nan Plagnol

Use of targeted exome sequencing as a diagnostic tool for Familial Hypercholesterolaemia

Background Familial Hypercholesterolaemia (FH) is an autosomal dominant disease, caused by mutations in LDLR, APOB or PCSK9, which results in high levels of LDL-cholesterol (LDL-C) leading to early coronary heart disease. An autosomal recessive form of FH is also known, due to homozygous mutations in LDLRAP1. This study assessed the utility of an exome capture method and deep sequencing in FH diagnosis. Methods Exomes of 48 definite FH patients, with no mutation detected by current methods, were captured by Agilent Human All Exon 50Mb assay and sequenced on the Illumina HiSeq 2000 platform. Variants were called by GATK and SAMtools. Results The mean coverage of FH genes varied considerably (PCSK9=23x, LDLRAP1=36x, LDLR=56x and APOB=93x). Exome sequencing detected 17 LDLR mutations, including three copy number variants, two APOB mutations, missed by the standard techniques, two LDLR novel variants likely to be FH-causing, and five APOB variants of uncertain effect. Two variants called in PCSK9 were not confirmed by Sanger sequencing. One heterozygous mutation was found in LDLRAP1. Conclusions High-throughput DNA sequencing demonstrated its efficiency in well-covered DNA regions, in particular LDLR. This highly automated technology is proving to be effective for heterogeneous diseases and may soon replace laborious conventional methods. However, the poor coverage of gene promoters and repetitive, or GC-rich sequences, remains problematic, and validation of all identified variants is currently required.

Neuropathy target esterase impairments cause Oliver–McFarlane and Laurence–Moon syndromes

Background Oliver–McFarlane syndrome is characterised by trichomegaly, congenital hypopituitarism and retinal degeneration with choroidal atrophy. Laurence–Moon syndrome presents similarly, though with progressive spinocerebellar ataxia and spastic paraplegia and without trichomegaly. Both recessively inherited disorders have no known genetic cause. Methods Whole-exome sequencing was performed to identify the genetic causes of these disorders. Mutations were functionally validated in zebrafish pnpla6 morphants. Embryonic expression was evaluated via in situ hybridisation in human embryonic sections. Human neurohistopathology was performed to characterise cerebellar degeneration. Enzymatic activities were measured in patient-derived fibroblast cell lines. Results Eight mutations in six families with Oliver–McFarlane or Laurence–Moon syndrome were identified in the PNPLA6 gene, which encodes neuropathy target esterase (NTE). PNPLA6 expression was found in the developing human eye, pituitary and brain. In zebrafish, the pnpla6 curly-tailed morphant phenotype was fully rescued by wild-type human PNPLA6 mRNA and not by mutation-harbouring mRNAs. NTE enzymatic activity was significantly reduced in fibroblast cells derived from individuals with Oliver–McFarlane syndrome. Intriguingly, adult brain histology from a patient with highly overlapping features of Oliver–McFarlane and Laurence–Moon syndromes revealed extensive cerebellar degeneration and atrophy. Conclusions Previously, PNPLA6 mutations have been associated with spastic paraplegia type 39, Gordon–Holmes syndrome and Boucher–Neuhäuser syndromes. Discovery of these additional PNPLA6-opathies further elucidates a spectrum of neurodevelopmental and neurodegenerative disorders associated with NTE impairment and suggests a unifying mechanism with diagnostic and prognostic importance.

Autosomal-recessive cerebellar ataxia caused by a novel ADCK3 mutation that elongates the protein: clinical, genetic and biochemical characterisation

