Multiple System Atrophy: Advances in Diagnosis and Therapy
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Abstract
This review summarizes improvements in understanding the pathophysiology and early clinical symptoms of multiple system atrophy (MSA) and advancements in diagnostic methods and disease-modifying therapies for the condition. In 2022, the Movement Disorder Society proposed new diagnostic criteria to develop disease-modifying therapies and promote clinical trials of MSA since the second consensus was proposed in 2008. Regarding pathogenesis, cutting-edge findings have accumulated on the interactions of α-synuclein, neuroinflammation, and oligodendroglia with neurons. In neuroimaging, introducing artificial intelligence, machine learning, and deep learning has notably improved diagnostic accuracy and individual analyses. Advancements in treatment have also been achieved, including immunotherapy therapy against α-synuclein and serotonin-targeted and mesenchymal stem cell therapies, which are thought to affect several aspects of the disease, including neuroinflammation. The accelerated progress in clarifying the pathogenesis of MSA over the past few years and the development of diagnostic techniques for detecting early-stage MSA are expected to facilitate the development of disease-modifying therapies for one of the most intractable neurodegenerative diseases.
INTRODUCTION
Multiple system atrophy (MSA) is a progressive neurodegenerative disease characterized by varying degrees of autonomic failure (AF), parkinsonism, and cerebellar ataxia [1]. Pathologically, it is characterized by glial cytoplasmic inclusions (GCIs), which consist of insoluble α-synuclein accumulated within oligodendrocytes. MSA is classified as an α-synucleinopathy along with Parkinson’s disease (PD) and dementia with Lewy bodies (DLB).
Cutting-edge technology has clarified the structure of α-synuclein in MSA, and pathophysiological and differential diagnostic techniques have been developed based on structural differences [2,3]. Additionally, increasing evidence supports the involvement of neuroinflammation and oligodendroglial cell changes in MSA pathogenesis [4-8].
Symptomatic treatment has limited efficacy in MSA, and no treatments suppress or alleviate disease progression. However, notable advancements have been achieved in the development of antibody therapies against α-synuclein [9], multitargeted disease-modifying therapies, including mesenchymal stem cell (MSC)-mediated neuroinflammation treatments, and other symptomatic treatments, such as selective serotonin reuptake inhibitors (SSRIs) [10-14].
In 2022, the Movement Disorder Society (MDS) proposed new diagnostic criteria to develop disease-modifying therapies and promote clinical trials of MSA [15], which was the first time that it had been revised since the second consensus was proposed in 2008. Additionally, novel biomarkers for diagnosis and progression have been identified from brain imaging, and blood and cerebrospinal fluid (CSF) data have been reported [16-26].
This review summarizes recent developments in MSA research, clarifying the early pathophysiology, psychiatric and cognitive symptoms, diagnostic biomarker development, and drug discovery.
MOVEMENT DISORDER SOCIETY CRITERIA FOR THE DIAGNOSIS OF MULTIPLE SYSTEM ATROPHY
The second consensus criteria, which are widely used to diagnose MSA, were not sufficiently sensitive for the early stages; therefore, since many patients with MSA have been excluded from clinical trials for disease-modifying therapy, the MDS developed the current criteria for MSA diagnosis to improve accuracy early in the course of the disease. According to the MDS criteria, MSA is classified into four levels of certainty: neuropathologically established MSA, clinically established MSA, clinically probable MSA, and possible prodromal MSA.
