Confounding factors in fragile X diagnosis

Barrett, Nancy L.

January 1984

Thesis (M.S.)--University of Wisconsin--Madison, 1984. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 70-75).

The effects of BMS-204352, an activator of voltage-gated potassium channels, in the infralimbic cortex of the Fmr1 knockout mouse, an animal model of fragile X syndrome

January 2020

archives@tulane.edu / Autism spectrum disorders (ASD) are commonly characterized by abnormal social behaviors. Fragile X syndrome (FXS) is the most common inherited intellectual disability in humans and the most common single-gene cause of ASD symptoms. FXS is caused by the loss or malfunction of the fragile X mental retardation protein (FMRP), an mRNA-binding protein that regulates numerous synaptic proteins, both translationally and through direct protein-protein interactions. One direct-binding target is the large-conductance potassium (BK) channel. BK channels have been shown to be hypoactive in FXS, and represent possible targets for treatment in both general ASD and in FXS specifically. Also, two members of the KCNQ class of voltage-activated potassium channels, KV7.2 and KV7.3, have been identified as FMRP translation targets. Finally, a commonly observed abnormality in the ASD brain is an imbalance in the ratio of excitatory to inhibitory signaling (E/I balance) causing general hyperexcitability in numerous brain areas. One area in which altered E/I balance is often observed is the medial prefrontal cortex (mPFC), which is involved with the processing of social information. Therefore, the goal of this dissertation was to determine if stimulating potassium channel function in the mPFC of Fmr1 KO mice would correct abnormal social behavior. In addition, the possible mechanistic determinants and effects on E/I balance were investigated in WT and Fmr1 KO mice. Infusion of the potassium channel activator, BMS-204352, into the mPFC of KO mice had no effect on social approach behavior, but corrected social novelty impairments as measured by a 3-Chamber Test. Whole-cell patch clamp recordings of pyramidal neurons in layer V of the mPFC revealed no differences in mEPSCs between KO and WT mice, but did reveal higher frequency of mIPSCs in KO mice. Treatment with BMS-204352 resulted in a decrease in mEPSC amplitude in both genotypes, which was blocked by the BK channel antagonist, paxilline. Effects of BMS-204352 treatment on mIPSCs revealed two possible populations of cell types. One population of exhibited a decrease in frequency of mIPSCs, an effect seen in both genotypes. The other population exhibited a slight increase in frequency of mIPSCs, but this was seen only in KO cells. Treatment with paxilline caused a decrease in mIPSC frequency in both genotypes, which was not altered with subsequent BMS-204352 treatment. Pretreatment with the KV7 channel antagonist XE 991 prevented BMS-204352-induced cross-genotype decrease in mIPSC frequency, but did not prevent BMS-204352-induced frequency increase in KO cells. Western blot analyses revealed no changes between genotypes in BK channel expression, but a trend to increased KV7.3 expression in the PFC of KOs compared to WTs. With these data, it was concluded that aberrant activity of potassium channels in the mPFC of KOs mediates some of the social abnormalities observed in the phenotype, that KOs may exhibit increased KV7.3 expression as a potential compensatory mechanism for BK channel dysfunction, and that potassium channels are a promising potential target for future treatment of ASD symptoms / 1 / Ted Sawyer

prefrontal cortex

fragile X syndrome

social behavior

Fragile X Syndrome: A Family Study

Wessels, Tina-Marie

31 October 1997

A research report submitted to the Faculty of Medicine, University of the Witwatersrand, Johannesburg, in partial fulfilment of the requirements for the Degree of Master of Science in Medicine. Johannesburg October, 1997 / Fragile X syndrome is, second to Down syndrome, the commonest form of genetic mental retardation. The aim of this research project was to investigate the impact of having a child with this syndrome on the family relationships. The subjects were 21 mothers and 9 fathers of affected children. The data were collected by means of specially constructed questionnaires in interviews with 19 mothers and 8 fathers and completed by post in three cases. A control group of parents with a normal child, matched for sex and age of the affected child, family size and ethnic groups, was interviewed. The data were computerised and analyzed. The results showed that more experimental parents than controls enjoyed their child’s nature, but disliked the behavioural problems. About half of the experimental parents tended not to reward good behaviour physically. However, although most of the affected children were accepted by their siblings, they had fewer friends and more problems with their peers. Some parents thought that their relationship with their spouse had improved and others thought that it had deteriorated after the affected child’s birth. Most parents in both study groups would request prenatal diagnosis in subsequent pregnancies and significantly more experimental parents than controls would request a termination of pregnancy for an affected fetus. Most parents were satisfied with the health service they received. These results show that family dynamics are disturbed by the presence of a child with FMR. Counsellors and therapists working with these families should be aware of the effects of the syndrome on the family / IT2017

