Silvia Jesús1, Isabel Hinarejos1, Fátima Carrillo1, Dolores Martínez-Rubio1, Daniel Macías-García1, Ana Sánchez-Monteagudo1, Astrid Adarmes1, Vincenzo Lupo1, Belén Pérez-Dueñas1, Pablo Mir1, Carmen Espinós1. 1. Unidad de Trastornos del Movimiento (S.J., F.C., D.M.-G., A.A., P.M.), Servicio de Neurología y Neurofisiología Clínica, Instituto de Biomedicina de Sevilla, Hospital Universitario Virgen del Rocío/CSIC/Universidad de Sevilla, Spain; Centro de Investigación Biomédica en Red Enfermedades Neurodegenerativas (CIBERNED) (S.J., F.C., D.M.-G., A.A., P.M.), Spain; Unit of Genetics and Genomics of Neuromuscular and Neurodegenerative Disorders (I.H., D.M.-R., A.S.-M., V.L., C.E.), Centro de Investigación Príncipe Felipe (CIPF), Valencia, Spain; Joint Units INCLIVA and IIS La Fe Rare Diseases (I.H., D.M.-R., A.S.-M., V.L., C.E.), Centro de Investigación Príncipe Felipe (CIPF), Valencia, Spain; Department of Pediatric Neurology (B.P.-D.), Hospital Universitari Vall d'Hebron, Barcelona, Spain; and Universitat Autònoma de Barcelona (B.P.-D.), Spain.
The NR4A2/NURR1 gene (MIM*601828) has recently been associated with autosomal-dominant early-onset dystonia-parkinsonism with intellectual disability.[1]
NR4A2 codifies for a nuclear transcription factor and is expressed mainly in the substantia nigra, ventral tegmental area, and limbic areas.[2] To date, 14 different alterations in NR4A2 have been described associated with various clinical phenotypes, mainly with neurodevelopment disorders (table e-1, links.lww.com/NXG/A371). We describe here an interesting case suffering a persistent dystonia-parkinsonism syndrome (DPS) with motor tics, which expands the clinical phenotype of NR4A2-associated DPS.This is a 30-year-old man with no family history of neurologic disease who was born after a normal pregnancy and childbirth. He started walking with support at 13 months, but his gait was clumsy, resulting in numerous falls during childhood. At 2 years old, the patient presented attention deficit. He began to speak at 3 years of age but with impaired fluency, vocabulary, and articulation. The patient required special education to learn basic writing and arithmetic skills. At the age of 7 years, his intelligence quotient was 77. At 16 years old, he presented trichotillomania, and he began to experience motor tics characterized by an urge to move his right shoulder upward, an urge that was relieved after performing the movement. He was satisfactorily treated with atomoxetine. He also noticed an abnormal backward-cervical deviation. This clinical situation remained stable for 10 years, although motor tics tended to improve with age.At 28 years old, the patient complained of slowness, walking difficulties, and a worsening abnormal craniocervical posture. He presented marked jaw-opening dystonia and parkinsonian features, with rigidity and a progressive reduction in the amplitude and frequency of repetitive movements in the left hemibody. The gait difficulties manifested with dragging steps, mainly in the left hemibody (Video 1). The patient also presented nonmotor symptoms such as gastrointestinal and sleep-related symptoms, with the mobility and communication domains affecting his quality of life the most (figures e-1 and e-2, links.lww.com/NXG/A371).Download Supplementary Video 1 via http://dx.doi.org/10.1212/000543_Video_1The results of supplementary and neuroimaging tests were normal (figure 1, table e-2, links.lww.com/NXG/A371), whereas 123FP-CIT-single photon emission CT revealed reduced bilateral (predominantly right sided) uptake in both striatum (figure e-1).
