Clinical and genetic keys to cerebellar ataxia due to FGF14 GAA expansions.

BACKGROUND: SCA27B caused by FGF14 intronic heterozygous GAA expansions with at least 250 repeats accounts for 10-60% of cases with unresolved cerebellar ataxia. We aimed to assess the size and frequency of FGF14 expanded alleles in individuals with cerebellar ataxia as compared with controls and to characterize genetic and clinical variability. METHODS: We sized this repeat in 1876 individuals from France sampled for research purposes in this cross-sectional study: 845 index cases with cerebellar ataxia and 324 affected relatives, 475 controls, as well as 119 cases with spastic paraplegia, and 113 with familial essential tremor. FINDINGS: A higher frequency of expanded allele carriers in index cases with ataxia was significant only above 300 GAA repeats (10.1%, n = 85) compared with controls (1.1%, n = 5) (p < 0.0001) whereas GAA250-299 alleles were detected in 1.7% of both groups. Eight of 14 index cases with GAA250-299 repeats had other causal pathogenic variants (4/14) and/or discordance of co-segregation (5/14), arguing against GAA causality. We compared the clinical signs in 127 GAA≥300 carriers to cases with non-expanded GAA ataxia resulting in defining a key phenotype triad: onset after 45 years, downbeat nystagmus, episodic ataxic features including diplopia; and a frequent absence of dysarthria. All maternally transmitted alleles above 100 GAA were unstable with a median expansion of +18 repeats per generation (r2 = 0.44; p < 0.0001). In comparison, paternally transmitted alleles above 100 GAA mostly decreased in size (-15 GAA (r2 = 0.63; p < 0.0001)), resulting in the transmission bias observed in SCA27B pedigrees. INTERPRETATION: SCA27B diagnosis must consider both the phenotype and GAA expansion size. In carriers of GAA250-299 repeats, the absence of documented familial transmission and a presentation deviating from the key SCA27B phenotype, should prompt the search for an alternative cause. Affected fathers have a reduced risk of having affected children, which has potential implications for genetic counseling. FUNDING: This work was supported by the Fondation pour la Recherche Médicale, grant number 13338 to JLM, the Association Connaître les Syndrome Cérébelleux - France (to GS) and by the European Union's Horizon 2020 research and innovation program under grant agreement No 779257 ("SOLVE-RD" to GS). DP holds a Fellowship award from the Canadian Institutes of Health Research (CIHR). SK received a grant (01GM1905C) from the Federal Ministry of Education and Research, Germany, through the TreatHSP network. This work was supported by the Australian Government National Health and Medical Research Council grants (GNT2001513 and MRFF2007677) to MB and PJL.

Detection of ATXN2 Expansions in an Exome Dataset: An Underdiagnosed Cause of Parkinsonism.

Background: CAG-repeat expansions in Ataxin 2 (ATXN2) are known to cause spinocerebellar ataxia type 2 (SCA2), but CAA interrupted expansions may also result in autosomal dominant Parkinson's disease (AD PD). However, because of technical limitations, such expansions are not explored in whole exome sequencing (WES) data. Objectives: To identify ATXN2 expansions using WES data from PD cases. Methods: We explored WES data from a cohort of 477 index cases with PD using ExpansionHunter (Illumina DRAGEN Bio-IT Platform, San Diego, CA). Putative expansions were confirmed by combining polymerase chain reaction and fragment length analysis followed by sub-cloning and sequencing methods. Results: Using ExpansionHunter, we identified three patients from two families with AD PD carrying either ATXN2 22/39 or 22/37 repeats, both interrupted by four CAA repeats. Conclusion: These findings demonstrate the usefulness of WES to detect pathogenic CAG repeat expansions, which were found in 1.7% of AD PD in the ATXN2 gene in our exome dataset.

Propensity for somatic expansion increases over the course of life in Huntington disease.

