Whole exome sequencing (WES) is a recently developed technique in genetics research that attempts to identify causative mutations in complex, undiagnosed genetic conditions. Causative mutations are usually identified after filtering the hundreds of variants on WES from an individual's DNA selected by the phenotype. We investigated a patient with a slowly progressive chronic axonal distal motor neuropathy and extrapyramidal syndrome using WES, in whom common genetic mutations had been excluded. Variant filtering identified potentially deleterious mutations in three known disease genes: DCTN1, KIF5A and NEFH, which have been all associated with similar clinical presentations of amyotrophic lateral sclerosis, Parkinsonism and/or hereditary spastic paraplegia. Predicting the functional effect of the mutations were analysed in parallel with detailed clinical investigations. This case highlights the difficulties and pitfalls of applying WES in patients with complex neurological diseases and serves as an instructive tale

Chinnery, Patrick F

Daud, Daniyal

Douroudis, Konstantinos

Eglon, Gail

Griffin, Helen

Horvath, Rita

Kleinle, Stephanie

Pyle, Angela

English

PubMed

Apollo (Cambridge)

ORIGINAL COMMUNICATIONWhole exome sequencing and the clinician: we need clinical skillsand functional validation in variant filteringDaniyal Daud1,2 • Helen Griffin1 • Konstantinos Douroudis1 • Stephanie Kleinle3 •Gail Eglon1 • Angela Pyle1 • Patrick F. Chinnery1 • Rita Horvath1Received: 8 March 2015 / Revised: 11 April 2015 / Accepted: 12 April 2015 / Published online: 10 May 2015 The Author(s) 2015. This article is published with open access at Springerlink.comAbstract Whole exome sequencing (WES) is a recentlydeveloped technique in genetics research that attempts toidentify causative mutations in complex, undiagnosed ge-netic conditions. Causative mutations are usually identifiedafter filtering the hundreds of variants on WES from anindividual’s DNA selected by the phenotype. We investi-gated a patient with a slowly progressive chronic axonaldistal motor neuropathy and extrapyramidal syndrome us-ing WES, in whom common genetic mutations had beenexcluded. Variant filtering identified potentially deleteriousmutations in three known disease genes: DCTN1, KIF5Aand NEFH, which have been all associated with similarclinical presentations of amyotrophic lateral sclerosis,Parkinsonism and/or hereditary spastic paraplegia. Pre-dicting the functional effect of the mutations were analysedin parallel with detailed clinical investigations. This casehighlights the difficulties and pitfalls of applying WES inpatients with complex neurological diseases and serves asan instructive tale.Keywords Genetics  Whole exome sequencing  Spasticparaplegia  Motor neuropathyAbbreviationsALS Amyotrophic lateral sclerosisHSP Hereditary spastic paraplegiaCMT Charcot–Marie–Tooth diseaseIntroductionWhole exome sequencing (WES) is an increasinglyavailable second-generation sequencing technique thatidentifies variants in the coding regions of the humangenome [1]. In the field of neurology, it has helped pa-tients by elucidating the cause of their often long-standingsymptoms, and many previously undiagnosed patientswith a range of neurological syndromes which can now begiven the name of the causative gene and counselledappropriately. For researchers, WES has led to the rapidrise in the discovery of novel mutations in both knownand novel disease genes, further unravelling the cellularfunction and relationships of various genes with humandisease. However, one of the many limitations of WES isin its application to single patients with late-onset disease.WES of one individual’s DNA can identify up to 20,000variants [1]. Even in patients with a characteristic clinicalphenotype choosing the causative mutation remain achallenge if DNA from other affected or healthy relativesis not available to determine which variant segregateswith the phenotype [2].Here we describe a case wherein, we used WES to guidediagnosis in a patient with complex neurodegenerativedisease.