The TWNK gene encodes Twinkle, the mitochondrial DNA helicase that cooperates with the mitochondrial DNA polymerase (POLG) to maintain mitochondrial DNA integrity. Heterozygous TWNK mutations cause autosomal dominant progressive external ophthalmoplegia (PEO). Some patients with TWNK-linked PEO additionally develop late-onset neurodegenerative parkinsonism.1 However, little is known about the neuropathology of TWNK-linked parkinsonism. In this study, we describe neuropathologic findings in a patient with PEO and parkinsonism and a heterozygous TWNK mutation.
The proband, a 76-year-old Flemish woman, presented with a 1-year history of gait difficulties and reduced facial expression. She reported no tremor, diplopia, autonomic symptoms, cognitive complaints, hallucinations, or nightmares. She had undergone bilateral corrective upper eyelid surgery because of ptosis at the age of 66 years and again at the age of 73 years. Clinical examination showed limitation of eye movements in all directions, which could not be overcome by oculocephalic maneuvers. Pupillary responses were normal. Speech was hypophonic, and there was mild hypomimia. Finger tapping showed mild decrement on the right side. There was mild rigidity in the right arm. She had no tremor. Gait was slow with reduced stride length and reduced right arm swing. Posture was stooped. Postural reflexes were normal. The Mini-Mental State Examination (MMSE) score was 29/30. Proprioception was reduced in the distal legs. Muscle strength, tendon reflexes, plantar reflexes, and coordination were normal. There was no muscle atrophy.
According to the patient, her mother, maternal aunt, and 2 of her 5 siblings also had bilateral ptosis (eFigure 1A, links.lww.com/NXG/A447). An MRI examination of the brain showed mild atrophy and white matter lesions, presumably due to small vessel disease (eFigure 1B), without disproportionate midbrain atrophy. The 123I‐FP‐CIT SPECT revealed severely reduced putaminal binding bilaterally (eFigure 1C). EMG showed mild myopathic changes in proximal muscles. TWNK sequencing showed a heterozygous c.1120C>T (p.R374W) mutation, previously reported as pathogenic.2 There were no mutations in POLG.
Levodopa had a favorable effect. Disease progression was slow. She developed freezing of gait but no dyskinesias or dementia. The MMSE score at the age of 82 years was still 27/30. She died of pyelonephritis with sepsis at the age of 84 years.
Brain autopsy revealed obvious neuron loss in the substantia nigra, dentate nucleus, and cerebellar Purkinje cell layer (Figure 1A and B, eFigure 2, links.lww.com/NXG/A447) and a tauopathy with predominantly four-repeat tau lesions (Figure 1C–K, eFigures 2 and 3). These lesions included threads, neuronal lesions in the form of neurofibrillary tangles (NFTs), pretangles, and single ballooned neurons, and astroglial lesions with features of tufted astrocytes and subpial and perivascular thorn-shaped astrocytes. A few three-repeat tau-positive threads and NFTs were also observed (Figure 1I). The tau lesions were found in all brain regions investigated except the occipital cortex (eTable 1) and were positive for pS202/pT205-tau, pT231-tau, pS396/pS404-tau, and, to a smaller extent, acetylated ac-K274-tau and tau with the MC1 configuration previously proposed to be Alzheimer disease (AD)–specific (Figure 1D–K, eTable 2). Most severe tau pathology was found in the substantia nigra and other midbrain nuclei, whereas the putamen and globus pallidus were only mildly affected (eTable 1, eFigures 2 and 3). In the pons, tau lesions were also positive for ubiquitin and phosphoubiquitin (eFigure 4). TDP43 was seen in a few inclusions in subiculum/CA1. Neuritic plaques or α-synuclein pathology were not observed. Alzheimer-related pathology (Braak NFT stage II and Thal amyloid phase 4) was prevalent. There was moderate cerebral amyloid angiopathy of the noncapillary type, moderate atherosclerosis of the circle of Willis, and severe small vessel disease. The psoas muscle showed mild neurogenic changes without obvious signs of a mitochondriopathy.