Background The autosomal-recessive cerebellar ataxias (ARCA) are a clinically and genetically heterogeneous group of neurodegenerative disorders. The large number of ARCA genes leads to delay and difficulties obtaining an exact diagnosis in many patients and families. Ubiquinone (CoQ10) deficiency is one of the potentially treatable causes of ARCAs as some patients respond to CoQ10 supplementation. The AarF domain containing kinase 3 gene (ADCK3) is one of several genes associated with CoQ10 deficiency. ADCK3 encodes a mitochondrial protein which functions as an electron-transfer membrane protein complex in the mitochondrial respiratory chain (MRC). Methods We report two siblings from a consanguineous Pakistani family who presented with cerebellar ataxia and severe myoclonus from adolescence. Whole exome sequencing and biochemical assessment of fibroblasts were performed in the index patient. Results A novel homozygous frameshift mutation in ADCK3 (p.Ser616Leufs*114), was identified in both siblings. This frameshift mutation results in the loss of the stop codon, extending the coding protein by 81 amino acids. Significant CoQ10 deficiency and reduced MRC enzyme activities in the index patients fibroblasts suggested that the mutant protein may reduce the efficiency of mitochondrial electron transfer. CoQ10 supplementation was initiated following these genetic and biochemical analyses. She gained substantial improvement in myoclonic movements, ataxic gait and dysarthric speech after treatment. Conclusion This study highlights the importance of diagnosing ADCK3 mutations and the potential benefit of treatment for patients. The identification of this new mutation broadens the phenotypic spectrum associated with ADCK3 mutations and provides further understanding of their pathogenic mechanism.

Novel C12orf65 mutations in patients with axonal neuropathy and optic atrophy

Objective Charcot-Marie Tooth disease (CMT) forms a clinically and genetically heterogeneous group of disorders. Although a number of disease genes have been identified for CMT, the gene discovery for some complex form of CMT has lagged behind. The association of neuropathy and optic atrophy (also known as CMT type 6) has been described with autosomaldominant, recessive and X-linked modes of inheritance. Mutations in Mitofusin 2 have been found to cause dominant forms of CMT6. Phosphoribosylpyrophosphate synthetase-I mutations cause X-linked CMT6, but until now, mutations in the recessive forms of disease have never been identified. Methods We here describe a family with three affected individuals who inherited in an autosomal recessive fashion a childhood onset neuropathy and optic atrophy. Using homozygosity mapping in the family and exome sequencing in two affected individuals we identified a novel protein-truncating mutation in the C12orf65 gene, which encodes for a protein involved in mitochondrial translation. Using a variety of methods we investigated the possibility of mitochondrial impairment in the patients cell lines. Results We described a large consanguineous family with neuropathy and optic atrophy carrying a loss of function mutation in the C12orf65 gene. We report mitochondrial impairment in the patients cell lines, followed by multiple lines of evidence which include decrease of complex V activity and stability (blue native gel assay), decrease in mitochondrial respiration rate and reduction of mitochondrial membrane potential. Conclusions This work describes a mutation in the C12orf65 gene that causes recessive form of CMT6 and confirms the role of mitochondrial dysfunction in this complex axonal neuropathy.

Profilin1 E117G is a moderate risk factor for amyotrophic lateral sclerosis

Background Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) are progressive neurodegenerative disorders that share significant clinical, pathological and genetic overlap and are considered to represent different ends of a common disease spectrum. Mutations in Profilin1 have recently been described as a rare cause of familial ALS. The PFN1 E117G missense variant has been described in familial and sporadic cases, and also found in controls, casting doubt on its pathogenicity. Interpretation of such variants represents a significant clinical-genetics challenge. Objective and results Here, we combine a screen of a new cohort of 383 ALS patients with multiple-sequence datasets to refine estimates of the ALS and FTD risk associated with PFN1 E117G. Together, our cohorts add up to 5118 ALS and FTD cases and 13 089 controls. We estimate a frequency of E117G of 0.11% in controls and 0.25% in cases. Estimated odds after population stratification is 2.44 (95% CI 1.048 to ∞, Mantel-Haenszel test p=0.036). Conclusions Our results show an association between E117G and ALS, with a moderate effect size.

Recessive Retinopathy Consequent on Mutant G-Protein β Subunit 3 (GNB3).

IMPORTANCE Mutations in phototransduction and retinal signaling genes are implicated in many retinopathies. To our knowledge, GNB3 encoding the G-protein β subunit 3 (Gβ3) has not previously been implicated in human disease. OBSERVATIONS In this brief report, whole-exome sequencing was conducted on a patient with distinct inherited retinal disease presenting in childhood, with a phenotype characterized by nystagmus, normal retinal examination, and mild disturbance of the central macula on detailed retinal imaging. This sequencing revealed a homozygous GNB3 nonsense mutation (c.124C>T; p.Arg42Ter). Whole-exome sequencing was conducted from April 2015 to July 2015. CONCLUSIONS AND RELEVANCE Expressed in cone photoreceptors and ON-bipolar cells, Gβ3 is essential in phototransduction and ON-bipolar cell signaling. Knockout of Gnb3 in mice results in dysfunction of cone photoreceptors and ON-bipolar cells and a naturally occurring chicken mutation leads to retinal degeneration. Identification of further affected patients may allow description of the phenotypic and genotypic spectrum of disease associated with GNB3 retinopathy.

