This study showed that in adult Drosophila melanogaster, the type of sugar—either present within the crop lumen or in the bathing solution of the crop—had no effect on crop muscle contraction. What is important, however, is the volume within the crop lumen. Electrophysiological recordings demonstrated that exogenous applications of serotonin on crop muscles increases both the amplitude and the frequency of crop contraction rate, while adipokinetic hormone mainly enhances the crop contraction frequency. Conversely, octopamine virtually silenced the overall crop activity. The present study reports for the first time an analysis of serotonin effects along the gut-brain axis in adult D. melanogaster. Injection of serotonin into the brain between the interocellar area shows that brain applications of serotonin decrease the frequency of crop activity. Based on our results, we propose that there are two different, opposite pathways for crop motility control governed by serotonin: excitatory when added in the abdomen (i.e., directly bathing the crop) and inhibitory when supplied within the brain (i.e., by injection). Finally, our results point to a double brain-gut serotonergic circuitry suggesting that not only the brain can affect gut functions, but the gut can also affect the central nervous system. On the basis of our results, and data in the literature, a possible mechanism for these two discrete serotonergic functions is suggested.
Mounting clinical and preclinical evidence demonstrates an important role for the intestinal microbiome in mediating efficacy of immune checkpoint inhibitor (ICI) antibody therapy across a number of tumor contexts. We sought to determine the effects of microbiome modulation on ICI therapy in a clinically recapitulative orthotopic murine lung cancer model. The microbiome of C57Bl/6NHsd mice was sterilized with antibiotic (ampicillin, streptomycin and colistin) for ten days, resulting in a 99.9% mean decrease in fecal aerobic and anaerobic bacterial load in comparison to naïve mice, handled under specific pathogen free (SPF) conditions. Luciferase-expressing murine Lewis lung carcinoma cells (LL/2-Red-FLuc) were surgically implanted into the left lung parenchyma of all animals. Animals were treated with locoregional radiotherapy (2x 9Gy fractions) targeted to the left lung. The gastrointestinal microbiome was reconstituted via oral gavage Q3D of ~1e09/dose commensal A. muciniphila (A. muc) and E. hirae (E. hir) over five doses or sterile saline as control and animals were randomized within commensal/saline treatment groups to equivalent mean tumor burden as measured by Lumina Series III In-Vivo Imaging System (IVIS). Animals were then administered anti-murine PD-1 or isotype control (0.25 mg) antibody (Ab) treatments Q3D over four doses via intraperitoneal injection. Tumor growth was monitored by IVIS over the course of the study, and ex-vivo IVIS was performed on lungs at endpoint (Day 12 post-tumor implantation). Tumor growth of microbiota non-reconstituted antibiotic-sterilized animals was only slightly inhibited by anti-PD-1 therapy. Animals administered commensal A. muc and E. hir and treatments also displayed slightly inhibited tumor growth kinetics, similar to those observed under saline/anti-PD-1 therapy. Fecal microbial sequencing and immunophenotypic analyses are ongoing. This study demonstrates the utility and ongoing development of a clinically recapitulative contextually accurate preclinical murine lung cancer model to assess the effects of specific microbiota in mediating the efficacy of anti-tumor immunotherapy. Citation Format: Benjamin G. Cuiffo, Caitlin S. Parello, Chelsea Ritchie, Nicholas Rivelli, Alexandra Kury, Sallyann Vu, Gavin Gagnon, Veronica Ritchie, Kasey Reardon, Catarina Costa, Samantha Rogers, Gregory D. Lyng, Stephen T. Sonis. Recolonizing microbiota may impact tumor response to PD-1 inhibition following antibiotic and radiotherapy treatment in a bioluminescent orthotopic model of murine lung cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 1499.
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