theories have been advanced as to its causes. These have ranged from discredited concepts—“refrigerator” mothers and vaccines—to the modern idea of gene-environment interactions. Although no one gene simply explains the predisposition of patients for ASD, these disorders are wellknown to have a strong genetic component. Here, Noor et al. report the results of genetic analysis in thousands of patients and control subjects: Mutations at the PTCHD1 (patched-related gene) locus are associated with the inheritance of ASD and with intellectual disability in a small fraction of cases. In this study, the authors analyzed the PTCHD1 gene from 1896 patients with ASD and 246 with intellectual disability, and compared these to more than 10,000 control individuals, and found mutations in various parts of this gene in 25 affected individuals in 20 different families, but not in any of the controls. Some patients had large deletions, in one case spanning the entire gene, and in others the culprit was a missense mutation. A result of this gene’s location on the X chromosome, the affected patients were almost all male, and most had unaffected mothers and other female relatives. The authors also present evidence that the PTCHD1 gene may be part of the Hedgehog signaling pathway, which is important in embryonic development. Autism and intellectual disability are not straightforward disorders that can be attributed to mutations in a single gene. Even when candidate genes such as PTCHD1 are known, differences in the gene sequence do not perfectly correlate with phenotype, because there are many as yet undefined additional genes and environmental influences that dictate the ultimate characteristics of the person. Identifying some of these genes, as Noor et al. have done in this study, allows a better understanding of the disorder and the development of ways to compensate for its disabilities. Autism is a common neurodevelopmental disorder with a complex mode of inheritance. It is one of the most highly heritable of the complex disorders, although the underlying genetic factors remain largely unknown. Here, we report mutations in the X-chromosome PTCHD1 (patched-related) gene in seven families with autism spectrum disorder (ASD) and in three families with intellectual disability. A 167-kilobase microdeletion spanning exon 1 was found in two brothers, one with ASD and the other with a learning disability and ASD features; a 90-kilobase microdeletion spanning the entire gene was found in three males with intellectual disability in a second family. In 900 probands with ASD and 208 male probands with intellectual disability, we identified seven different missense changes (in eight male probands) that were inherited from unaffected mothers and not found in controls. Two of the ASD individuals with missense changes also carried a de novo deletion at another ASD susceptibility locus (DPYD and DPP6), suggesting complex genetic contributions. In additional males with ASD, we identified deletions in the 5′ flanking region of PTCHD1 that disrupted a complex noncoding RNA and potential regulatory elements; equivalent changes were not found in male control individuals. Thus, our systematic screen of PTCHD1 and its 5′ flanking regions suggests that this locus is involved in ~1% of individuals with ASD and intellectual disability.

Behavioral Relationship between Autism and Fragile X Syndrome.

Previous researchers have reported autistic features in children with fragile X syndrome. We compared 21 children with pervasive developmental disorders (autism group) to 15 with fragile X syndrome on the Childhood Autism Rating Scale and the Reiss Scales for Childrens Dual Diagnosis. The 7 children (47%) with fragile X who scored above the Childhood Autism Rating Scale cut-off (fragile X-autism group) were more impaired than the remaining children (fragile X-no autism) on Childhood Autism Rating Scale subscales related to emotion, visual and listening responses, and communication. The autism groups Reiss scores were higher than fragile X-no autism group, but not fragile X-autism group. Although the Childhood Autism Rating Scale identified almost 50% of children with fragile X as having autism, qualitative differences may exist in specific autistic-like behaviors between children with autism and children with fragile X.

