Heterozygous variants in DCC: Beyond congenital mirror movements

Sebastian Thams; Mominul Islam; Marie Lindefeldt; Ann Nordgren; Tobias Granberg; Bianca Tesi; Gisela Barbany; Daniel Nilsson; Martin Paucar

doi:10.1212/NXG.0000000000000526

. 2020 Oct 20;6(6):e526. doi: 10.1212/NXG.0000000000000526

Heterozygous variants in DCC

Beyond congenital mirror movements

Sebastian Thams ¹, Mominul Islam ¹, Marie Lindefeldt ¹, Ann Nordgren ¹, Tobias Granberg ¹, Bianca Tesi ¹, Gisela Barbany ¹, Daniel Nilsson ¹, Martin Paucar ^1,^✉

PMCID: PMC7670573 PMID: 33209984

Abstract

Objective

To perform a comprehensive characterization of a cohort of patients with congenital mirror movements (CMMs) in Sweden.

Methods

Clinical examination with the Woods and Teuber scale for mirror movements (MMs), neuroimaging, navigated transcranial magnetic stimulation (nTMS), and massive parallel sequencing (MPS) were applied.

Results

The cohort is ethnically diverse and includes a total of 7 patients distributed in 2 families and 2 sporadic cases. The degree of MMs was variable in this cohort. MPS revealed 2 novel heterozygous frameshift variants in DCC netrin 1 receptor (DCC). Two siblings harboring the pathogenic variant in c.1466_1476del display a complex syndrome featuring MMs and in 1 case receptive-expressive language disorder, chorea, epilepsy, and agenesis of the corpus callosum. The second DCC variant, c.1729delG, was associated with a typical benign CMM phenotype. No variants in DCC, NTN1, RAD51, or DNAL4 were found for the 2 sporadic CMM cases. However, one of these sporadic cases had concomitant high-risk myelodysplastic syndrome and a homozygous variant in ERCC excision repair like 2 (ERCC6L2). Reorganized corticospinal projection patterns to upper extremities were demonstrated with nTMS.

Conclusions

The presence of chorea expands the clinical spectrum of syndromes associated with variants in DCC. Biallelic pathogenic variants in ERCC6L2 cause bone marrow failure, but a potential association with CMM remains to be studied in larger cohorts.

Congenital mirror movements (CMMs) constitute a group of nonprogressive movement disorders with aberrant mirroring in contralateral extremities on intentional movements. CMMs manifest in childhood with predominant involvement of the upper extremities, persist throughout life, and are typically observed in the absence of other neurologic symptoms. Pathogenic variants in DDC netrin 1 receptor (DCC), RAD51, and netrin-1 (NTN1) are associated with CMM.^1–3 Only 1 consanguineous large CMM family harboring a homozygous variant in dynein axonemal light chain 4 (DNAL4) has been reported so far⁴; some CMM cases/families lack detectable mutations.¹ Mutations in DCC are associated with a spectrum of neurologic syndromes resulting from disrupted commissural connections in the brain and spinal cord.³ DCC encodes a netrin-1 receptor involved in developmental axon guidance across the midline,^5,6 which is the likely cause of abnormal ipsilateral cortical projections. The netrin-1 receptor consists of 4 extracellular immunoglobulin-like (Ig1-4), 6 fibronectin 3-like (FN1-6) domains, a transmembrane domain, and 3 intracellular domains (P1-3). Heterozygous pathogenic variants in DCC are associated with isolated mirror movements (MMs), agenesis of the corpus callosum (ACC), abnormal development of nociceptive topognosis, and reorganized projections of the corticospinal tracts (CST), either as isolated phenomena or in combination.^7,8 Biallelic DCC mutations cause the severe developmental split-brain syndrome.⁹

Here, we present a cohort of 7 patients with CMM, of which 5 were found to carry heterozygous truncating variants in DCC. One of these variants was associated with ACC, chorea, epilepsy, and expressive aphasia, suggesting that pathogenic variants in DCC may cause a broader spectrum of phenotypes than previously known. One sporadic CMM case with concomitant myelodysplastic syndrome (MDS) harbors a homozygous variant in ERCC excision repair like 2 (ERCC6L2).