& Rita Horvathrita.horvath@ncl.ac.ukDaniyal Dauddbdaud@gmail.com1 Wellcome Trust Centre for Mitochondrial Research, Instituteof Genetic Medicine, Newcastle University, Central Parkway,Newcastle upon Tyne NE1 3BZ, UK2 Department of Medicine, James Cook University Hospital,Middlesbrough TS4 3BW, UK3 Medical Genetic Center, 80336 Munich, Germany123J Neurol (2015) 262:1673–1677DOI 10.1007/s00415-015-7755-yMethodsWe assessed the patient’s clinical history, examination andserological, neurophysiological, radiological and histo-logical investigations. Exome sequencing was carried outusing genomic blood DNA by Illumina TruseqTM 62 Mbexome capture. We used our in-house bioinformaticspipeline to align data to the reference human genome(UCSC hg19), remove duplicate sequence reads (Picardv1.85) and variant detection (Varscan v2.29, Dindelv1.0110). Results were filtered for variants with a minorallele frequency less than 0.01 in several databases:dbSNP135, 1000 genomes (February 2012 data release),the National Heart, Lung and Blood Institute (NHLBI,NIH, Bethesda, MD) Exome Sequencing Project (ESP)6500 exomes, and 238 unrelated in-house controls. Rarehomozygous and compound heterozygous variants weredefined, and protein altering and/or putative ‘disease-causing’ mutations, along with their functional annotation,were identified using ANNOVAR. Further filtering hasbeen performed by gene ontology (GO) terms associatedwith neuronal function, and Online Mendelian Inheritancein Man (OMIM) disease descriptions related to neuropathy,ataxia or extrapyramidal disorders (i.e., the patient’s clin-ical phenotype). We carried out PCR (IMMOLASETMDNA Polymerase, Bioline UK) and Sanger sequencing(BigDye Terminator v3.1) of variants predicted to bedeleterious by five online prediction tools (MutationTaster,SIFT, Polyphen2, A-GVGD, and LRT).ResultsCase reportA 74-year-old left-handed man originally presented at theage of 45 with right-sided back pain and sciatica as well asbilateral grip weakness. His gait had also changed but he wasable to walk and play sports. Past medical history includedpoliomyelitis at the age of ten, during the 1950s epidemic.Both of his parents died at age 88 and 72, and had noneuromuscular symptoms. He has one son and fourdaughters (28–36 years of age), and one daughter was re-cently diagnosed with multiple sclerosis. He has a 71-year-old healthy brother who was not available for testing.At age 45, examination revealed wasting and weaknessof the right sternocleidomastoid muscle, bilateral wastingof thenar and intrinsic hand muscles (Fig. 1a). In particular,the abductor pollicis brevis was weak bilaterally. Therewas distal lower limb weakness with foot drop but no pescavus. Tone and reflexes were normal.He was seen again at the age of 64 with worseningtorticollis. He had jerky ocular pursuit movements andbilateral wasting of the tongue. His previous weakness hadpersisted with additional weakness in the shoulders. He haddeveloped pes cavus bilaterally (Fig. 1a), brisk upper limband knee reflexes with absent ankle reflexes bilaterally. Heprogressed to develop dysmetria and dysdiadochokinesisbut no dysarthria.More recent examination at 74 years revealed progres-sion of the complex movement disorder with facial dys-tonia, head tremor, distal amyotrophy, ataxia and somerigidity at the wrists. He had a wide-based steppage gaitwith reduced arm swing.InvestigationsBasic haematological and biochemical investigations werenormal except for gamma-glutamyl transferase (83 units/L,normal \70), creatine kinase (193 and 215 U/L, normal10–190), random glucose (8.3 mmol/L), cholesterol(7.9 mmol/L, normal\5.2) and triglycerides (6.1 mmol/L,normal fasting level \1.8). Thyroid function tests, auto-antibodies, Vitamin E, 24-h urinary copper, alpha-feto-protein, lysosomal enzymes, hexosaminidase A were allwithin normal limits.Brain MRI revealed marked cerebellar atrophy and mildcortical atrophy without signal change (Fig. 1b). CervicalMRI showed mild spondylotic changes at C5/6 and C6/7.DatScan showed no abnormalities in dopamine metabo-lism. Nerve conduction