Organization of a repetitive human 1.8 kb KpnI sequence localized in the heterochromatin of chromosome 15

We have isolated a repetitive 1.8 kb Kpnl DNA sequence which is amplified in the homogeneously staining regions of a human melanoma cell line. Under low stringency conditions this sequence (D15Z1) hybridized in situ to the centromeric heterochromatin of chromosomes 1, 9, 15p, 16, and distal Yq as well as to the the short arms of the other acrocentric chromosomes. Under conditions of high stringency, labelling was predominantly on the short arm of chromosome 15. D15Z1 was shown to be present at approximately 3,000 copies per haploid genome and organized in long tandem arrays showing restriction site heterogeneity. Sequences homologous to D15Z1 were highly enriched in the less dense shoulder region of a Ag+—Cs2SO4 gradient. Analysis of D15Z1 indicated that this sequence is composed of tandemly arranged imperfect repeats of the consensus 5′ AATGG 3′ similar to previously identified satellite III sequences. Digestion of D15Z1 with HinfI resulted in a series of restriction fragments making up a subset of the HinfI ladder components of satellites III and IV. These data suggest that D15Z1 represents a chromosome 15 specific domain of human satellites III or IV and that it makes up the major fraction of the heterochromatin of this chromosome. Possible relationships between this sequence and the cytochemical staining properties of human chromosomes with distamycin A/DAPI, D280/170, and antiserum to 5-methylcytosine are discussed.

Longitudinal study of cognitive abilities and adaptive behavior levels in fragile X males: A prospective multicenter analysis

Retrospective longitudinal studies have noted declines in IQ scores in many but not all fra(X) (fragile X) males and females. We report on a prospective investigation of longitudinal changes in cognitive ability (IQ) and adaptive behavior (DQ) in 24 fra(X) males from four test sites. Individuals who were tested ranged in age from 3-15 years. To determine cognitive ability, all males were administered the Stanford-Binet test (4th Edition). To assess adaptive behavior, all males were evaluated using the Vineland Adaptive Behavior Scales. Mean interest interval was 2.3 years. Using identical DNA protocols, all subjects were identified as bearing the fra(X) mutation. Results showed declines in IQ scores in 18/24 (75%) males. Four males showed no change in scores. Declines in DQ scores were noted in 22/24 (92%) of those tested. DQ scores were higher than IQ scores in 20/24 (83%) subjects. From a descriptive cohort analysis, decreases in IQ scores appear to follow a well-defined, negatively decelerating function. Declines in DQ were steeper and more nearly linear. Declining scores are not indicative of regression of intellectual and/or social skills, but of a relative inability to keep pace with their age-normed cohort. We conclude that the fra(X) mutation affects cognitive abilities in a uniform, nonlinear manner comparable to outcomes observed in earlier retrospective studies. Adaptive behavior also declines, but in a more linear fashion.

The DLX1and DLX2 genes and susceptibility to autism spectrum disorders

An imbalance between excitation and inhibition in the cerebral cortex has been suggested as a possible etiology of autism. The DLX genes encode homeodomain-containing transcription factors controlling the generation of GABAergic cortical interneurons. The DLX1 and DLX2 genes lie head-to-head in 2q32, a region associated with autism susceptibility. We investigated 6 Tag SNPs within the DLX1/2 genes in two cohorts of multiplex (MPX) and one of simplex (SPX) families for association with autism. Family-based association tests showed strong association with five of the SNPs. The common alleles of rs743605 and rs4519482 were significantly associated with autism (P<0.012) in the first sample of 138 MPX families, with the latter remaining significant after correction for multiple testing (Pcor=0.0046). Findings in a second sample of 169 MPX families not only confirmed the association at rs4519482 (P=0.034) but also showed strong allelic association of the common alleles at rs788172, rs788173 and rs813720 (Pcor=0.0003–0.04). In the combined MPX families, the common alleles were all significantly associated with autism (Pcor=0.0005–0.016). The GGGTG haplotype was over transmitted in the two MPX cohorts and the combined samples [Pcor<0.05: Pcor=0.00007 for the combined MPX families, Odds Ratio: 1.75 (95% CI: 1.33–2.30)]. Further testing in 306 SPX families replicated the association at rs4519482 (P=0.033) and the over transmission of the haplotype GGGTG (P=0.012) although P-values were not significant after correction for multiple testing. The findings support the presence of two functional polymorphisms, one in or near each of the DLX genes that increase susceptibility to, or cause, autism in MPX families where there is a greater genetic component for these conditions.

