Dissociation of social and nonsocial anxiety in a mouse model of fragile X syndrome

Anxiety is a common symptom in fragile X patients. However, an anxiety-prone phenotype in mouse models of fragile X syndrome is not clear. In most studies of fmr1 knockout mice, decreased anxiety-like responses in exploratory-based models are found, but mice also exhibit abnormal social interactions. We hypothesize the coexistence of elevated social anxiety and reduced nonsocial anxiety in fmr1 knockout mice. In the present study, we applied an automated three-chambered social approach method and the elevated zero maze test to further investigate social interactions and general anxiety, respectively. Results indicate lower levels of both social approach behavior and response to social novelty in fmr1 knockout mice compared with wild-type littermates in the social interaction test. In the elevated zero maze, fmr1 knockout mice spent a greater percent time in open quadrants than wild-type mice, suggesting reduced nonsocial anxiety. These findings support the hypothesis that social and nonsocial anxiety can be dissociated and that in the fragile X mouse model, behavior consistent with hyper-social anxiety coexists with hypo-nonsocial anxiety.     

Transgenic mouse model for the fragile X syndrome

Transgenic fragile X knockout mice have been constructed to provide an animal model to study the physiologic function of the fragile X gene (FMR1) and to gain more insight into the clinical phenotype caused by the absence of the fragile X protein. Initial experiments suggested that the knockout mice show macroorchidism and cognitive and behavioral deficits, abnormalities comparable to those of human fragile X patients. In the present study, we have extended our experiments, and conclude that the Fmr1 knockout mouse is a reliable transgenic model to study the fragile X syndrome. © 1996 Wiley-Liss, Inc.     

Altered maturation of the primary somatosensory cortex in a mouse model of fragile X syndrome

Fragile X syndrome (FXS) is the most common inherited form of intellectual disability and results from the loss of the fragile X mental retardation protein (FMRP). Many fragile X-related cognitive and behavioral features emerge during childhood and are associated with abnormal synaptic and cellular organization of the cerebral cortex. Identifying the roles of FMRP in cortical development will provide a basis for understanding the pathogenesis of the syndrome. However, how the loss of FMRP influences the developmental trajectory of cortical maturation remains unclear. We took advantage of the stereotyped and well-characterized development of the murine primary somatosensory cortex to examine cortical maturation during a time-window that corresponds to late embryonic and early postnatal development in the human. In the Fmr1 knockout mouse, we find a delay in somatosensory map formation, alterations in the morphology profile of dendrites and spines of layer 4 neurons and a decrease in the synaptic levels of proteins involved in glutamate receptor signaling at times corresponding to the highest levels of FMRP expression. In contrast, cortical arealization, synaptic density in layer 4 and early postnatal regulation of mRNAs encoding synaptic proteins are not altered in Fmr1 knockout mice. The specificity of the developmental delay in Fmr1 knockout mice indicates that the loss of FMRP does not result in a general stalling of cerebral cortex maturation. Instead, our results suggest that inaccurate timing of developmental processes caused by the loss of FMRP may lead to alterations in neural circuitry that underlie behavioral and cognitive dysfunctions associated with FXS.     

Craniofacial characteristics of fragile X syndrome in mouse and man

For a disorder as common as fragile X syndrome, the most common hereditary form of cognitive impairment, the facial features are relatively ill defined. An elongated face and prominent ears are the most commonly accepted dysmorphic hallmarks. We analysed 3D facial photographs of 51 males and 15 females with full FMR1 mutations and 9 females with a premutation using dense-surface modelling techniques and a new technique that forms a directed graph with normalized face shapes as nodes and edges linking those with closest dysmorphism. In addition to reconfirming known features, we confirmed the occurrence of some at an earlier age than previously recorded. We also identified as yet unrecorded facial characteristics such as reduced facial depth, hypoplasticity of the nasal bone–cartilage interface and narrow mid-facial width exaggerating ear prominence. As no consistent craniofacial abnormalities had been reported in animal models, we analysed micro-CT images of the fragile X mouse model. Results indicated altered dimensions in the mandible and both outer and inner skull, with the latter potentially reflecting differences in neuroanatomy. We extrapolated the mouse results to face shape differences of the human fragile X face.     

