Ga Young Park1, Hyun Jin Yu2, Jee Soo Son2, Sang Joon Park3, Hee-Jae Cha4, Kyoung Seob Song5. 1. Department of Cell Biology, Kosin University College of Medicine, 34 Amnam-dong, Seo-gu, Busan, 49267, Korea. 2. Institute of Life Technology, iNtRON Biotechnology, Seongnam, Korea. 3. College of Veterinary Medicine, Kyungpook National University, Daegu, Korea. 4. Department of Parasitology and Genetics, Kosin University College of Medicine, Busan, Korea. 5. Department of Cell Biology, Kosin University College of Medicine, 34 Amnam-dong, Seo-gu, Busan, 49267, Korea. kssong@kosin.ac.kr.
Abstract
BACKGROUND: Although Pasteurella multocida is highly prevalent pathogen in animals and plays an important role in swine respiratory diseases, only a few studies on the use of bacteriophages specific to Pasteurella multocida disease have been reported. OBJECTIVE: The object of this study was to investigate the therapeutic effect of specific P. multocida bacteriophages and to identify genes related to bacteriophage signaling utilizing RNA microarrays in swine nasal turbinate cells. METHODS: Pas-MUP-1 phages were applied 24 h prior to P. multocida infection (1 × 107 cfu/ml) at several concentrations of bacterial infection. Cells were incubated to detect cytokines and 24 h to detect mucin production. And real-time quantitative PCR was performed to examine related genes expression. To determine the change of total gene expression based on P. multocida and Pas-MUP-1 treatment, we performed RNA sequencing experiments. RESULTS: We found that P. multocida-infected PT-K75 cells show increased gene expression of IL-1β, IL-6, and Muc1 in a dose-dependent manner. Interestingly, these genes resulted in decreased expression in P. multocida pretreated with the P. multocida-specific Pas-MUP-1 bacteriophage. RNA sequencing analysis revealed that bacteriophage administration regulated genes associated with immune and inflammatory responses, and the regulated genes were dramatically concentrated in the cytokine/chemokine-based signaling pathways. Pas-MUP-1 treatment was shown to regulate P. multocida induced gene expression in the bacteria. CONCLUSION: These results suggest the specific bacteriophage has therapeutic potential as an alternative to antibiotic treatment to defend against P. multocida infection by altering inflammatory gene expression profiles.
BACKGROUND: Although Pasteurella multocida is highly prevalent pathogen in animals and plays an important role in swinerespiratory diseases, only a few studies on the use of bacteriophages specific to Pasteurella multocida disease have been reported. OBJECTIVE: The object of this study was to investigate the therapeutic effect of specific P. multocida bacteriophages and to identify genes related to bacteriophage signaling utilizing RNA microarrays in swine nasal turbinate cells. METHODS: Pas-MUP-1 phages were applied 24 h prior to P. multocida infection (1 × 107 cfu/ml) at several concentrations of bacterial infection. Cells were incubated to detect cytokines and 24 h to detect mucin production. And real-time quantitative PCR was performed to examine related genes expression. To determine the change of total gene expression based on P. multocida and Pas-MUP-1 treatment, we performed RNA sequencing experiments. RESULTS: We found that P. multocida-infected PT-K75 cells show increased gene expression of IL-1β, IL-6, and Muc1 in a dose-dependent manner. Interestingly, these genes resulted in decreased expression in P. multocida pretreated with the P. multocida-specific Pas-MUP-1 bacteriophage. RNA sequencing analysis revealed that bacteriophage administration regulated genes associated with immune and inflammatory responses, and the regulated genes were dramatically concentrated in the cytokine/chemokine-based signaling pathways. Pas-MUP-1 treatment was shown to regulate P. multocida induced gene expression in the bacteria. CONCLUSION: These results suggest the specific bacteriophage has therapeutic potential as an alternative to antibiotic treatment to defend against P. multocida infection by altering inflammatory gene expression profiles.
Authors: Ga Young Park; Hye Min Lee; Hyun Jin Yu; Jee Soo Son; Sang Joon Park; Kyoung Seob Song Journal: Genes Genomics Date: 2018-10-23 Impact factor: 1.839
Authors: Robert C Gentleman; Vincent J Carey; Douglas M Bates; Ben Bolstad; Marcel Dettling; Sandrine Dudoit; Byron Ellis; Laurent Gautier; Yongchao Ge; Jeff Gentry; Kurt Hornik; Torsten Hothorn; Wolfgang Huber; Stefano Iacus; Rafael Irizarry; Friedrich Leisch; Cheng Li; Martin Maechler; Anthony J Rossini; Gunther Sawitzki; Colin Smith; Gordon Smyth; Luke Tierney; Jean Y H Yang; Jianhua Zhang Journal: Genome Biol Date: 2004-09-15 Impact factor: 13.583
Authors: G Bhuvana Priya; Viswas Konasagara Nagaleekar; A Arun Prince Milton; M Saminathan; Amod Kumar; Amit Ranjan Sahoo; Sajad Ahmad Wani; Amit Kumar; S K Gupta; Aditya P Sahoo; A K Tiwari; R K Agarwal; Ravi Kumar Gandham Journal: PLoS One Date: 2017-07-13 Impact factor: 3.240