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INTRODUCTION
Adult‐onset leukoencephalopathies are a rare group of neurological diseases disorders characterized by progressive degeneration of cerebral white matter (Euro et al., ). They are associated with a variety of clinical phenotypes dominated by dementia, psychiatric changes, movement disorders, and upper motor neuron signs (Lakshmanan et al., ). The differential diagnosis of adult‐onset leukoencephalopathies is often challenging due to the high heterogeneity of etiologies (Lakshmanan et al., ). With advances in the genetic testing, several causative gene mutations have been shown to be responsible for the etiology of adult‐onset leukoencephalopathies (Lynch et al., ; Renaud, ). Of these gene mutations, mitochondrial alanyl‐tRNA synthetase 2 gene (AARS2, OMIM:612035) is a nuclear gene, accounting for AARS2 loading of alanine onto tRNA during mitochondrial translation. AARS2 mutations can result in two very different phenotypes with different tissue involvement: some mutations particularly affect the heart (Calvo et al., ; Gotz et al., ), thus producing a fatal, early‐onset cardiomyopathy, whereas others are associated with late‐onset leukoencephalopathy without cardiac involvement, and ovarian failure also been described in female.
Leukoencephalopathy due to AARS2 mutations is a syndrome with progressive cerebral white matter degeneration (Kaye & Moser, ). Since first identified in 2014, only 19 AARS2‐related leukoencephalopathy cases have been reported in English literature until now (Dallabona et al., ; Dong et al., ; Hamatani et al., ; Lee et al., ; Peragallo, Keller, van der Knaap, Soares, & Shankar, ; Szpisjak et al., ; Taglia et al., ). Owing to the low number of known cases, most clinicians have limited knowledge about the clinical presentation and neuroimaging features of AARS2‐related leukoencephalopathy. In addition, there are many different kinds of leukoencephalopathies, which makes a definitive diagnosis difficult.
Here, we report the first description of typical ragged red fiber (RRF) identified by muscle biopsy in a male patient with AARS2‐related leukoencephalopathy, suggesting that AARS2‐related leukoencephalopathy be a new variant of mitochondrial encephalomyopathy. We summarized the main findings of our case and all previously reported 19 cases to provide an overview of the genetic, clinical, and neuroimaging characteristics of AARS2‐related late‐onset leukoencephalopathy. Then, we compared clinical and neuroimaging features of AARS2‐related leukoencephalopathy with three other frequently diagnosed types of adult‐onset leukoencephalopathy to provide insight into diagnostic strategies.
CASE REPORT
A 30‐year‐old Chinese man was admitted with complaints of progressive motor deficits in the right lower limb for 1 year and dysarthria for 2 months. The patient's motor symptoms had developed 1 year earlier, along with an unsteady gait. Subsequently, he had gradually developed weakness and numbness of the right limbs, rigidity and aphasia, with occasional dysphagia and dysarthria. The patient had a 6‐year history of drug abuse and had taken methamphetamine on ten occasions in the previous 6 months. His symptoms were considered to be encephalopathia toxica in a local hospital and were treated with 500 mg of methylprednisolone per day followed by 30 mg prednisone per day. No improvement was observed. There was no family history of cerebellar symptoms.
Neurological examination revealed normal mental status and normal cranial nerve functions. The strength of the right lower limb was 4/5 with brisk tendon reflexes, bilateral ankle clonus, and bilateral Rossolimo and Chaddock signs. The patient also showed spastic gait and positive Romberg's sign, with slight decrease in pinprick sensation in the lower extremities. The patient was unable to perform the finger‐nose tests and rapid alternating movements.
Laboratory evaluation showed normal routine studies. Examination of the cerebrospinal fluid revealed 507.7 mg/dl protein (normal range 15–45 mg/dl) and normal IgG index. Autoimmune, infectious, endocrinologic, neoplastic, and paraneoplastic screenings were unremarkable. However, serum levels of alanine aminotransferase and lactic acid (instant state, resting state, 1 min, and 10 min) were all increased. Brain magnetic resonance imaging (MRI) showed abnormal signals in the bilateral periventricular white matter, the posterior part of the corpus callosum and symmetrically along the corticospinal tract without gadolinium enhancement. In addition, a thin posterior corpus callosum, enlarged lateral ventricle, and widened bilateral parietal sulcus were demonstrated. The diffusion‐weighted image (DWI) shows patchy areas of restricted diffusion in the abnormal white matter, confirmed by low signal of the corresponding areas on the apparent diffusion coefficient (ADC) map. The restricted diffusion areas exist for more than 1 year. PET‐MRI showed hypometabolism in the posterior part of the cerebral white matter (Figure a). A typical RRF was identified in muscle biopsy for the first time (Figure a).
