TrpA1 Regulates Defecation of Food-Borne Pathogens under the Control of the Duox Pathway

Du, Eun Jo; Ahn, Tae Jung; Kwon, Ilmin; Lee, Ji Hye; Park, Jeong Ho; Park, Sun Hwa; Kang, Tong Mook; Cho, Hanna; Kim, Tae Jin; Kim, Hyung Wook; Jun, Youngsoo; Lee, Hee Jae; Lee, Young Sik; Kwon, Jae Young; Kang, Kyeong Jin

doi:10.1371/journal.pgen.1005773

Cited by 54 publications

(78 citation statements)

References 55 publications

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“…Enteroendocrine cells secrete factors [13-15] that promote ISC proliferation [16, 17], influence cell fate choice [18, 19], regulate intestinal peristalsis and defecation [6, 20], and inhibit lipogenesis in enterocytes [21]. Interspersed among the enterocytes and ee cells, along the entire length of the midgut, are intestinal stem cells (ISCs) [22, 23].…”

Section: The Midgutmentioning

confidence: 99%

Maintenance of the adult Drosophila intestine: all roads lead to homeostasis

Guo

Lucchetta

Rafel

et al. 2016

Current Opinion in Genetics & Development

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Maintenance of tissue homeostasis is critical in tissues with high turnover such as the intestinal epithelium. The intestinal epithelium is under constant cellular assault due to its digestive functions and its function as a barrier to chemical and bacterial insults. The resulting high rate of cellular turnover necessitates highly controlled mechanisms of regeneration to maintain the integrity of the tissue over the lifetime of the organism. Transient increase in stem cell proliferation is a commonly used and elaborate mechanism to ensure fast and efficient repair of the gut. However, tissue repair is not limited to regulating ISC proliferation, as emerging evidence demonstrates that the Drosophila intestine uses multiple strategies to ensure proper tissue homeostasis that may also extend to other tissues.

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Section: The Midgutmentioning

confidence: 99%

Maintenance of the adult Drosophila intestine: all roads lead to homeostasis

Guo

Lucchetta

Rafel

et al. 2016

Current Opinion in Genetics & Development

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“…TrpA1 is more generally associated chemo- and thermo-sensing 22,23 in Drosophila , however a study by Du et al . 2006 links TrpA1 to the expulsion of food-borne pathogens by increased defecation and the DUOX pathway (discussed further below) 24 . Speculatively, reduction in TrpA1 transcripts after L. donovani feeding may hint at modification of host defensive pathways to promote survival.…”

Section: Resultsmentioning

confidence: 99%

The Phlebotomus papatasi transcriptomic response to trypanosomatid-contaminated blood is robust but non-specific

Sloan

Sádlová

Leštinová

et al. 2019

Preprint

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The Phlebotomus papatasi transcriptomic response to trypanosomatid-contaminated 1 blood is robust but non-specific 2 3 4 5 6 Abstract 24 Leishmaniasis, caused by parasites of the genus Leishmania, is a disease that effects up to 8 25 million people worldwide. Parasites are transmitted to human and animal hosts through the 26 bite of an infected sand fly. Novel strategies for disease control, require a better 27 understanding of the key step for transmission namely, the establishment of infection inside 28 the fly. In this work we wanted to identify fly transcriptomic signatures associated with 29 infection success or failure. We used next generation sequencing to describe the 30 transcriptome of the sand fly Phlebotomus papatasi when fed with blood alone or with blood 31 containing one of three trypanosomatids: Leishmania major, Leishmania donovani and 32Herpetomonas muscarum: a parasite not transmitted to humans. Of these, only L. major was 33 able to successfully establish an infection in P. papatasi. However, the transcriptional 34 signatures observed were not specific to success or failure of infection but a generalised 35 response to the blood meal. This implies that sand flies perceive Leishmania as just a feature 36 of their microbiome landscape and that any strategy to tackle transmission should focus on 37 the response towards the blood meal rather than parasite establishment. 38 39 40 3 Authors summary 41 Leishmania are parasites that cause leishmaniasis, a group of serious diseases that affect 42 millions of people, mainly across the subtropics and tropics. They are transmitted to humans 43 by phlebotomine sand flies. However, despite establishment in the insect's midgut being key 44 to transmission, early infection events inside the insect are still unclear. Here, we study the 45 gene expression response of the insect vector to a Leishmania parasite that is able to establish 46 infection (L. major) one that is unable to do so (L. donovani) as well as one that is not a natural 47 parasite of sand flies (Herpetomonas muscarum). We found that responses following any of 48 the infected blood meals was very similar to uninfected blood meal. However, changes post-49 blood meal from day 1 to day 9 were dramatic. As a blood feeding insect can accumulate 50 three times its weight in one blood meal, this seems to be the most important physiological 51 change rather than the presence of the parasite. The latter might be just one in a number of 52 microbes the insect encounters. This result will generate new thinking around the concept of 53 stopping transmission by controlling the parasite inside the insect. 54 55

