Stela Filipovic-Sadic scite author profile

BACKGROUND Fragile X Syndrome (FXS) is a trinucleotide repeat disease that is caused by the expansion of CGG sequences in the 5’ untranslated region of the FMR1 gene. Molecular diagnoses of FXS and other emerging FMR1 disorders typically rely on two tests, PCR and Southern blotting. However, performance or throughput limitations in these methods currently constrain routine testing. METHODS We evaluated a novel FMR1 gene-specific PCR technology with 20 cell line DNA templates and 146 blinded clinical specimens. The CGG repeat number was determined by fragment sizing of PCR amplicons using capillary electrophoresis and compared with the results of FMR1 Southern blotting performed with the same samples. RESULTS The FMR1 PCR accurately detected full mutation alleles up to at least 1300 CGG repeats and comprising >99% GC character. All categories of alleles detected by Southern blot, including 66 specimens with full mutations, were also identified by FMR1 PCR for each of 146 clinical specimens. Since all full mutation alleles in heterozygous female samples were detected by PCR, allele zygosity was reconciled in every case. The PCR reagents also detected a 1% mass fraction of a 940 CGG allele in a background of 99% 23 CGG allele—roughly 5-fold greater sensitivity than Southern blotting. CONCLUSIONS The novel PCR technology can accurately categorize the spectrum of FMR1 alleles, including alleles previously considered too large to amplify, reproducibly detect low abundance full mutation alleles, and correctly infer homozygosity in female specimens, thus greatly reducing the need for sample reflexing to Southern blot.

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An Information-Rich CGG Repeat Primed PCR That Detects the Full Range of Fragile X Expanded Alleles and Minimizes the Need for Southern Blot Analysis

Chen

Hadd

Sah

et al. 2010

The Journal of Molecular Diagnostics

165

198

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(CGG) n repeat expansion in the FMR1 gene is associated with fragile X syndrome and other disorders. Current methods for FMR1 molecular testing rely on Southern blot analysis to detect expanded alleles too large to be PCR-amplified and to identify female homozygous alleles that often confound interpretations of PCR data. A novel , single-tube CGG repeat primed FMR1 PCR technology was designed with two genespecific primers that flank the triplet repeat region, as well as a third primer that is complementary to the (CGG) n repeat. This PCR was evaluated with 171 unique DNA samples , including a blinded set of 146 clinical specimens. The method detected all alleles reported by Southern blot analysis , including full mutations in 66 clinical samples and comprised up to 1300 CGG. Furthermore , a blinded cohort of 42 female homozygous and heterozygous specimens, including 21 with full mutation alleles , was resolved with 100% accuracy. Last , AGG interrupter sequences, which may influence the risk of (CGG) n expansion in the children of some carriers , were each correctly identified in 14 male and female clinical samples as referenced to DNA sequencing. As a result , this PCR provides robust detection of expanded alleles and resolves allele zygosity , thus minimizing the number of samples that require Southern blot analysis and producing more comprehensive FMR1 genotyping data than other methods. Expansion of cytosine-guanine-guanine (CGG) triplet repeats in the 5Ј-untranslated region of the fragile X mental retardation 1 (FMR1, NM_002024.4) gene is associated with several disorders, including fragile X syndrome, fragile X-associated tremor/ataxia syndrome, and fragile X-associated primary ovarian insufficiency. [1][2][3][4] Patients with the FMR1 full mutation (Ͼ200 CGG repeats) may be affected by a range of neurological, psychiatric, or emotional challenges, including mental retardation and/or autism.5 Deficits in development and particularly in attention and social communication have also been noted for many children with the FMR1 premutation. Moreover, premutation carriers (55 to 200 CGG repeats) are known to be at risk for fragile X-associated primary ovarian insufficiency and fragile X-associated tremor/ataxia syndrome, and some of these individuals may present additional complications, such as hypothyroidism and fibromyalgia.6 As a result, FMR1 disorders are linked to a range of clinical conditions, necessitating testing patients at different times during their life span. 7Fragile X syndrome molecular diagnosis is usually based on quantification of the (CGG) n repeat elements and the assessment of the methylation state of expanded alleles.5 Although PCR is the preferred approach to determine the (CGG) n repeat length of FMR1 alleles, typically only alleles with less than 100 to 150 CGG have

