Article Text

Original research
Craniofacial features of POLR3-related leukodystrophy caused by biallelic variants in POLR3A, POLR3B and POLR1C
  1. Amytice Mirchi1,2,3,
  2. Simon-Pierre Guay4,5,
  3. Luan T Tran1,3,
  4. Nicole I Wolf6,
  5. Adeline Vanderver7,8,
  6. Bernard Brais1,4,9,
  7. Michel Sylvain10,
  8. Daniela Pohl11,
  9. Elsa Rossignol12,
  10. Michael Saito13,
  11. Sebastien Moutton14,
  12. Luis González-Gutiérrez-Solana15,
  13. Isabelle Thiffault16,17,
  14. Michael C Kruer18,19,20,
  15. Dolores Gonzales Moron21,
  16. Marcelo Kauffman22,
  17. Cyril Goizet23,24,
  18. László Sztriha25,
  19. Emma Glamuzina26,
  20. Serge B Melançon27,
  21. Sakkubai Naidu28,
  22. Jean-Marc Retrouvey29,
  23. Suzanne Lacombe29,
  24. Beatriz Bernardino-Cuesta30,
  25. Isabelle De Bie4,5,31,
  26. Geneviève Bernard1,2,3,4,5
  1. 1 Department of Neurology and Neurosurgery, McGill University, Montreal, Quebec, Canada
  2. 2 Department of Pediatrics, McGill University, Montreal, Quebec, Canada
  3. 3 Child Health and Human Development Program, Research Institute of the McGill University Health Centre, Montreal, Quebec, Canada
  4. 4 Department of Human Genetics, McGill University, Montreal, Quebec, Canada
  5. 5 Department of Specialized Medicine, Division of Medical Genetics, McGill University Health Center, Montreal, Quebec, Canada
  6. 6 Department of Child Neurology, Amsterdam Leukodystrophy Center, Emma Children’s Hospital, Amsterdam University Medical Centers, and Amsterdam Neuroscience, Cellular & Molecular Mechanisms, Vrije Universiteit, Amsterdam, Netherlands
  7. 7 Division of Neurology, Children's Hospital of Philadelphia, Philadelphia, Pennsylvania, USA
  8. 8 Department of Neurology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania, USA
  9. 9 Montreal Neurological Institute, Montreal, Quebec, Canada
  10. 10 Centre Mère Enfant, CHU de Québec, Québec City, Quebec, Canada
  11. 11 Division of Neurology, Children's Hospital of Eastern Ontario, University of Ottawa, Ottawa, Ontario, Canada
  12. 12 Departments of Neurosciences and Pediatrics, CHU-Sainte-Justine, Université de Montréal, Montreal, Quebec, Canada
  13. 13 Department of Pediatrics, University of California Riverside School of Medicine, Riverside Medical Clinic, Riverside, California, USA
  14. 14 Centre Pluridisciplinaire de Diagnostic PréNatal, MSPBordeaux Bagatelle, Talence, France
  15. 15 Sección de Neuropediatría, Hospital Infantil Universitario Niño Jesús, Madrid, España; Grupo Clínico Vinculado al Centro de Investigación Biomédica en Red para Enfermedades Raras (CIBERER) GCV14/ER/6, Hospital Infantil Universitario Nino Jesus, Madrid, Spain
  16. 16 Genomic Medicine Center, Children's Mercy Hospital, Kansas City, Missouri, USA
  17. 17 University of Missouri Kansas City School of Medicine, Kansas City, Missouri, USA
  18. 18 Departments of Child Health, Neurology, and Cellular & Molecular Medicine and Program in Genetics, University of Arizona College of Medicine, Phoenix, Arizona, USA
  19. 19 Programs in Neuroscience and Molecular & Cellular Biology, School of Life Sciences, Arizona State University, Tempe, Arizona, USA
  20. 20 Pediatric Movement Disorders Program, Barrow Neurological Institute, Phoenix Children's Hospital, Phoenix, Arizona, USA
  21. 21 Neurogenetics Unit, Department of Neurology, Hospital JM Ramos Mejia, ADC, Buenos Aires, Argentina
  22. 22 Neurogenetics Unit, Department of Neurology, Hospital JM Ramos Mejia and CONICET-Universidad Austral, Buenos Aires, Argentina
  23. 23 Centre de Référence Neurogénétique, Service de Génétique Médicale, Bordeaux University Hospital, CHU Bordeaux, Bordeaux, France
  24. 24 NRGEN team, INCIA, CNRS UMR 5287, University of Bordeaux, Bordeaux, France
  25. 25 Department of Paediatrics, Albert Szent-Györgyi Medical School, University of Szeged, Szeged, Hungary
  26. 26 Adult and Paediatric National Metabolic Service, Starship Children’s Hospital, Auckland, Te Whatu Ora, New Zealand
  27. 27 Department of Medical Genetics, McGill University Health Centre, Montreal Children’s Hospital, Montreal, Quebec, Canada
  28. 28 Department of Neurogenetics, Kennedy Krieger Institute, Johns Hopkins Medical Institutions, Baltimore, Maryland, USA
  29. 29 Department of Orthodontics, University of Missouri, Kansas City, Missouri, USA
  30. 30 Sección de Neuropediatría, Hospital Infantil Universitario Niño Jesús, Madrid, Spain
  31. 31 Department of Laboratory Medicine, McGill University Health Centre, Montreal, Quebec, Canada
  1. Correspondence to Dr Geneviève Bernard, Departments of Neurology and Neurosurgery, Pediatrics, and Human Genetics, McGill University & Department of Specialized Medicine, Division of Medical Genetics, McGill University Health Centre, Montreal, Canada; genevieve.bernard{at}mcgill.ca