Fragile X Syndrome

Child

Humans

DNA Methylation

A Comparison of Straight-Stained, Q-stained, and Reverse Flourescent-Stained Cell Lines for Detection of Fragile Sites on the Human X Chromosome

Coultas, Susan L. (Susan Lynette)

05 1900

Cell cultures were examined for percentage of fragile sites seen in straight-stained, Q-stained and reverse fluorescent-stained preparations. In all cases, percentage of fragile site expression was decreased when compared to straight-stained preparations. However, fragile sites seen in Q- and RF-stain could be identified as on X chromosomes.

human chromosome abnormalities

chromosomes

fragile x syndrome

The role of Fragile X mental retardation protein in Drosophila cleavage furrow formation

Monzo, Kate Frances

20 August 2010

Reduced activity of Fragile X mental retardation protein (FMRP) in brain neurons results in the most common form of heritable mental retardation in humans, Fragile X Syndrome (FXS). FMRP is a selective RNA-binding protein that is implicated in the translational regulation of specific mRNAs in neurons. Although very few direct targets of FMRP have been identified and verified in vivo, FXS is thought to result from the aberrant regulation of potentially hundreds of mRNAs causing defects in neuron morphology and synapse function. Identifying additional targets will be important for elucidating the mechanism of FMRP regulation as well as the etiology of FXS. Drosophila melanogaster offers a unique and powerful system for studying the function of FMRP. Flies with loss of FMRP activity have neuronal and behavioral defects similar to those observed in humans with FXS. Importantly, FMRP regulates common target mRNAs in neurons in both mice and flies. Here, I will describe our discovery of a previously unknown requirement for Drosophila FMRP (dFMRP) during the cleavage stage of early embryonic development. First, we identified a requirement for dFMRP for proper cleavage furrow formation and found that dFMRP functions to regulate the expression of specific target mRNAs during the cleavage stage. Among these is trailer hitch (tral) mRNA, which encodes a translational regulator as well, and represents a new in vivo target of dFMRP translational regulation. In addition, I have identified twenty-eight proteins that change in expression in the absence of dFMRP using a comparative proteomics based screen for dFMRP targets. One of these is the Chaperonin containing tcp-1 complex (CCT), a previously unidentified target, which I found is itself also required for cleavage furrow formation. Finally, we have identified a new dFMRP protein-binding partner, Caprin, and found that together dFMRP and Caprin are required for the proper timing of the MBT. This set of work has led to a better understanding of the mechanism of dFMRP-dependent regulation of cellular morphogenesis in early embryos and has the potential to lead to a better understanding of the etiology of FXS. / text

Fragile X Syndrome

Fragile X mental retardation protein

Drosophila

Cleavage

Cellularization

A Drosophila model of cellular and molecular mechanisms of fragile X syndrome

Pan, Luyuan,

January 2007

Thesis (Ph. D. in Biological Science)--Vanderbilt University, Dec. 2007. / Title from title screen. Includes bibliographical references.

The FMR1 gene in mental retardation. / CUHK electronic theses & dissertations collection

January 1997

by Priscilla Miu-kuen Poon. / Thesis (Ph.D.)--Chinese University of Hong Kong, 1997. / Includes bibliographical references (p. 176-193). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web.

