Reference (Jul-21-A5)
D. Erny, A.L. Hrabe De Angelis, D. Jaitin, P. Wieghofer, O. Staszewski, E. David, H. Keren-Shaul, T. Mahlakoiv, K. Jakobshagen, T. Buch, V. Schwierzeck, O. Utermohlen, E. Chun, W.S. Garrett, K.D. Mccoy, A. Diefenbach, P. Staeheli, B. Stecher, I. Amit, M. Prinz. (2015). Host microbiota constantly control maturation and function of microglia in the CNS, Nat. Neurosci. 18: 965–977.
Larica Mohantaa , Bhaskar C. Dasb , Manorama Patria. (2020). Microbial communities modulating brain functioning and behaviors in zebrafish: A mechanistic approach. Microbial Pathogenesis 145: 104521 1-6.
Mark Lyte. Host-microbiota neuroendocrine interactions influencing brain and behaviour, Gut Microbes. 5:3, 381–389.
Nicolas Derome and Marie Filteau. (2020). A continuously changing selective context on microbial communities associated with fish, from egg to fork. Evolutionary Applications. 1–22.
P. Bercik and S.M. Collins. (2014). The effects of inflammation, infection and antibiotics on the microbiota-gut-brain axis, Adv. Exp. Med. Biol. 817: 279–289.
Q. He, L. Wang, F. Wang, C. Wang, C. Tang, Q. Li, J. Li, Q. Zhao. (2013). Microbial fingerprinting detects intestinal microbiota dysbiosis in Zebrafish models with chemically-induced enterocolitis, BMC Microbiol. 13: 289.
S.M. Collins, Z. Kassam, P. Bercik. (2013). The adoptive transfer of behavioral phenotype via the intestinal microbiota: experimental evidence and clinical implications, Curr. Opin. Microbiol. 16: 240–245.
T.G. Dinan and J.F. Crayan. (2013). Melancholic microbes: a link between gut microbiota and depression? Neuro Gastroenterol. Motil. 25 (9): 713–719.