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“…Usually, commensal bacteria do not release uracil, which may be an evolutionary outcome that adaptive symbionts modify the uracil secretion mechanism to avoid an induction of host ROS production [82]. Interestingly, uracil can modulate Drosophila defecation [87]. This process requires both Duox pathway and transient receptor potential (TRP) channel TRPA1.…”

Section: Duox Mediated Ros and Gut Microbial Homeostasismentioning

confidence: 99%

“…TRPA1 is a HOCl receptor and promotes defecation. Pathogen-derived uracil activates Duox system to generate ROS and HOCl, the latter triggers TRPA1 to promote defecation, resulting in the expulsion of pathogens in parallel to the microbicidal effects of ROS and HOCl [87]. …”

Section: Duox Mediated Ros and Gut Microbial Homeostasismentioning

confidence: 99%

The impact of metagenomic interplay on the mosquito redox homeostasis

Champion

2017

Free Radical Biology and Medicine

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Mosquitoes are exposed to oxidative challenges throughout their life cycle. The primary challenge comes from a blood meal. The blood digestion turns the midgut into an oxidative environment, which imposes pressure not only on mosquito fecundity and other physiological traits but also on the microbiota in the midgut. During evolution, mosquitoes have developed numerous oxidative defense mechanisms to maintain redox homeostasis in the midgut. In addition to antioxidants, SOD, catalase, and glutathione system, sufficient supply of the reducing agent, NADPH, is vital for a successful defense against oxidative stress. Increasing evidence indicates that in response to oxidative stress, cells reconfigure metabolic pathways to increase the generation of NADPH through NADP-reducing networks including the pentose phosphate pathway and others. The microbial homeostasis is critical for the functional contributions to various host phenotypes. The symbiotic microbiota is regulated largely by the Duox-ROS pathway in Drosophila. In mosquitoes, Duox-ROS pathway, heme-mediated signaling, antimicrobial peptide production and C-type lectins work in concert to maintain the dynamic microbial community in the midgut. Microbial mechanisms against oxidative stress in this context are not well understood. Emerging evidence that microbial metabolites trigger host oxidative response warrants further study on the metagenomic interplay in an oxidative environment like mosquito gut ecosystem. Besides the classical Drosophila model, hematophagous insects like mosquitoes provide an alternative model system to study redox homeostasis in a symbiotic metagenomic context.

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TrpA1 Regulates Defecation of Food-Borne Pathogens under the Control of the Duox Pathway

Cited by 54 publications

References 55 publications

Maintenance of the adult Drosophila intestine: all roads lead to homeostasis

Maintenance of the adult Drosophila intestine: all roads lead to homeostasis

The Phlebotomus papatasi transcriptomic response to trypanosomatid-contaminated blood is robust but non-specific

The impact of metagenomic interplay on the mosquito redox homeostasis

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