Disrupted Homer scaffolds mediate abnormal mGluR5 function in a mouse model of fragile X syndrome

Enhanced metabotropic glutamate receptor subunit 5 (mGluR5) function is causally associated with the pathophysiology of fragile X syndrome, a leading inherited cause of intellectual disability and autism. Here we provide evidence that altered mGluR5-Homer scaffolds contribute to mGluR5 dysfunction and phenotypes in the fragile X syndrome mouse model, Fmr1 knockout (Fmr1(-/y)). In Fmr1(-/y) mice, mGluR5 was less associated with long Homer isoforms but more associated with the short Homer1a. Genetic deletion of Homer1a restored mGluR5-long Homer scaffolds and corrected several phenotypes in Fmr1(-/y) mice, including altered mGluR5 signaling, neocortical circuit dysfunction and behavior. Acute, peptide-mediated disruption of mGluR5-Homer scaffolds in wild-type mice mimicked many Fmr1(-/y) phenotypes. In contrast, Homer1a deletion did not rescue altered mGluR-dependent long-term synaptic depression or translational control of target mRNAs of fragile X mental retardation protein, the gene product of Fmr1. Our findings reveal new functions for mGluR5-Homer interactions in the brain and delineate distinct mechanisms of mGluR5 dysfunction in a mouse model of cognitive dysfunction and autism.     

Attentional dysfunction, impulsivity, and resistance to change in a mouse model of fragile X syndrome

On a series of attention tasks, male mice with a mutation targeted to the fragile X mental retardation 1 (Fmrl) gene (Fmrl knockout [KO] mice) committed a higher rate of premature responses than wild-type littermates, with the largest differences seen when task contingencies changed. This finding indicates impaired inhibitory control, particularly during times of stress or arousal. The KO mice also committed a higher rate of inaccurate responses than controls, particularly during the final third of each daily test session, indicating impaired sustained attention. In the selective attention task, the unpredictable presentation of potent olfactory distractors produced a generalized disruption in the performance of the KO mice, whereas for controls, the disruption produced by the distractors was temporally limited. Finally, the attentional disruption seen following an error was more pronounced for the KO mice than for controls, further implicating impaired regulation of arousal and/or negative affect. The present study provides the first evidence that the Fmrl KO mouse is impaired in inhibitory control, attention, and arousal regulation, hallmark areas of dysfunction in fragile X syndrome. The resistance to change also seen in these mice provides a behavioral index for studying the autistic features of this disorder.     

Survey of the fragile X syndrome and the fragile X E syndrome in a special education needs population

To begin to understand the population dynamics of the fragile X (FRAXA) mutation and to learn more about the fragile X E (FRAXE) syndrome, we have initiated a survey of children in special needs education programs in the public school system. With respect to the FRAXA syndrome, we found approximately 1/1,000 full mutations among males. No large alleles at the FRAXE locus were observed among 462 individuals. The allele distributions at the two loci among Caucasians and among African Americans were examined as well as the level of heterozygosity. We found a significant difference in the FRAXA allele distribution among the two ethnic groups; the major difference was due to the lack of smaller alleles among the African Americans. No difference was found for the FRAXE allele distribution among the two groups. The level of heterozygosity was less than predicted by the allele distribution at both loci. This is probably due to unidentified large alleles among females with a test result of a single band. Alternatively, this excess may indicate that the population is not at equilibrium. © 1996 Wiley-Liss, Inc.     

A metabolomic and systems biology perspective on the brain of the fragile X syndrome mouse model

Fragile X syndrome (FXS) is the first cause of inherited intellectual disability, due to the silencing of the X-linked Fragile X Mental Retardation 1 gene encoding the RNA-binding protein FMRP. While extensive studies have focused on the cellular and molecular basis of FXS, neither human Fragile X patients nor the mouse model of FXS--the Fmr1-null mouse--have been profiled systematically at the metabolic and neurochemical level to provide a complementary perspective on the current, yet scattered, knowledge of FXS. Using proton high-resolution magic angle spinning nuclear magnetic resonance ((1)H HR-MAS NMR)-based metabolic profiling, we have identified a metabolic signature and biomarkers associated with FXS in various brain regions of Fmr1-deficient mice. Our study highlights for the first time that Fmr1 gene inactivation has profound, albeit coordinated consequences in brain metabolism leading to alterations in: (1) neurotransmitter levels, (2) osmoregulation, (3) energy metabolism, and (4) oxidative stress response. To functionally connect Fmr1-deficiency to its metabolic biomarkers, we derived a functional interaction network based on the existing knowledge (literature and databases) and show that the FXS metabolic response is initiated by distinct mRNA targets and proteins interacting with FMRP, and then relayed by numerous regulatory proteins. This novel "integrated metabolome and interactome mapping" (iMIM) approach advantageously unifies novel metabolic findings with previously unrelated knowledge and highlights the contribution of novel cellular pathways to the pathophysiology of FXS. These metabolomic and integrative systems biology strategies will contribute to the development of potential drug targets and novel therapeutic interventions, which will eventually benefit FXS patients.     

