Project description:Acinonyx jubatus overview

Project description:Acinonyx jubatus Genome sequencing

Project description:Acinonyx jubatus Transcriptome or Gene expression

Project description:Acinonyx jubatus Genome sequencing and assembly

Project description:Acinonyx jubatus isolate:Rico Genome sequencing and assembly

Project description:Acinonyx jubatus isolate:Ajub_Pintada_27869175 Genome sequencing and assembly

Project description:Burgeoning study of host-associated microbiomes has accelerated the development of microbial therapies, including fecal microbiota transplants (FMTs). FMTs provide host-specific microbial supplementation, with applicability across host species. Studying FMTs can simultaneously provide comparative frameworks for understanding microbial therapies in diverse microbial systems and improve the health of managed wildlife. Ex-situ carnivores, including cheetahs (Acinonyx jubatus), often suffer from intractable gut infections similar to those treated with antibiotics and FMTs in humans, providing a valuable system for testing FMT efficacy. Using an experimental approach in 21 cheetahs, we tested whether autologous FMTs facilitated post-antibiotic recovery of gut microbiota. We used 16S rRNA sequencing and microbial source tracking to characterize antibiotic-induced microbial extirpations and signatures of FMT engraftment for single versus multiple FMTs. We found that antibiotics extirpated abundant bacteria and FMTs quickened post-antibiotic recovery via engraftment of bacteria that may facilitate protein digestion and butyrate production (Fusobacterium). Although multiple FMTs better sustained microbial recovery compared to a single FMT, one FMT improved recovery compared to antibiotics alone. This study elucidated the dynamics of microbiome modulation in a non-model system and improves foundations for reproducible, low-cost, low-dose, and minimally invasive FMT protocols, emphasizing the scientific and applied value of FMTs across species.

Project description:The aim of this study was to test the hypothesis that replenishing the microbiota with a fecal microbiota transplant (FMT) can rescue a host from an advanced stage of sepsis. We developed a clinically-relevant mouse model of lethal polymicrobial gut-derived sepsis in mice using a 4-member pathogen community (Candida albicans, Klebsiella oxytoca, Serratia marcescens, Enterococcus faecalis) isolated from a critically ill patient. In order to mimic pre-operative surgical patient condition mice were exposed to food restriction and antibiotics. Approximately 18 hours prior to surgery food was removed from the cages and the mice were allowed only tap water. Each mouse received an intramuscular Cefoxitin injection 30 minutes prior to the incision at a concentration of 25 mg/kg into the left thigh. Mice were then subjected to a midline laparotomy, 30% hepatectomy of the left lateral lobe of the liver and a direct cecal inoculation of 200 µL of the four pathogen community. On postoperative day one, the mice were administered rectal enema. Mice were given either 1 ml of fecal microbiota transplant (FMT) or an autoclaved control (AC). This was again repeated on postoperative day two. Mice were then followed for mortality. Chow was restored to the cages on postoperative day two, approximately 45 hours after the operation. The injection of fecal microbiota transplant by enema significantly protected mice survival, reversed the composition of gut microflora and down-regulated the host inflammatory response. The cecum, left lobe of the liver, and spleen were isolated from mice for microarray processing with three or more replicates for six expermental conditions: non-treated control, SAHC POD1, SAHC.AC POD2, SAHC.FMT POD2, SAHC.AC POD7, SAHC.FMT POD7

Project description:fecal microbiota Raw sequence reads

Project description:Fecal microbiota - Raw sequence reads