untitled LE JOURNAL CANADIEN DES SCIENCES NEUROLOGIQUES LETTER TO THE EDITOR TO THE EDITOR SAMHD1 MUTATIONS ARE ALSO RESPONSIBLE FOR AICARDI– GOUTIÈRES IN THE CREE POPULATION Keywords: Encephalopathy, Aicardi–Goutières syndrome, Cree encephalitis Aicardi–Goutières syndrome (AGS) is a progressive inflammatory encephalopathy with multi-organ involvement. There are seven genes known to be responsible for AGS (TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1, ADAR, and IFIH1). The most common is TREX1, typically presenting as neonatal encephalopathy with cystic leukoencephalopathy and calcifications on brain imaging. Affected infants may present with hepatosplenomegaly, transaminitis, and thrombocytopenia and are often presumed to have a congenital viral infection. However, many children with AGS present within the first weeks of life following a normal neonatal period. Clinical manifestations include developmental regression, difficulty feeding, micro- cephaly, spasticity, seizures, and sterile pyrexias. First described in 11 Cree children from a Northern Quebec village, Cree encephalitis is thought to be an immune condition possibly triggered by a prenatal viral or retroviral infection in a genetically predisposed population.1 Currently, only TREX1 mutations have been implicated in Cree encephalitis.2 A pathogenic variant affecting SAMHD1 has not been described in Cree children. We report a case of a Cree boy with phenotypic severe AGS and a homozygous SAMHD1 mutation. Consent was obtained from his biological parents. The AGS phenotype due to the common muta- tion in the Cree population has traditionally been referred to as Cree encephalitis but is allelic to AGS in some patients. Therefore, Cree encephalitis is likely part of the AGS spectrum of disorders. Our patient is a 5-year-old boy born at term by caesarean section to a healthy gravida-5/para-5 mother after an uncompli- cated pregnancy and delivery. Prenatal ultrasounds were normal. He required no resuscitation, and there were no postnatal complications. To the parents, he appeared developmentally nor- mal for the first 2 months of life with normal head control and feeding. However, he never learned to smile, coo, or reach for objects. Between the age of 2 and 3 months, he had an arrest of gross motor development and lost head control. He developed spastic quadriplegia with opisthotonus. At 6 months, he required a gastrostomy tube for feeding, through which he is now exclusively fed. At 12 months, he developed myoclonic seizures. He was diagnosed with glaucoma at 2 years and is cortically blind. He has several hospital admissions for aspiration pneumonia and status epilepticus. Other issues included hypertension, secundum atrial septal defect, and recurrent fevers of unknown origin. Physical examination at 3.5 years revealed severe micro- cephaly (<2%), spastic quadriplegia with severe contractures of all limbs, spontaneous clonus, dystonic posturing, upgoing plantar responses bilaterally, and hepatosplenomegaly. He demonstrated small violaceous palpable lesions on his nose and right great toe. Currently, at age 5, he smiles in response to his parents’ voice and occasionally coos, but he has no spontaneous movements. He continues to have intermittent fevers without infections. His seizures are under control. Both parents are of Cree origin and reside in northeastern Ontario along James Bay, and are from different communities. The mother had two male cousins via her maternal aunt with developmental delay and seizures, both of whom died at age 8 months. No other family member has had neurological issues. Head MRI at age 1 year showed tiny periventricular white matter and basal ganglia T1 hyperintensities (Figure 1). Findings on T2-weighted imaging included frontal predominant periven- tricular hyperintensities extending into the subcortical U-fibers, anterior temporal lobe and bifrontal subcortical cysts, frontal encephalocele, cavum septum pellucidum, abnormal myelination of external capsules and the internal capsule, and a thin corpus