Data Sheet 2_Altered gut microbial networks and metabolic pathways in multiple system atrophy: a comparative 16S rRNA study.csv

IntroductionThe alterations in the gut microbial network in multiple system atrophy (MSA) remain poorly understood. This study aimed to identify key gut microbial interaction networks in MSA through comprehensive multimodal analyses. MethodsDemographic information and frozen fecal specimens were collected from 119 participants [MSA, n = 26; Parkinson’s disease (PD), n = 66; healthy control (HC), n = 27]. Raw amplicons of the bacterial 16S rRNA V3–V4 gene region were processed using two methods: DADA2-denoising and clustering into operational taxonomic units. We conducted univariate and multivariable analyses to assess the differential abundance of bacterial genera and predicted metabolic pathways using four statistical methods: ANCOM, ANCOM-BC, ALDEx2, and MaAsLin 2. Interbacterial interactions were assessed using four correlation and two network analyses. ResultsWe consistently observed lower levels of Fusicatenibacter in MSA patients and lower levels of Butyricicoccus in PD patients compared with HCs (q < 0.05), both before and after adjusting for comorbidities, diet, and constipation status. The random forest classifiers effectively differentiated between MSA and PD, achieving high AUCs (0.75–0.78) in 5-fold cross-validation. A significant positive interbacterial interaction between Ruminococcus gnavus group and Erysipelatoclostridium was uniquely observed in MSA patients. Additionally, we identified an increase in the ARGORNPROST-PWY pathway (L-arginine degradation, q = 0.003) and a decrease in the PWY-6478 pathway (GDP-D-glycero-α-D-manno-heptose biosynthesis, q = 0.015) in MSA patients compared with HCs. ConclusionFuture studies are warranted to determine whether fecal microbiome-derived signatures can serve as reliable biomarkers for MSA.