Prevalence of fragile X syndrome

The much-quoted prevalence figure of 1:1,000 males for fragile X syndrome is an overestimate in a mixed ethnic population. A reexamination of the individuals from whom those data were derived using molecular diagnostic techniques demonstrates a more realistic figure of 1:4,000 males. © 1996 Wiley-Liss, Inc.     

脆性X综合征诊断方法进展

脆性X综合征发病率高,目前尚无有效的治疗方法.降低脆性X综合征发病率的关键是尽早查出双亲致病基因携带者及胎儿,通过遗传咨询、产前诊断避免患儿出生.随着分子遗传技术方法的进展,对脆性X综合征的诊断水平也不断提高.本文在对脆性X综合征临床体征诊断基础上,简要介绍了对脆性X综合征诊断的细胞遗传学分析方法、DNA分子诊断方法以及基因表达产物的免疫细胞化学诊断方法的应用.     

Preventive screening for the fragile X syndrome

In an Australian population of 1.2 million, we screened 1977 intellectually handicapped persons, who were identified through the public schools and sheltered workshops, for the X-linked semidominant fragile X syndrome. We excluded 527 because they had another known diagnosis. The remaining 1450 were offered chromosomal analysis. Of the 1117 who consented (77 percent), an additional 196 were excluded, and among the 921 who were tested cytogenetically, 40 probands were found. Prevalence rates for persons with an intellectual handicap and the fragile X syndrome in the public school population were 1:2610 for males and 1:4221 for females. Family studies identified 84 women who were either obligate carriers or at high risk of being carriers, who were under the age of 35 and had no children. These women were given genetic counseling, and the availability of antenatal diagnosis was explained to them. If each of these 84 women had two children, 27 of their sons would have an intellectual handicap. We recommend cytogenetic screening for the fragile X syndrome in all currently identified intellectually handicapped people, followed by routine screening of children newly identified as intellectually handicapped in the school system.     

Prader-Willi-like phenotype in fragile X syndrome

Henk Meyer¹
A 3-year-old boy was referred to the pediatric department because of unexplained extreme obesity. Height and occipitofrontal circumference were just above the 90th centile. Endocrine studies failed to show any significant abnormality. Motor and speech development were generally delayed. On clinical-cytogenetic-molecular grounds, Prader-Willi syndrome was excluded. Fragile X syndrome was diagnosed by the presence of the classical FMR-1 mutation and confirmed by cytogenetic studies, revealing 20% fragile X positive cells. We compare the clinical features in the present patient with the nine reported patients with fra(X) syndrome and extreme obesity. In pathogenesis, hypothalamic dysregulation is hypothesized. In differential diagnosis of Prader-Willi syndrome, fragile X has to be considered, especially when laboratory workup for Prader-Willi syndrome is negative. Clinical behavior can be of help.     

Oral findings in fragile X syndrome

This study compares the oral findings in fragile X syndrome individuals to those of normal age-matched patients. Sixteen fra(X) males (mean age 22 10/12 years) had a low caries rate (decayed, missing and filled surfaces (DMFS) = 12.3) and minimal intraoral hard or soft tissue disease. Rate of malocclusion, as determined by the first permanent molar classification of Angle, was not significantly different from that of matched subjects. Fra(X) subjects had a significantly higher occurrence of malocclusion as compared to matched subjects using crossbite and openbite as criteria. Palatal dimensions of fra(X) subjects did not differ significantly from those of the matched sample. The fra(X) males also demonstrated significantly more severe occlusal wear of their teeth than the matched sample.     

Autonomic regulation in fragile X syndrome

Autonomic reactivity was studied in individuals with fragile X syndrome (FXS), a genetic disorder partially characterized by abnormal social behavior. Relative to age-matched controls, the FXS group had faster baseline heart rate and lower amplitude respiratory sinus arrhythmia (RSA). In contrast to the typically developing controls, there was a decrease in RSA with age within the FXS group. Moreover, within the FXS group heart rate did not slow with age. The FXS group also responded with an atypical increase in RSA to the social challenge, while the control group reduced RSA. In a subset of the FXS group, the autonomic profile did not change following 2 months and 1 year of lithium treatment. The observed indices of atypical autonomic regulation, consistent with the Polyvagal Theory, may contribute to the deficits in social behavior and social communication observed in FXS.     