callosum, as well as brainstem and cerebellar atrophy. These findings persisted at 26 months with further cortical and brainstem atrophy. There was no enhancement on gadolinium. MR spec- troscopy demonstrated lactate peak and an increased choline- to-NAA ratio. No vessel imaging was acquired. Chromosomal microarray done at age 1 year was normal. Initial testing for Cree encephalitis (TREX1) followed by testing for RNASEH2A, Cree leukoencephalopathy (eIF2B5), leukodystro- phies, and fibroblasts for respiratory chain analysis were negative. He was then tested for an AGS panel including TREX1, RNASEH2A/B/C, and SAMHD1, and was found to have a homozygous sequence variant at c1265T > A; p.Leu422Gln in SAMHD1, which has not been previously reported in the literature. Both parents are carriers of this variant. In-silico analysis was done using four different programs (Align GVGD, SIFT, MutationTa- ster, and PolyPhen-2). Based on the current available information, SAMHD1:c.1265T> A is classified as a “variant of uncertain significance” (VUS, ACMG 3). Evidence supporting pathogenicity (PM2, PP3, PP4), falls short of being sufficient to classify the variant as “likely pathogenic” (ACMG 4). A different amino acid substitution has been reported at the same position (c.1265T> C, p.Leu422Pro) in a case of gastric adenocarcinoma (COSMIC ID: COSM4098095). Based on the in-silico FATHMM algorithm, this variant is classified as “pathogenic.” This evidence (PM5) was not included in the final ACMG classification because the pathogeni- city of the c.1265T > C (p.Leu422Pro) variant was based entirely on in-silico predictions. If this additional information is considered (PP5), the SAMHD1:c.1265T> A variant would be classified as “likely pathogenic” (ACMG 4). Homozygous and compound heterozygous mutations in SAMHD1 were first implicated in AGS patients in 2009.3 Approximately 13% of AGS is caused by mutations in SAMHD1 (including missense and null mutations as well as large deletions).3.4 The majority of these patients have a normal neonatal course with neurological symptoms presenting in the first year of life. SAMHD1 mutations have been found in Amish populations,5 Maltese patients,6 Ashkenazi Jews,6 and patients of Northern European, North American, Asian, and Australian descent.4 The phenotypic similarities between AGS and Cree encepha- litis are well-described. Currently, only TREX1 mutations have been identified in Cree encephalitis.2 To our knowledge, there are no reports of SAMHD1 mutations in Cree children. THE CANADIAN JOURNAL OF NEUROLOGICAL SCIENCES 749 https://www.cambridge.org/core/terms. https://doi.org/10.1017/cjn.2017.226 Downloaded from https://www.cambridge.org/core. Carnegie Mellon University, on 06 Apr 2021 at 01:38:33, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms https://doi.org/10.1017/cjn.2017.226 https://www.cambridge.org/core Several conditions are associated with AGS, including glau- coma, autoimmune diseases, familial chilblain cardiomyopathy, intracerebral vasculitis,7 and arthropathy.4 Among AGS patients, those with SAMHD1 mutations have a higher likelihood of devel- oping glaucoma and chilblains. They are also the only group to develop intracerbral vasculopathy and arthropathy. In a series of five patients with SAMHD1 mutations, all had both a cerebral arteriopathy and peripheral vasculopathy with chilblains, and two had leukocytoclastic vasculitis on skin biopsy.7 These findings were convincing for a role for SAMHD1 in systemic inflammation. Therefore, for this subgroup of AGS, anti-inflammatory therapies and immunosuppression may help prevent disease progression. Patients with AGS display increased interferon activity in cerebrospinal fluid and serum.8 This was not investigated in our patient due to his deteriorating condition. Currently, in Canada, TREX1 testing for the common mutation is typically done first-line in patients suspected of having Cree encephalitis. If negative, an AGS panel (including SAMHD1) or individual SAMHD1 testing should be performed. A wider genetic screen of the