Methods

This study was approved by the Regional Ethical Board in Stockholm. Patients or legal guardians gave oral and written consent to the study. MMs were evaluated with the Woods and Teuber scale (range 0–4),¹⁰ beside standard neuroimaging, genetic analyses, and neurophysiologic studies. In addition, brain MRI, tractography, and volumetric brain assessment were performed in 4 patients (I:1 and II:1 in family 1 and sporadic cases 6 and 7) and in age- and sex-matched healthy controls (HCs) (supplemental material, links.lww.com/NXG/A331). Whole-exome sequencing (WES) was performed on the index case in family 1. Whole-genome sequencing (WGS) was applied for the index case of family 2 and patients 6 and 7. In both families, segregation was performed after a candidate variant was confirmed with Sanger sequencing. Variants in the candidate genes reported in association with CMM—DCC, NTN1, RAD51, and DNAL4—were sought. Navigated transcranial magnetic stimulation (nTMS) was applied in patient I:1 from family 1 and patient 6 to assess reorganization of corticomotor projection patterns (for method description, see appendix e-1, links.lww.com/NXG/A331).

Results

Clinical features and neuroimaging

Briefly, all patients presented with variable degree of childhood-onset MM. Clinical features, neuroimaging, and nTMS findings are summarized in the table. MMs were pronounced in patient 6 (video 1) and mild in family 2 (video 2). Pedigrees of both families 1 and 2 are shown in figure e-1, links.lww.com/NXG/A329.

Table.

Summary of patients with congenital mirror movements (CMM)

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Video 1

This is patient 6 in our cohort. Segment 1: examination at age 21 years demonstrates pronounced mirror movements in the arms. To a lesser degree, these movements also affected his feet. Segment 2: reorganized corticospinal tracts affecting hands only are revealed with nTMS.Download Supplementary Video 1^{(9.9MB, mp4)} via http://dx.doi.org/10.1212/000526_Video_1

Video 2

This child is the index case in family 2. His recent examination demonstrates variable degree of mirror movements but also chorea.Download Supplementary Video 2^{(5MB, mp4)} via http://dx.doi.org/10.1212/000526_Video_2

Family 1

The index case (patient II:1) is a 9-year-old girl whose MMs were noticed during an examination for developmental mile stones. At age 9 years, these MMs became spontaneously less pronounced. Her father (I:1) and younger sister (II:2) also displayed MMs.

Family 2

The index case (patient II:2) is a 7-year-old boy with involuntary movements investigated at age 3 years for delayed speech and language development. His brother (patient II:1) also has MMs and dyslexia but no language impairment. Brain MRI for patient II:1 was normal (figure 1); his guardian declined cognitive assessment. At age 6 years, patient II:2 presented with seizures, and brain CT revealed complete ACC, but no evidence of cortical abnormalities (figure 1). Of note, the anterior, posterior, and hippocampal commissures were present. EEG demonstrated focal motor seizures originating in the left hemisphere with bilateral spreading during sleep, responsive to treatment with valproic acid. A speech-language assessment concluded that he had receptive-expressive language disorder (International Classification of Diseases, Tenth Revision: F80.2). Reading and writing skills were reportedly delayed, but no formal dyslexia assessment had been performed due to the young age. The cognitive assessment with Wechsler Intelligence Scale for Children Fifth Edition (WISC-V) revealed that full-scale IQ was 79–91, verbal IQ was significantly lower than performance IQ, and impaired processing speed and executive functions. Examination at age 7 years demonstrated mild chorea and MMs; no other motor abnormalities were found.