Abstract

Background RNA polymerase III-related or 4H leukodystrophy (POLR3-HLD) is an autosomal recessive hypomyelinating leukodystrophy characterized by neurological dysfunction, hypodontia and hypogonadotropic hypogonadism. The disease is caused by biallelic pathogenic variants in POLR3A, POLR3B, POLR1C or POLR3K. Craniofacial abnormalities reminiscent of Treacher Collins syndrome have been originally described in patients with POLR3-HLD caused by biallelic pathogenic variants in POLR1C. To date, no published studies have appraised in detail the craniofacial features of patients with POLR3-HLD. In this work, the specific craniofacial characteristics of patients with POLR3-HLD associated with biallelic pathogenic variants in POLR3A, POLR3B and POLR1C are described.

Methods The craniofacial features of 31 patients with POLR3-HLD were evaluated, and potential genotype–phenotype associations were evaluated.

Results Various craniofacial abnormalities were recognized in this patient cohort, with each individual presenting at least one craniofacial abnormality. The most frequently identified features included a flat midface (61.3%), a smooth philtrum (58.0%) and a pointed chin (51.6%). In patients with POLR3B biallelic variants, a thin upper lip was frequent. Craniofacial anomalies involving the forehead were most commonly associated with biallelic variants in POLR3A and POLR3B while a higher proportion of patients with POLR1C biallelic variants demonstrated bitemporal narrowing.

Conclusion Through this study, we demonstrated that craniofacial abnormalities are common in patients with POLR3-HLD. This report describes in detail the dysmorphic features of POLR3-HLD associated with biallelic variants in POLR3A, POLR3B and POLR1C.

  • neurology
  • genetics
  • neurodegenerative diseases
  • genetics, medical
  • pediatrics

Data availability statement

All data relevant to the study are included in the article or uploaded as supplementary information.

https://creativecommons.org/licenses/by/4.0/

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WHAT IS ALREADY KNOWN ON THIS TOPIC

  • Craniofacial abnormalities in patients harbouring biallelic pathogenic variants in genes encoding different subunits of RNA polymerases including RNA polymerase III have been described only for a specific small subset of phenotypes, that is, Treacher Collins syndrome/POLR1C-related HLD and Wiedemann-Rautenstrauch syndrome. Despite this, description of craniofacial features in individuals with RNA polymerase III-related hypomyelinating leukodystrophy (POLR3-HLD) is currently very limited.

WHAT THIS STUDY ADDS

  • This is the first study to explore and assess the craniofacial features of a cohort of patients with POLR3-HLD. It is the only study proposing genotype–phenotype correlations based on facial features identified in patients with POLR3-HLD.

