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Molecular and clinical study of a cohort of 110 Algerian patients with autosomal recessive ataxia PDF

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Preview Molecular and clinical study of a cohort of 110 Algerian patients with autosomal recessive ataxia

Hamzaetal.BMCMedicalGenetics (2015) 16:36 DOI10.1186/s12881-015-0180-3 RESEARCH ARTICLE Open Access Molecular and clinical study of a cohort of 110 Algerian patients with autosomal recessive ataxia Wahiba Hamza1, Lamia Ali Pacha2,3, Tarik Hamadouche3,4, Jean Muller5,6, Nathalie Drouot5, Farida Ferrat7, Samira Makri8, Malika Chaouch7, Meriem Tazir2,3, Michel Koenig9 and Traki Benhassine1* Abstract Background: Autosomal recessive cerebellar ataxias (ARCA) are a complex group of neurodegenerative disorders withgreatgenetic and phenotypic heterogeneity, over 30 genes/loci have been associated with more than 20 different clinical forms of ARCA. Genetic heterogeneity combined with highly variable clinical expression of the cerebellar symptoms and overlappingfeatures complicate furthermorethe etiological diagnosis ofARCA. The determination of themost frequent mutations and corresponding ataxias, as well as particular features specific to a population, are mandatory to facilitate and speed upthe diagnosis process, especially when an appropriate treatment is available. Methods: We explored166 patients (115 families) refered to theneurologyunits of Algiers central hospitals (Algeria) with a cerebellar ataxia phenotype segregating as an autosomal recessive pattern ofinheritance. Genomic DNA was extracted from peripheral blood samples and mutational screening was performed byPCR and direct sequencing or by targeted genomic capture and massive parallel sequencing of57 genes associated withinherited cerebellar ataxia phenotypes. Results: Inthis workwereport theclinical and molecular resultsobtained ona large cohort of Algerian patients (110patients/76 families) with genetically determinedautosomal recessive ataxia, representing 9different types of ARCA and 23 different mutations, including 6 novel ones. The five most common ARCA in this cohort were Friedreich ataxia, ataxia withisolated vitamin E deficiency, ataxia withoculomotor apraxia type 2, autosomal recessive spastic ataxia of Charlevoix-Saguenay and ataxia withoculomotor apraxia type1. Conclusion: We report here a large cohort of patients withgenetically determined autosomal recessive ataxia and thefirst study ofthe genetic context of ARCA in Algeria. Thisstudy showed that in Algerian patients, the two most common types of ataxia (Friedreich ataxia and ataxia withisolated vitamin E deficiency) coexistwith forms that may be less common or underdiagnosed. Torefine thegenotype/phenotype correlation inrare and heteregeneous diseases as autosomal recessiveataxias, more extensive epidemiological investigations and reports are necessary as well as more accurateand detailed clinical characterizations. The use of standardized clinical and molecular protocols would thus enable a betterknowledge ofthedifferent forms of ARCA. Keywords: ARCA, Autosomal recessive ataxias, Algeria, Cohort, Molecular analysis *Correspondence:[email protected] 1LaboratoiredeBiologieCellulaireetMoléculaire,FacultédesSciences Biologiques,USTHB,Alger,Algeria Fulllistofauthorinformationisavailableattheendofthearticle ©2015Hamzaetal.ThisisanOpenAccessarticledistributedunderthetermsoftheCreativeCommonsAttributionLicense (http://creativecommons.org/licenses/by/4.0),whichpermitsunrestricteduse,distribution,andreproductioninanymedium, providedtheoriginalworkisproperlycredited.TheCreativeCommonsPublicDomainDedicationwaiver(http:// creativecommons.org/publicdomain/zero/1.0/)appliestothedatamadeavailableinthisarticle,unlessotherwisestated. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page2of12 Background different ataxia entities. Wealsoreportsomenovelmuta- Inherited cerebellar ataxia is the consequence of an tions,additionalytomutationsalreadydescribedsofar. impairment of the cerebellum, the brainstem and/or spinocerebellar tracts. Phenotypic manifestations may Methods include gait-limb ataxia, frequent falls, dysarthria, adia- Patientsselection dochokinesia, ophthalmological abnormalities and may We studied 166 patients (115 families) refered to the also involve other neurological and/or extraneurological neurology units of Algiers central hospitals (Algeria) and symptoms. Progression of these features lead to the loss report a cohort of 110 Algerian patients, belonging to 76 ofambulatory abilities andoftentoanearly death [1,2]. families,with identifiedcausal mutations. Althoughallpatternsofinheritancehavebeendescribed All patients studied had cerebellar ataxia phenotypes in hereditary cerebellar ataxia [2, 3], we focused in this with an autosomal recessive pattern of inheritance. The work on the Autosomal Recessive Cerebellar Ataxias existence of similar cases among siblings (and/or family “ARCA” forms because of the consanguineous context members) were observed in 30 families and a consan- characterizingtheAlgerianpopulation. guineous background were noted for about 80 % of the ARCA’s first symptoms usually appear before 25 years families. Whenever possible, affected siblings and other old, despite the fact that late-onset forms have been familymemberswerealso analyzed. described [1], and are considered as one of the most Blood samples were obtained for all the patients who complex group in neurogenetics with more than 20 gave