The second consensus criterion was consistent with the neuropathologically established MSA: findings of widespread and abundant α-synuclein-positive GCIs in the central nervous system associated with neurodegenerative changes in striatonigral or olivopontocerebellar structures that characterize MSA on autopsy. A distinction between the MSA-parkinsonian type (MSA-P) and MSA-cerebellar type (MSA-C) is evident according to the predominant motor phenotype. The proposed new category of possible prodromal MSA with very low specificity is expected to undergo continuous refinement with emerging data, particularly from prospective investigations and biomarker studies. All three clinical diagnostic categories (clinically established, clinically probable, and possible prodromal MSAs) need validation in future studies. For clinically established MSA, clinically probable and possible prodromal MSA, symptoms must begin after 30 years of age because no MSA cases have been confirmed postmortem in the third decade of life or earlier; no past family history can be present, and the disease must progress, as in the second consensus criteria. Older-onset MSA has been clinically and pathologically demonstrated, and MSA-P has been reported to be a significant disease type in South Korea and Japan [27]. Patients with MSA onset after 75 years of age were excluded from the second consensus statement but not from the MDS MSA criteria. Figure 1 summarizes the concept of the MDS criteria for the clinical diagnosis of MSA. Table 1 compares supportive motor and nonmotor features, magnetic resonance imaging (MRI) markers of clinically established MSA, exclusion criteria among MDS criteria, and additional features of possible MSA, supportive features, and nonsupporting features in the second consensus statement.
Clinically established MSA is defined as a combination of 1) core clinical features (at least one of three AFs and poorly levodopa-responsive parkinsonism and/or cerebellar syndrome), 2) at least two supportive motor or nonmotor features, 3) at least one brain MRI marker suggestive of MSA, and 4) no exclusion criteria met. The severity and definition of orthostatic hypotension differed from those in the second consensus criteria. In the MDS criteria, supportive features and MRI markers are necessary for clinically established MSA compared to the second consensus statement. Rapid progression, moderate-to-severe postural instability, severe speech impairment and dysphagia within three years of motor onset; craniocervical dystonia induced or exacerbated by levodopa in the absence of limb dyskinesia; unexplained Babinski signs; jerky myoclonic postural or kinetic tremors; and postural deformities were the eight motor supportive features. Stridor, inspiratory signs, cold, discolored hands and feet, erectile dysfunction (in those aged < 60 years for clinically probable MSA), and pathological laughter or crying were the five nonmotor features. MRI markers of clinically established MSA-P include atrophy of the putamen (and signal decreases on iron-sensitive sequences), middle cerebellar peduncle, pons, or cerebellum, the hot-cross-bun sign, and increased diffusivity of the putamen or middle cerebellar peduncle. MRI markers of clinically established MSA-C included atrophy of the putamen (and signal decreases on iron-sensitive sequences), middle cerebellar peduncle, or pons, the hot-cross-bun sign, and increased diffusivity of the putamen.
Clinically probable MSA was defined as a combination of 1) AF, parkinsonism, and cerebellar impairment; at least two in any combination, including parkinsonism combined with cerebellar impairment without AF, although AF was essential in the second consensus statement, 2) at least one supportive feature, and 3) no exclusion criteria met. The orthostatic hypotension and residual volume definitions for clinically probable MSA differed from those for clinically established MSA (Figure 1).
The exclusion criteria for clinically established and clinically probable MSA included 1) substantial and persistent beneficial response to dopaminergic medications, 2) unexplained anosmia on olfactory testing, 3) fluctuating cognition with pronounced variation in attention and alertness and early decline in visuoperceptual abilities, 4) recurrent visual hallucinations not induced by drugs within three years of disease onset, 5) dementia according to Diagnostic & Statistical Manual of Mental Disorders (DSM)-V within three years of disease onset, 6) downgaze supranuclear palsy or slowing of vertical saccades, 7) brain MRI findings suggestive of an alternative diagnosis (e.g., progressive supranuclear palsy [PSP], multiple sclerosis, vascular parkinsonism, symptomatic cerebellar disease), and 8) documentation of an alternative condition (MSA-like condition, including genetic or symptomatic ataxia and parkinsonism) known to produce AF, ataxia, or parkinsonism and plausibly connected to the patient’s symptoms.