HOW THIS STUDY MIGHT AFFECT RESEARCH, PRACTICE OR POLICY

  • This study is the first to describe the specific phenotypic spectrum of craniofacial anomalies in POLR3-HLD. This detailed account will assist clinicians in diagnosing this condition and will therefore help to provide care directed to this patient population’s specific needs. It will also allow future studies characterizing the underlying pathophysiology of this condition. Indeed, the pathophysiological relationship between biallelic pathogenic variants in a housekeeping gene and specific organ involvement remains to this day unresolved. Characterizing the entire clinical spectrum of this condition will help guide future studies in understanding disease pathogenicity, opening the door for therapy development.

Introduction

Leukodystrophies are a group of rare heterogenous inherited disorders that affect the cerebral white matter and are typically associated with progressive neurodegeneration.1 Although individually rare, they collectively affect 1 in 4733 live births.2 The clinical manifestations of this group of disorders can appear at any time from infancy to adulthood and may include developmental delay and/or regression, cerebellar features, gait difficulties, pyramidal and extrapyramidal signs, seizures, cognitive and psychiatric manifestations.3

RNA polymerase III-related hypomyelinating leukodystrophy (POLR3-HLD; MIM: 607694, 614381, 616494), one of the most common hypomyelinating leukodystrophies, is an autosomal recessive disorder caused by biallelic pathogenic variants in POLR3A, POLR3B, POLR1C or POLR3K, each encoding subunits of RNA polymerase III.4–10 POLR3A and POLR3B encode the largest subunits that form the catalytic core of RNA polymerase III. POLR1C encodes a subunit of both RNA polymerase I and III while POLR3K encodes for a different subunit of RNA polymerase III.4–7 11 RNA polymerase III is a crucial enzyme responsible for the transcription of small RNAs including transfer RNAs, 5S ribosomal RNA and U6 small nuclear RNA. These are implicated in transcriptional activity regulation, RNA processing, ribosomal assembly and translation necessary for protein synthesis.12 13

POLR3-HLD is also known as 4H leukodystrophy in reference to the phenotypic constellation of hypomyelination in addition to hypodontia and hypogonadotropic hypogonadism.14–17 Onset of symptoms is typically in early childhood with evidence of motor dysfunction including predominant cerebellar signs in addition to cognitive impairment, abnormal dentition including hypodontia, oligodontia or delayed dentition, endocrinological abnormalities including short stature, delayed or absent puberty and ocular abnormalities, particularly progressive myopia. In addition to the classical hypomyelinating leukodystrophy pattern consisting of mild T2 hyperintensity and variable T1 signal of the white matter compared with grey matter structures, brain MRI typically reveals relative preservation of myelination (i.e., hypointense T2 signal) of specific structures including the dentate nuclei, anterolateral nuclei of the thalami, globi pallidi, pyramidal tracts in the posterior limbs of the internal capsules and optic radiations. In addition, cerebellar atrophy and thinning of the corpus callosum are commonly present.14 15 18 19

In recent years, the phenotypic spectrum of POLR3-related disorders has enlarged significantly, including severe neonatal and infantile presentations to late onset mild ones.20–32 Reports of craniofacial characteristics of individuals with POLR3-related disorders are scarce and include patients with biallelic pathogenic variants in POLR1C,14 a gene also associated with Treacher Collins syndrome (TCS), as well as patients with Wiedemann-Rautenstrauch syndrome (WRS) associated with biallelic pathogenic variants in POLR3A.21 However, to this day, there have been no studies specifically dedicated to exploring the craniofacial features in POLR3-HLD. Here, we further expand the phenotypic description of POLR3-HLD caused by biallelic variants in POLR3A, POLR3B and POLR1C by systematically assessing and characterizing the craniofacial features of 31 identified affected individuals.

Methods

Thirty-one individuals were included in this single-centre cross-sectional study. The participants were included based on the clinical and radiological features in keeping with a POLR3-HLD diagnosis in addition to biallelic pathogenic or likely pathogenic variants in POLR3A, POLR3B or POLR1C identified by gene panels, exome or genome sequencing using DNA extracted from whole blood according to standard protocols. Interpretation of sequence variants were done as per consensus recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology.31 Only pathogenic and likely pathogenic variants were considered as disease causing. Variants were described based on reference sequence GRCh37 (NM_007055.4 for POLR3A, NM_018082.6 for POLR3B and NM_203290.4 for POLR1C). Compliance with HGVS nomenclature has been verified using VariantValidator. In addition, participants were selected based on availability of photographs of adequate quality for craniofacial analysis. The individuals were recruited at the Montreal Children’s Hospital of the McGill University Health Center between 2012 and 2021.