(A–C) Brain MRI of patient II:1 at age 9 years showing normal anatomy, including the corpus callosum. A small cavum septum pellucidum is noted as a normal variant. From left to right: 3D T1-weighted axial, coronal, and sagittal 1-mm isotropic slices. (D–F) Nonenhanced brain CT of patient II:2 at age 6 years showing agenesis of the corpus callosum, giving rise to a racing car sign. From left to right: axial, coronal, and sagittal 3-mm thick slices centered at the posterior commissure. CMM = congenital mirror movement.

Patients 6 and 7 are apparent sporadic cases. Of interest, patient 6 developed pancytopenia at age 21 years; further investigations with bone marrow aspiration revealed MDS and the presence of 1 pathogenic somatic TP53 variant in about 20% of bone marrow cells. Taken together, this high-risk MDS motivated stem cell transplantation and a targeted analysis of ERCC6L2.

Neuroimaging and nTMS

Volumetric analyses in patient I:1 in family 1 and patients 6 and 7 did not reveal any differences compared with HCs. Volumetric assessment in patient II:1 from family 1 was not possible to perform due to movement artifacts. Reorganized corticospinal projection patterns to upper extremities were demonstrated on nTMS (figure 2, supplemental material, links.lww.com/NXG/A331).

Motor evoked potentials (MEP) after MRI navigated TMS in the hand area in the left hemisphere (A). Motor responses were elicited from both right (contralateral) (EMG Ch1. APB dx, Ch2. ADM dx, Ch3. IOD1 dx) and left (ipsilateral) sides (EMG channel Ch4. APB sin, Ch5. ADM sin, Ch6. IOD1 sin). Stimulation in left leg motor area (C) elicited motor responses only in the contralateral side (D) (EMG Ch1. AH dx, Ch2. TA dx). APB = Abductor pollicis brevis, ADM = Abductor digiti minimi, IOD1 = 1st dorsal interossei, AH = Abductor Hallucis, TA = Tibialis anterior.

Genetics

WES revealed the novel variant c.1729delG p.Glu577Argfs*12 in DCC (NM_005215.3, exon 11) in the index case of family 1, which segregates with disease (table and figure e-2, links.lww.com/NXG/A330). WGS detected the novel variant c.1466_1476del p.Val489Glufs*15 in DCC (NM_005215.3, exon 9) in the index case of family 2. This variant is also present in his older brother but absent in their mother; the father was not available for genetic testing. Both variants are located in exons encoding the fibronectin type III-like (FN3) domains 2 and 1, respectively. This region of the protein interacts with netrin-1 that specifically binds to the 4–6th FN3 domains,³ and these domains are more frequently associated with ACC.

In patient 6, a homozygous 10-kb large deletion with intronic breakpoints around exon 11 (coordinates hg19: chr9:98690859-98700947) was identified in ERCC6L2. Mutations in ERCC6L2 are associated with autosomal recessive bone marrow failure and susceptibility to acute myeloid leukemia.¹¹ No candidate variants in DCC, RAD51, NTN1, or DNAL4 were found for patients 6 and 7.

