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19.05.2020 | Original Article

Transcriptome Landscape of Intracellular Brucella ovis Surviving in RAW264.7 Macrophage Immune System

verfasst von: Hanwei Jiao, Bowen Li, Zonglin Zheng, Zhixiong Zhou, Wenjie Li, Guojing Gu, Juan Liu, Yichen Luo, Xuehong Shuai, Yu Zhao, Yuxuan Liu, Yidan Wang, Xinglong Wang, Xiaoyan Hu, Li Wu, Jixuan Chen, Qingzhou Huang

Erschienen in: Inflammation | Ausgabe 5/2020

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Abstract

Brucella ovis infection results in genital damage and epididymitis in rams, placental inflammation and rare abortion in ewes, and neonatal mortality in lambs. However, the mechanism underlying B. ovis infection remains unclear. In the present study, we used prokaryotic transcriptome sequencing to identify the differentially expressed genes (DEGs) between wild-type B. ovis and intracellular B. ovis in RAW264.7 macrophages. Gene ontology (GO) term enrichment and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis were performed, and quantitative reverse transcriptase PCR (qRT-PCR) was used to validate the top 10 upregulated and downregulated DEGs. The results showed that 212 genes were differentially expressed, including 68 upregulated and 144 downregulated genes, which were mainly enriched in 30 GO terms linked to biological process, cellular component, and molecular function. KEGG analysis showed that the DEGs were enriched in the hypoxia-inducible factor 1 (HIF-1) signaling pathway, mitogen-activated protein kinase (MAPK) signaling pathway, beta-alanine metabolism, and quorum sensing pathway. BME_RS01160, BME_RS04270, BME_RS08185, BME_RS12880, BME_RS25875, predicted_RNA865, and predicted_RNA953 were confirmed with the transcriptome sequencing data. Hence, our findings not only reveal the intracellular parasitism of B. ovis in the macrophage immune system, but also help to understand the mechanism of chronic B. ovis infection.

Pandey, A., F. Lin, A.L. Cabello, L.F. da Costa, X. Feng, H.Q. Feng, M.Z. Zhang, T. Iwawaki, A. Rice-Ficht, T.A. Ficht, P. de Figueiredo, and Q.M. Qin. 2018. Activation of host IRE1α-dependent signaling axis contributes the intracellular parasitism of Brucella melitensis. Frontiers in Cellular and Infection Microbiology 8: 103.PubMedPubMedCentral

Rittig, M.G., A. Kaufmann, A. Robins, B. Shaw, H. Sprenger, D. Gemsa, V. Foulongne, B. Rouot, and J. Dornand. 2003. Smooth and rough lipopolysaccharide phenotypes of Brucella induce different intracellular trafficking and cytokine/chemokine release in human monocytes. Journal of Leukocyte Biology 74: 1045–1055.PubMed

Adams, L.G. 2002. The pathology of brucellosis reflects the outcome of the battle between the host genome and the Brucella genome. Veterinary Microbiology 90: 553–561.PubMed

Li, S., Y. Liu, Y. Wang, H. Chen, C. Liu, and Y. Wang. 2019. Lateral flow biosensor combined with loop-mediated isothermal amplification for simple, rapid, sensitive, and reliable detection of Brucella spp. Infect Drug Resist 12: 2343–2353.PubMedPubMedCentral

Das, A., B. Kumar, S. Chakravarti, C. Prakash, R.P. Singh, V. Gupta, K.P. Singh, R.K. Agrawal, V.K. Chaturvedi, Abhishek, and G. Shrinet. 2018. Rapid visual isothermal nucleic acid-based detection assay of Brucella species by polymerase spiral reaction. Journal of Applied Microbiology 125: 646–654.PubMed

Lusk Pfefer, T.S., R. Timme, and J.A. Kase. 2018. Identification of Brucella genus and eight Brucella species by Luminex bead-based suspension array. Food Microbiology 70: 113–119.PubMed

Abd El-Wahab, E.W., Y.M. Hegazy, W.F. El-Tras, A. Mikheal, A.F. Kabapy, M. Abdelfatah, M. Bruce, and M.M. Eltholth. 2019. A multifaceted risk model of brucellosis at the human-animal interface in Egypt. Transboundary and Emerging Diseases 66: 2383–2401.PubMed

Hosein, H.I., H.M. Zaki, N.M. Safwat, A.M.S. Menshawy, S. Rouby, A. Mahrous, and B.E. Madkour. 2018. Evaluation of the General Organization of Veterinary Services control program of animal brucellosis in Egypt: An outbreak investigation of brucellosis in buffalo. Vet World 11: 748–757.PubMedPubMedCentral

Njeru, J., G. Wareth, F. Melzer, K. Henning, M.W. Pletz, R. Heller, and H. Neubauer. 2016. Systematic review of brucellosis in Kenya: Disease frequency in humans and animals and risk factors for human infection. BMC Public Health 16: 853.PubMedPubMedCentral

10.