Facial images including face front and/or profile views of each individual with POLR3-HLD were independently reviewed by two specialists in dysmorphology (SPG and IDB). Both observers were blinded to the genotype. The two physicians performing the dysmorphologic evaluations of patients reviewed and scored all provided pictures independently using ‘Elements of morphology: standard terminology for the head and face’ as a reference.33 All evaluations were subsequently revised jointly. There were no instances of significant discordance in scoring and description. Occasional omissions of scoring of some features was the only noted difference. This was resolved through the joint revision of features initially omitted.

Pearson χ2 was used to investigate the association between the presence of craniofacial features and the genotype, that is, POLR3A, POLR3B or POLR1C biallelic variants. Only features present in at least 10% of the patients (>3/31) were included for comparison. Identified craniofacial features were also grouped based on their location (forehead, eyes, philtrum, lip and chin). The individual carrying variants in POLR3A and POLR3B (subject 31) was excluded from the statistical analysis. Results were considered statistically significant when p values were less than 0.05 (two-sided). All statistical analyses were performed with the IBM SPSS Statistics 28 software (release 28.0.0).

Results

Among the 31 participants, there were 21 males (67.7%) and 10 females (32.3%). All thirty-one participants had a confirmed diagnosis of POLR3-HLD on the basis of their clinical and radiological features in addition to molecularly confirmed presence of likely pathogenic or pathogenic variants in POLR3A, POLR3B or POLR1C (table 1). Variants were present either in the compound heterozygous or homozygous state in each patient. Sixteen participants had biallelic variants in POLR3A (51.6%), ten in POLR3B (32.2%) and four in POLR1C (12.9%). One participant (subject 31) had a combination of a pathogenic and likely pathogenic variant in POLR3A in addition to a pathogenic and a deep intronic variant of unknown significance in POLR3B. In this participant, we believe that the POLR3A variants are disease causing, either solely or in combination with the POLR3B variants.

Table 1.

Description of the pathogenic or likely pathogenic variants identified in our subjects

All individuals presented at least one craniofacial abnormality (figure 1 and online supplemental file 1). Although some of these could be familial, a subset of craniofacial abnormalities was described in more than 50% of the individuals. In total, 16 craniofacial abnormalities were recognized in at least 10% of the individuals, including a high anterior hairline, high forehead, bitemporal narrowing, hypertelorism, telecanthus, long palpebral fissures, low-set ears, flat midface, pinched nose, bulbous tip of the nose, short and/or smooth philtrum, thin upper lip, full lower lip, short chin and pointed chin. Our analysis revealed that more than half of the subjects in our cohort have craniofacial abnormalities involving the eyes, the midface, the philtrum or the chin. A flat midface (61.3%; 19/31), smooth philtrum (58.0%; 18/31) and pointed chin (51.6%; 16/31) were the most common craniofacial features observed (figure 2). Moreover, 83.9% (26/31) of subjects had an anomaly of the philtrum with either a short and/or smooth philtrum. Seventy-one per cent (22/31) of patients had an anomaly of the chin consisting of a short and/or pointed chin. An anomaly of the eyes was seen in 51.6% (16/31) of subjects with hypertelorism, telecanthus and/or long palpebral fissures. Interestingly, subject 28, previously published,14 who has biallelic variants in POLR1C, whose photograph is shown in figure 1, displayed some craniofacial features typically observed in TCS including bitemporal narrowing, downslanting palpebral fissures and abnormalities of the external ears.

Supplemental material

Figure 1

Craniofacial characteristics in patients with POLR3-HLD by genotype. Selection of representative pictures of our patient cohort are shown. Anomaly of the lower face including a flat midface (subjects 5, 7, 9, 12, 20, 23, 27, 31), smooth philtrum (subjects 1, 9, 12, 21, 26, 27, 31) and pointed chin (subjects 1, 5, 11, 12, 21, 26, 27, 31) were among the most common craniofacial features in our cohort of patients. 1This patient also has a variant of unknown significance and a pathogenic variant in POLR3B.

Figure 2

Frequency of the craniofacial features described in our cohort of patients with POLR3-HLD.