Possible prodromal MSA is defined as a combination of 1) at least one of three clinical nonmotor features as entry criteria (polysomnography-proven rapid eye movement [REM] sleep behavior disorder, neurogenic orthostatic hypotension [decrease ≥ 20/10 mm Hg in blood pressure] within 10 min of standing or head-up tilt, urogenital failure [erectile dysfunction in men aged < 60 years combined with unexplained voiding difficulties with postvoid urinary residual volume > 100 mL or unexplained urinary urge incontinence]), 2) at least one of the subtle parkinsonian or cerebellar signs, and 3) absence of exclusion criteria. Exclusion criteria for possible prodromal MSA included the following: unexplained anosmia in olfactory testing and/or abnormal cardiac sympathetic imaging (123I-metaiodobenzylguanidine-scintigraphy); fluctuating cognition with pronounced variation in attention and alertness and early decline in visuoperceptual abilities; recurrent visual hallucinations not induced by drugs within three years of disease onset; dementia according to DSM-V within three years of disease onset; downgaze supranuclear gaze palsy or slowing vertical saccades; brain MRI findings suggestive of an alternative diagnosis (e.g., PSP, multiple sclerosis, vascular parkinsonism, symptomatic cerebellar disease, etc.); and documentation of an alternative condition (MSA-like condition, including genetic or symptomatic ataxia and parkinsonism) known to produce AF, ataxia, or parkinsonism and plausibly connected to the patient’s symptoms. More recently, novel biomarkers for MSA diagnosis have been provided but were excluded from the new MDS criteria given the limited availability, suboptimal diagnostic accuracy, or lack of diagnostic validation. However, a biomarker, which will allow the improved diagnosis of MSA, will be applied to all MSA diagnostic categories.
OTHER EARLY CLINICAL PHENOTYPES AND FEATURES
The clinical diagnosis of MSA requires the presence of various combinations of AF and/or parkinsonism or cerebellar ataxia [1,15]. However, the median time from disease onset that meets the criteria for probable diagnosis based on the second consensus criteria is approximately two years [28]. Moreover, patients often have only AF, parkinsonism, or cerebellar ataxia early during the disease [29]. Therefore, in addition to the novel MDS diagnostic criteria, a biomarker that can diagnose this stage of “monosystem atrophy” with high accuracy is desirable.
In a recent report reviewing clinical symptoms before MSA diagnosis using a sizable medical database [30], hypotension, urinary disturbance, dizziness, and disequilibrium were more frequent. Additionally, the importance of new-onset or exacerbated snoring has also been noted [31]. These clinical indicators, however, are less specific because they can be detected in the presence of diseases other than MSA or the absence of organic disease.
Concerning cognitive dysfunction and psychiatric symptoms, memory impairment and depression have also been reported as prodromal symptoms of MSA with high frequencies [32]. In particular, a history of depression was confirmed more than five years before diagnosis. In a study, following the onset of MSA, 40% of patients had mild to moderate cognitive dysfunction with or without orthostatic hypotension, which was characterized by executive dysfunction and verbal memory impairment, with depression in 28% and anxiety disorders in 22% of patients [32]. According to a neuropathological study, neurocytoplasmic inclusions in the hippocampal dentate gyrus, Ammon’s horn regions [33], and the entorhinal cortex may cause memory deterioration. Investigation of the pathogenesis of cognitive dysfunction, including complex pathology, remains a future challenge.