Cree population may help elucidate the carrier rate of SAMHD1 in this population. If additional cases are identified, it would assist in defining the pathogenicity of the variant. This testing would be particularly important, as AGS with SAMHD1 mutations can have potential complications, including glaucoma and arteriopathy, requiring anticipatory screening and treatment. Fur- thermore, immunosuppressive therapies may play a role in the management of this subgroup of AGS patients. ACKNOWLEDGMENTS We thank Dr. John Waye for his support in writing this manuscript and the patient’s family for their permission to report his case. DISCLOSURES Ashraf Kharrat, Jennifer MacKenzie, and Sunita Venkateswaran do not have anything to disclose. Ashraf Kharrat Department of Paediatrics, University of Toronto Toronto, Ontario, Canada Figure 1: A through C, age 4 months, T2W and T2 FLAIR axial images demonstrating temporal and frontal cysts; D through F, age 11 months, T2W and T2 FLAIR axial images demonstrating temporal and frontal cysts and abnormal myelination status; G, age 18 months, T1W axial image demonstrating left glaucoma; H, age 18 months, T2W axial image demonstrating ongoing cerebral atrophy; I, age 18 months, T1W axial image demonstrating basal ganglia calcifications. THE CANADIAN JOURNAL OF NEUROLOGICAL SCIENCES 750 https://www.cambridge.org/core/terms. https://doi.org/10.1017/cjn.2017.226 Downloaded from https://www.cambridge.org/core. Carnegie Mellon University, on 06 Apr 2021 at 01:38:33, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms https://doi.org/10.1017/cjn.2017.226 https://www.cambridge.org/core Jennifer MacKenzie Department of Paediatrics, McMaster University Hamilton, Ontario, Canada Sunita Venkateswaran Division of Paediatric Neurology, Department of Paediatrics University of Ottawa, Ottawa, Ontario, Canada REFERENCES 1. Black DN, Watters GV, Andermann E, et al. Encephalitis among Cree children in Northern Quebec. Ann Neurol. 1988;24(4): 483-9. 2. Crow YJ, Black DN, Ali M, et al. Cree encephalitis is allelic with Aicardi–Goutières syndrome: implications for the pathogenesis of disorders of interferon alpha metabolism. J Med Genet. 2003; 40(3):183-7. 3. Rice GI, Bond J, Asipu A, et al. Mutations involved in Aicardi– Goutières syndrome implicate SAMHD1 as regulator of the innate immune response. Nat Genet. 2009;41(7):829-32. 4. Crow YJ, Chase DS, Lowenstein Schmidt J, et al. Characterization of human disease phenotypes associated with mutations in TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1, ADAR, and IFIH1. Am J Med Genet A. 2015;167A(2):296-312. 5. Xin B, Jones S, Puffenberger EG, et al. Homozygous mutation in SAMHD1 gene causes cerebral vasculopathy and early onset stroke. Proc Natl Acad Sci U S A. 2011;108(13):5372-7. 6. Straussberg R, Marom D, Sanado-Inbar E, et al. A possible geno- type–phenotype correlation in Ashkenazi Jewish individuals with Aicardi–Goutières syndrome associated with SAMHD1 mutation. J Child Neurol. 2015;30(4):490-5. 7. Ramesh V, Bernardi B, Stafa A, et al. Intracerebral large artery disease in Aicardi–Goutières syndrome implicates SAMHD1 in vascular homeostasis. Dev Med Child Neurol. 2010;52(8):725-32. 8. Lebon P, Badoual J, Ponsot G, Goutières F, Hémeury-Cukier F, Aicardi J. Intrathecal synthesis of interferon-alpha in infants with progressive familial encephalopathy. J Neurol Sci. 1988;84 (2–3):201-8. LE JOURNAL CANADIEN DES SCIENCES NEUROLOGIQUES Volume 44, No. 6 – November 2017 751 https://www.cambridge.org/core/terms. https://doi.org/10.1017/cjn.2017.226 Downloaded from https://www.cambridge.org/core. Carnegie Mellon University, on 06 Apr 2021 at 01:38:33, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms https://doi.org/10.1017/cjn.2017.226 https://www.cambridge.org/core Outline placeholder Figure 1A through C, age 4 months, T2W and T2 FLAIR axial images demonstrating temporal and frontal cysts; D through F, age 11 months, T2W and T2 FLAIR axial images demonstrating temporal and frontal cysts and abnormal myelination status; G, age 18 months