Discussion

To date, 31 DCC mutations have been described, but clear-cut genotype-phenotype correlations are not possible to establish at the moment.^3,12 Herein, we provide data on 2 novel truncating variants in DCC associated with isolated MMs and in 1 case with ACC, chorea, epilepsy, and receptive-expressive language disorder. The presence of chorea in association with the variant c.1466_1476del expands the clinical spectrum of CMM. Normal corpus callosum morphometry in a sibling with MMs and dyslexia harboring the same variant illustrates a striking intrafamilial variability. Epilepsy associated with DCC mutations has been described in 1 patient in a report by Marsh et al.,³ but seizures ceased at age 2 years. The contralateral spread of focal epileptic activity observed in our patient with ACC is intriguing because the corpus callosum constitutes the major pathway for bilateral synchrony,¹³ suggesting propagation through noncanonical routes. Notably, a previous study reports that ACC associated with truncating DCC variants was frequently observed in 2 families of Northern African origin, with a clear preference for females.⁷ ACC in association with DCC mutations entails a better prognosis than without variants in this gene, illustrating the importance of etiologic diagnosis for the prognosis of complex syndromes.³ The occurrence of aggressive MDS in association with a homozygous variant in ERCC6L2 in a young patient with CMM is striking. ERCC6L2 has been thought to have role in DNA-damage response.¹¹ However, any possible association between CMM and the reported homozygous variant in ERCC6L2 may be just coincidental. Of interest, RAD51 encodes a protein involved in repair of DNA double-strand breaks. Heterozygous variants in RAD51 have been associated with a very rare form of Fanconi anemia.¹⁴ Our findings are in keeping with the variable intrafamilial expressivity for variants in DCC, but still the factors modulating this variability remain to be determined.³ WGS did not identify any other variants in the 3 other CMM genes or syndromic forms of MMs in 2 sporadic cases, reflecting genotypic heterogeneity and the need for refined sequencing tools. We used MRI-navigated TMS to perform focal cortical stimulation of hand motor cortex, but even when stimulating with higher certainty it is still difficult to approach the legs' homunculus.¹⁵ Our findings describe reorganized CST to upper extremities, while typical contralateral pathways to the lower extremities, are in accordance with previous studies.¹⁶

Acknowledgment

The authors are grateful to the patients and healthy volunteers who participated in the study and to speech therapist Fritjof Norrelgen.

Glossary

ACC: agenesis of the corpus callosum
CMM: congenital mirror movement
CST: corticospinal tract
HC: healthy control
MDS: myelodysplastic syndrome
MM: mirror movement
MPS: massive parallel sequencing
nTMS: navigated transcranial magnetic stimulation
WES: whole-exome sequencing
WGS: whole-genome sequencing

Appendix. Authors

Appendix.

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Study funding

M. Paucar obtained funding from Region Stockholm and from the Follin Foundation.

Disclosure

The authors report no disclosures. Go to Neurology.org/NG for full disclosure.

References

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9.Jamuar SS, Schmitz-Abe K, D'Gama AM, et al. Biallelic mutations in human DCC cause developmental split-brain syndrome. Nat Genet 2017;49:606–612. [DOI] [PMC free article] [PubMed] [Google Scholar]
10.Woods BT, Teuber HL. Mirror movements after childhood hemiparesis. Neurology 1978;28:1152–1157. [DOI] [PubMed] [Google Scholar]
11.Tummala H, Kirwan M, Walne AJ, et al. ERCC6L2 mutations link a distinct bone‐marrow failure‐syndrome to DNA repair and mitochondrial function. Am J Hum Genet 2014;94:246–256. [DOI] [PMC free article] [PubMed] [Google Scholar]
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13.Pustina D, Doucet G, Skidmore C, Sperling M, Tracy J. Contralateral interictal spikes are related to tapetum damage in left temporal lobe epilepsy. Epilepsia 2014;55:1406–1414. [DOI] [PMC free article] [PubMed] [Google Scholar]
14.Takenaka S, Kuroda Y, Ohta S, et al. A Japanese patient with RAD51-associated Fanconi anemia. Am J Med Genet A 2019;179:900–902. [DOI] [PubMed] [Google Scholar]
15.Kesar TM, Stinear JW, Wolf SL. The use of transcranial magnetic stimulation to evaluate cortical excitability of lower limb musculature: challenges and opportunities. Restor Neurol Neurosci 2018;36:333–348. [DOI] [PMC free article] [PubMed] [Google Scholar]
16.Kim ED, Kim GW, Won YH, Ko MH, Seo JH, Park SH. Ten-Year follow-up of transcranial magnetic stimulation study in a patient with congenital mirror movements: a case report. Ann Rehabil Med 2019;43:524–529. [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Video 1

Video 2

[R1] 1.Franz EA, Chiaroni-Clarke R, Woodrow S, et al. Congenital mirror movements: phenotypes associated with DCC and RAD51 mutations. J Neurol Sci 2015;351:140–145. [DOI] [PubMed] [Google Scholar]