Figure 1
Functional and Structural Brain Images
(A) 123FP-CIT-SPECT revealed bilateral uptake reduction with impairment of the caudate and putamen and a predominance in the right hemisphere and both putamen. (B and C) Normal 18FDG-PET coronal and axial images. (D) Normal cranial MRI T2 axial image. 18FDG = 18-fluorodeoxyglucose.A genetic analysis using a custom gene panel of 498 genes involved in movement disorders (MovDisord-498)[3] revealed no causative mutations (appendix e-1, links.lww.com/NXG/A371). The proband and healthy parents (trio) then underwent whole exome sequencing (WES) using the Whole Exome Family Plus test (Blueprint Genetics, Helsinki, Finland). WES data were filtered as previously described[4] and 3 candidate disease-causing changes were found (table e-3). We further investigated the detected changes by Sanger sequencing in all the available relatives (figure e-3). The KCNQ2c.1807-5A>T resulted to be a false-positive result. The proband, his parents, and his brother carried the CEP170c.2375C>A (p.S792*) change in heterozygosis, and therefore, this variant was discarded as disease-causing mutation. Regarding the NR4A2c.956G>A (p.R319Q) substitution, only the patient harbored it, and consequently, this mutation was de novo. Moreover, 2 frameshift mutations in NR4A2 were recently described in 2 patients with DPS.[1] R319 is an evolutionarily conserved amino acid (data not shown) located on the essential domain Zf-C4/DBD (figure e-4). The variant was considered likely pathogenic according to the American College of Medical Genetics and Genomics classification, based mainly on the PS2 and PM2 criteria, although the NR4A2c.956G>A mutation also meets the PP3 and PM1 criteria.[5]Consistent with previous descriptions of NR4A2 subjects,[1] our patient also presented craniocervical dystonia with parkinsonian features that started in early adulthood, with previous intellectual disability and language impairment. In our proband, however, the dystonia was persistent and worsened in stressful situations, contrasting with the previously reported paroxysmal dystonic episodes.[1] Clinicians should therefore be aware of paroxysmal and persistent dystonia features related to NR4A2.Our proband also shared with previously reported cases, clear signs, and symptoms of dopaminergic degeneration,[1] suggesting a relationship between the role of NR4A2 and dysfunction of the dopaminergic nigrostriatal network. Of interest, our patient also experienced motor tics and attention deficit during childhood. Previous reports have shown the involvement of gross deletions in NR4A2 in autism spectrum disorders, with some patients manifesting “restlessness” during childhood.[6] To date, however, there have been no reported data on the comorbidity with motor tics, which are therefore a novel feature associated with the NR4A2 phenotype, a feature that will become clearer as more cases are reported.In NR4A2, there seems to be no association between the mutation type and the resulting phenotype, except for patients with complex neurodevelopmental disorders that are caused by large deletions. In fact, diverse NR4A2-related phenotypes can even be caused by the same mutation.[7] In this case study, we presented the first patient with DPS caused by a missense NR4A2 mutation, the p.R319Q. NR4A2-associated DPS can therefore be caused by more than just loss-of-function mutations.In conclusion, motor tics and persistent dystonia in NR4A2-associated DPS should be included within its phenotypic description along with early-onset parkinsonism and intellectual disability with language impairment. The description of new cases may help to improve the correlation between NR4A2 and its clinical picture, which, so far, is mainly relevant for neurodevelopmental disorders.
Authors: J Lévy; S Grotto; C Mignot; A Maruani; A Delahaye-Duriez; B Benzacken; B Keren; D Haye; J Xavier; M Heulin; E Charles; A Verloes; C Dupont; E Pipiras; A-C Tabet Journal: Clin Genet Date: 2018-08 Impact factor: 4.438
Authors: Sue Richards; Nazneen Aziz; Sherri Bale; David Bick; Soma Das; Julie Gastier-Foster; Wayne W Grody; Madhuri Hegde; Elaine Lyon; Elaine Spector; Karl Voelkerding; Heidi L Rehm Journal: Genet Med Date: 2015-03-05 Impact factor: 8.822
Authors: Luiza L P Ramos; Fabiola P Monteiro; Leticia P B Sampaio; Larissa A Costa; Mara D O Ribeiro; Erika L Freitas; Joao P Kitajima; Fernando Kok Journal: Clin Case Rep Date: 2019-07-11
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