Enlarge this image.Brain MRI scans of patients with various types of leukoencephalopathy. (a) Brain MRI of P20 (the presented case) with AARS2‐related leukoencephalopathy. T1‐weighted, T2‐weighted, axial scans show symmetrical and extended white matter abnormalities at bilateral periventricular areas and corpus callosum involvement mainly in the posterior part. Fluid‐attenuated inversion recovery (FLAIR)‐weighted, axial scans present symmetrical, longitudinal, striped, and intense signals present on both sides of the corticothalamic level. The diffusion‐weighted image (DWI) and apparent diffusion coefficient (ADC) image show patchy areas of restricted diffusion in the abnormal white matter. PET MRI of the patient shows that decreased metabolism is pronounced in the white matter lesions. (b) T2‐weighted, axial scans of Patient 3 at age 33 years (left) demonstrates pronounced leukoencephalopathy at bilateral periventricular areas. Axial T2‐weighted MRI of Patient 4 at age 24 years (middle) shows that abnormal signals are found in the frontal and parietal lobe white matter and the pyramidal tract at the internal capsule. FLAIR MRI image of Patient 7 at age 30 (right) shows that the affected white matter is rarefied. (c) In a patient with ALSP (left), axial T2‐weighted MRI shows confluent slightly asymmetric frontoparietal‐predominant white matter hyperintensity, with more atrophy compared with AARS2 leukoencephalopathy. In a patient with X‐ALD (middle), axial postgadolinium contrast sequences show diffuse white matter signal T2‐weighted hyperintensity and volume loss of the posterior frontal, posterior callosal and parieto‐occipital regions. In a patient with MLD (right), an axial T2‐weighted sequence demonstrates widespread symmetrical white matter signal hyperintensity sparing the subcortical U fibers and radiating transmedullary bands
Enlarge this image.Muscle biopsy and genetic analysis of our patient. (a) Morphologic analysis of muscle biopsy, with succinate dehydrogenase (SDH) staining, hematoxylin‐eosin staining (HE) and Gomori trichrome (GT) staining. A typical RRF was indicated by arrow. (b) Sequencing of AARS2 in the presented case shows both mutations c.179C>A and c.1703_1704del
Targeted gene sequencing of AARS2 identified two variations: c.179C>A and c.1703_1704del (Figure b). These two mutations have not been previously described, and they were not found in the ExAC database (
The treatment was generally supportive. After the application of intravenous coenzyme complex 200 U one time per day for 10 days, the patient showed gradual improvement in motor function. He could walk 1,000 m alone and remained stable on six‐month follow‐up. However, the patient showed rapidly deterioration of cerebellar ataxia and motor deficits in 1 year.
LITERATURE REVIEW
To date, AARS2 mutations have been reported in 19 patients with late‐onset leukoencephalopathy. To provide an overview of the clinical characteristics of AARS2‐related late‐onset leukoencephalopathy, we searched the MEDLINE database to October 2018 using the terms “AARS2” or “alanyl‐tRNA synthetase 2 gene” and reviewed all identified articles and articles referenced therein, including non‐English articles (Dallabona et al., ; Dong et al., ; Hamatani et al., ; Lee et al., ; Peragallo et al., ; Szpisjak et al., ; Taglia et al., ). We identified 19 previous cases and combined them with the current case to provide a summary of the genetic, clinical, and neuroimaging features of AARS2‐related leukoencephalopathy.