informed consent to take part in the study which different clinical entities and at least 30 associated genes/ was approved by the Ministry of Health, Health Ethic loci[4].Someofthesegenesareresponsibleforworldwide Committee,Algeria. well-known ataxia forms, while others underlie very rare forms.Amongthese,somehaveonlybeendescribedinan isolatedpopulationoreveninonefamily[4,5]. Molecularanalysis Despite the increasing knowledge in the molecular Genomic DNA was extracted from peripheral blood aspects of ARCA, a significant proportion of patients samplesusingQIAamp DNA MiniKit®. remain with unidentified ARCA. In addition to the For all 166 patients, the approach consisted in per- genetic heterogeneity of this group of ataxias, there is an forming a systematic screening, using PCR and direct important phenotypic variability in the expression of the sequencing, of the mutations responsible for the major cerebellar impairment. The clinical manifestations are forms of ataxia: the (GAA) expansion in the first intron n indeed as varied as the possible underlying mutations. of the frataxin gene causing Friedreich ataxia, and the The heterogeneous expression of these disorders occurs c.744delA mutation in exon 5 of the TTPA gene which within unrelated patients as well as between siblings of causes ataxiawithisolatedvitaminEdeficiency. the same family and with the same ataxia form. Further- When these targeted mutations were absent, patients’ more,theexistenceofatypicalphenotypesandoverlapping DNA was then analyzed by PCR and sequencing of characteristics bring more complexity to the etiological genes accountable for some other forms of ataxia diagnosis of ARCA.The delineation of the specific clinical (Ataxia with ocular apraxia 1 and 2 “AOA1, AOA2”; features to each ARCA is in fact under permanent discus- AutosomalrecessivespasticataxiaofCharlevoix-Saguenay sion, thus complicating the molecular investigations, but “ARSACS”; Polyneuropathy, hearing loss, ataxia, retinitis alsomakeitanabsolutenecessity. pigmentosa, and cataract syndrome “PHARC”; and Despite ARCA’s high physiopathological diversity, some Autosomal recessive cerebellar ataxia 2 “ARCA2”) by clinical entities are known to be the most frequent, such taking into account the specific clinical indications, asFriedreichataxia(FRDA)andataxiatelangiectasia(AT) while not always strictly relying on them because of in Europe [6–8] or FRDA and AVED in the Algerian the encountered phenotypic heterogeneity, as well as population[9]. on the basis of previous reports incriminating these Given the great clinical and genotypic heterogeneity, genesinourpopulation. as well asoverlapping features, identification ofthe most Finally, taking advantage of the availability of targeted common mutations and corresponding ataxia forms, genomic capture of 57 genes (responsible for inherited together with the specific clinical features observed in a cerebellar ataxia phenotypes as well as genes associated particular population, is crucial to facilitate and speed with pathologies presenting ataxia as a major and/or only up the diagnosis process, especially when an appropriate sign) and massive parallel sequencing using the Agilent treatmentcould beprovided. SureSelect kit®, we were able to select 16 of our patients, This work reports the molecular findings and pheno- taking into account specific clinical indications as well as typic features of a large cohort of 110 Algerians patients more heterogeneous phenotypes. The used strategy was with autosomal recessive cerebellar ataxia representing 9 similartotheonedescribedbyVaslietal.[10]. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page3of12 Results Table1ClinicalfeaturesofagroupofAlgerianpatientswith Clinicalcharacteristics autosomalrecessiveataxia Outof 110patients with identified molecular alterations, Features(68patients) Numberofpatients(%)orvalue 68 had undergone a complete neurologic examination. Ageofonset(mean,range-years) 11.1±5.97SD(birth-35) Those patients belonged to 52 unrelated families among Cerebellarsyndrome 68(100%) which 40 families (55 patients out of 68) were consan- Onsetsign guineous. 57 patients were males and 53 females. The Gaitataxia 47(69.12%) sex ratio was not statistically different (1.07). The mean age at onset for those 68 patients was 11.1±5.97 SD Gaitataxia,frequentfalls 7(10.29%) yearsandrangedfrombirthto35yearsold. Gaitataxia,muscleweakness 6(8.82%) The most common onset sign was gait limb ataxia Gaitataxia,dysarthria 3(4.41%) with unbalance and lack of coordination. Cerebellar Gaitataxia,headtremor 1(1.47%) syndrome was a constant feature, although with various Headtremor 1(1.47%) degreesofdisability. Mostpatientshadataxia(unbalance Headtremor,dysarthria 1(1.47%) and limb incoordination) and experienced frequent falls along withdifferent symptoms like dysmetria and adiado- Psychomotorretardation 2(2.94%) chokinesia. Different stages of disability were observed: Dysarthria 59(86.76%) mostpatientswerecapableofwalkingwithouthelp,some Nystagmus 37(54.41%) of them with unilateral or bilateral help, while 3 were Visualacuitydecline 7(10.29%) wheelchair-bound at the time of clinical diagnosis. A few Spasticity 11(16.17%) patients had a mild cerebellar syndrome. Table 1 summa- Babinskisign 22(32.35%) rizes the clinical data of this cohort of 68 patients. MRI results were available for 50 out of 68 patients and EMG Dysmophricsigns examination was performed in 51 patients. Results are Scoliosis 11(16.17%) summarizedinTable2. Pescavus 