Sequence of abnormal dendritic spine development in primary somatosensory cortex of a mouse model of the fragile X mental retardation syndrome

Anatomical analyses of occipital and temporal cortex of patients with fragile X mental retardation syndrome (FXS) and in a mouse model of the syndrome (FraX mice) compared to controls have suggested that the fragile X mental retardation protein (FMRP) is important for normal spine structural maturation and pruning. However, a recent analysis of spine properties in somatosensory cortex of young FraX mice has suggested that this region may not exhibit spine abnormalities. While spine abnormalities were present 1 week after birth in somatosensory cortex, by 4 weeks almost all spine abnormalities had disappeared, suggesting that adult spine abnormalities observed in other cortical regions may not persist post-developmentally in somatosensory cortex. To resolve this discrepancy we examined spine properties in somatosensory cortex of young (day 25) and adult (day 73-76) FraX compared to wild-type (WT) mice. Spine properties in young FraX and WT mice did not consistently differ from each other, consistent with the recent analysis of developing somatosensory cortex. However, adult FraX mice exhibited increased spine density, longer spines, more spines with an immature-appearing structure, fewer shorter spines, and fewer spines with a mature structure, a pattern consistent with prior analyses from other adult cortical brain regions in humans and mice. These findings (1) support the previous report of the absence of major spine abnormalities in the fourth postnatal week, (2) demonstrate normal spine development in WT mice, (3) demonstrate abnormal spine development after the fourth postnatal week in FraX mice, and (4) demonstrate spine abnormalities in somatosensory cortex of adult FraX compared to adult WT mice. In doing so, these findings resolve a potential conflict in the literature and more thoroughly describe the role of FMRP in spine development.     

Epilepsy and fragile X syndrome: a follow-up study

This paper describes EEG and clinical findings resulting from a follow-up investigation in a group of 18 males with fragile X syndrome, in whom a characteristic paroxysmal EEG pattern was previously described. The following types of evolution were observed: (1) disappearance of the pattern (with a gradual lowering of the amplitude of spikes and in some cases with asynchrony between the two hemispheres); (2) disappearance of the quasi-rhythmic centrotemporal spikes and persistence of bisynchronous polyspike and wave complexes in the temporo-parieto-frontal regions; and (3) persistence of the previously observed pattern. These results confirm the already observed similarity between this condition and the benign childhood epilepsy with centrotemporal spikes, also from the maturational point of view; on the other hand, they also indicate some difference (i.e., mental retardation, slow background EEG activity, brain atrophy). Moreover, these findings are encouraging for the possible development of research in the field of molecular genetics in epilepsy, because they provide a precise site of investigation on the X chromosome.     

Metabotropic receptor-dependent long-term depression persists in the absence of protein synthesis in the mouse model of fragile X syndrome

Fragile X syndrome (FXS), a form of human mental retardation, is caused by loss of function mutations in the fragile X mental retardation gene (FMR1). The protein product of FMR1, fragile X mental retardation protein (FMRP) is an RNA-binding protein and may function as a translational suppressor. Metabotropic glutamate receptor-dependent long-term depression (mGluR-LTD) in hippocampal area CA1 is a form of synaptic plasticity that relies on dendritic protein synthesis. mGluR-LTD is enhanced in the mouse model of FXS, Fmr1 knockout (KO) mice, suggesting that FMRP negatively regulates translation of proteins required for LTD. Here we examine the synaptic and cellular mechanisms of mGluR-LTD in KO mice and find that mGluR-LTD no longer requires new protein synthesis, in contrast to wild-type (WT) mice. We further show that mGluR-LTD in KO and WT mice is associated with decreases in AMPA receptor (AMPAR) surface expression, indicating a similar postsynaptic expression mechanism. However, like LTD, mGluR-induced decreases in AMPAR surface expression in KO mice persist in protein synthesis inhibitors. These results are consistent with recent findings of elevated protein synthesis rates and synaptic protein levels in Fmr1 KO mice and suggest that these elevated levels of synaptic proteins are available to increase the persistence of LTD without de novo protein synthesis.