Clinical features
The detailed clinical features of the case presented here and the previously reported patients (9 males and 11 females) are summarized in Table . The patients had adult‐onset signs of neurologic deterioration with an average age of onset of 27.3 years. All 20 patients exhibited rapid deterioration after onset. Psychiatric symptoms, such as changes in personality, delusions, anxiety and depression, usually preceded neurological symptoms. The neurological dysfunctions are composed of motor deterioration, including cerebellar ataxia and pyramidal signs, and progressive cognitive decline with features of frontal lobe dysfunction, such as poor attention, inactivity, and other neurological changes. Among these symptoms, cognitive decline was the most frequent (18 patients [90%]). Pyramidal signs (15 patients [75%]) and cerebellar ataxia (13 patients [65%]) were also prominent clinical features. Psychiatric dysfunction, such as anxiety and depression (11 patients [55%]), was often observed. All women with the condition had primary or secondary amenorrhea related to ovarian failure. General physical examination usually revealed no abnormalities and no evidence of cardiac dysfunction.
Clinical and genetic characteristics of patients with AARS2‐mutations reported in literature| Case number | Sex | Age at onset (years) | First neurological symptoms | Cerebellar symptoms | Cognitive impairment | Psychiatric symptoms | Pyramidal signs | Ovarian failure | AARS2 mutation | Amino acid change | Reference |
| P1 | Female | 15 | Gait ataxia, cognitive decline, tremor | + | + | + | − | + | c.149T>G; c.1561C>T | p.Phe50Cys; p.Arg521a | 8 |
| P2 | Male | 7 | Ataxia | + | + | − | + | Male | c.2893G>A; c.1213G>A | p.Gly965Arg; p.Glu405Lys | 8 |
| P3 | Female | 33 | Cognitive decline and depression | + | + | + | + | + | c.1609C>T & c.2350del; c.595C>T | p.Gln537 & p.Glu784Serfs*9; p.Arg199Cys | 8 |
| P4 | Female | 15 | Tremor | + | + | + | + | c.230C>T; c.595C>T | p.Ala77Val; p.Arg199Cys | 8 | |
| P5 | Female | 40 | Cognitive decline and depression | − | + | + | − | + | c.595C>T; c.390_392del | p.Arg199Cys; p.Phe131del | 8 |
| P6 | Female | 22 | Spastic paraparesis and depression | + | − | + | + | + | c.595C>T; c.2611dup | p.Arg199Cys; p.Thr871Asnfs*21 | 8 |
| P7 | Female | 30 | Cognitive decline and psychosis | − | + | + | + | + | c.1145C>A; c.2255 + 1G> A* | p.Thr382Lys | 9 |
| P8 | Male | 27 | Psychosis | + | + | + | + | Male | c.578T>G; c.595C>T | p.Leu193a; p.Arg199Cys | 10 |
| P9 | Female | 40 | Anxiety and cognitive decline | − | + | − | + | + | c.1041‐1G>A*; c.595C>T | p. Arg199Cys | 11 |
| P10 | Male | Late 30s | Cognitive decline | − | + | − | − | Male | c.1188G>A*; c.1709delG | p. Gly570Afs*21 | 11 |
| P11 | Male | Mid 20s | Rapid motor decline | + | + | + | + | Male | c.1188G>A*; c.1709delG | p. Gly570Afs*21 | 11 |
| P12 | Male | 15 | Cognitive decline and psychosis | + | + | + | + | Male | c.892_894del; c.2234_2235 del | p.298_298delGln; p.Ser745Cysfs*60 | 11 |
| P13 | Male | Mid 40s | Right upper limb dystonia | − | + | + | + | Male | c.595C>T (homozygous) | p. Arg199Cys | 11 |
| P14 | Male | 17 | Tremor | + | + | + | + | + | c.2265dupA; c.650C>T | p.Arg756 fs; p.Pro217Leu | 13 |
| P15 | Female | 44 | Gait ataxia and cognitive decline | + | + | − | + | + | c.595C>T; c.390_392del | p.Arg199Cys; p.Phe131del | 14 |
| P16 | Female | 32 | Cognitive decline | − | + | − | − | + | c.595C>T; c.236T>A | p.Arg199Cys; p.Met79Lys | 14 |
| P17 | Female | 23 | Ataxia and spastic gait | + | − | − | + | + | c.595C>T; c.2611_2612 insA | p.Arg199Cys; p.Thr871Asnfs | 14 |
| P18 | Female | 33 | Ovarian failure and cognitive decline | − | + | − | + | + | c.963C>A; c.452T>C | Tyr321*; p.Met151Thr | 12 |
| P19 | Male | 35 | Dystonia | + | + | − | + | Male | c.963C>A; c.452T>C | Tyr321*; p.Met151Thr | 12 |
| P20 | Male | 29 | Axatia | + | + | − | + | Male | c.179C>A; c.1703_1704del | p.Arg199Cys; p.Val730Met | Presented case |
Genetic analysis
Genetic analysis revealed that in all 20 cases the mutations followed autosomal recessive inheritance. Nineteen patients were compound heterozygotes for AARS2 mutations and only one male patient was homozygous. The pathogenic gene mutations were derived from the paternal and maternal side. All nucleotide and amino acid changes are summarized in Table . Among these nucleotide changes, c.595C>T was the most common (nine patients). The most prominent amino acid changes were p.Arg199Cys. P20 (the present case) carried two new heterogeneous missense mutations, c.179C>A and c.1703_1704del.
