Project description:Hymenolepis spp. (H. diminuta, H. nana and H. microstoma) are rodent-hosted tapeworms (Platyhelminthes: Cestoda) that have been used as laboratory and teaching models since the 1950s, and consequently much of our understanding of the basic physiology, biochemistry and anatomy of tapeworms in general stems from research using these species. As representatives of the order Cyclophyllidea, they are closely related to species with significant medical and economic importance such as Taenia and Echinococcus spp., but unlike these may be maintained in vivo using only laboratory mice and flour beetles (n.b. Echinoccous spp. are hosted by foxes and Taenia spp. are hosted by pigs or cows). This effort brings a classical laboratory model into the genomic age, allowing researchers in silico access to its genome and expressed gene transcripts and thereby greatly expediting research directed at understanding the genetic basis of tapeworm biology.
Project description:Mouse infection with the tapeworm Hymenolepis diminuta leads to a less severe DNBS-colitis. Increased Th2 and regulatory cytokine production in the spleen is a hallmark of Hymenolepis diminuta infection, therefore we hypothesized that given this microenvironment, splenic adaptive cells acquire an anti-inflammatory phenotype. We tested the ability of putative splenic regulatory B cells generated by Hymenolepis diminuta infection to down-regulate intestinal inflammation. We found that unlike splenic B cells from uninfected mice, splenic B cells from Hymenolepis diminuta -infected animals ameliorated chemically-induced colitis.
