Gut bacterial isoamylamine promotes age-related cognitive dysfunction by promoting microglial cell death

Yun Teng; Jingyao Mu; Fangyi Xu; Xiangcheng Zhang; Mukesh K. Sriwastva; Qiaohong M. Liu; Xiaohong Li; Chao Lei; Kumaran Sundaram; Xin Hu; Lifeng Zhang; Juw Won Park; Jae Yeon Hwang; Eric C. Rouchka; Xiang Zhang; Jun Yan; Michael L. Merchant; Huang Ge Zhang

doi:10.1016/j.chom.2022.05.005

Gut bacterial isoamylamine promotes age-related cognitive dysfunction by promoting microglial cell death

Yun Teng, Jingyao Mu, Fangyi Xu, Xiangcheng Zhang, Mukesh K. Sriwastva, Qiaohong M. Liu, Xiaohong Li, Chao Lei, Kumaran Sundaram, Xin Hu, Lifeng Zhang, Juw Won Park, Jae Yeon Hwang, Eric C. Rouchka, Xiang Zhang, Jun Yan, Michael L. Merchant, Huang Ge Zhang

Genomic Medicine

Research output: Contribution to journal › Article › peer-review

32 Scopus citations

Abstract

The intestinal microbiome releases a plethora of small molecules. Here, we show that the Ruminococcaceae metabolite isoamylamine (IAA) is enriched in aged mice and elderly people, whereas Ruminococcaceae phages, belonging to the Myoviridae family, are reduced. Young mice orally administered IAA show cognitive decline, whereas Myoviridae phage administration reduces IAA levels. Mechanistically, IAA promotes apoptosis of microglial cells by recruiting the transcriptional regulator p53 to the S100A8 promoter region. Specifically, IAA recognizes and binds the S100A8 promoter region to facilitate the unwinding of its self-complementary hairpin structure, thereby subsequently enabling p53 to access the S100A8 promoter and enhance S100A8 expression. Thus, our findings provide evidence that small molecules released from the gut microbiome can directly bind genomic DNA and act as transcriptional coregulators by recruiting transcription factors. These findings further unveil a molecular mechanism that connects gut metabolism to gene expression in the brain with implications for disease development.

Original language	English (US)
Pages (from-to)	944-960.e8
Journal	Cell Host and Microbe
Volume	30
Issue number	7
DOIs	https://doi.org/10.1016/j.chom.2022.05.005
State	Published - Jul 13 2022

Keywords

DNA unwinding
aged brain
binding promoter
cognitive dysfunction
gut bacterial metabolite
gut bacteriophages
isoamylamine
microglial
sensome gene S100A8
transcription factor p53

ASJC Scopus subject areas

Parasitology
Microbiology
Virology

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10.1016/j.chom.2022.05.005

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Teng, Y., Mu, J., Xu, F., Zhang, X., Sriwastva, M. K., Liu, Q. M., Li, X., Lei, C., Sundaram, K., Hu, X., Zhang, L., Park, J. W., Hwang, J. Y., Rouchka, E. C., Zhang, X., Yan, J., Merchant, M. L., & Zhang, H. G. (2022). Gut bacterial isoamylamine promotes age-related cognitive dysfunction by promoting microglial cell death. Cell Host and Microbe, 30(7), 944-960.e8. https://doi.org/10.1016/j.chom.2022.05.005

Teng, Y, Mu, J, Xu, F, Zhang, X, Sriwastva, MK, Liu, QM, Li, X, Lei, C, Sundaram, K, Hu, X, Zhang, L, Park, JW, Hwang, JY, Rouchka, EC, Zhang, X, Yan, J, Merchant, ML & Zhang, HG 2022, 'Gut bacterial isoamylamine promotes age-related cognitive dysfunction by promoting microglial cell death', Cell Host and Microbe, vol. 30, no. 7, pp. 944-960.e8. https://doi.org/10.1016/j.chom.2022.05.005