Neuroimaging features
The MRI abnormalities of the 20 patients are summarized in Table . All patients exhibited T2‐W hyperintense, T1‐W hypointense white matter signal abnormalities. Typically, the abnormalities were predominantly present in the frontal and parietal periventricular and deep white matter, sparing a segment of white matter in between. White matter structures were affected in a tract‐like manner, with involvement of interhemispheric connections through the corpus callosum and descending pathways. The cases with involvement of the corpus callosum may show either a single lesion in the splenium or the entire corpus callosum in an inhomogeneous manner. Among the other patients, the lesion involved the entire corpus callosum in an inhomogeneous manner. The abnormalities were confined to white matter structures and were progressive over time. No gadolinium enhancement was observed. Cerebellar atrophy was variable, and cerebral atrophy, if present, was mild.
Clinical examinations of patients with AARS2‐mutations| Case number | MRI abnormalities | Cardiac ultrasound | ECG | Muscle biopsy | Plasma lactate level | Sex hormone levels | ||||
| White Matter Rarefaction | Corticospinal Tracts | Corpus Callosum | Atrophy | U‐fibers | ||||||
| P1 | + | + | + | + | − | Normal | Normal | Isolated COX deficiency | Normal | Low estradiol, FSH & LH↑ |
| P2 | + | + | + | − | − | n.i. | Normal | n.i. | Normal | n.i. |
| P3 | + | + | + | − | + | n.i. | Normal | n.i. | Normal | Low estradiol, FSH & LH↑ |
| P4 | + | + | − | − | − | n.i. | n.i. | n.i. | Normal | FSH & LH↑ |
| P5 | + | + | − | − | − | n.i. | n.i. | n.i. | n.i. | FSH, LH and prolactin↑ |
| P6 | + | + | − | − | − | n.i. | Normal | Isolated COX deficiency | n.i. | low estradiol, normal FSH &LH |
| P7 | + | + | + | + | + | Normal | Normal | Normal | n.i. | Normal |
| P8 | − | + | − | − | − | Normal | Normal | n.i. | n.i. | Normal |
| P9 | − | + | + | + | − | n.i. | n.i. | n.i. | Increased | Low estradiol, FSH & LH↑ |
| P10 | + | + | + | − | − | Normal | Normal | n.i. | Normal | Normal |
| P11 | + | + | + | − | − | Normal | Normal | n.i. | Normal | Normal |
| P12 | − | + | + | + | − | Normal | Normal | n.i. | Normal | Normal |
| P13 | + | + | + | − | − | Normal | Normal | n.i. | Normal | Normal |
| P14 | + | + | + | + | − | Normal | Normal | n.i. | Normal | Normal |
| P15 | + | + | + | − | + | n.i. | Normal | n.i. | n.i. | n.i. |
| P16 | + | + | − | + | − | n.i. | n.i. | n.i. | n.i. | n.i. |
| P17 | + | + | − | − | − | n.i. | n.i. | n.i. | n.i. | n.i. |
| P18 | + | + | + | − | − | Normal | n.i. | n.i. | n.i. | n.i. |
| P19 | + | + | + | − | − | Normal | n.i. | n.i. | n.i. | n.i. |
| P20 | + | + | + | + | + | Normal | Normal | Typical RRF | Increased | Normal |
Muscle biopsy and cardiac function analysis
Morphologic analysis of muscle biopsy and cardiac function analysis of the patients with AARS2 mutations are summarized in Table . Cardiac ultrasonography and electrocardiogram revealed no evidence of cardiac dysfunction. Patients P1, P6, P7, and P20 (the presented case) underwent skeletal muscle biopsy to further investigate possible mitochondrial defects. Patients P1 and P6 showed isolated cytochrome c oxidase deficiency. Our group identified a typical RRF in the patient with AARS2‐related leukoencephalopathy for the first time.