(A) Reduced pigmentation of the substantia nigra (arrows). (B) Loss of melanin-containing neurons in the substantia nigra and detection of extraneuronal melanin (arrows), indicative of degeneration of melanin-containing neurons. (C) Schematic distribution of tau pathology in the brain. Yellow indicates areas with mild tauopathy manifestation, orange indicates those with moderate, and red indicates those with severe tau pathology. (D-G) Examples of different types of tau lesions, as demonstrated with an antibody against pSer202/pT205-tau: pretangles (arrow in D), astrocytic tau lesions best fitting with the criteria for astrocytic plaques (arrowhead in D), tufted astrocytes (E), ballooned neurons (F), and coiled bodies in the reticular part of the medial longitudinal fascicle (G). (H–K) Molecular pattern of tau pathology (see also eTable 2, links.lww.com/NXG/A447): 4-repeat tau was observed in the astrocytic plaque-like lesions (H), whereas 3-repeat tau was observed only in neurofibrillary tangles (I). Neurofibrillary tangles and threads also exhibited the MC1-conformational epitope (J) and acetylated acK274-tau (K).
After the neuropathologic finding of a tauopathy, genetic analysis of MAPT, GRN, C90RF72, LRRK2, VPS35, PRKN, PINK1, and PARK7 was performed, but no mutations were found.
The absence of Lewy pathology confirmed that the patient's parkinsonism did not represent coincidental idiopathic Parkinson disease (PD) but was likely caused by the TWNK mutation. Brain autopsy findings have previously been reported in only 3 heterozygous TWNK mutation carriers. Two of these 3 cases did not have parkinsonism but, nevertheless, showed loss of substantia nigra dopaminergic neurons, albeit without Lewy or tau pathology.3 A very recent report described a TWNK mutation carrier with PEO and parkinsonism who had dopaminergic cell loss with Lewy pathology and no tau deposition,1 in contrast with our case. Taken together, these cases suggest that heterozygous TWNK mutations can cause dopaminergic cell death with either Lewy pathology or tau pathology or with neither of these. Similar pathologic heterogeneity has been observed in PD patients with LRRK2 mutations.4
The presence of mitochondrial dysfunction in this patient was supported by detection of phosphoubiquitin, a marker of PINK1-mediated mitophagy activation.5 Tau pathology was previously also observed in a patient with a mutation in the gene for the mitochondrial metalloprotease paraplegin (SPG7).6 We cannot exclude the possibility that the unusual pattern of tau pathology and neuron loss in our case was unrelated to the TWNK mutation and resulted from coincidental parallel presence of multiple tauopathies such as progressive supranuclear palsy (PSP), AD, and age-related tau astrogliopathy. However, the tau pathology pattern was not typical of PSP because of the only mild involvement of globus pallidus and putamen7 and the multiple phenotypes of tau-exhibiting astrocytes. Future work will need to elucidate the role of mitochondrial failure in the etiology of tauopathies.
Study Funding
Research Foundation-Flanders (FWO): G0F8516N and G065721N.
Disclosure
D.R. Thal received consultant honorary from GE Healthcare (UK) and Covance Laboratories (UK), speaker honorary from Novartis Pharma AG (Switzerland), and travel reimbursement from GE Healthcare (UK) and UCB (Belgium) and collaborated with Novartis Pharma AG (Switzerland), Probiodrug (Germany), GE Health care (UK), and Janssen Pharmaceutical Companies (Belgium). The other authors report no disclosures. Go to Neurology.org/NG for full disclosures.
Acknowledgment
The authors thank Dr. Guy Wilms (University Hospitals Leuven) for performing MRI, Dr. Valérie Race (University Hospitals Leuven) for genetic analysis, Dr. Peter Davies (Albert Einstein College of Medicine, New York, USA) for the gift of the PHF1 and MC1 antibodies, and the J. David Gladstone Institutes (San Francisco, USA) for the gift of the acK274-tau antibody (MAB359).
Acknowledgment
The authors thank Dr. Guy Wilms (University Hospitals Leuven) for performing MRI, Dr. Valérie Race (University Hospitals Leuven) for genetic analysis, Dr. Peter Davies (Albert Einstein College of Medicine, New York, USA) for the gift of the PHF1 and MC1 antibodies, and the J. David Gladstone Institutes (San Francisco, USA) for the gift of the acK274-tau antibody (MAB359).
Appendix Authors
Footnotes
The Article Processing Charge is funded by the authors.
Go to Neurology.org/NG for full disclosures. Funding information is provided at the end of the article.
- Received March 5, 2021.
- Accepted in final form June 30, 2021.
- Copyright © 2021 The Author(s). Published by Wolters Kluwer Health, Inc. on behalf of the American Academy of Neurology.
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