As shown in table 2, comparisons of the craniofacial abnormalities based on underlying genotype revealed some distinctive features between the three groups of patients. More specifically, a statistically significant difference was identified between genotypes and the presence of a thin upper lip. Patients with biallelic variants in POLR3B were found to most frequently display a thin upper lip as opposed to patients with POLR3A and POLR1C biallelic variants (p=0.036). POLR3B patients were identified more frequently as presenting a thin upper lip compared with POLR3A patients (p=0.011). Craniofacial abnormalities involving the forehead characterized as a high anterior hairline and/or a high forehead were found to be most common in individuals with POLR3A (50.0%; 8/16) and POLR3B (60%; 6/10) pathogenic variants as opposed to POLR1C, with none of our four POLR1C patients being described as having an anomaly of the forehead. There was a statistically significant difference between the POLR3B and POLR1C groups with a p value of 0.040 when evaluating for the presence of an anomaly of the forehead. On the other hand, bitemporal narrowing was identified most commonly in patients with POLR1C variants (50.0%; 2/4) as opposed to patients with POLR3A variants (18.8%; 3/16). Bitemporal narrowing was absent in all our patients with POLR3B variants. When comparing the groups of patients with POLR3B and POLR1C variants, there was a statistically significant difference supporting that the presence of bitemporal narrowing is most commonly seen in POLR1C patients (p=0.016).

Table 2

Craniofacial features of POLR3-HLD patients according to genotype

Discussion

Our study illustrates the various craniofacial features present in patients with POLR3-HLD caused by biallelic variants in POLR3A, POLR3B and POLR1C. Anomalies of the lower face including a flat midface, smooth philtrum and pointed chin were among the most common craniofacial features in our cohort of patients. In addition, genotype–phenotype correlations enabled the identification of differences between the craniofacial features and underlying genotype of patients. Presence of a thin upper lip was most frequently associated with POLR3B biallelic variants while patients with POLR3A variants were most commonly found to have forehead abnormalities. In addition, bitemporal narrowing was associated with underlying POLR1C biallelic variants. The gene-specific dysmorphic features described in this study are additional clues that could help clinicians suspect POLR3-HLD in patients presenting with a hypomyelinating leukodystrophy.

Specific craniofacial characteristics have previously been associated with biallelic variants in various genes encoding four RNA polymerase III subunits. WRS is a neonatal progeroid disorder characterized by premature ageing and associated with intrauterine growth restriction, postnatal growth failure, short stature, lipodystrophy, hypotonia and intellectual disability.21 23 34 A previous study in 2018 identified specific combinations of biallelic POLR3A variants associated with WRS. It was hypothesized that the specific combinations of compound heterozygous variants in this gene correlate with the WRS disease phenotype.14 20 Individuals with WRS typically have a characteristic facial appearance with a triangular facies, sparse scalp hair, an enlarged fontanelle, prominent scalp veins, a pointed chin, a convex or pinched nose, low-set eyes, a small mouth and dental abnormalities reminiscent of what can be seen in patients with POLR3-HLD including presence of natal teeth or hypodontia.21 23 34 In 2021, report of pathogenic compound heterozygous variants in POLR3B in a patient with WRS led to further expansion of the genotypic spectrum of this condition.23 A prior study has also identified a nonsense variant in POLR3GL, a gene encoding another subunit of RNA polymerase III, as being associated with WRS.22

