2021
DOI: 10.1111/jne.12924
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Endocrine cross‐talk between the gut microbiome and glial cells in development and disease

Abstract: Glial cells make up the major cellular component of the nervous system. Glial development is usually investigated through perturbations of host genetics, although non-host-derived signalling molecules can also regulate glial cells. Indeed, gut microbiome colonisation and the presence of microbiome-derived factors in the blood coincide with glial cell development. Emerging data suggest that the gut microbiome can regulate gliogenesis, myelination and glial epigenetics. Neurodegenerative diseases are characteris… Show more

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Cited by 8 publications
(4 citation statements)
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“…Indeed, experimental evidence clearly indicates that dysbiosis occurs in several disorders characterized by myelin damage or disruption. Since shaping of the gut microbiota coincides with the critical period of developmental myelination, authors speculated on the regulation of the oligodendrocyte progenitor niche by the gut microbiota via different mechanisms (for review see [ 41 , 42 ]). Moreover, the absence of gut microbiota in GF mice reduced callosal myelination and white matter plasticity in the prefrontal cortex, due to reduced gene expression of myelin-related proteins and reduced levels of mature oligodendrocytes [ 43 ].…”
Section: Gut–glia Axis In Brain Physiology and Pathology: Modulation ...mentioning
confidence: 99%
“…Indeed, experimental evidence clearly indicates that dysbiosis occurs in several disorders characterized by myelin damage or disruption. Since shaping of the gut microbiota coincides with the critical period of developmental myelination, authors speculated on the regulation of the oligodendrocyte progenitor niche by the gut microbiota via different mechanisms (for review see [ 41 , 42 ]). Moreover, the absence of gut microbiota in GF mice reduced callosal myelination and white matter plasticity in the prefrontal cortex, due to reduced gene expression of myelin-related proteins and reduced levels of mature oligodendrocytes [ 43 ].…”
Section: Gut–glia Axis In Brain Physiology and Pathology: Modulation ...mentioning
confidence: 99%
“…Now, if we still argue that this is not classical endocrine signaling, and that we need a different name, then as I proposed previously, I suggest calling endocrine signaling via gasotransmitters 'gasocrine signaling'. 106 CONCLUSION With all the above listed arguments, I call oxygen and/or its derivatives a gasocrine signaling molecule acting via the receptor HIF1α or equivalent transcription factors on the organism. To ensure the survival of our ecosystem, we need appropriate model organisms and tools to study gasocrine signaling [107][108][109] .…”
Section: Is There a Receptor For Oxygen Or Not?mentioning
confidence: 99%
“…It has the potential to unite researchers in recognizing the importance of vertebrate animal model organisms whose gasocrine signaling is also influenced by diet, environment and non-host factors. [28][29][30][31][32][33][34][35][36] Finally, I propose a modification of the definition of 'gasocrine signaling' from 'a cell signaling event based on the binding of gaseous signaling molecules or gasotransmitters to gasoreceptor proteins' to 'a cell signaling event based on the interaction of gaseous signaling molecules or gasotransmitters to gasoreceptor proteins'. Accepting E. coli SoxR as a gasoreceptor will enable us to explore other transcription factor-based gasoreceptor proteins in the cells of almost all other organisms.…”
Section: Introductionmentioning
confidence: 99%