Recent work on Huntington disease (HD) suggests that somatic instability of CAG repeat tracts, which can expand into the hundreds in neurons, explains clinical outcomes better than the length of the inherited allele. Here, we measured somatic expansion in blood samples collected from the same 50 HD mutation carriers over a twenty-year period, along with post-mortem tissue from 15 adults and 7 fetal mutation carriers, to examine somatic expansions at different stages of life. Post-mortem brains, as previously reported, had the greatest expansions, but fetal cortex had virtually none. Somatic instability in blood increased with age, despite blood cells being short-lived compared to neurons, and was driven mostly by CAG repeat length, then by age at sampling and by interaction between these two variables. Expansion rates were higher in symptomatic subjects. These data lend support to a previously proposed computational model of somatic instability-driven disease.

Expanding the Spectrum of Genes Involved in Huntington Disease Using a Combined Clinical and Genetic Approach.

IMPORTANCE: Huntington disease (HD), a prototypic monogenic disease, is caused by an expanded CAG repeat in the HTT gene exceeding 35 units. However, not all patients with an HD phenotype carry the pathological expansion in HTT, and the positive diagnosis rate is poor. OBJECTIVES: To examine patients with HD phenotypes to determine the frequency of HD phenocopies with typical features of HD but without pathological CAG repeat expansions in HTT in an attempt to improve the positive diagnosis rate. DESIGN, SETTING, AND PARTICIPANTS: Between January 1, 2004, and April 18, 2011, a total of 226 consecutive index patients with an HD phenotype were referred to specialized clinics of the French National Huntington Disease Reference Centre for Rare Diseases. They underwent detailed clinical examination and follow-up, as well as neuropsychological, biological, imaging, and genetic examinations. Nucleotide expansions in JPH3, ATN1, TBP, and C9ORF72 and mutations in PRNP, as well as acquired conditions commonly causing HD phenocopies, were first screened. MAIN OUTCOMES AND MEASURES: The diagnostic rate of HD phenocopies and frequency of other etiologies using deep clinical phenotyping and next generation sequencing. Our goal was to improve the genetic diagnosis of HD phenocopies and to identify new HD related genes. RESULTS: One hundred ninety-eight patients carried a pathological CAG repeat expansion in HTT, whereas 28 patients (12 women and 16 men) did not. Huntington disease phenocopies accounted for 12.4%, and their mean (SD) age at onset was similar to those of the HD-HTT group (47.3 [12.7] years vs 50.3 [16.4] years, P = .29). We first identified 3 patients with abnormal CTG expansions in JPH3, a fourth patient with an antiphospholipid syndrome, and a fifth patient with B12 avitaminosis. A custom-made 63-gene panel was generated based on clinical evolution and exome sequencing. It contained genes responsible for HD phenocopies and other neurodegenerative conditions, as well as candidate genes from exome sequencing in 3 index cases with imaging features of brain iron accumulation. We identified mutations in genes associated with neurodegeneration, including CACNA1A (n = 2), VPS13A (n = 1), UBQLN2 (n = 1), and VCP (n = 1). CONCLUSIONS AND RELEVANCE: Huntington disease phenocopies without CAG repeat expansions in HTT are not rare, occurring in 12.4% (28 of 226) herein, and should be considered in genetic counseling. We used next-generation sequencing combined with clinical data and disease evolution to explore multiple etiologies simultaneously. Our combined clinical and genetic exploration of 28 HD phenocopies identified the underlying cause in 35.7% (10 of 28). In conclusion, the etiologies of HD phenocopies are heterogeneous, and clinical evolution should be taken into account when searching for a genetic cause. The panel of candidate genes to be examined is larger than expected but can be guided by specific imaging and clinical features. Other neurodegenerative diseases with late onset in which variant segregation cannot be verified could be productively explored with the combined approach illustrated herein.

Prenatal testing in Huntington disease: after the test, choices recommence.