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abstract = "The intestinal microbiome releases a plethora of small molecules. Here, we show that the Ruminococcaceae metabolite isoamylamine (IAA) is enriched in aged mice and elderly people, whereas Ruminococcaceae phages, belonging to the Myoviridae family, are reduced. Young mice orally administered IAA show cognitive decline, whereas Myoviridae phage administration reduces IAA levels. Mechanistically, IAA promotes apoptosis of microglial cells by recruiting the transcriptional regulator p53 to the S100A8 promoter region. Specifically, IAA recognizes and binds the S100A8 promoter region to facilitate the unwinding of its self-complementary hairpin structure, thereby subsequently enabling p53 to access the S100A8 promoter and enhance S100A8 expression. Thus, our findings provide evidence that small molecules released from the gut microbiome can directly bind genomic DNA and act as transcriptional coregulators by recruiting transcription factors. These findings further unveil a molecular mechanism that connects gut metabolism to gene expression in the brain with implications for disease development.",

keywords = "DNA unwinding, aged brain, binding promoter, cognitive dysfunction, gut bacterial metabolite, gut bacteriophages, isoamylamine, microglial, sensome gene S100A8, transcription factor p53",

author = "Yun Teng and Jingyao Mu and Fangyi Xu and Xiangcheng Zhang and Sriwastva, {Mukesh K.} and Liu, {Qiaohong M.} and Xiaohong Li and Chao Lei and Kumaran Sundaram and Xin Hu and Lifeng Zhang and Park, {Juw Won} and Hwang, {Jae Yeon} and Rouchka, {Eric C.} and Xiang Zhang and Jun Yan and Merchant, {Michael L.} and Zhang, {Huang Ge}",

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AU - Teng, Yun

AU - Mu, Jingyao

AU - Xu, Fangyi

AU - Zhang, Xiangcheng

AU - Sriwastva, Mukesh K.

AU - Liu, Qiaohong M.

AU - Li, Xiaohong

AU - Lei, Chao

AU - Sundaram, Kumaran

AU - Hu, Xin

AU - Zhang, Lifeng

AU - Park, Juw Won

AU - Hwang, Jae Yeon

AU - Rouchka, Eric C.

AU - Zhang, Xiang

AU - Yan, Jun

AU - Merchant, Michael L.

AU - Zhang, Huang Ge

PY - 2022/7/13

Y1 - 2022/7/13

N2 - The intestinal microbiome releases a plethora of small molecules. Here, we show that the Ruminococcaceae metabolite isoamylamine (IAA) is enriched in aged mice and elderly people, whereas Ruminococcaceae phages, belonging to the Myoviridae family, are reduced. Young mice orally administered IAA show cognitive decline, whereas Myoviridae phage administration reduces IAA levels. Mechanistically, IAA promotes apoptosis of microglial cells by recruiting the transcriptional regulator p53 to the S100A8 promoter region. Specifically, IAA recognizes and binds the S100A8 promoter region to facilitate the unwinding of its self-complementary hairpin structure, thereby subsequently enabling p53 to access the S100A8 promoter and enhance S100A8 expression. Thus, our findings provide evidence that small molecules released from the gut microbiome can directly bind genomic DNA and act as transcriptional coregulators by recruiting transcription factors. These findings further unveil a molecular mechanism that connects gut metabolism to gene expression in the brain with implications for disease development.

AB - The intestinal microbiome releases a plethora of small molecules. Here, we show that the Ruminococcaceae metabolite isoamylamine (IAA) is enriched in aged mice and elderly people, whereas Ruminococcaceae phages, belonging to the Myoviridae family, are reduced. Young mice orally administered IAA show cognitive decline, whereas Myoviridae phage administration reduces IAA levels. Mechanistically, IAA promotes apoptosis of microglial cells by recruiting the transcriptional regulator p53 to the S100A8 promoter region. Specifically, IAA recognizes and binds the S100A8 promoter region to facilitate the unwinding of its self-complementary hairpin structure, thereby subsequently enabling p53 to access the S100A8 promoter and enhance S100A8 expression. Thus, our findings provide evidence that small molecules released from the gut microbiome can directly bind genomic DNA and act as transcriptional coregulators by recruiting transcription factors. These findings further unveil a molecular mechanism that connects gut metabolism to gene expression in the brain with implications for disease development.

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KW - microglial

KW - sensome gene S100A8

KW - transcription factor p53

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Gut bacterial isoamylamine promotes age-related cognitive dysfunction by promoting microglial cell death

Abstract

Keywords

ASJC Scopus subject areas

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