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A Genotype-Phenotype Study of High-Resolution FMR1 Nucleic Acid and Protein Analyses in Fragile X Patients with Neurobehavioral Assessments

et al. 2020

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Fragile X syndrome (FXS) is caused by silencing of the FMR1 gene, which encodes a protein with a critical role in synaptic plasticity. The molecular abnormality underlying FMR1 silencing, CGG repeat expansion, is well characterized; however, delineation of the pathway from DNA to RNA to protein using biosamples from well characterized patients with FXS is limited. Since FXS is a common and prototypical genetic disorder associated with intellectual disability (ID) and autism spectrum disorder (ASD), a comprehensive assessment of the FMR1 DNA-RNA-protein pathway and its correlations with the neurobehavioral phenotype is a priority. We applied nine sensitive and quantitative assays evaluating FMR1 DNA, RNA, and FMRP parameters to a reference set of cell lines representing the range of FMR1 expansions. We then used the most informative of these assays on blood and buccal specimens from cohorts of patients with different FMR1 expansions, with emphasis on those with FXS (N = 42 total, N = 31 with FMRP measurements). The group with FMRP data was also evaluated comprehensively in terms of its neurobehavioral profile, which allowed molecular–neurobehavioral correlations. FMR1 CGG repeat expansions, methylation levels, and FMRP levels, in both cell lines and blood samples, were consistent with findings of previous FMR1 genomic and protein studies. They also demonstrated a high level of agreement between blood and buccal specimens. These assays further corroborated previous reports of the relatively high prevalence of methylation mosaicism (slightly over 50% of the samples). Molecular-neurobehavioral correlations confirmed the inverse relationship between overall severity of the FXS phenotype and decrease in FMRP levels (N = 26 males, mean 4.2 ± 3.3 pg FMRP/ng genomic DNA). Other intriguing findings included a significant relationship between the diagnosis of FXS with ASD and two-fold lower levels of FMRP (mean 2.8 ± 1.3 pg FMRP/ng genomic DNA, p = 0.04), in particular observed in younger age- and IQ-adjusted males (mean age 6.9 ± 0.9 years with mean 3.2 ± 1.2 pg FMRP/ng genomic DNA, 57% with severe ASD), compared to FXS without ASD. Those with severe ID had even lower FMRP levels independent of ASD status in the male-only subset. The results underscore the link between FMR1 expansion, gene methylation, and FMRP deficit. The association between FMRP deficiency and overall severity of the neurobehavioral phenotype invites follow up studies in larger patient cohorts. They would be valuable to confirm and potentially extend our initial findings of the relationship between ASD and other neurobehavioral features and the magnitude of FMRP deficit. Molecular profiling of individuals with FXS may have important implications in research and clinical practice.

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High-resolution methylation polymerase chain reaction for fragile X analysis: Evidence for novel FMR1 methylation patterns undetected in Southern blot analyses

Chen

Hadd

Sah

et al. 2011

Genetics in Medicine

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PURPOSE Fragile X syndrome is associated with the expansion of CGG trinucleotide repeats and subsequent methylation of the fragile X mental retardation-1 (FMR1) gene. Molecular diagnosis of fragile X currently requires Southern blot analysis to assess methylation. This study describes the evaluation of a PCR-only workflow for the determination of methylation status across a broad range of FMR1 genotypes in male and female specimens. METHODS We evaluated a novel method that combines allele-specific methylation PCR and capillary electrophoresis with 8 cell line and 80 clinical samples, including 39 full mutations. Methylation status was determined using a 3-step workflow: 1) differential treatment of genomic DNA using a methylation-sensitive restriction enzyme; 2) PCR with 2 sets of dye-tagged primers; and 3) amplicon sizing by capillary electrophoresis. All samples were analyzed by both methylation PCR and Southern blot analysis. RESULTS FMR1 methylation status and CGG repeat sizing were accurately and reproducibly determined in a set of methylation controls, and genomic DNA samples representing a spectrum of CGG repeat lengths and methylation states. Moreover, methylation PCR revealed allele-specific methylation patterns in premutation alleles that were unobtainable using Southern blot analysis. CONCLUSIONS Methylation PCR enabled high throughput, high resolution, and semi-quantitative methylation assessments of FMR1 alleles, as well as determinations of CGG repeat length. Results for all samples were concordant with corresponding Southern blot analyses. As a result, this study presents a PCR-based method for comprehensive FMR1 analysis. In addition, the identification of novel methylation mosaic patterns revealed after PCR and capillary electrophoresis may be relevant to several FMR1 disorders.

