Faculty Bibliography

The intestinal tissue notably responds to stressful, cholinergic and innate immune signals by microRNA (miRNA) changes, but whether and how those miRNA regulators modify the intestinal cholinergic and innate immune pathways remained unexplored. Here, we report changes in several miRNA regulators of cholinesterases (ChEs) and correspondingly modified ChE activities in intestine, splenocytes and the circulation of mice exposed to both stress and canonical or alternative Toll-Like Receptor 9 (TLR9) oligonucleotide (ODN) aptamer activators or blockers. Stressful intraperitoneal injection of saline, the anti-inflammatory TLR9 agonist mEN101 aptamer or the inflammation-activating TLR9 aptamer ODN 1826 all increased the expression of the acetylcholinesterase (AChE)-targeting miR-132. In comparison, mEN101 but neither ODN 1826 nor saline injections elevated intestinal miR-129-5p, miR-186 and miR-200c, all predicted to target both AChE and the homologous enzyme butyrylcholinesterase (BChE). In cultured immune cells, BL-7040, the human counterpart of mEN101, reduced AChE activity reflecting inflammatory reactions in a manner preventable by the TLR9 blocking ODN 2088. Furthermore, the anti-inflammatory BL-7040 TLR9 aptamer caused reduction in nitric oxide and AChE activity in both murine splenocytes and human mononuclear cells at molar concentrations four orders of magnitude lower than ODN 1826. Our findings demonstrate differential reaction of cholinesterase-targeting miRNAs to distinct TLR9 challenges, indicating upstream miRNA co-regulation of the intestinal alternative NFκB pathway and cholinergic signaling. TLR9 aptamers may hence potentiate miRNA regulation that enhances cholinergic signaling and the resolution of inflammation, which opens new venues for manipulating bowel diseases.

MicroRNAs (miRNAs) can notably control many targets each and regulate entire cellular pathways, but whether miRNAs can regulate complete neurotransmission processes is largely unknown. Here, we report that miRNAs with complementary sequence motifs to the key genes involved in acetylcholine (ACh) synthesis and/or packaging show massive overlap with those regulating ACh degradation. To address this topic, we first searched for miRNAs that could target the 3'-untranslated regions of the choline acetyltransferase (ChAT) gene that controls ACh synthesis; the vesicular ACh transporter (VAChT), encoded from an intron in the ChAT gene and the ACh hydrolyzing genes acetyl- and/or butyrylcholinesterase (AChE, BChE). Intriguingly, we found that many of the miRNAs targeting these genes are primate-specific, and that changes in their levels associate with inflammation, anxiety, brain damage, cardiac, neurodegenerative, or pain-related syndromes. To validate the in vivo relevance of this dual interaction, we selected the evolutionarily conserved miR-186, which targets both the stress-inducible soluble "readthrough" variant AChE-R and the major peripheral cholinesterase BChE. We exposed mice to predator scent stress and searched for potential associations between consequent changes in their miR-186, AChE-R, and BChE levels. Both intestinal miR-186 as well as BChE and AChE-R activities were conspicuously elevated 1 week post-exposure, highlighting the previously unknown involvement of miR-186 and BChE in psychological stress responses. Overlapping miRNA regulation emerges from our findings as a recently evolved surveillance mechanism over cholinergic neurotransmission in health and disease; and the corresponding miRNA details and disease relevance may serve as a useful resource for studying the molecular mechanisms underlying this surveillance.