Adult-onset leukoencephalopathy with neuroaxonal spheroids and pigmented glia
Adult-onset leukoencephalopathy with spheroids and pigmented glia (ALSP) is a genetic disease characterized by progressive cognitive, movement and neuropsychiatric disorders, bilateral periventricular white matter hyperintensity in fluid attenuated inversion recovery (FLAIR) and diffuse weighted imaging (DWI) sequences, and axonal spheroids and pigmented microglia by brain biopsy. Heterozygous variants in CSF1R (colony stimulating factor 1 receptor) were firstly associated with ALSP (CSF1R-ALSP) [1]. Later, variants in AARS2 (encoding alanyl-transfer tRNA synthetase 2) were found pathogenic for autosomal recessive ALSP patients (AARS2-ALSP) [2]. However, there is still a group of patients negative for mutations in both genes. Here, we report an autosomal-recessive ALSP family associated with AARS1 mutation.
The patient from a consanguineous family suffered from difficulties in walking since age 23. At age 25, he was wheelchair-dependent with progressive dysarthria, blurred vision and cognitive decline. Physical examination showed marasmus (1.73 m height, 40 kg weight, body mass index 13.36), hypertonia, hyperreflexia and decreased muscle strength. Scores for Mini-mental State Examination and Montreal Cognitive Assessment were 12/30 and 3/30, respectively. Neurophysiological examinations revealed axonal impairment in the left superficial peroneal sensory nerve and motor fibers, and myelin damage in distal motor fibers of upper limbs. His uncorrected best vision was 4.0 and FC/20 cm; best corrected vision in the right eye was 4.2 and no improvement in the left eye through − 6.0D correction binocularly. Wide-angle fundus photography showed slender vessels in both eyes. Optical coherence tomography showed decreased thickness above the retinal nerve fiber layer in the left eye and the outer nuclear layer of the left retina (Additional file 1: Fig. S1). No abnormality was revealed by electroencephalogram. Blood tests indicated hypoalbuminemia (26 g/l). His parents and younger brother had no neurological symptoms, as confirmed by electromyogram and magnetic resonance imaging (MRI).
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Similar to patients with CSF1R-ALSP and AARS2-ALSP from our ALSP cohort, brain MRI of the patient revealed predominant symmetric hyperintensity of periventricular white matter and the corpus callosum in FLAIR (Fig. 1c-1) and DWI (Fig. 1d-1) sequences. Cortical atrophy was marked in T1 sequence (Fig. 1a-1, b-1). The subcortical U-fibers, cerebellum and midbrain were spared. CT scan (Fig. 1e-1) revealed symmetric patchy calcifications in the basal ganglia. [18F]FDG-PET/CT (Fig. 1f-1) showed diffusive hypometabolism, especially in the temporal and occipital lobes. [18F]DPA714-PET/CT illustrated symmetric bindings in the thalamus and the midbrain (Fig. 1g-1), indicating extensive neuroinflammation [3].
Fig. 1
Radiological, pathological and genetic characteristics of AARS1-AR-ALSP, CSF1R-ALSP and AARS2-ALSP. a–g Sagittal and transverse view of neuroimaging. h–n Immunohistochemistry of brain biopsy. *, swollen neurons; red triangles, axonal spheroids; #, PAS-, CD68- or p62-positive microglia. o–p Genetic features of the family. q Predicted protein structures of wild-type, p.Thr606Ile- and p.Cys152Phe-mutant AlaRS predicted by i-TASSER. Blue: aminoacylation domain; grey: tRNA recognition domain; light orange: editing domain; orange: C-terminal. r Diagram of AARS1 structure with reported mutations. Purple, DEE29-related variants; red, AARS1-AR-ALSP; black, CMT2N; green, AARS1-AD-ALSP
Biopsy showed mild loss of neurofilaments (Fig. 1h-1, i-1), swollen neurons (Fig. 1h-1), and sporadic spheroids (Fig. 1i-1). Myelin loss was prominent based on MBP staining (Fig. 1j-1). PAS-, CD68- and p62-positive microglia accumulated in the lesions (Fig. 1k-1, l-1, m-1). Electron microscopy (Fig. 1n-1) confirmed the loss of myelinated nerve fibers and existence of spheroids.