[R2] 2.Méneret A, Franz EA, Trouillard O, et al. Mutations in the netrin-1 gene cause congenital mirror movements. J Clin Invest 2017;127:3923–3936. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R3] 3.Marsh APL, Edwards TJ, Galea C et al. DCC mutation update: congenital mirror movements, isolated agenesis of the corpus callosum, and developmental split brain syndrome. Hum Mutat 2018;39:23–39. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R4] 4.Ahmed I, Mittal K, Sheikh TI, et al. Identification of a homozygous splice site mutation in the dynein axonemal light chain 4 gene on 22q13.1 in a large consanguineous family from Pakistan with congenital mirror movement disorder. Hum Genet 2014;133:1419–1429. [DOI] [PubMed] [Google Scholar]

[R5] 5.Srour M, Rivière JB, Pham JM, et al. Mutations in DCC cause congenital mirror movements. Science 2010;328:592. [DOI] [PubMed] [Google Scholar]

[R6] 6.Kennedy TE, Serafini T, de la Torre JR, Tessier-Lavigne M. Netrins are diffusible chemotropic factors for commissural axons in the embryonic spinal cord. Cell 1994;78:425–435. [DOI] [PubMed] [Google Scholar]

[R7] 7.Marsh AP, Heron D, Edwards TJ, et al. Mutations in DCC cause isolated agenesis of the corpus callosum with incomplete penetrance. Nat Genet 2017;49:511–514. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R8] 8.da Silva RV, Johannssen HC, Wyss MT, et al. DCC is required for the development of nociceptive topognosis in mice and humans. Cell Rep 2018;22:1105–1114. [DOI] [PubMed] [Google Scholar]

[R9] 9.Jamuar SS, Schmitz-Abe K, D'Gama AM, et al. Biallelic mutations in human DCC cause developmental split-brain syndrome. Nat Genet 2017;49:606–612. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R10] 10.Woods BT, Teuber HL. Mirror movements after childhood hemiparesis. Neurology 1978;28:1152–1157. [DOI] [PubMed] [Google Scholar]

[R11] 11.Tummala H, Kirwan M, Walne AJ, et al. ERCC6L2 mutations link a distinct bone‐marrow failure‐syndrome to DNA repair and mitochondrial function. Am J Hum Genet 2014;94:246–256. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R12] 12.Bierhals T, Korenke GC, Baethmann M, Marín LL, Staudt M, Kutsche K. Novel DCC variants in congenital mirror movements and evaluation of disease-associated missense variants. Eur J Med Genet 2018;61:329–334. [DOI] [PubMed] [Google Scholar]

[R13] 13.Pustina D, Doucet G, Skidmore C, Sperling M, Tracy J. Contralateral interictal spikes are related to tapetum damage in left temporal lobe epilepsy. Epilepsia 2014;55:1406–1414. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R14] 14.Takenaka S, Kuroda Y, Ohta S, et al. A Japanese patient with RAD51-associated Fanconi anemia. Am J Med Genet A 2019;179:900–902. [DOI] [PubMed] [Google Scholar]

[R15] 15.Kesar TM, Stinear JW, Wolf SL. The use of transcranial magnetic stimulation to evaluate cortical excitability of lower limb musculature: challenges and opportunities. Restor Neurol Neurosci 2018;36:333–348. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R16] 16.Kim ED, Kim GW, Won YH, Ko MH, Seo JH, Park SH. Ten-Year follow-up of transcranial magnetic stimulation study in a patient with congenital mirror movements: a case report. Ann Rehabil Med 2019;43:524–529. [DOI] [PMC free article] [PubMed] [Google Scholar]

PERMALINK

Heterozygous variants in DCC

Sebastian Thams, MD, PhD

Mominul Islam, MD, PhD

Marie Lindefeldt, MD, PhD

Ann Nordgren, MD, PhD

Tobias Granberg, MD, PhD

Bianca Tesi, MD, PhD

Gisela Barbany, MD, PhD

Daniel Nilsson, PhD

Martin Paucar, MD, PhD