Fragile X Syndrome

Intellectual Disability

Fragile X Syndrome--epidemiology

Intellectual Disability--epidemiology

Role of mGluR5 and FMRP in mouse primary somatosensory cortex

Wijetunge, Lasani Sulochana

January 2009

The accurate development of the wiring between the billions of neurons in our brain is fundamental to brain function. Development of this connectivity relies on activity-dependent modification of synapses similar to those that underlie learning and memory. Glutamate is the principal excitatory neurotransmitter in the mammalian brain and several brain disorders result from altered glutamatergic receptor signalling (Catania et al., 2007; Lau and Zukin, 2007). Genes encoding glutamate receptor associated proteins have a high incidence of mutation in cognitive disorders, especially X-linked mental retardation (MR)(Laumonnier et al., 2007). MR has long been associated with altered cortical connectivity, particularly dendritic spine dysgenesis. There is also an emerging view that aberrant local protein synthesis within dendrites and protein trafficking to dendrites underlies some forms of MR (Kelleher and Bear, 2008; Pfeiffer and Huber, 2006; Zalfa and Bagni, 2005). Most studies examining the role of glutamatergic receptors in MR have focused on adults. Little is known about how these MR genes regulate brain development despite their neurodevelopmental aetiology. Fragile X mental retardation (FXS) is the most common form of inherited MR and results from the loss of fragile X mental retardation protein (FMRP). FMRP is a RNA binding protein and is hypothesised to have a role in protein trafficking from nucleus to sites of synapses, and regulating local protein synthesis at sites of synapses (Bagni and Greenough, 2005). A prevalent theory of FXS causation is ‘metabotropic glutamate receptor (mGluR) theory of fragile X’, which postulates that all functional consequences of mGluR (predominantly mGluR5)-dependent protein synthesis maybe exaggerated in FXS (Bear et al., 2004). Primary somatosensory cortex (S1) of rodents provides an excellent model system to study the role of MR genes in development because of its stereotypic, glutamate receptor-dependent, anatomical development (Barnett et al., 2006b; Erzurumlu and Kind, 2001). Hannan et al., (2001) reported that genetic deletion of mGluR5 results in loss of ‘barrels’, the anatomical correlates of rodent whiskers in S1. Chapter 3 extends these findings to show that there is expression of mGluR5 as early as P4 in S1 prior to segregation of layer 4 cells into barrels suggesting a tropic role for glutamate in barrel formation. The expression of mGluR5 is postsynaptic during barrel formation and does not regulate tangential or radial cortical development. Its effects on barrel segregation are dose dependent and are not due to a developmental delay. During late S1 development, loss of mGluR5 results in decreased spine density suggesting a role in synaptogenesis. Supporting this hypothesis in mGluR5 mutant mice there is a general decrease in expression of synaptic markers in early S1 development. Chapter 4 explores the role of FMRP in cortical development. FMRP is expressed early in S1 development with peak expression prior to synaptogenesis at P14. It is expressed postsynaptically at P7 and pre and postsynaptically at P14. FMRP does not regulate cortical arealisation during barrel formation but results in decreased barrel segregation. In the absence of FMRP, biochemical studies show altered expression of glutamatergic receptors in the neocortex P7 and P14 suggesting altered glutamatergic receptor composition at synaptic sites. During late S1 development, loss of FMRP results in increased spine density in layer 4 spiny cells. Together these data indicate a role for FMRP during early and late S1 development. Chapter 5 directly tests the mGluR theory of FXS by examining whether genetic reduction of mGluR5 levels rescues anatomical phenotypes characterised in Fmr1-/y mice. The defect in barrel formation in Fmr1-/y mice is partially rescued by reducing mGluR5 levels. However, layer 4 spine density in Fmr1-/y mice does not appear to be rescued. Chapter 6 explores the expression patterns of three key synaptic MAGUKs (Membrane associated guanylate kinases) PSD95, SAP102 and PSD93, one of which (PSD95) is regulated by FMRP (Zalfa et al., 2007) and the others which have putative binding sites for FMRP. MAGUKs tether glutamatergic receptors to their associated signalling complexes at the postsynaptic membrane and also regulate glutamatergic receptor trafficking (Collins and Grant, 2007; Kim and Sheng, 2004). The immunohistochemical expression profiles of PSD95, SAP102 and PSD93 show dynamic regulation during S1 development that is unaffected by loss of FMRP (at P7), and biochemical data indicates that basal levels of these MAGUKs in neocortex are unaltered at P7 and P14 in Fmr1-/y mice. In Sap102-/y and Psd95-/- mice, there is altered expression of several synaptic proteins biochemically providing evidence for differential roles of SAP102 and PSD95 in regulating expression of glutamatergic receptors at synaptic sites during early S1 development. This thesis demonstrates that synaptic proteins associated with MR are expressed early in development and display regulatory roles in cellular processes governing S1 formation. An understanding of their role in early brain development would be critical in fully appreciating when and where they exert their regulatory effects, and this in turn would be beneficial in designing therapeutic interventions.