A DRD1 haplotype is associated with risk for autism spectrum disorders in male-only affected sib-pair families.

Individuals with autism spectrum disorders (ASDs) have impairments in executive function and social cognition, with males generally being more severely affected in these areas than females. Because the dopamine D1 receptor (encoded by DRD1) is integral to the neural circuitry mediating these processes, we examined the DRD1 gene for its role in susceptibility to ASDs by performing single marker and haplotype case–control comparisons, family‐based association tests, and genotype–phenotype assessments (quantitative transmission disequilibrium tests: QTDT) using three DRD1 polymorphisms, rs265981C/T, rs4532A/G, and rs686T/C. Our previous findings suggested that the dopaminergic system may be more integrally involved in families with affected males only than in other families. We therefore restricted our study to families with two or more affected males (N = 112). There was over‐transmission of rs265981‐C and rs4532‐A in these families (P = 0.040, P = 0.038), with haplotype TDT analysis showing over‐transmission of the C‐A‐T haplotype (P = 0.022) from mothers to affected sons (P = 0.013). In addition, haplotype case–control comparisons revealed an increase of this putative risk haplotype in affected individuals relative to a comparison group (P = 0.004). QTDT analyses showed associations of the rs265981‐C, rs4532‐A, rs686‐T alleles, and the C‐A‐T haplotype with more severe problems in social interaction, greater difficulties with nonverbal communication and increased stereotypies compared to individuals with other haplotypes. Preferential haplotype transmission of markers at the DRD1 locus and an increased frequency of a specific haplotype support the DRD1 gene as a risk gene for core symptoms of ASD in families having only affected males.

Longitudinal changes in cognitive and adaptive behavior in fragile X females: A prospective multicenter analysis

In prospective studies of young, fragile X [fra(X)] males with the full mutation, cognitive abilities (IQ scores) and adaptive behavior levels (DQ scores) declined in most subjects tested. Little is known about longitudinal changes in IQ and DQ scores in young fra(X) females, although one earlier retrospective study showed declines in IQ scores in 8 of 11 subjects. To examine fra(X) females prospectively, we tested and retested 13 females with the full mutation, age 4 to 15 years. Nine were tested and retested in North America, and four were evaluated at the Catholic University in Leuven, Belgium. Cognitive abilities of North American females were measured using the Stanford-Binet 4th Edition. Adaptive behavior levels were ascertained from the Vineland Adaptive Behavior Scales. For Belgians, test-retest scores from the Wechsler Intelligence Scales for Children-Revised were used. Subjects were subsequently separated into two age cohorts: those tested initially before age 7 years and those tested initially after age 7 years. Compared with young males with the full mutation and of the same age, females expectedly display a wider range of IQ scores. Test-retest IQ scores showed statistically significant decreases (P < 0.03). Analysis of individual test-retest scores indicate that declines in eight females were statistically significant. Adaptive behavior scores were available only for North American females. Five of nine (55%) showed significant declines in DQ. Like young males with the full mutation, all females with the full mutation attained higher adaptive behavior levels than cognitive scores, i.e., DQ > IQ.

Multilocus analysis of the fragile X syndrome

SummaryA multilocus analysis of the fragile X (fra(X)) syndrome was conducted with 147 families. Two proximal loci, DXS51 and F9, and two distal loci, DXS52 and DXS15, were studied. Overall, the best multipoint distances were found to be DXS51-F9, 6.9%, F9-fra(X), 22.4%; fra(X)-DXS52, 12.7%; DXS52-DXS15, 2.2%. These distances can be used for multipoint mapping of new probes, carrier testing and counseling of fra(X) families. Consistent with several previous studies, the families as a whole showed genetic heterogeneity for linkage between F9 and fra(X).