Multiple System Atrophy is associated with brain somatic mutations in clonal haematopoiesis genes

Multiple system atrophy (MSA) is a sporadic progressive neurodegenerative disorder characterised by central nervous system alpha-synuclein inclusions. MSA pathologically most commonly shows a spectrum of two patterns, olivopontocerebellar atrophy and striatonigral degeneration, with significant overlap. Although germline variants are unlikely to play a major role, an association with the KCTD7 gene was recently reported. Somatic mutations are abundant in the brain, and may play a role in neurodegeneration. In MSA, somatic SNCA (alpha-synuclein) copy number gains occur, but single nucleotide mutations have not been investigated. In Alzheimers disease, somatic mutations in tumour suppressor genes were reported in microglia. We hypothesised that brain somatic mutations in SNCA, KCTD7, or the tumour suppressor genes mutated in Alzheimers, may contribute to MSA. To test this, we developed a targeted duplex sequencing pipeline using unique molecular identifiers, encompassing SNCA, KCTD7, and 10 tumour suppressor genes. Seven of these are involved in clonal haematopoiesis, an age-related process which predisposes to haematological malignancy, and can be subdivided into myeloid and lymphoid, based on the cell type affected, with the former much more frequent. We analysed DNA from the cerebellum, cingulate cortex, and putamen of 20 MSA cases (10 olivopontocerebellar atrophy, 10 striatonigral degeneration) and 9 controls. We observed an enrichment of clonal haematopoiesis gene mutations in MSA brains (median 1 vs 0, p=0.054). These included mutations in DNMT3A and TET2, the most frequently affected myeloid clonal haematopoiesis genes, and a recurrent mutation in three cases in KMT2D, a lymphoid clonal haematopoiesis gene. Clonal haematopoiesis mutations were often found in multiple brain regions, and multiregional mutations occurred in 12/20 MSA cases versus 1/9 controls (p=0.020), with 11 cases harbouring clonal haematopoiesis mutations in all three brain regions, compared to 0/9 controls (p=0.005). In striatonigral degeneration, clonal haematopoiesis mutations showed elevated variant allele fractions in the most pathologically affected region, the putamen, versus the cerebellum (p=0.013). MSA clonal haematopoiesis mutations included eight unique non-synonymous variants, which had higher allelic fractions than synonymous changes (p=0.076), and five of these were predicted to confer a proliferative advantage and were found in multiple brain regions. We detected no coding SNCA mutations, and the small number of KCTD7 variants, including one coding deletion, precludes any conclusions. These findings reveal enrichment of clonal haematopoiesis mutations in MSA brain, potentially due to infiltration from the periphery, suggesting a disease-associated proliferative process extending beyond peripheral haematopoiesis.