Laboratory findings
The laboratory findings, including the results of routine hematology and biochemistry tests, were normal among all 20 patients (Table ). None of the patients had elevated CSF lactate levels; however, patients P9 showed increased plasma levels of lactate. Most women with ovarian failure showed low estradiol levels and high levels of follicle‐stimulating hormone (FSH) and luteotropic hormone (LH).
DISCUSSION
Herein, we present the case of a 30‐year‐old man with progressive motor deficits in the right lower limb and severe cerebellar ataxia for 1 year. MRI revealed extensive white matter lesions in bilateral periventricular regions and the posterior part of corpus callosum and along the corticospinal tract. Genetic analysis revealed two new heterogeneous missense mutations in AARS2: c.179C>A and c.1703_1704del. The serum lactic acid level was elevated. It is noteworthy that this is the first reported case of AARS2‐related leukoencephalopathy with a typical RRF identified by muscle biopsy.
As AARS2‐related encephalopathy is a newly reported encephalopathy, clinicians have scant knowledge about the clinical presentation and neuroimaging features. By reviewing all published cases, the following findings are strongly indicative of AARS2‐related leukoencephalopathy: late‐onset and rapidly progressing encephalopathy; cerebellar ataxia and cognitive decline; white matter signal abnormalities in periventricular regions, posterior part of the corpus callosum and symmetrically along the corticospinal tract. In the presence of these symptoms, the diagnosis should be confirmed by genetic analysis.
Adult onset leukoencephalopathy is a category of neurological disorders with high heterogeneity. It is always difficult to make definite diagnosis, even for experienced neurologists. Therefore, we compared AARS2‐related leukoencephalopathy with three other types of common adult‐onset leukoencephalopathies to provide insight into diagnostic strategies, including leukoencephalopathy with axonal spheroids and pigmented glia (ALSP) (Lynch et al., ), X‐linked adrenoleukodystrophy (X‐ALD) (Mirabella, Di Giovanni, Silvestri, Tonali, & Servidei, ), and metachromatic leukodystrophy (MLD) (Taylor et al., ) (Table ). ALSP is the most common adult‐onset leukoencephalopathy caused by autosomal dominant mutations in the colony‐stimulating factor receptor 1 (CSF1R) gene. Mutations in the CSF1R gene occur in the tyrosine kinase domain of the CSF1R, which is primarily expressed in the microglia in the CNS, and result in microglial dysfunction in ALSP. X‐ALD is caused by mutations in the ABCD1 gene encoding the adrenoleukodystrophy protein (ALDP). X‐ALD is an X‐linked disorder that results from a deficient very‐long‐chain fatty acid transport protein on the surface of the peroxisome. The adult‐onset form accounts for 5% of all X‐ALD patients. Metachromatic leukodystrophy (MLD) is an autosomal recessive lysosomal disorder owing to ARSA gene mutations resulting in deficiency of the enzyme arylsulfatase A (ASA). The adult form accounts for approximately 20% of all MLD cases. ALSP has a relatively late onset, typically occurring in the fifth decade, as opposed to AARS2, for which the disease onset tends to occur in the third decade of life. Men and women with adult‐onset X‐ALD may remain asymptomatic into the fourth and sixth decade of life, respectively. The age of MLD's onset can be up to 70 years. The course after deterioration onset of ALSP and AARS2 is rapid; however, disease progression of X‐ALD and MLD is generally slower, with death occurring after decades. Cognitive and motor symptoms are the most common symptoms overall in all four leukoencephalopathies. Patients with ALSP and AARS2 typically present with cognitive impairment and gait problems first, then develop spasticity and ataxia. Adult‐onset cerebral ALD usually presents with psychiatric features followed by cognitive impairment, ataxia, movement disorders, and peripheral neuropathy. Adrenal insufficiency is also frequently associated with the condition. The initial symptoms of MLD are often psychiatric and are followed by motor symptoms, including spastic paraparesis and cerebellar ataxia, then intellectual and cognitive decline. MLD patients often experience other symptoms late in life, including optic nerve atrophy and peripheral neuropathy. All female patients with AARS2 mutation presented with ovarioleukodystrophy and ovarian failure, a feature not seen in other leukoencephalopathies.