20(29.41%) Otherwise, wenoticedthatthe56patientswhosediag- Scoliosis,pescavus 21(30.88%) nosis was not clarified, mostly issued from consanguin- Scoliosis,flatfeet 3(4.41%) eous families (39patients),wererepresented by30 males Pescavus,cranio-facialdysmorphy 1(1.47%) and 26 females (sex ratio of 1.15), a ratio close to the group of 110 patients with genetic diagnosis. The mean None 12(17.64%) age at onset was 7.63±8.17 SD years and ranged from Cognitiveimpairment 6(8.82%) birth to 31 years old, data not statistically different from Cardiomyopathy 7(10.3%) the subgroup of patients with genetic diagnosis, while Epilepsy(epilepticseizures) 3(4.41%) cerebellar syndrome, from severe to moderate, was al- Oculomotorapraxia 5(7.35%) ways present. When available, MRI results and EMG Hypoacusia 6(8.82%) examination showed the same heterogeneous features as the group of patients with genetic diagnosis, with no Headtremor 10(14.7%) remarkable delineation of particular phenotypic charac- teristics or additional associated signs. Also, when avail- able, deficiency of vitamin E, hypoalbuminia, or elevated but one patient, these mutations were found at the AFP, cholesterol or cholestanol levels, could not be homozygousstate. noticed andwere inthenormalrange. The most common mutation was the (GAA) expan- n sion in the first intron of the FXN (frataxin) gene which is responsible for the Friedreich ataxia phenotype [11], Molecularcharacteristicsandfindings present at the homozygous state in 49 (44.54 %) patients Among the 110 patients issued from 76 Algerian fam- representing 31 (40.79 %) families. 35 of the 49 homozy- ilies, consanguinity was present in 76.36 % of patients gous patients (22/35 families) belonged to consanguin- (84 patients/56 families) and absent in 18.18 % of eousfamilies. patients (20 patients/15 families), whereas an undeter- In our cohort, 19 patients representing 16 families mined inbreeding context could be noted for the were found to be homozygous for the c.744delA muta- remaining5.45%(6patients/5families). tion in the fifth exon of the TTPA (tocopherol transfer We report 23 different molecular alterations, including protein alpha) gene, responsible for ataxia with isolated 6 not as yet described, in 9 different genes responsible vitamin E deficiency [12]. 12/19 patients (9/16 families) for autosomal recessive cerebellar ataxia forms. In all were issued fromconsanguineousfamilies. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page4of12 Table2BrainMRIandEMGresultsofagroupofAlgerian Discussion patientswithautosomalrecessiveataxia The present study is the first description of Algerian pa- Imagingandelctrophysiologicalinvestigation Numberofpatients(%) tients with autosomal recessive ataxia and represents the BrainMRI(50patients) largest cohort of patients with genetically characterized ataxia, with 110 Algerian patients (76 families). Table 4 Normal 21(30.88%) summarizes the clinical features in the patients for the Cerebellarhemisphereatrophy 14(20.6%) different forms of ARCA studied.Mostpatients (76.36%) Cerebellarandvermianatrophy 7(10.3%) had consanguineous parents, a proportion that might be Vermianatrophy 5(7.35%) higherifweconsiderdistantconsanguinity,andallthepa- Frontoparietalatrophy 1(1.47%) tientsexceptonecarriedmutationsatahomozygousstate, Parietooccipitalatrophy 1(1.47%) a predictable issue if we consider cultural practices of in- breedinginourpopulation. Spinalcordatrophy 1(1.47%) Our cohort did not include any ataxia telangiecta- Unavailable 18(26.47%) sia patients, although it is reported to be the second Electromyography(EMG)(51patients) most common ARCA [6, 13]. Despite the fact that Demyelinatingsensorymotorpolyneuropathy 24(35.3%) the gene was included in the panel of genes screened SensoryNeuropathy 15(22.06%) by targeted genomic capture and high-throughput se- Axonalsensorimotorneuropathy 4(5.88%) quencing, no mutations were identified in the Algerian patients. Indeed, since the diagnosis of ataxia telangi- Normal 8(11.76%) ectasia is based primarily on clinical criteria in our Unavailable 17(25%) country, we didn’t get samples to analyze as the evok- ing phenotype of this disease could be sufficient. Therefore, this form of ataxia could be more common 18 patients representing 12 families were homozygous inAlgeria. for different mutations in the SETX (senataxin) gene However, we were able to report 23 different molecu- responsible for ataxiawithoculomotorapraxia2 (AOA2). lar alterations, including 6 novel mutations, allowing us 14/18patients(9/12families)wereconsanguineous. to identify 9 different forms of autosomal recessive cere- Wealsoreportpatientswithmutationsinthefollow- bellar ataxias in our population (Fig. 1). Five forms of ing genes: SACS (sacsin), APTX (aprataxin), ADCK3 ARCA appear to be most frequent in the Algerian (aarf domain-containing kinase 3), ABHD12 (abhydro- population. lase domain-containing protein 12), SYNE1 (synaptic nuclear envelope protein 1), and SIL1 (SIL1 nucleotide FRDApatients exchange factor 1), respectively responsible for autosomal We identified 49 patients (31 families) carrying muta- recessivespasticataxiaofCharlevoix-Saguenay(ARSACS), tions in the FXN gene responsible for Friedreich ataxia ataxia with oculomotor apraxia type 1 (AOA1), spino- (FRDA) [11], in accordance with epidemiological data cerebellar ataxia, autosomal recessive 9 (SCAR9), poly- acknowledging Friedreich ataxia as the most common neuropathy, hearing loss, ataxia, retinitis pigmentosa, form of autosomal recessive ataxia in Europe [14]. Even andcataractsyndrome(PHARC),spinocerebellarataxia, if rare compound heterozygous mutations, (GAA) ex- n autosomal recessive 8 (SCAR8) and Marinesco-Sjögren pansion associated with a point mutation, were de- syndrome (MSS). These forms were found in less than scribed in some patients, all our patients carried 10patientsandsomeoftheminasinglepatient: exclusivelythehomozygous unstabletrinucleotide repeat (GAA) in the first intron of the FXN gene, as reported n -8patientsbelongingto6familiescarriedmutations inthemajority ofpatientsreportedworldwide[15]. intheSACSgene. In our cohort, 26 of the 49 patients had undergone -6patientsbelongingto5familieshad mutations in neurological examination. 