612.8

Novel Roles for Fragile X Protein in Neurogenesis

Callan, Matthew Aron

January 2011

Fragile X Syndrome (FXS) is the most common form of inherited mental retardation, affecting approximately 1/4000 males and 1/6000 females worldwide. FXS is caused by loss of FMR1 gene expression, resulting in the lack of the protein product, Fragile X protein (FMRP). FMRP is an RNA-binding protein thought to regulate synaptic plasticity by controlling the localization and translation of specific mRNAs in neurons. To determine whether FMRP is also required in early brain development we examined the distribution of cell cycle markers in Drosophila FMR1 (dFmr1) mutant brains compared to wild-type brains. Our results indicate that the loss of dFmr1 leads to a significant increase in the number of mitotic neuroblasts and BrdU incorporation in the brain, consistent with the notion that FMRP controls proliferation in neural stem cells. To determine the role of FMRP in neuroblast division and differentiation, we used Mosaic Analysis with a Repressible Marker (MARCM) approaches in the developing larval brain and found that single dFmr1 neuroblasts generate significantly more neurons than controls. Developmental studies suggest that FMRP also inhibits neuroblast exit from quiescence, or reactivation, in early larval brains, as indicated by misexpression of the G1 to S phase transition marker Cyclin E. We have also identified a novel role for FMRP in the glia surrounding the neuroblasts, indicating that FMRP in these cells contributes to the regulation of neuroblast reactivation via signaling from the supporting glial cells. Our results demonstrate that FMRP is required during brain development to control the exit from quiescence and proliferative capacity of neuroblasts as well as neuron production, which may provide insights into Fragile X Syndrome and other Autism-Spectrum disorders.

Autism Spectrum

Fragile X

Glia

Neural Stem Cell

Neurogenesis

Resilience in the presence of fragile X syndrome : a multiple case study / Chantel L. Fourie

Fourie, Chantel Lynette

January 2011

The purpose of this study was to explore what contributes to resilience in females diagnosed with Fragile X Syndrome. Fragile X Syndrome can be defined as an inherited (genetic) condition that causes mental impairment, attention deficit and hyperactivity, anxiety and unstable mood, autistic behaviours, hyper-extensible joints, and seizures. I became aware of Fragile X Syndrome during my time as a live-in caretaker to an adolescent female who was diagnosed with Fragile X Syndrome. Because she coped with her disability so resiliently, I was encouraged to explore what contributes to resilience in females diagnosed with Fragile X Syndrome. I followed a qualitative approach, anchored in the interpretivist paradigm. This means that I tried to understand the resilience of females diagnosed with Fragile X Syndrome through the meanings that the participants in my study assigned to them. Furthermore, I worked from a transformative paradigm, which meant that I was interested in changing the traditionally negative ways in which females diagnosed with Fragile X Syndrome are seen. I followed a multiple case study approach, which included four case studies. I conveniently selected the first participant, but realised that convenience sampling was not very credible for a qualitative case study. An Advisory Panel was then used to purposefully recruit three more participants. In order to explore what contributed to their resilience, I made use of interviews, observations, and visual data collection. I also interviewed adults (e.g. parents, teachers and consulting psychologists) who were significantly involved in the lives of my participants. My findings suggest that resilience in females with Fragile X Syndrome is rooted in protective processes within the individual as well as within her family and environment. Because my findings do not point to one specific resource, my study underscores newer understandings of resilience as an Eco systemic transaction. Most of the resilience-promoting resources noted by the participants in my study as contributing to their resilience have been identified as resilience-promoting in previous studies. Although the themes that emerged in my study have been reported in resilience previously, I make a contribution to theory because I link traditional resilience-promoting resources to resilience in females diagnosed with Fragile X Syndrome. Peer support was previously reported as a resilience-promoting resource, but in my study I noticed that the main source of peer support came from peers who were also disabled. Furthermore, my study transforms how we see females diagnosed with Fragile X Syndrome. This transformation encourages communities and families to work together towards resilience in females diagnosed with Fragile X Syndrome. / Ph.D, North-West University, Vaal Triangle Campus, 2011

Resilience

Protective resources

Fragile X syndrome

Ecosystemic

Qualitative research