TCS is a disorder presenting with specific craniofacial features caused by defects of embryogenesis of the first and second brachial arches, most often transmitted as an autosomal dominant condition. TCS is characterized by downslanting palpebral fissures, facial bone hypoplasia, micrognathia and external ear anomalies including microtia in addition to conductive hearing loss.35–37 Some individuals with TCS may also have a cleft palate or choanal atresia.37 Although TCS is most frequently attributed to heterozygous pathogenic variants in TCOF1, rarer forms of this condition result from heterozygous pathogenic variant in POLR1B or POLR1D, or biallelic pathogenic variants in POLR1C or POLR1D.36 37 In 2019, Gauquelin and colleagues characterized, in a multicentre study, the clinical spectrum of 23 patients with POLR3-HLD caused by biallelic pathogenic variants in POLR1C. In their cohort of patients, one had craniofacial features compatible with TCS including downslanting palpebral fissures, strabismus, bitemporal narrowing, external ear anomaly, cleft palate and micrognathia corresponding to subject 28 in our cohort. Four patients had more subtle craniofacial anomalies with mild mandibular hypoplasia and one patient had laryngomalacia. Their results illustrated that POLR1C-related HLD can be associated with craniofacial features reminiscent of TCS.14 Prior in vitro functional studies have demonstrated that mutations in POLR1C associated with POLR3-HLD prevent assembly and targeting of RNA polymerase III to the nucleus but not RNA polymerase I. In contrast, a TCS-causing mutation, p.Arg279Gln, was shown not to affect assembly of either polymerases but rather impaired targeting of RNA polymerase I to the nucleolus.6 This study was the first illustrating the concept that mutations in POLR1C coding for a subunit common to RNA polymerase I and RNA polymerase III can lead to different effects on these two protein complexes and therefore result in different or combined phenotypes. This work provided a potential pathophysiologic mechanism underlying the phenotypic heterogeneity seen with mutations in this gene.6 However, in a later cohort of patients described by Gauquelin and colleagues in 2019, two participants were carrying the pathogenic variant p.Arg279Gln previously associated with TCS, yet none showed abnormal craniofacial development suggesting that the underlying pathophysiological mechanism is likely even more complex and raising the question of implications of genetic modifiers influencing the pathophysiology of POLR1C-related disorders.14

Development of craniofacial structures is a complex process occurring in an orderly fashion throughout embryonic and fetal stages. Craniofacial growth occurs due to a relatively rapid and orderly composition of mesodermal and cranial neural crest cells involved in the first and second branchial arch formation.38 Interestingly, generation of insufficient neural crest cells is a known mechanism leading to general craniofacial anomalies described in TCOF1, POLR1C and POLR1D-related TCS.39 40 Indeed, haploinsufficiency of Tcof1 in mice and Polr1c or Polr1d in zebrafish results in deficient ribosome biogenesis, which is incapable of meeting the proliferative needs of the neuroepithelium and leads to a high degree of neuroepithelial apoptosis.40 41 Interestingly, the craniofacial features described here for individuals with biallelic pathogenic or likely pathogenic variants in POLR3A and POLR3B could also be potentially explained by perturbation of the neural crest cells. We hypothesize that the decrease in POLR3A or POLR3B impairs RNA polymerase III biogenesis leading to dysregulation of the expression of certain RNA polymerase III targets and thereby perturbating cytoplasmic protein synthesis essential for neural crest cell development.4 42 This reduced RNA and protein production may alter the proliferation of neuroepithelium and similarly lead to neuroepithelial apoptosis as seen in Tcof1-haploinsufficient cells in mice or Polr1c/Polr1d-haploinsufficient cells in zebrafish. However, further studies are required to confirm this hypothesis.

As illustrated with this study, craniofacial abnormalities are common among individuals with POLR3-HLD. In this cohort of patients with pathogenic or likely pathogenic biallelic variants in POLR3A, POLR3B and POLR1C, each patient presented at least one craniofacial abnormality. This work further expands the phenotypic spectrum of POLR3-HLD. We present a novel group of craniofacial features associated with POLR3-HLD from what has been previously described in the literature, with the exception of the TCS craniofacial features previously described in a study by Gauquelin and colleagues.14 One limitation of this study is that the description of dysmorphic features was limited by the number of pictures available for some patients. Another limitation is the small sample size. Nevertheless, sample size is quite large considering that POLR3-HLD is a rare condition. Moreover, parental pictures were not available to determine if some of the facial features could be familial in nature. However, the independent analysis of pictures by two physicians experienced in dysmorphology clearly established the presence of craniofacial abnormalities mainly affecting the lower face associated with pathogenic variants in genes encoding RNA polymerase III subunits.

In conclusion, with this addition to the detailed characterization of the disease phenotype, we hope for early recognition and diagnosis of individuals with POLR3-HLD, an important task for clinicians in an era where clinical trial development and advancement in gene therapy for rare neurodegenerative disorders has been booming. Detailed phenotyping of the condition also allows for further genotype–phenotype correlations and contribute to the advancement in understanding the pathophysiology underlying POLR3-HLD.

Data availability statement

All data relevant to the study are included in the article or uploaded as supplementary information.

Ethics statements

Patient consent for publication

Ethics approval

This study involves human participants and was approved by Montreal Children’s Hospital and McGill University Health Center Research Ethics Boards (11-105-PED, 2019-4972). Informed consent for the research study was obtained from patients and/or caregivers in addition to consent for publication of photographs.