24 of them had gait-limb theAPTXgene. ataxia as a first sign. Head tremor was the first sign in -6patientsbelongingto3familiesshowedmutations one patient, while another patient displayed muscle intheABHD12gene. weakness. -1patient carriedahomozygous mutationinthe The age at onset in our cohort ranged from 4 to SYNE1geneand another patientwashomozygousfor 35 years old, with a mean onset age of 12.74±7.15 SD amutation intheSIL1 gene. years. Most patients (24) had a classical onset age, between 4 and 20 years old, while one patient had onset Table 3 summarizes the molecular findings for the at 27 and another at 35 years, considering them affected patients/familiesforwhichthemutationswereidentified. bylateonsetforms. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page5of12 Table3MolecularfindingsinAlgerianpatientsaffectedwithautosomalrecessiveataxia ARCA(Gene) Numberofpatients(families) Familymutation(E,Exon.I,Intron) Reference FRDA(FXN) 49(31) Homo(GAA) expansion(I1) [12] n AVED(TTPA) 19(16) Homoc.744delA;p.Glu249Asnfs*15(E5) [11] AOA2(SETX) 2(1) Homoc.2602C>T;p.Gln868*(E8) [32] 1(1) Homoc.5267T>C;p.Phe1756Ser(E8) [32] 9(5) Homodelexon17and18 [9] 1(1) Homodelexon5 [9] 1(1) Homoc.5123G>C;p.Trp1708Ser(E8) Thisstudy 1(1) Homoc.5308_5311delGAGA;p.Glu1770Ilefs*15(E9) [64] 2(1) Homoc.915G>T;p.Trp305Cys(E8) [32] 1(1) Comp.Heterc.915G>T;p.Trp305Cys(E8)c.985C>T;p.Arg329*(E8) [32]Thisstudy ARSACS(SACS) 1(1) Homoc.7372_7376delCTTAT;p.Leu2458Alafs*5(E10) [65] 2(1) Homoc.4882_4886delCAGTT/insAGAAGCp.Gln1628Thrfs*13(10) [65] 4(3) Homoc.12220G>C(exon10),p.Ala4074Pro(E10) [36] 1(1) Homoc.6355C>T(exon10);p.Arg2119*(E10) Thisstudy AOA1(APTX) 5(3) Homoc.837G>A;p.Trp279*(E6) [44] 1(1) Homoc.875-1G>A(disruptionofsplicesite)(E7) [46] SCAR9(ADCK3) 4(1) Homoc.1398+2T>A;p.Asp420Trpfs*40/p.Ile467Alafs*22(I11) [49] 1(1) Homoc.500_521delinsTTG,p.Gln167leufs*36(E3) [49] 1(1) Homoc.1334_1335delCA;p.Thr445Argfs*51(E11) Thisstudy PHARC(ABHD12) 1(1) Homoc.846_852dupTAAGAGC;p.His285fs*1(E9) [56] SCAR8(SYNE1) 1(1) Homoc.3715G>T;p.Glu1239*(E30) Thisstudy MSS(SIL1) 1(1) Homoc.1285T>G;p.Tyr429Asp(E11) Thisstudy AOA1,AtaxiawithOculomotorAparaxiatype1;AOA2,AtaxiawithOculomotorAparaxiatype2;ARCA,AutosomalRecessiveCerebellarAtaxia;ARSACS,Autosomal RecessiveSpasticAtaxiaofCherlevoix-Saguenay;AVED,AtaxiawithisolatedVitaminEDeficiency;FRDA,FriedreichAtaxia;MSS,Marinesco-Sjögrensyndrome; PHARC,Polyneupathy,Hearingloss,Ataxia,RetinitispigmentosaandCataract;SCAR8,SpinocerebellarAtaxia,AutosomalRecessive8;SCAR9,SpinocerebellarAtaxia, AutosomalRecessive9;Homo,homozygote;Comp.Heter,compoundheterozygte *Stopcodon Dysarthria, which is considered as a clinical feature in Another patient showed a parieto-occipital atrophy, with Friedreich patients [16], was present in 23 patients, anonsetat27yearsandadurationofthediseaseof39years. beingsevere intwo ofthem. Onepatient,withananageatonsetof14yearsand9years The upper limb tendon reflexes were abolished in 15 ofdiseaseevolution,showedspinalcordatrophy. patients, were brisk in 3 and normal in 5. At the same In our cohort, 4 patients (15.4 %) with FXN mutations time, lower limb tendon reflexes were abolished in 19 hadhypoacusia,ashasalreadybeenreportedina similar patients, brisk in 4 and normal in one patient. Babinski proportion [19,20]. sign wasnoted in12patients,aspointed outbyprevious Electromyography (EMG) was normal in 2 patients, reports[14,17,18]. while sensory motor polyneuropathy was found in 10, In22patients,dysmorphicfeatureswaseitherscoliosis sensory neuropathy in 8 and axonal neuropathy detected (8 patients), pes cavus (3 patients) or both scoliosis and in2otherpatients. pes cavus (11 patients), one patient presented with a Cardiac impairment, frequent and usually correlated thoracic deformation, according to the progression of to a premature death in Friedreich ataxia [15, 19, 21], thesymptomsinFriedreich ataxia[14]. wasnoted in7patients. MRI was mostly normal (10 patients), whereas 2 None of the patients of our cohort had diabetes, patients presented with cerebellar atrophy as can be although it has been reported in approximately 10 % of observedinadvancedstagesofthedisease[15,16].These FRDApatients[16]. patients were diagnosed after 9 and 3 years of disease duration and the age at onset was respectively 20 and AVEDpatients 13 years. One of the patients had vermian atrophy, with The second most common ARCA diagnosed was the an age at onset of 4 years and after 20 years of evolution. ataxia with isolated vitamin E deficiency (AVED), with Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page6of12 Table4Genotype/phenotypecorrelationsinagroupofpatientsoftheAlgeriancohort FRDA AVED AOA2 ARSACS AOA1 SACR9 PHARC SCAR8 MSS (26P/18F) (12P/10F) (6P/6F) (8P/6F) (2P/2F) (5P/3F) (2P/1F) (1P/1F) (1P/1F) Ageatonset(range) 12.74±7.15 11±4.69 14.57±3.87 7.75±4.62 