Clinical features of patients with AARS2‐mutations and other common types adult‐onset leukoencephalopathies| Disorder | Age of onset | Prevalence | Inheritance | Affected gene(s) | Cognitive involvement | Movement disorder | Pyramidal weakness/spasticity | Cerebellar ataxia | Peripheral neuropathy | Psychiatric symptoms | Visual involvement | Primary/secondary amenorrhea | Adrenal insufficiency | Hyper‐pigmentation |
| AARS2‐L | Mean 20 years | 20 reported cases | AR | AARS2 | + | + | + | + | − | + | − | + | − | − |
| ALSP | Mean 40 years | 52 reported cases | AD | CSFR1 | + | + | + | + | − | − | − | − | − | − |
| X‐ALD | Childhood to adulthood | Up to 40/million, 5% adult onset | X linked | ABCD1 | − | + | + | − | − | + | − | − | + | + |
| MLD | Up to 70 years | 2/million, 20% adult onset | AR | ARSA | + | + | + | + | + | + | + | − | − | − |
Brain MRI of all these leukoencephalopathies show confluent patterns of white matter lesions (van der Knaap, Breiter, Naidu, Hart, & Valk, ; Schiffmann & van der Knaap, ) (Table ). However, the predominant pattern is different. In AARS2‐related leukoencephalopathy and ALSP, white matter changes are typically seen in the frontal and parietal periventricular region, whereas white matter abnormalities are usually seen in occipital regions in X‐ALD and frontal regions in MLD. Corpus callosum involvement is present in all diseases. Cerebral and cerebellar atrophy are prominent in ALSP and MLD and are disproportionately mild in AARS2. Spinal cord atrophy may develop in X‐ALD. The distribution of white matter lesions is symmetric in AARS2 and MLD and asymmetric in ALD and ALSP. Each leukoencephalopathy has a unique pattern of MRI‐abnormalities. ALSP occasionally shows calcifications in the frontal periventricular white matter. In cerebral ALD, contrast enhancement at the periphery of the white matter lesions is characteristic. The subcortical U‐fibers are typically spared in MLD. AARS2‐related leukoencephalopathy is associated with white matter rarefaction, which suppresses on a FLAIR image, a feature not seen in other leukoencephalopathies.
Neuroimaging features of AARS2‐related leukoencephalopathy and three other common adult‐onset leukodystrophies| Disorder | Pattern of white matter involvement | Findings in the corpus callosum | Atrophy | Symmetry | Unique MRI features |
| AARS2‐L | Predominantly frontoparietal periventricular | Atrophy in the posterior part | Mild cerebral and cerebellar atrophy | Symmetric | White matter rarefaction |
| ALSP | Predominantly frontoparietal periventricular | Thinning | Prominent cerebral atrophy | Asymmetric | Calcifications |
| X‐ALD | Predominantly parieto‐occipital | Atrophy in the splenium | Spinal cord atrophy | Asymmetric | Contrast enhancement |
| MLD | Predominantly frontal periventricular | Thinning | Cerebral atrophy | Symmetric | Spared U fibers |
The pathogenesis of AARS2‐related encephalopathy is not clear yet. Here, for the first time we reported a typical RRF identified by muscle biopsy in a patient with AARS2‐related leukoencephalopathy, which suggests that AARS2‐related leukoencephalopathy might be a new variant of mitochondrial encephalomyopathy. Mitochondrial encephalomyopathy is a heterogeneous group of disorders with various biochemical defects in the respiratory chain (McFarland, Taylor, & Turnbull, ; Shoubridge, ). Mutation of AARS2, which is also a kind of mtARS mutation (Diodato, Ghezzi, & Tiranti, ), may affect mitochondrial protein synthesis and functioning of the respiratory chain, and thus might cause a disorder of energy metabolism. Mitochondrial encephalomyopathy can lead to a wide range of nervous system and muscle disorders (Moulinier, Ripp, Castillo, Poch, & Sissler, ). The diagnostic workup routinely includes skeletal muscle biopsies and genetic studies (Bernier et al., ; Bourgeois & Tarnopolsky, ). Isolated cytochrome c oxidase (COX) deficiency and typical RRF could be shown in the skeletal muscle biopsy of mitochondrial encephalomyopathy (Holt, Harding, & Morgan‐Hughes, ; Shy, ). COX is a multimeric inner mitochondrial membrane enzyme formed by subunits encoded by nuclear or mitochondrial genomes. The RRF is the histological hallmark of abnormal mitochondria proliferation in muscle fibers. Identification of any RRF in an individual aged <30 years is indicative of mitochondrial disease and can be regarded as a diagnostic indicator of myopathy. All of these findings strongly suggest that AARS2‐related leukoencephalopathy is a new variant of mitochondrial encephalomyopathy.