studies demonstrated preservedsensory nerve action potentials, sensory and motor con-duction velocities but symmetrically diminished compoundmotor potentials in all four limbs, suggesting that thesyndrome could not be attributed to previous poliomyelitis.Electromyography revealed chronic neurogenic changes,suggesting spinal muscular atrophy or distal spinal mus-cular atrophy. With electromyography, unstable polyphasicunits were observed with reduced interference and ampli-tudes up to 10 mV, confirming a chronic progressive an-terior horn cell disease. Muscle biopsy showed onlyneurogenic changes.Genetic analysisGenetic tests performed before WES excluded Hunting-ton’s disease (IT15), spinal muscular atrophy (SMN1),spinal bulbar muscular atrophy (AR), primary torsiondystonia (DYT1), and the common forms of spastic para-plegias (SPG4, REEP1, ATL1, SPG7). No mtDNA dele-tions were detected in his muscle DNA. Rare, potentiallydisease-causing variants found in filtered WES data arelisted in Tables 1 and 2; we could confirm all variants inheterozygous state in the patient’s DNA by Sanger se-quencing. No further mutations were detected in any of theknown disease genes involved in inherited movement1674 J Neurol (2015) 262:1673–1677123Fig. 1 a Photographs of the patient demonstrating a partially treated torticollis, a broad-based stance, distal upper and lower limb atrophy as wellas bilateral pes cavus. b MRI of the patient’s brain demonstrating cerebellar atrophyTable 1 Predicted deleterious variants filtered from whole exome sequencing dataGene Position Variant Bioinformatic score Disease associationDCTN1 Chr2:g.74588640 C NM_004082.4: c.3823 C[T, p.Arg1275Cys 5 ALS, Perry syndromeKIF5A Chr12:g.57965854 C NM_004984.2: c.1373 C[T, p.Ser458Phe 3.5 HSP, CMTNEFH Chr22:g.29885580_2988 603 NM_021076.3: c.1965 1988del, p.Glu658_Lys665del N/A ALSScores were calculated from the output of five mutation deleteriousness prediction programmes: SIFT (score 1 for prediction of ‘Deleterious’, 0for others), LRT (score 1 for prediction of ‘Deleterious’), Polyphen2 (score 1 for ‘probably damaging’ prediction, 0.5 for ‘possibly damaging’prediction, 0 for ‘benign’), Align-GVGD (score 1 for predictions C55 or C66, score 0 for other predictions) and MutationTaster (score 1 for‘disease-causing’ prediction, 0 for ‘polymorphism). Predictions were not available for the deletion in the NEFH geneTable 2 Coverage and depth statistics of exome sequencing for the patientMean targetbasecoverageNumber ofbases covered20-fold% Basescovered20-foldNumber ofbases coveredtenfold% BasescoveredtenfoldNumber ofbases coveredfivefold% BasescoveredfivefoldNumber ofbases coveredonefold% Basescoveredonefold88.23 29129128 91.21 30151406 94.41 30585401 95.77 31131999 97.49Coverage calculated for Consensus Coding Sequence (CCDS) bases (31,935,069 bp)J Neurol (2015) 262:1673–1677 1675123disorders, neuropathies or spastic paraplegias and no fur-ther family members were available for genetic analysis.DiscussionWe have found novel, potentially pathogenic mutations inthe patient in multiple genes (DCTN1, KIF5A, NEFH) as-sociated with various neurological syndromes. Based onprevious reports, heterozygous mutations in all three genescan be associated with similar clinical presentation ob-served in our case. In further support of the pathogenicrole, the selected variants have not been reported previ-ously at all (KIF5A) or are extremely rare (one singleheterozygous DCTN1 and NEFH variant in 65,000 exomes(http://exac.broadinstitute.org/).DCTN1 mutations have been associated with a familialform of ALS (p.Gly59Ser) [3], familial progressivesupranuclear palsy [4], Perry syndrome (p.Gly71Ala/Glu/Arg, p.Thr72Pro, and p.Gln74Pro) which is characterizedby central hypoventilation and parkinsonism [5]. Our pa-tient exhibited a distal motor neuropathy with ataxia and anextrapyramidal syndrome of tremor and focal dystonia—aninexact fit with the previously described phenotypes ofDCTN1. However, the involvement of the spinal motorneurones in combination with a movement disorder re-sembles