3and7 9.2±3.7 12and16 7 birth SD(4-35) SD(4-17) SD(9-21) SD(2-14) SD(8-14) Initialsigns Gaitlimbataxia 24 11 6 7 2 5 2 1 / Dysarthria / / / / / / / / / Headtremor 1 1 / / / / / / / MuscleWeakness 1 / / / / 4 / / / CerebellarSyndrome Mild / / / / / 5 / 1 / Moderate 23 10 6 5 2 / 2 / / Severe 3 2 6 3 / / / / 1 Headtremor 3 7 / / / 1 / / / Dysarthria 23 12 5 7 2 3 1 1 1 Nystagmus 14 7 5 6 / / / / 1 Visualacuitydecline 1 1 / 1 / / 1 / 1 Upperlimbstendon reflexes normal 5 2 / 3 / 1 / 1 / weak 1 / 2 1 2 2 / / / absent 15 10 4 / / / 2 / / brisk 3 / / 3 / 1 / / 1 Lowerlimbstendon reflexes normal 1 / / 3 / 1 / / / weak / / 2 / 1 2 / / / absent 19 12 4 / 1 / 2 1 / brisk 4 / / 4 / 1 / / 1 Babinkisign 12 4 / 6 / / / / / Dysmorphicsyndrome Scoliosis 19 9 3 1 1 1 / / / Pescavus 14 7 3 6 / 4 2 1 1 Flatfeet / 3 / / / / / / / Spasticity 3 1 / 6 / / / / 1 Cognitiveimpairment / / 1 2 2 2 / / / MRI normal 10 7 / 1 / 1 1 / / cerebellaratrophy 2 1 6 1 1 3 1 / 1 vermianatrophy 1 3 4 1 1 / / / notavailable 10 4 / 2 / / / 1 / EMG Normal 2 4 / 1 1 / / / / SMP 10 4 3 4 / / 2 / / SN 8 2 3 1 1 / / / / AN 2 2 / / / / / / / Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page7of12 Table4Genotype/phenotypecorrelationsinagroupofpatientsoftheAlgeriancohort(Continued) Cardiacimpairment 7 / / / / / / / / Epilepsy / 1 / 2 / / / / / Hypoacusia 4 / / 2 / / 1 / / AOA1,AtaxiawithOculomotorAparaxiatype1;AOA2,AtaxiawithOculomotorAparaxiatype2;ARCA,AutosomalRecessiveCerebellarAtaxia;ARSACS,Autosomal RecessiveSpasticAtaxiaofCherlevoix-Saguenay;AVED,AtaxiawithisolatedVitaminEDeficiency;FRDA,FriedreichAtaxia;MSS,Marinesco-Sjögrensyndrome; PHARC,Polyneupathy,Hearingloss,Ataxia,RetinitispigmentosaandCataract;SCAR8,SpinocerebellarAtaxia,AutosomalRecessive8SCAR9,SpinocerebellarAtaxia, AutosomalRecessive9;/,absenceofthesign(nopatients) 19 patients (16 families) genetically confirmed: a unique remaining patient. Head titubation was noted in 7 out of mutation (c.744delA) in the TTPA gene was found at a the 12 patients, a sign that could in fact be considered homozygous state in all the patients, which further con- significant todistinguishFRDAfrom AVED[23–25]. firms its high frequency in the Mediterranen basin [22] The upper limbs reflexes were abolished in 10 patients and its strong founder effect as suggested by Ouahchi and normal in 2, while the lower limb reflexes were et al. [12] and supported by the recent report of El abolishedinallthepatients.Theseobservationswereex- Euch-Fayache et al., 2014 [23] or our personal data pected as most AVED patients reported in the literature (unpublishedresults). haveabsentorweaktendon reflexes [24,25]. Among our AVED patients, 12 (10 families) had under- Nystagmus was present in 7 patients and one patient gone neurological examination and 8 patients (6 families) had a visual acuity decline. None of the Algerian patients wereconsanguineous. presented other ocular features such as retinitis pigment- Themean age at onset was11±4.69 SD years,ranging osa[26,27]oroculomotorapraxiaandexotropia[23]. from 4 to 17 years old, in accordance with the fact that Dysmorphicsignswereeithersolelypescavus(1patient) most of the patients already described have onset before or scoliosis, which was associated with either pes cavus 20yearsold[22,23]. (6 patients) or flat feet (3 patients). All the patients but one (11) had gait-limb ataxia as a In this cohort, MRI was normal in 7 patients, showed first sign. Head tremor was the initial sign for the the presence of cerebellar and vermian atrophy in one patient and was not available for 4patients. EMG results were normal in 4 patients and abnormal in 8: two patients had axonal neuropathy, four patients presented with sensorimotor neuropathy and two patients displayed purely sensoryneuropathy. AlthoughAVED isconsidered tobeanataxiaformpresentingwithapuresensoryneur- opathy[14,15,28],patientswithsensorimotorneuropathy have in fact also been reported, particularly in aTunisian cohort[23]. All the patientscarrying the c.744delAmutation in the TTPA gene showed significantly low levels of vitamin E in plasma, as initially stated by this biomarker for this disease[22]. Although it has been reported that an early supple- mentation with vitamin E can slow down the progres- sion of the disease and maintain the walking capability of the patients [29, 30], most of our patients received an intermittent treatment, due to socioeconomic circum- stances,makingitdifficulttoassessthetruecourseofthe diseaseandtherealbenefitofvitaminEsupplementation. Fig.1PatientsoftheAlgeriancohortwithidentifiedformsofARCA. One of our patients that had generalized tonico-clonic AOA1,Ataxiawithoculomotoraparaxiatype1;AOA2,Ataxiawith seizurespresented withearlycerebellar syndrome, dysarth- oculomotoraparaxiatype2;ARSACS,Autosomalrecessivespastic ria, abolished tendon reflexes, scoliosis and sensorimotor ataxiaofCherlevoix-Saguenay;AVED,AtaxiawithisolatedvitaminE deficiency;FRDA,Friedreichataxia;MSS,Marinesco-Sjögrensyndrome; neuropathy at 4 years of age, while cerebral computed PHARC,Polyneupathy,hearingloss,ataxia,retinitispigmentosa tomography was normal, as has been reported for a andcataract;SCAR8,Spinocerebellarataxia,autosomalrecessive Norway patient with vitamin E deficiency and epileptic 8(orARCA1);SCAR9,Spinocerebellarataxia,autosomalrecessive seizures but with compound heterozygous mutations in 9(orARCA2) theTTPAgene[31]. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page8of12 AOA2patients [36], was the most common mutation and was found in The third most frequent form of ataxia in our cohort 4patients(3families). was the ataxia with oculomotor apraxia type 2 with All the patients with SACS mutations had undergone different mutations in the SETX gene. This cohort neurological examination. The 8 patients (6 families) included 18 patients (12 families) with AOA2, and this were consanguineous. study backs up the hypothesis already stated by Tazir The mean age at onset for our patients was 7.75±4.62 et al. [9] setting the AOA2 as the third most frequent SD years, ranging from 2 to 14 years old. Two patients recessive ataxiainAlgeriaafter FRDAandAVED. had onset at 12 years old and one at 14 years old, which Most of the mutations in our cohort have been previ- can be considered as late onset for ARSACS phenotype ously described (Table 3). One mutation, c.5267 T>C ; [36,37]. p.Phe1756Ser, previously found at a heterozygous state Dysarthria was present in 7 of our patients and was in a patient from the United Kingdom [32] was found in acute for one of them, in accordance with one of the one of our patients at a homozygous state. All patients major manifestations of the disease during the first two but one were homozygous for the SETX mutations. This decades ofdiseaseprogression[37]. patient was a compound heterozygote for a new muta- Although hyper myelinated retinal fibers has been con- tion c.985C>T; p.Arg329* associated with a previously stantly described in Canadian ARSACS patients [38, 39], describedmutationc.915G>T;Trp305Cys,both inexon we could notice their absence in all Algerian patients, as eightofthegene[9]. hasalsobeenobservedinTunisianfamilies[36]. Out of the 18 patients with SETX mutations, 10 Pyramidal signs wereobserved in ourpatients: Babinski patients (6 families) have been previously reported [9], sign in 6 of our 8 patients; spasticity, either severe or while the remaining 8 (6 families) were newly diagnosed moderate, in 6 patients; upper and lower limbs reflexes, patients. Out of the 18 patients, 8 (7 families) were con- brisk or very brisk, in 4 patients; while tendon reflexes sanguineous, and out of the 8 newly diagnosed patients, were normal in 3 patients, which could be explained by 6 (4 families) were consanguineous and 6 (6 families) theprogressionofperipheralneuropathythatthusmask hadundergoneacomplete neurologicalexamination. spasticity and pyramidal signs with the evolution of the Themeanageat onset inourpatientswas14.57±3.87 disease[37]. SD years, ranging from 9 to 21 years old, in accordance Cognitive impairment has been noted for two of the with the data of other published series of AOA2 patients patientsofourcohort. [9,33–35]. Two patients had epileptic seizures, a feature which The 8 newly diagnosed patients presented with cere- has been reported in a small proportion of patients bellar syndrome, dysarthria and nystagmus, as indicated harboring SACS mutations [40, 41], while hearing loss, a by the AOA2 phenotype that includes such features in rare feature not mentioned in ARSACS patients, was the great majority of the patients [9, 33, 34], whereas found intwo ofourpatients. only 2 of our patients had oculomotor apraxia, a sign A larger study of ARSACS is being conducted in present inlessthanhalf ofthepatients[33,34]. our population and will provide more insights on All patients had elevated alpha-fetoprotein levels this ataxia in our population, as the patients from which is the main biological marker of AOA2 [32, 33]. Algeria seems to share clinical phenotypes that can Due to the significant size of the gene, only the pa- be rather rare and can mislead the diagnosis (such tients with elevated AFP levels were therefore tested as later onset during the second decade, absence of for the presence of mutations in the SETX gene. myelinated retinal fibers, epileptic seizures, mental Although pes cavus and scoliosis are considered to be disability). occasional features [9, 33, 34], in our cohort, we could ThehugesizeoftheSACSgenecomplicatesthescreen- observe 1 aptient with scoliosis only, 2 patients with ing of patients presenting atypical clinical phenotype and scoliosis and pes cavus, and 2 patients with pes cavus indicates thatthis form of ataxia may beunder-diagnosed only. in several populations, including ours. The screening of thegeneisthereforeworthwhileevenwhensomefeatures ARSACSpatients areabsent. Our study suggests that ARSACS is the fourth most fre- quent form of ataxia in Algeria, with 8 patients and 6 AOA1patients families. The ataxia with oculomotor apraxia type 1 (AOA1) was We identified 4 different mutations in the SACS gene the fifth most frequent ARCA in our cohort since we in 8 patients. One of the mutations (c.6355C>T; have identified 6 patients (3 families) carrying APTX p.Arg2119*) was novel, and the mutation (c.12220G>C; mutations, although it seems to be a rare condition out- p.Ala4074Pro), previously described in Tunisian families sideJapanorPortugal[42,43]. Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page9of12 The nonsense mutation, c.837G>A; p.Trp279*, known which can be explained by the early diagnosis and the asthemostfrequentmutationintheEuropeanpopulation short time of disease duration. All the other patients [44,45],waspresentin5ofourpatients(2families),while (with 14 to over 30 years of disease duration) showed one patient was homozygous for a splice mutation on the cerebellaratrophy. acceptorsplicesiteofexon7,c.875-1G>A. Our patient should also be surveyed for signs of inte- A consanguineous context was noted in 5 patients lectual deficiency as mild forms have been observed in (4families) andtwoofthesepatients(from two unrelated two of the Algerian patients and was reported as mild, families)hadundergoneneurologicalexamination. moderateorsevereinnon-Algerianpatients[49–52]. The age at onset in our patients was 3 and 7 years old All the Algerian patients with SCAR9 seems to have a respectively, with gait-limb ataxia as a first sign for both mild, slowly progressive or even stable cerebellar ataxia, patients, accordingly with the early-onset status of this whichwassuggestedasamainfeatureforSCAR9pheno- form ofataxia[42,46,47]. type, in contrast with most of childhood-onset ARCA Our patients had moderate cerebellar syndrome with [50–52]. The existence of severe SCAR9 phenotypes can dysarthria, but absence of nystagmus although this later however be observed, probably explained by the occur- feature accounts for one of the main clinical signs of renceofstroke-likeepisodesorsevereprogressiveenceph- AOA1 [42]. However, both patients had oculomotor alopathyincludingcerebellaratrophy[51,53]. apraxia and one of them presented with sensory neur- opathy. Our two AOA1 patients had cognitive impair- PHARCpatients ment, which was acute for one of them. This feature, Our cohortof 6patientsincluded 2of the siblings previ- initially thought to be exclusive to Japanese patients ously described in studies of PHARC and which allowed [43], was nevertheless found in a cohort of Italian the identification of the gene, showing that all reported patients [47] and is here described for the second time mutations so far results in premature stop codons pre- innon-Japanese patients. sumed to cause a loss of function of the protein [54, 55]. MRI showed in our patients a severe cerebellar atro- All Algerian patients had thus the same homozygous phy in one case and a severe vermian atrophy in the mutation c.852insTAAGAGC (c.846_852dupTAAGAGC); other,ashasbeenreported inallaffected AOA1patients p.His285fs1*.Inourstudy,wescreenedtheABHD12gene [42,47,48]. for two Algerian patients who presented a phenotype somewhatsimilartotheAlgerianpatientsidentifiedinthe SCAR9patients report of Fiskerstrand et al. [56]. The two previously The report of a new case of SCAR9 in Algeria in this reportedAlgerianpatientsandincludedinourcohorthad study, after the identification of the causal gene in two onset at 12 and 18 years of age respectively, had both Algerian families [49], brings the number of patients cerebellar ataxia and peripheral neuropathy; one had an with genetically confirmed SCAR9 to 6 (3 families) in importantdeclineinvisualacuityandtheotherpresented Algeria andto24worldwide[49–51]. withcataract.However, thetwonewpatientsweexplored The patient we report here carried a novel frameshift did not carry ABHD12 mutations. Although our criteria mutation c.1334_1335delCA, p.Thr445Argfs*51 in the were mainly the presence of ataxia and polyneuropathy ADCK3 gene, highlighting that all the mutations identi- associated with either cataract, a decline in visual acuity fiedsofarinAlgeriaaretruncating. and/or hearing loss, it could not exclude the presence of Although the delineation of the SCAR9 phenotype atypical clinical presentations, as was the case for non- remains difficult because of the great clinical differences Algerian PHARC patients. Indeed, neither signs of from one patient to another [51], the clinical features of polyneuropathynorataxiawereobservedinthesesiblings, all the SCAR9 Algerian patients seems relatively similar. while their hearing loss and cataract were wrongly attrib- In fact, this new patient was diagnosed after 2 years of uted to their age or the progression of the retinitis pig- disease duration and shared with the other Algerian mentosa,therebyexpandingthephenotypicalspectrumof patients already described a similar age at onset (8 years PHARC[55].Wecanhoweverassumethatthissyndrome old/mean onset age of 6.8±2.95 SD years, ranging from couldbeinfactextremelyrare. 4 to 11 years old) and a very mild cerebellar syndrome with gaitlimbataxia andmuscleweakness asfirst signs. SCAR8patient The upper and lower limb reflexes were weak for 2 We identified in the present cohort a patient carrying a patients including the newly reported one but were novel mutation, c.3715G>T; p.Glu1239*, in the SYNE1 either brisk or normal for the others. All patients had gene, thereby reporting the first Algerian patient with a dysarthria and pes cavus but only the patient carrying geneticallyconfirmedrecessive ataxiaSCAR8. the newly found mutation presented with mild scoliosis. Thepatienthadconsanguineousparentsand10siblings The MRI showed no abnormalities for this patient, who were all healthy. The age at onset was 7 years old, Hamzaetal.BMCMedicalGenetics (2015) 16:36 Page10of12 which can be considered as early-onset in contrast to the that, in addition to the most common mutations and findings in the French-Canadian patients who showed a ataxias, other rarer or underdiagnosed forms might be middle-aged onset [57, 58]. The patient had gait limb involved and could be underestimated. Taken together, ataxia as a first sign and presented with mild cerebellar FRDA and AVED patients thus represented 61.82 % of syndrome and dysarthria; she had normal upper limb re- the patients in this cohort (68 patients) while combined, flexes but abolished lower ones. The identification of the FRDA, AVED, AOA2, ARSACS and AOA1 accounted causal mutation was performed by targeted genomic cap- for 90.9 % of the cohort (100 patients) of the whole