The objective of this study was (1) to determine the impact of prenatal diagnosis (PND) for Huntington disease (HD) on subsequent reproductive choices and family structure; and (2) to assess whether children born after PND were informed of their genetic status. Out of 354 presymptomatic carriers of HD gene mutation, aged 18-45 years, 61 couples requested 101 PNDs. Fifty-four women, 29 female carriers and 25 spouses of male carriers, accepted to be interviewed (0.6-16.3 years after the last PND, median 6.5 years) on their obstetrical history and information given to children born after PND. Women were willing to undergo two or more PNDs with a final success rate of 75%. Reproductive decisions differed depending on the outcome of the first PND. If favourable, 62% couples decided against another pregnancy and 10% chose to have an untested child. If unfavourable, 83% decided for another pregnancy (P<0.01), and the majority (87%) re-entered the PND procedure. In contrast, after a second PND, only 37% asked for a PND and 30% chose to have an untested child. Thirty-three percent had both, tested and untested children. Among children born after PND, 10 years and older, 75% were informed of their genetic status. The decision to prevent transmission of the HD mutation is made anew with each pregnancy. Couples may need more psychological support after PND and pre-counselling sessions should take into account the effect of the outcome of a first PND on subsequent reproductive choices.

Partial deletions of the GRN gene are a cause of frontotemporal lobar degeneration.

Mutations in the progranulin gene (GRN) are an important cause of frontotemporal lobar degeneration (FTLD). Most known GRN mutations are null mutations, such as nonsense and frameshift mutations, which create a premature stop codon resulting in loss of function of the progranulin protein. Complete or near-complete genomic GRN deletions have also been found in three families, but heterozygous partial deletions that remove only one or two exons have not been reported to date. In this study, we analysed three unrelated FTLD patients with low plasma progranulin levels but no point GRN mutations by multiplex ligation-dependent probe amplification (MLPA) and quantitative multiplex polymerase chain reaction of short fluorescent fragments (QMPSF). We detected two heterozygous partial GRN deletions in two patients. One deletion removed exon 1 and part of intron 1. The second deletion was complex: it removed 1,410 bp extending from the part of intron 1 to the part of exon 3, with a small 5-bp insertion at the breakpoint junction (c.-7-1121_159delinsGATCA). Our findings illustrate the usefulness of a quantitative analysis in addition to GRN gene sequencing for a comprehensive genetic diagnosis of FTLD, particularly in patients with low plasma progranulin levels.

Use of a low-cost biosorbent to remove pesticides from wastewater.

A lignocellulosic substrate (LS) obtained from our local agroindustry was used as a low-cost and effective adsorbent for the removal of pesticides from wastewaters. The studied pesticides were terbumeton (N-(1,1-dimethyl)-Nethyl-6-methoxy-1,3,5-triazine-2,4-diamine), desethyl terbumeton (N-(1,1-dimethylethyl)-6-methoxy-1,3,5-triazine-2,4-diamine), dimetomorph (4-[3-(4-chlorophenyl)-3-(3,4-dimethoxyphenyl)acryloyl]morpholine), and isoproturon (3-(4-isopropylphenyl)-1,1-dimethylurea). Batch and column experiments were conducted as a function of pH and pesticide concentration under laboratory and industrial conditions. The concentration range studied for the pesticides varied from 2 x 10(-7) to 3 x 10(-4) mol L(-1). The influence of organic and inorganic pollutants was assessed by studying the retention of pesticide in the presence of copper(II) and a surfactant. These experiments indicated that LS is an efficient adsorbent toward the investigated pesticides and has little influence of the other pollutants. The kinetic adsorptions are fast, and the amounts of adsorbed pesticide varied from 1 to 8 g kg(-1) of LS. These retention capacities show that LS can provide a simple, effective, and cheap method for removing pesticides from contaminated waters. Thus, this biomaterial may be useful for cleaning up polluted waters.