ADVANCES IN UNDERSTANDING THE PATHOPHYSIOLOGY
Synucleinopathies, which are divided into Lewy body diseases, including PD, DLB, and MSA, are clinically and pathologically heterogeneous disorders characterized by pathological aggregates of α-synuclein in neurons and glia in the form of Lewy bodies and neurites, neuronal cytoplasmic inclusions, and GCIs. Recent breakthroughs have demonstrated that α-synuclein species derived from Lewy body disease and MSA are distinct “strains” with different seeding properties. First, cryo-electron microscopy shows the following characteristic structures of α-synuclein in the brains of patients with MSA: 1) α-synuclein consists of two different protofilaments, 2) the filaments of α-synuclein from the brains of patients with MSA and DLB are different, and 3) the structure of α-synuclein filaments extracted from the brains of patients with MSA was found to differ from the structure formed in vitro using recombinant proteins [2]. A study in which genetically modified mice were inoculated with recombinant or brainderived α-synuclein aggregates with different structures showed that structural differences might cause differences in clinical presentation, the time to disease onset, and the structure of α-synuclein brain deposits, in addition to the types of cells deposited and α-synuclein propagation [3]. GCIs from patients with MSA injected into the striatum of nonhuman primates resulted in the loss of substantia nigra dopaminergic neurons and medium-sized striatal spinous cells and the loss of oligodendrocytes in the same region, and demyelination, neuroinflammation, and α-synuclein pathology were noted [34]. Despite controversy regarding oligodendrocytes’ α-synuclein expression, MSA-derived extracts can exacerbate oligodendroglial α-synuclein pathology. Furthermore, nigral and striatal degeneration appears to precede GCI formation, which is linked to a-synuclein redistribution in oligodendrocytes. However, Lewy bodies injected into nonhuman primates did not show such redistribution [34]. As a result, disease-related strains could differentiate between PD and MSA. These findings indicated the significant role of structural abnormalities in α-synuclein in the pathogenesis of MSA (Figure 2).
The role of inflammatory pathogenesis has also offered important insights, with significant increases in HLA-DR+ microglia in the putamen and substantia nigra of patients with MSA compared with controls and significant increases in CD3+, CD4+, and CD8+ T cells in these brain regions [4]. Furthermore, [11C]PBR28 positron emission tomography (PET), which visualizes the translocator protein expressed in glial cells, revealed a significant increase in the accumulation of lentiform nuclei and cerebellar white matter in MSA compared with PD, and both diseases could be differentiated with 83% sensitivity and 100% specificity [5]. Conversely, a genome-wide association study revealed a multifactorial overlap between MSA and inflammatory bowel disease, identifying three shared loci with reading variants upstream of the DENND1B and RSP04 genes and in an intron of the C7 gene, which has been implicated in various neuroinflammatory conditions [6].
GCI, a diagnostic indicator of MSA, is generated within oligodendroglia. p25α/tubulin polymerization-promoting protein is expressed in mature oligodendroglia and is essential for myelin reorganization and stabilization. Ferreira et al. [7] found that in MSA, 1) oligodendroglial cell body expansion and myelin primary protein degradation occur; 2) p25α/TPP leaves the nucleus and forms an inclusion body in the cytoplasm; 3) the α-synuclein monomer enters the inclusion body, and p25α/TPP becomes nucleated and forms MSA-type α-synuclein aggregates; and 4) p25α/TPP can be released from oligodendroglial cells to form nuclear and cytoplasmic inclusions in neurons. Moreover, a study profiling the expression of microRNAs in the serum of 20 MSA cases compared with 40 controls via genome-wide analysis found 25 microRNAs associated with MSA [8]. In particular, the expression of microRNA-7641, which regulates axonal myelination, and microRNA-191, which is involved in T-cell survival and prion pathways, were significantly different between MSA and PD, which is worth noting considering the association between neuroinflammation and abnormal oligodendroglia.
DIAGNOSTIC BIOMARKER DEVELOPMENT
New diagnostic methods focusing on MSA-type α-synuclein are being developed. The properties of α-synuclein aggregates in CSF treated with protein misfolding cyclic amplification (PMCA) and real-time Quaking-Induced Conversion (RT-QuIC) provided useful findings for the early diagnosis of MSA and differentiation from PD. Initially, the PMCA reaction was performed by cyclic sonication and incubating infected samples with typical brain homogenates containing cellular prion protein (PrPC) as the substrate. Then, PMCA products were analyzed with protease digestion, and Western blotting was performed to detect amplified conversion products. However, as a limitation, PMCA requires a week-long reaction time, and Western blotting carries the risk of biohazardous infectivity of the amplified products. In contrast, RT-QuIC provides much shorter assay times (e.g., 1–2 days) and noninfectious amplification products using multiwell plates; shaking instead of sonication, a recombinant rather than brain-derived PrPC substrate, and fluorescence (thioflavin T) instead of a Western blot readout (Figure 3).