Genetic analysis demonstrated that the mutations in all 20 cases followed autosomal recessive inheritance, and 19 patients were compound heterozygotes for AARS2 mutations. To date, AARS2 mutations have been reported among patients with infantile mitochondrial hypertrophic cardiomyopathy with early fatal outcomes, and patients with late‐onset leukoencephalopathy. Therefore, the question arises as to why AARS2 mutations cause two very different subtypes with distinct systemic involvement. Euro et al. (Euro et al., ) have provided an elegant explanation for this phenomenon. In addition to the aminoacylation domain and the C‐terminal domain (Guo et al., ), AARS2 also has an editing domain that can deacylate mischarged amino acids. None of the missense mutations identified in patients with adult‐onset leukoencephalopathy were in the editing domain, whereas at least one c.1774C>T mutation in the editing domain was present in patients with infantile‐onset cardiomyopathy (Scheper et al., ). The difference in the location of AARS2 missense mutations leads to different aminoacylation activity, such that cardiomyopathy results from a severe decrease in aminoacylation activity, and leukoencephalopathy results from only a moderate decrease. The location of the mutations in P20 (the present case) is consistent with this hypothesis.
CONCLUSIONS
In conclusion, we report an AARS2‐related leukoencephalopathy case with typical RRF for the first time. On the basis of reviewing all known cases, the following findings are strongly indicative of AARS2‐related leukoencephalopathy: late‐onset and rapidly progressing encephalopathy; progressive cognitive decline; cerebellar ataxia; white matter signal abnormalities in the frontal and parietal periventricular regions, posterior part of the corpus callosum and symmetrically along the corticospinal tract; and amenorrhea secondary to ovarian failure among affected women. In the presence of these symptoms, the diagnosis should be confirmed by genetic analysis. Finally, on the basis of the combination of encephalopathy, increased plasma lactate level, isolated cytochrome c oxidase deficiency and typical RRF in muscle biopsy, we propose that AARS2‐related leukoencephalopathy is a new variant of mitochondrial encephalomyopathy. Currently, there are no treatment options for AARS2 leukoencephalopathy. The good response to intravenous coenzyme complex in our patient will shed light on future treatment development.
ACKNOWLEDGMENTS
The authors have declared that no conflicts of interest exist. All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards.
CONFLICT OF INTEREST
None declared.
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; Xing, Yi 1 ; Guo, Dongmei 1 ; Li, Di 1 ; Jia, Jianping 2 1 Innovation Center for Neurological Disorders, Department of Neurology, Xuan Wu Hospital, Capital Medical University, Beijing, China
2 Innovation Center for Neurological Disorders, Department of Neurology, Xuan Wu Hospital, Capital Medical University, Beijing, China; Center of Alzheimer's Disease, Beijing Institute for Brain Disorders, Beijing Key Laboratory of Geriatric Cognitive Disorders, Neurodegenerative Laboratory of Ministry of Education of the People's Republic of China, Beijing, China