DCTN1-related disease and our patient may rep-resent a new phenotype associated with DCTN1 mutation.DCTN1 codes for the p150glued subunit of the dynactincomplex, which together with dynein is responsible for ret-rograde transport of vesicle cargo in axons [6]. The C-ter-minal region of p150glued has been shown in N. crassa to beresponsible for the interaction of the dynactin complex withmembranous cargo [7]. However, previous work in HeLAand COS7 cells could not confirm that mutations in theC-terminal region of DCTN1 (Arg1101Lys and Thr1249Ile)are functionally pathogenic [8]. Our patient’s DCTN1 mu-tation is located to this region; nevertheless, this variant hasnot been reported previously and no functional data areavailable on it to date. However, functional in vivo imagingstudies in patients possessing the variants associated withPerry syndrome, have demonstrated a reduced uptake ofFDOPA, a marker of dopamine synthesis and storage [9].Mutations in KIF5A are associated with spastic para-plegia (SPG10), and can also cause peripheral neuropathy,parkinsonism, retinitis pigmentosa and behavioural prob-lems [10, 11]. Therefore, the pyramidal signs in our patientmay also represent a KIF5A-related disease. KIF5A codesfor the kinesin heavy chain which is responsible for an-terograde transport of cargo (thought to be neurofilaments)towards the synapse [12]. The KIF5A mutation in our pa-tient occurs in the neck region that links two domains in theprotein [10]. To our knowledge, only one mutation (p.Ala361Val) has previously been reported in the neck re-gion in spastic paraplegia [13]; however, its pathogenicrole has not been confirmed in functional studies [14].WES also detected a heterozygous 24-base pair deletionin the neurofilament heavy chain (NEFH) gene in our pa-tient. Such deletions of a lysine-serine-proline unit, thatshorten the repetitive tail region of the NEFH protein, havebeen associated with an increased risk of developing ALS[15], but no highly penetrant causative alleles have beendescribed in this gene.Another intriguing point is the poliomyelitis in our pa-tient’s previous history. Whether the childhood neuropathywas indeed poliomyelitis, and coupled with a potentiallydeleterious mutation contributed to the development of aslowly progressive predominantly distal motor neuropathy,or the childhood onset polio-like neuropathy represents thefirst manifestation of a genetic condition remains unclear.This case illustrates the problems that can be encoun-tered in using next generation sequencing to guide the di-agnosis of sporadic cases. Despite having confirmedpotentially disease-causing mutations in DCTN1 andKIF5A, as well as a genetic predisposing variant in NEFH,we cannot surely prove that they are the cause for thepatient’s phenotype without an informative family history,which is often not available in late-onset disease. The ab-sence of clinical signs and symptoms in younger familymembers may simply reflect a later disease onset or lowpenetrance of the mutation rather than its non-pathogeni-city. Moreover, we cannot exclude the possibility that morethan one of the variants are relevant, and the differentaspects of the patient’s condition potentially may haveindependent causes.The case also highlights the importance of clinical his-tory and examination in filtering through the enormousnumber of possible diagnoses generated by the results ofnext generation sequencing, and the need for functionalstudies at a molecular level to identify which mutationcontributes to the cellular dysfunction. The overlappingphenotypes of genetic forms of ALS, HSP and dystoniahighlight the importance of an unbiased testing approach,but also illustrate the difficulties of confirming the geneticdiagnosis and functional tests provided evidence for thepathogenicity of these mutations are still lacking.In conclusion, we present a patient with a complexneurological phenotype including predominantly distalmotor neuropathy, extrapyramidal and cerebellar signs forwhom we have identified a number of potentially patho-genic candidate