Clinical Characterization of CNGB1-Related Autosomal Recessive Retinitis Pigmentosa

Importance There are limited published data on the phenotype of retinitis pigmentosa (RP) related to CNGB1 variants. These data are needed both for prognostic counseling of patients and for understanding potential treatment windows. Objective To describe the detailed clinical and molecular genetic findings in a series of patients with RP with likely pathogenic variants in CNGB1. Design, Setting, and Participants In this case series, 10 patients from 9 families underwent full ophthalmologic examination. Molecular investigations included whole-exome analysis in 6 patients. The study was conducted from April 17, 2013, to March 3, 2016, with final follow-up completed on March 2, 2016, and data were analyzed from October 27, 2014, to March 29, 2016. Main Outcomes and Measures Results of ophthalmologic examination and molecular genetic analysis of CNGB1. Results In this case series, 7 women and 3 men from 9 families with a mean (SD) age of 47.4 (13.2) years identified as having CNGB1 variants were included in this study; there was a mean (SD) follow-up length of 3.7 (2.8) years. The first clinical presentation was with nyctalopia in childhood with visual field loss documented later at a mean (SD) age of 33.2 (8.0) years. All patients had preserved best-corrected visual acuity into adulthood, with a mean of 0.1 logMAR (Snellen equivalent, 20/25) in each eye (logMAR range, 0.0 to 0.3 [Snellen 20/20 to 20/40] in the right eye and −0.1 to 0.3 [Snellen 20/16 to 20/40] in the left eye). Fundus examination revealed midperipheral retinal pigment epithelial atrophy and intraretinal pigment migration. Optical coherence tomography of the macula demonstrated complete preservation of the inner segment ellipsoid band in 1 patient, with variable lateral extent in the other patients corresponding to the diameter of a paracentral ring of increased fundus autofluorescence. Electrophysiologic testing in 6 patients confirmed a rod-cone dystrophy phenotype. Molecular investigations identified a previously reported missense variant (p.[N986I]) and 7 variants not previously reported in disease including 4 nonsense (p.[(Q88*], p.[Q222*], p.[Q318*], and p.[R729*]), 2 frameshift (p.[A1048fs*13], p.[L849Afs*3]), and a splice site variant (c.761 + 2T>A). Conclusions and Relevance The data from this study suggest that visual acuity and foveal structure in patients with RP are preserved into adult life such that a lengthy window of opportunity should exist for intervention with novel therapies.

The ophthalmic presentation of Hermansky–Pudlak syndrome 6

Background Hermansky–Pudlak syndrome (HPS) may present to the ophthalmologist with signs suggestive of oculocutaneous albinism. Consideration of HPS as a differential diagnosis is important due to its potential systemic complications. HPS6 is a rarely reported subtype. Methods Three patients from two families underwent clinical examination, imaging and targeted systemic investigations. Electrophysiology with visual-evoked potentials (VEPs) was performed in both children of family 1. Whole exome sequencing (WES) was performed on the proband of family 1. Bidirectional Sanger sequencing of the single exon and intron–exon boundaries of HPS6 was performed on all affected patients and segregation confirmed in available relatives. Results Two siblings presented in infancy with nystagmus and reduced vision. They were initially diagnosed with isolated foveal hypoplasia with no aberrant chiasmal misrouting on VEPs. WES performed in the proband when 10 years of age identified a novel homozygous missense variant in HPS6 and further questioning elicited a history of nose bleeds and mild bruising. Segregation supported causality of this variant in the affected younger sibling. In the third unrelated patient, an initial diagnosis of ocular albinism was made at 3 months with HPS only diagnosed at 26 years. Biallelic, truncating mutations in HPS6 were identified by candidate Sanger sequencing and included a novel variant. Abnormal platelet function consistent with HPS was confirmed in all patients. Conclusions The diagnosis of HPS in all patients was delayed due to a mild systemic phenotype. Next-generation sequencing can aid diagnosis of syndromic conditions with important consequences for preventing morbidity.