Microbiota-derived SCFAs Promote Chronic Neurogenesis and Anti-inflammatory Gene Expression after Traumatic Brain Injury
Zujian Xiong1, Brittany Nelson1, Chaim Sneiderman1, Keri Janesko-Feldman1, Patrick Kochanek1, Dhivyaa Rajasundaram1, Ruchira Jha2, Gary Kohanbash1, Dennis Simon1
1University of Pittsburgh, 2Barrow Neurological Institute
Objective:
 To evaluate whether short-chain fatty acids (SCFAs) will benefit the long-term recovery of traumatic brain injury (TBI) in mice.
Background:

SCFAs, including acetate and butyrate, are the main metabolites generated by gut microbiota consuming dietary fiber in the colon. SCFAs have pleotropic effects throughout the body including influences on immunity and neurogenesis. We hypothesized that SCFAs could influence recovery from TBI.

Design/Methods:

 Adult C57BL6/J mice (n=4/group) were randomized to standard high-amylose maize starch (HAMS) chow or acetylated- and butyrylated-HAMS (HAMS-AB). Fermentation of HAMS-AB by gut bacteria releases acetate and butyrate in the intestinal lumen. The controlled cortical impact (CCI) model of TBI (6m/s, 2.2mm depth, 50msec dwell) was performed. Sham mice received anesthesia and skin incision without craniotomy. At 6 months post-injury, mice were sacrificed and single-cell mRNA from pericontusional tissue sequenced following the 10X Genomics protocol. After pre-processing by CellRanger and SCT normalization by Seurat, cells were annotated based on canonical markers. Cell subtype gene modules were clustered by weighted gene co-expression network analysis (WGCNA) and enriched at gene-ontology (GO) pathways. The GO pathway and regulon activity were evaluated by AUCell and SCENIC respectively. 

Results:

In a total of 116,134 cells, consisting of 12 cell types, from 3 groups (41,509 from sham_control, 36,409 from injury_control, 38,216 from injury_SCFA,) passed the quality control and doublet filtering. Both the cell composition and transcriptome were different in each group. SCFAs decreased gene expression associated with neuronal activity and increased the immature neuron frequency. During immature neuron differentiation, SCFAs downregulated neurodegenerative disease-related genes expression in injured mice. In addition, SCFAs decreased chronic microglia/macrophage activation and promoted an M2-like phenotype. Lastly, SCFAs attenuated T cell activation and cytotoxic-related pathways. 

Conclusions:

SCFAs impact gene expression in multiple cell types at 6 months after TBI. The pathways affected suggest a beneficial role for gut-derived SCFA administration for recovery after TBI. 

10.1212/WNL.0000000000203108