Further development of PMCA and RT-QuIC assays has improved their sensitivity, specificity and applicability to most prion diseases and proteinopathies. PD/DLB and MSA can be differentiated with high sensitivity and specificity using the differences in their aggregation rate and intensity of maximum fluorescence [16]. Interestingly, RT-QuIC showed high seeding activity in CSF from patients with PD, DLB, pure AF, and idiopathic REM sleep behavior disorders but no increase in seeding activity in those with MSA [17]. However, the results on RT-QuIC in MSA are not consistent among studies, and some studies report positive RT-QuIC in MSA [18,19]. Although no study has directly compared PMCA and RT-QuIC, differences in the structure of α-synuclein may have influenced the results, and further investigation is warranted. Concerning the immunostaining results for α-synuclein phosphorylated explicitly at serine 129 residues in nerves in the skin of the neck, thighs, and lower legs, 72% of patients with MSA-P showed positive findings, mainly in somatic fibers in the distal subepidermal plexus. In contrast, all patients with PD and orthostatic hypotension had positive findings of autonomic cutaneous fibers in the proximal and distal areas [20]. Differences in the structure of α-synuclein may also influence these differences in sites with lesion tendencies.
The neurofilament light chain (NFL), a cytoskeleton component abundant in the axonal projections of neurons, can be elevated in CSF and blood, indicating neuronal damage. NFL in CSF is significantly elevated in MSA compared to PD and DLB, and α-synuclein measured using PMCA was characterized by faster aggregation but lowered maximal fluorescence in MSA compared to PD/DLB [21]. By combining the results of NFL and PMCA-based α-synuclein, differentiating MSA from PD/DLB with high sensitivity and specificity may be possible. NFL in blood also correlates well with the unified MSA rating scale (UMSARS) and is expected to serve as a biomarker of progression [22].
For novel imaging biomarkers, diffusion MRI was reported to detect abnormalities of the middle cerebellar peduncle and putamen in MSA with notable sensitivity. However, given that most studies used a manual region of interest (ROI), discrepancies in results have been a problem. Krismer et al. [23] reported that combining automated ROIs with machine learning and mean diffusivity, a measure of diffusion MRI in the middle cerebellar peduncle and putamen, can be a good discriminator between early and mid-stage MSA and PD. In a study of 1,002 patients with MSA at 17 centers, machine learning was used to analyze data from 60 template regions and fiber bundles on MRI diffusionweighted images, validating the discriminative ability for PD, MSA, and PSP. In this study, the area under the curve (AUC) for differentiating PD from MSA/PSP was 0.955, and the AUC for differentiating MSA from PSP was 0.926 [24]. Voxel-based morphometry, a method for standardizing differences between facilities compared to diffusion MRI, usually requires group comparisons, but individual analysis has recently become possible. Ebina et al. [25] applied a generalized linear model to each voxel of brain volume using age, sex, and total brain volume as covariates, which affected the results of individual analyses. They observed high diagnostic accuracy (individual voxel-based morphometry adjusting covariates) for differentiating MSA from PD. The combination of automation and machine learning will continue improving diagnostic accuracy and standardizing methods for individual analyses.
In a study focusing on laryngeal findings, 43.9% of patients with MSA showed clinically evident laryngeal dysfunction and inspiratory stridor. Endoscopic observation of laryngeal movement revealed abnormal findings in 93% of patients with MSA compared with only 1.8% of patients with PD (p < 0.0001). Additionally, irregular laryngeal cartilage movement was observed in 91.2% of patients with MSA but not in patients with PD (p < 0.0001). Various findings were also noted, including impaired vocal fold movement (75.4%), paradoxical vocal fold movement (33.3%), and vocal fold fixation (19.3%), signifying that laryngeal findings are diagnostic indicators of MSA [26].
