A tripartite of immune-, epithelial-, and nervous-systems in the homeostatic regulation of the gut
Various cell types in the intestinal mucosa are constantly exposed to complex signals emanating from the lumen, including the microbiota and its metabolites. How these bilateral interactions in turn influences intestinal homeostasis is an important question in order to understand microbiota-host...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/69921 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Various cell types in the intestinal mucosa are constantly exposed to complex signals
emanating from the lumen, including the microbiota and its metabolites. How these
bilateral interactions in turn influences intestinal homeostasis is an important question in
order to understand microbiota-host interactions. This thesis has attempted to address this
question in the following papers. Deletion of the diet- and microbiota-regulated aryl
hydrocarbon receptor in CD 11 c+ cells was found to result in aberrant intestinal epithelium
morphogenesis and increased susceptibility of these mice to chemically induced colitis
(Paper 1). Our data highlight a possible gateway of communication between the host and
its environment, through the AhR in intestinal antigen presenting cells, consequently
regulating intestinal epithelial cell biology and function.
In the second paper, we studied the impact of the microbiota on the development of the
enteric nervous system (ENS). The ENS controls many aspects of gut physiology,
including mucosal immunity. The major cellular component of the ENS is the enteric glia
cell (EGC). Our data showcased that the migration and expansion of EGC networks in the
lamina propria towards the lumen are under the influence of the microbiota. The postnatal
expansion of mucosal EGC networks was found to coincide with the same period where
the microbiota increases in number and diversity. Moreover, this microbiota-driven
mechanism is an active process that can be impaired following the exposure to antibiotics,
which abrogate signaling pathways mediating the host-microbe cross talk.
In the final manuscript, we developed a co-culture model system to study EGC functions
further, in relation to intestinal epithelial barrier functions. Using genetic labeling
techniques and live cell imaging, we observed close associations of EGCs with co-cultured intestinal epithelial organoids ex v1vo, reminiscent of the contacts reported
between these two cell types in vivo.
In conclusion, this thesis open more questions than answers especially as it addresses the
issue of cross communication between different biological systems required for the
development of complex organisms. The new player here is the microbiome and how it
constantly affects the response of different cell types, including cell-to-cell
communications, important for cellular adaptation to environmental cues. Future work
will address the precise molecular and cellular mechanisms underlying the interplay
between the microbiota and hosttissues to establish and maintain intestinal homeostasis. |
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