Acknowledgments

The authors thank all patients for their generous cooperation with this research. The authors also thank the McGill University and Genome Quebec Innovation Centre.

References

Supplementary materials

  • Supplementary Data

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Footnotes

  • AM and S-PG contributed equally.

  • IDB and GB contributed equally.

  • Contributors AM, S-PG, IDB and GB contributed to study conception and design, acquisition, analysis and interpretation of data, drafting and critically revising the manuscript. All of the other authors contributed to acquisition, analysis and interpretation of data, drafting and critically revising the manuscript. Guarantor: GB.

  • Funding This study was funded by grants from the Canadian Institutes of Health Research (377869, 426534), Montreal Children’s Hospital Foundation and Leuco-Action. This research was enabled in part by support provided by Compute Canada (www.computecanada.ca). GB has received the Clinical Research Scholar Junior one award from the Fonds de Recherche du Quebec – Santé (FRQS) (2012–2016), the New Investigator Salary Award from the CIHR (2017–2022) and the Clinical Research Scholar Senior award from the FRQS (2022–2025). ER is supported by a FRQS Clinical Research Scholar Senior award and is the recipient of a Canadian Research Chair CRC-II on the Neurobiology of epilepsy. We would like to thank the families for participating in our study. This work was made possible by the generous gifts to Children’s Mercy Research Institute and Genomic Answers for Kids programme at Children’s Mercy Kansas City

  • Competing interests LTT currently manages sponsored clinical trials at the site level for Ionis Pharmaceuticals (Alexander disease clinical trial 2021–present), Passage Bio (Krabbe disease and GM1 gangliosidosis clinical trials, 2021–present) and Teva Pharmaceuticals (chronic and episodic migraine clinical trials, 2022–present). He also manages a GM1 gangliosidosis natural history study sponsored by the University of Pennsylvania with funding from Passage Bio. NIW is advisor and/or co-investigator for trials in Metachromatic Leukodystrophy (Shire/Takeda, Orchard, Evidera) and other leukodystrophies (Ionis, PassageBio, Vigil Neuro, Sana Biotech), without personal payment. AV receives research grants or in-kind research support without any personal compensation from Takeda, Passage Bio, Sanofi, Affynia, Orchard Therapeutics, Eli Lilly, ISD therapeutics, Illumina, Myrtelle, Homology, Sana and Ionis. She is a site investigator for the Ionis clinical trial in Alexander’s disease, SHP611 in Metachromatic leukodystrophy of Shire/Takeda and Passage Bio gene therapy in Krabbe. She serves on the scientific advisory board of the ELA foundation, the ULF Foundation and the Yaya Foundation Scientific and Clinical Advisory Council. She is a member of the Vanishing White Matter Consortium, the H-ABC Clinical Advisory Board. She receives grant funding from this RDCRN NCATS/NINDS (U01 NS106845, U54TR002823 and R21 NS123477. GB is/was a consultant for Passage Bio Inc (2020–2022) and Ionis (2019). She is/was a site investigator for the Alexander’s disease trial of Ionis (2021–present), Metachromatic leukodystrophy of Shire/Takeda (2020–2021), Krabbe and GM1 gene therapy trials of Passage Bio (2021–present), GM1 natural history study sponsored by the University of Pennsylvania with funding from Passage Bio (2021–present) and Adrenoleukodystrophy/Hematopoietic stem cell transplantation natural history study of Bluebird Bio (2019), a site sub-investigator for the MPS II gene therapy trial of Regenxbio (2021–present) and the MPS II clinical trial of Denali (2022–present). She has received an unrestricted educational grant from Takeda (2021–2022). She serves on the scientific advisory board of the Pelizaeus-Merzbacher Foundation, the Yaya Foundation Scientific and Clinical Advisory Council and is the Chair of the Medical and Scientific Advisory Board of the United Leukodystrophy Foundation. She is a member of the Vanishing White Matter Consortium, the H-ABC Clinical Advisory Board and the Chair of the POLR3-related (4H) Leukodystrophy Consortium. She is on the editorial boards of Neurology Genetics, Frontiers in Neurology – Neurogenetics and Journal of Medical Genetics.

  • Provenance and peer review Not commissioned; externally peer reviewed.

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