tureshortlyafterthefirstconsulting,whileMRIandEMG autosomal recessive forms of ataxia in our cohort. examinations were not done. It would therefore be inter- Besides these most frequent forms, we were able to iden- estingtoseeifthispatienthasamarkeddiffusecerebellar tifyothertypesofataxiaseeminglyrareinourpopulation. atrophy and no signs of neuropathy, as was shown in the A precise assessment of the frequent forms and muta- French-Canadian patients [57, 59]. The phenotypic fea- tions specific to our population can strongly help the turesofourpatientshowedthattheoutlinesofthedisease orientation of the investigations in the long term. How- remain ambiguous, with probable great variability in pa- ever, for rare and heterogeneous pathologies as auto- tients outside Quebec and Canada. It also indicates that somal recessive ataxia, there is still a long way to go in unrecognized features, such as early onset, may lead to order to refine genotype/phenotype correlations. More the underdiagnosis of this form of ataxia, particularly be- extensive molecular and epidemiological investigations cause genetic analysis faces such a large gene as SYNE1 will allow a better knowledge of the different ARCA and with its 145 coding exons and complicates considerably facilitate the genetic explorations. The power of innova- themutationalscreening. tive approaches, such as high-throughput sequencing, opens now new perspectives for diagnosis and research MSSpatient and will certainly provide mandatory answers for patients We report in this study the first genetically confirmed remainingwithoutmoleculardiagnosis. case of Algerian patient with Marinesco-Sjögren syndrome Competinginterests (MSS) and the characterization of a new mutation in the Theauthorsdeclarethattheyhavenocompetinginterests. SIL1gene,c.1285T>G;p.Tyr429Asp,atthehomozygous state. Authors’contributions This patient had consanguineous parents and had an MK,TBandMTconceivedanddesignatedthestudy.LA,FF,SM,MC,andMT acquiredandprovidedclinicaldataandsamplesfrompatients.WHandTB initial psychomotor impairment that started at birth carryoutthelaboratorywork.JMandNDhelpedpreparingthelaboratory (sitting position acquired at 2 years and a half, walking work.WHandTBdraftedthemanuscript.TB,THandMKrevisedthe without help never acquired, and speech acquisition at manuscript.Alltheauthorsreadandapprovedthefinalmanuscript. 4 years old with an important dysarthria). The patient Acknowledgements was 14 years old when diagnosed and had severe Weexpressourgratitudetothefamiliesfortheircooperationintheresearch cerebellar syndrome (walk without bilateral help was project.WethankverymuchMariaMoreiraforherinvaluablecontribution. WewishtothankthehelpofBernardJost,SergeVicaireandStéphanie impossible),severedysarthria,nystagmusandvisualacuity Legrasfornext-generationsequencingandanalysis.Thisworkreceived decline. The upper and lower limbs reflexes were brisk supportfromtheAssociationFrançaisecontrelesMyopathies(AFM,France, andthepatientpresentedamildspasticitybutnoBabinski toT.B.),theInstitutNationaldelaSantéetdelaRechercheMédicale (INSERM,France),theCentreNationaldelaRechercheScientifique(CNRS, sign. Dysmorphic featuresconsisted in pes cavus and cra- France),theAgenceNationalepourlaRecherche-MaladiesRaresand niofacial dysmorphy. MRI showed cerebellar atrophy and MaladiesNeurologiquesetPsychiatriques(ANR-09-MNPS-001-01toM.K.), hypoplasia. The patient had congenital cataract, but has theANR/E-rareJTC2011“Euro-SCAR”(2011-RARE-004-01toM.K.),theAgence NationalepourleDéveloppementdelaRechercheScientifiqueforthe undergone surgery at 6 years of age. Once the molecular NationalProgramofResearch(PNR-310-ANDRS,Algeria,toT.B.),theMinistère diagnosisestablished,thepatientwas also found to have delaSanté,delaPopulationetdelaRéformeHospitalière(MSPRH,Algeria), hypergonadotropic hypogonadism, in accordance with andtheMinistèredel’EnseignementSupérieuretdelaRecherche Scientifique(MESRS,Algeria). the presentation of the syndrome [60, 61]. Although MSS patients have been reported in many Authordetails countries [60, 62, 63], there is no epidemiological data on 1LaboratoiredeBiologieCellulaireetMoléculaire,FacultédesSciences Biologiques,USTHB,Alger,Algeria.2ServicedeNeurologie,CHUMustapha the occurrence of this syndrome. Targeted genomic cap- Bacha,Alger,Algeria.3LaboratoiredeNeurosciences,Universitéd’Alger1, ture and massive parallel sequencing could therefore help Alger,Algeria.4LaboratoiredeBiologieMoléculaire,FacultédesSciences, toscreenforsuchgenesdescribedinraresyndromes. UMBB,Boumerdes,Algeria.5InstitutdeGénétiqueetdeBiologieMoléculaire etCellulaire,CNRS/UniversitédeStrasbourgUMR7104,INSERMU964,Illkirch, France.6LaboratoiredeDiagnosticGénétique,HôpitauxUniversitairesde Conclusions Strasbourg,Strasbourg,France.7ServicedeNeurologie,CHUBenAknoun, We report with this large cohort of genetically deter- Alger,Algeria.8ServicedeNeurologie,EHSAliAïtIdir,Alger,Algeria. 9LaboratoiredeGénétiquedeMaladiesRares,InstitutUniversitairede mined autosomal recessive ataxia, the first study of the RechercheClinique,UniversitédeMontpellier,CHUdeMontpellier, genetic context of ARCA in Algeria. Our study shows Montpellier,France.

Description:
Keywords: ARCA, Autosomal recessive ataxias, Algeria, Cohort, Molecular analysis. * Correspondence: samples using QIAamp DNA Mini Kit®. For all 166 patients, “ARSACS”; Polyneuropathy, hearing loss, ataxia, retinitis pigmentosa, and .. Although hyper myelinated retinal fibers has been con-.
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