Based on these features, the proband was diagnosed as ALSP. However, trio analysis did not find any mutations related to CSF1R or AARS2, but revealed a homozygous nonsynonymous variant AARS1:NM_001605:exon14:c.1817C > T:p.Thr606Ile, as confirmed by Sanger sequencing. His parents and brother carried the same heterozygous variant (Fig. 1o, p). This variant was not found in 1000G Project, dbSNP, ESP6500 or gnomAD database, but predicted damaging by SIFT, PolyPhen-2 and MutationTaster. As the patient’s symptoms were highly consistent with previous cases of late-onset AARS1-related leukoencephalopathy [4], this variant was rated as “likely pathogenic” according to the American College of Medical Genetics and Genomics Standard. In silico prediction also revealed structural differences caused by the mutation (Fig. 1q).
AARS1 gene encodes alanyl-tRNA synthetase (AlaRS), which catalyzes the aminoacylation of tRNAAla with alanine and diacylation of the incorrectly charged Ser-tRNAAla [5]. In aminoacylation and misaminoacylation assays, the AlaRS T606I variant showed deficient aminoacylation efficiency (Additional file 1: Fig. S2a) and higher mischarging rates (Additional file 1: Fig. S2b), supporting pathogenicity of this mutation.
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ALSP was previously associated with CSF1R [1] and AARS2 [2] mutations, and one heterozygous variant in AARS1 has been reported responsible for an ALSP family [6]. In this study, we associated a recessive AARS1 variant with ALSP (AARS1-AR-ALSP).
ALSP patients associated with different genes have different characteristics (Additional file 1: Table S1). In summary, recessive subtypes have an earlier onset and are usually accompanied by ophthalmologic dysfunction and cerebellum or brainstem atrophy. Calcifications were only reported in CSF1R-ALSP and AARS1-AR-ALSP. AARS1-AR-ALSP patients are also featured with posterior-predominant leukoencephalopathy, relatively mild pathological changes and neuroinflammation level, and hypoalbuminemia likely related to marasmus and malnutrition.
AARS1 is also related to autosomal-dominant Charcot-Marie-Tooth disease type 2N (CMT2N) [7] and autosomal-recessive developmental and epileptic encephalopathy-29 (DEE29) [8]. Phenotype-genotype features are as follows (Fig. 1r; Additional file 1: Table S2).
(1) CMT2N-related variants are mostly located in tRNA recognition and aminoacylation domains, affecting aminoacylation activity [9], typified by the hotspot mutation c.986G > A/p.Arg329His.
(2) Variants of DEE29 are mostly located in the editing domain and the C-terminal, or cause truncated protein [8]. Patients with only one variant meeting the criteria have milder phenotype [10]. c.2251A > G/p.Arg751Gly and c.2738G > A/p.Gly913Asp [4] are the hotspot mutations.
(3) Variants of AARS1-AR-ALSP affect the editing domain, but none is located in the C-terminal or causes truncated protein.
Human AlaRS has higher mischarging activity compared to other aminoacyl-tRNA synthetases, explaining the importance of the editing domain [5]. The phenotypic differences also illustrated the potential critical role of the C-terminal domain [5], though its specific role remains unclear.
Acknowledgements
We would like to acknowledge Dr. Xiaolong Zhou and Dr. Zihan Li from University of Chinese Academy of Sciences for assistance with aminoacylation and misaminoacylation kinetics assays.
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Declarations
Ethics approval and consent to participate
Written informed consent was obtained by the legal guardian of the patient. This study was endorsed by Ethics Committee of Shanghai Jiao Tong University Affiliated Sixth People’s Hospital (2021-219) and registered at http://www.chictr.org.cn (No. ChiCTR2100050834).
Consent for publication
This manuscript did not contain any identifiable personal data.
Competing interests
The authors declare they have no competing interests.
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