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A Novel Methylation PCR that Offers Standardized Determination of FMR1 Methylation and CGG Repeat Length without Southern Blot Analysis

Grasso

Boon

Filipovic-Sadic

et al. 2014

The Journal of Molecular Diagnostics

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Fragile X syndrome and associated disorders are characterized by the number of CGG repeats and methylation status of the FMR1 gene for which Southern blot (SB) historically has been required for analysis. This study describes a simple PCR-only workflow (mPCR) to replace SB analysis, that incorporates novel procedural controls, treatment of the DNA in separate control and methylation-sensitive restriction endonuclease reactions, amplification with labeled primers, and two-color amplicon sizing by capillary electrophoresis. mPCR was evaluated in two independent laboratories with 76 residual clinical samples that represented typical and challenging fragile X alleles in both males and females. mPCR enabled superior size resolution and analytical sensitivity for size and methylation mosaicism compared to SB. Full mutation mosaicism was detected down to 1% in a background of 99% normal allele with 50- to 100-fold less DNA than required for SB. A low level of full mutation mosaicism in one sample was detected using mPCR but not observed using SB. Overall, the sensitivity for detection of full mutation alleles was 100% (95% CI: 89%-100%) with an accuracy of 99% (95% CI: 93%-100%). mPCR analysis of DNA from individuals with Klinefelter and Turner syndromes, and DNA from sperm and blood, were consistent with SB. As such, mPCR enables accurate, sensitive, and standardized methods of FMR1 analysis that can harmonize results across different laboratories.

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A methylation PCR method determines FMR1 activation ratios and differentiates premutation allele mosaicism in carrier siblings

et al. 2016

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BackgroundEpigenetic modifications of the fragile X mental retardation 1 (FMR1) gene locus may impact the risk for reproductive and neurological disorders associated with expanded trinucleotide repeats and methylation status in the 5′ untranslated region. FMR1 methylation is commonly assessed by Southern blot (SB) analysis, yet this method suffers a cumbersome workflow and relatively poor sizing resolution especially for premutation allele characteristic for fragile X-associated disorders. In this study, a methylation PCR (mPCR) assay was used to evaluate correlations among genotype, epitype, and phenotype in fragile X premutation (PM) carrier women in order to advance the understanding of the association between molecular determinants and the presence of fragile X-associated tremor and ataxia (FXTAS).ResultsActivation ratios (ARs) in 39 PM women were determined by mPCR and compared with SB analysis. ARs were distributed across a range of values including five samples with <20% AR and six with >80% AR. The two methods were correlated (R 2 of 0.87 and F test of <0.001), indicating that mPCR can measure AR in agreement with established assays. However, mPCR was unique in identifying novel and distinct patterns of methylation mosaicism in premutation carrier women, including seven sibling pairs that were assessed using FXTAS clinical rating scales. Of note, four of six pairs with defined age of onset for neurological signs showed ARs consistent with skewed activation of the pathogenic expanded allele. One subject with severe FXTAS had a mosaic full mutation allele identified using mPCR but not detected by SB analysis.ConclusionsWe utilized a repeatable and streamlined methodology to characterize FMR1 inactivation in premutation carrier women. The method was concordant with SB analysis and provided higher resolution information on allele and methylation mosaicism. This approach can facilitate the characterization of epigenetic factors influencing fragile X phenotypes in larger cohort studies that can advance understanding and treatment of fragile X-associated disorders.Electronic supplementary materialThe online version of this article (doi:10.1186/s13148-016-0280-8) contains supplementary material, which is available to authorized users.

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Multisite Evaluation and Validation of a Sensitive Diagnostic and Screening System for Spinal Muscular Atrophy that Reports SMN1 and SMN2 Copy Number, along with Disease Modifier and Gene Duplication Variants

Milligan

Larson

Filipovic-Sadic

et al. 2021

The Journal of Molecular Diagnostics

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Following previously described ovarian phenotypes of the FMR1 gene, methylation fractions were significantly skewed between FMR1 genotypes and sub-genotypes

Barad

Latham

Filipovic-Sadic

et al. 2013

Fertility and Sterility

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