DISEASE-MODIFYING THERAPIES AND OTHER TREATMENT
Novel disease-modifying therapies for MSA are being developed to inhibit α-synuclein aggregation, alleviate neuroinflammation and confer neuroprotective effects [35]. In a study of PD01A and PD03A (α-synuclein peptide vaccines) administered to 30 patients with MSA, no safety or tolerability issues were observed in either group [9]. Rapid and sustained antibody production targeting α-synuclein was obtained in the PD01A group, but no significant clinical scores were observed during the observation period. Epigallocatechin gallate, a polyphenolic constituent of green tea that inhibits α-synuclein aggregation in basic research, did not significantly improve the UMSARS scores [36].
Extracellular α-synuclein aggregates can induce neurotoxic signals via neuroinflammation through microglial activation and the release of inflammatory factors. Autologous MSCs are expected to modulate neuroinflammation, inhibit cell death and intercellular transmission, promote neurogenesis and autophagy, degrade α-synuclein aggregates, stabilize axonal transport and phagocytose α-synuclein by microglia [10]. Singer et al. [11] found that the progression rate (UMSARS total scores) among 24 patients with MSA treated with intrathecal adipose-derived MSCs was significantly lower than that among matched historical controls (0.40 ± 0.59 vs. 1.44 ± 1.42 points/month, p = 0.004), with a clear dose-dependent effect. In 2012, Lee et al. [12] reported the potential of MSC therapy for MSA. Further development of MSC therapy is essential.
Other treatments, such as the mammalian target of rapamycin inhibitor sirolimus, which induces autophagy, were ineffective after 48 weeks of treatment [37]. A natural history study showed that low vitamin B12 levels (< 367 ng/L) were associated with shorter survival (hazard ratio, 1.8; 95% confidence interval, 1.3–2.7), increased frequency of falls within three years of onset, and a lower body mass index, suggesting a potential new target for therapeutic intervention [14].
Another retrospective natural history study revealed that patients with MSA treated with SSRIs showed a better prognosis than untreated patients [38]. Fluoxetine, a second-generation antidepressant categorized as an SSRI, did not affect the primary endpoint. However, it significantly improved UMSARS scores in Part II (motor examination) and quality-of-life scores related to emotional and social concerns at 12 weeks compared with baseline [13]. Brain 5-HT1A receptor-binding PET showed that 5-hydroxytryptamine dysfunction in several brain regions in MSA might contribute to fatigue, pain, and apathy [39]. Patients with autopsy-confirmed MSA with AFs in the absence of motor symptoms/signs preferentially showed the involvement of medullary serotonergic neurons and autonomic systems in the occurrence of sudden death [40]. Further studies are needed to determine whether serotonin-targeted therapy alleviates several symptoms and modifies the disease course of MSA.
CONCLUSION
Considerable progress in elucidating the structure of α-synuclein in MSA has offered novel insights into MSA pathophysiology and the development of breakthrough diagnostic tools. Neuroinflammation and oligodendroglia changes contribute to MSA pathogenesis. Introducing new methods, including artificial intelligence and machine and deep learning, has resulted in advancements in existing brain imaging tools. Moreover, clinical trials of immunotherapy against α-synuclein, multitargeted disease-modifying therapies, including MSC therapies, and various symptomatic therapies have provided new perspectives. Therefore, the development of MDS diagnostic criteria, early diagnostic methods, and cutting-edge disease-modifying treatments based on advances in understanding the pathophysiology of MSA is expected.
Notes
Conflicts of Interest
The authors have no financial conflicts of interest.
Funding Statement
This work was supported by Grants-in-Aid from the Research Committee of Ataxia, Health Labour Sciences Research Grant, the Ministry of Health, Labour and Welfare, Japan (20317603).
Author contributions
Conceptualization: Hirohisa Watanabe. Data curation: Yasuaki Mizutani, Mizuki Ito. Formal analysis: Hirohisa Watanabe. Funding acquisition: Hirohisa Watanabe. Investigation: Hirohisa Watanabe. Methodology: Hirohisa Watanabe. Supervision: Akihiro Ueda. Validation: Sayuri Shima. Visualization: Hirohisa Watanabe. Writing—original draft: Hirohisa Watanabe. Writing—review & editing: Sayuri Shima, Yasuaki Mizutani, Akihiro Ueda, Mizuki Ito.