mutations.Acknowledgments RH is supported by the Medical ResearchCouncil (UK) (G1000848) and the European Research Council(309548). PFC is a Wellcome Trust Senior Fellow in Clinical Scienceand National Institute for Health Research Senior Investigator. Hereceives funding from the Medical Research Council and the National1676 J Neurol (2015) 262:1673–1677123Institute for Health Research Biomedical Research Centre for Ageingand Age-Related Disease award to the Newcastle upon Tyne Foun-dation Hospitals National Health Service Trust.Conflicts of interest On behalf of all authors, the correspondingauthor states that there is no conflict of interest.Ethical standard Ethical approval has been obtained from localethics committee and the patient gave written consent for the study.Open Access This article is distributed under the terms of theCreative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricteduse, distribution, and reproduction in any medium, provided you giveappropriate credit to the original author(s) and the source, provide alink to the Creative Commons license, and indicate if changes weremade.References1. Bras J, Guerreiro R, Hardy J (2012) Use of next-generation se-quencing and other whole-genome strategies to dissect neuro-logical disease. Nat Rev Neurosci 13(7):453–4642. Yuan J, Higuchi Y, Nagado T, Nozuma S, Nakamura T, MatsuuraE et al (2013) Novel mutation in the replication focus targetingsequence domain of DNMT1 causes hereditary sensory and au-tonomic neuropathy IE. J Peripher Nerv Syst 18(1):89–933. Puls I, Jonnakuty C, LaMonte BH, Holzbaur ELF, Tokito M,Mann E et al (2003) Mutant dynactin in motor neuron disease.Nat Genet 33(4):455–4564. Caroppo P, Le Ber I, Clot F et al (2014) DCtn1 mutation analysisin families with progressive supranuclear palsy—like phenotypes.JAMA Neurol 71(2):208–2155. Wider C, Dachsel JC, Farrer MJ, Dickson DW, Tsuboi Y, Ws-zolek ZK (2010) Elucidating the genetics and pathology of Perrysyndrome. J Neurol Sci 289(1–2):149–1546. Moughamian AJ, Holzbaur ELF (2012) Dynactin is required fortransport initiation from the distal axon. Neuron 74(2):331–3437. Kumar S, Zhou Y, Plamann M (2001) Dynactin-membrane in-teraction is regulated by the C-terminal domains of p150Glued.EMBO Rep 2(10):939–9448. Dixit R, Levy JR, Tokito M, Ligon LA, Holzbaur ELF (2008)Regulation of dynactin through the differential expression ofp150Glued isoforms. J Biol Chem 283(48):33611–336199. Felicio AC, Dinelle K, Agarwal PA, McKenzie J, Heffernan N,Road JD et al (2014) In vivo dopaminergic and serotonergicdysfunction in DCTN1 gene mutation carriers. Mov Disord29(9):1197–120110. Kawaguchi K (2013) Role of kinesin-1 in the pathogenesis ofSPG10, a rare form of hereditary spastic paraplegia. Neurosci19(4):336–34411. Liu Y-T, Laura´ M, Hersheson J, Horga A, Jaunmuktane Z,Brandner S et al (2014) Extended phenotypic spectrum of KIF5Amutations: From spastic paraplegia to axonal neuropathy. Neu-rology 83(7):612–61912. Xia C-H, Roberts EA, Her L-S, Liu X, Williams DS, ClevelandDW et al (2003) Abnormal neurofilament transport caused bytargeted disruption of neuronal kinesin heavy chain KIF5A. J CellBiol 161(1):55–6613. LoGiudice M, Neri M, Falco M et al (2006) A missense mutationin the coiled-coil domain of the kif5a gene and late-onset her-editary spastic paraplegia. Arch Neurol 63(2):284–28714. Ebbing B, Mann K, Starosta A, Jaud J, Scho¨ls L, Schu¨le R et al(2008) Effect of spastic paraplegia mutations in KIF5A kinesinon transport activity. Hum Mol Genet 17(9):1245–125215. Al-Chalabi A, Andersen PM, Nilsson P, Chioza B, Andersson JL,Russ C et al (1999) Deletions of the heavy neurofilament subunittail in amyotrophic lateral sclerosis. Hum Mol Genet8(2):157–164J Neurol (2015) 262:1673–1677 1677123

Whole exome sequencing and the clinician: we need clinical skills and functional validation in variant filtering.

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Whole exome sequencing and the clinician: we need clinical skills and functional validation in variant filtering.

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