Perin, G., N.B. Bottari, A.D. Silva, A.M. Jaguezeski, T.M.A. Gomes, T.F. Lopes, M.R.C. Schetinger, V.M. Morsch, and A.S. Da Silva. 2019. Cholinesterase's activities of infected mice by Brucella ovis. Microbial Pathogenesis 132: 137–140.PubMed

11.

Pérez-Etayo, L., M.J. de Miguel, R. Conde-Álvarez, P.M. Muñoz, M. Khames, M. Iriarte, I. Moriyón, and A. Zúñiga-Ripa. 2018. The CO2-dependence of Brucella ovis and Brucella abortus biovars is caused by defective carbonic anhydrases. Veterinary Research 49: 85.PubMedPubMedCentral

12.

Sidhu-Muñoz, R.S., P. Sancho, and N. Vizcaíno. 2016. Brucella ovis PA mutants for outer membrane proteins Omp10, Omp19, SP41, and BepC are not altered in their virulence and outer membrane properties. Veterinary Microbiology 186: 59–66.PubMed

13.

Macedo, A.A., A.P. Silva, J.P. Mol, L.F. Costa, L.N. Garcia, M.S. Araújo, O.A. Martins Filho, T.A. Paixão, and R.L. Santos. 2015. The abcEDCBA-encoded ABC transporter and the virB operon-encoded type IV secretion system of Brucella ovis are critical for intracellular trafficking and survival in ovine monocyte-derived macrophages. PLoS One 10: e0138131.PubMedPubMedCentral

14.

Soler-Lloréns, P., Y. Gil-Ramírez, A. Zabalza-Baranguá, M. Iriarte, R. Conde-Álvarez, A. Zúñiga-Ripa, B. San Román, M.S. Zygmunt, N. Vizcaíno, A. Cloeckaert, M.J. Grilló, I. Moriyón, and I. López-Goñi. 2014. Mutants in the lipopolysaccharide of Brucella ovis are attenuated and protect against B. ovis infection in mice. Veterinary Research 45: 72.PubMedPubMedCentral

15.

Buccheri, M.A., E. Salvo, M. Coci, G.M. Quero, L. Zoccarato, V. Privitera, and G. Rappazzo. Investigating microbial indicators of anthropogenic marine pollution by 16S and 18S high-throughput sequencing (HTS) library analysis. 2019. FEMS Microbiology Letters. https://doi.org/10.1093/femsle/fnz179.

16.

Wu, Z., F.J. Gatesoupe, Q. Zhang, X. Wang, Y. Feng, S. Wang, D. Feng, and A. Li. 2019. High-throughput sequencing reveals the gut and lung prokaryotic community profiles of the Chinese giant salamander (Andrias davidianus). Molecular Biology Reports 46: 5143–5154.PubMed

17.

Jain, C., L.M. Rodriguez-R, A.M. Phillippy, K.T. Konstantinidis, and S. Aluru. 2018. High throughput ANI analysis of 90K prokaryotic genomes reveals clear species boundaries. Nature Communications 9: 5114.PubMedPubMedCentral

18.

Numanagić, I., J.K. Bonfield, F. Hach, J. Voges, J. Ostermann, C. Alberti, M. Mattavelli, and S.C. Sahinalp. 2016. Comparison of high-throughput sequencing data compression tools. Nature Methods 13: 1005–1008.PubMed

19.

Singh, A., and P. Bhatia. 2016. Automated Sanger Analysis Pipeline (ASAP): A tool for rapidly analyzing sanger sequencing data with minimum user interference. Journal of Biomolecular Techniques 27: 129–131.PubMed

20.

Albayrak, L., K. Khanipov, G. Golovko, and Y. Fofanov. 2019. Broom: Application for non-redundant storage of high throughput sequencing data. Bioinformatics 35: 143–145.PubMed

21.

Dodds, K.G., J.C. McEwan, R. Brauning, T.C. van Stijn, S.J. Rowe, K.M. McEwan, and S.M. Clarke. 2019. G3 (Bethesda). Exclusion and genomic relatedness methods for assignment of parentage using genotyping-by-sequencing data. 9: 3239–3247.

22.

Sadedin, S.P., and A. Oshlack. 2019. Bazam: A rapid method for read extraction and realignment of high-throughput sequencing data. Genome Biology 20: 78.PubMedPubMedCentral

23.

Nietsch, R., J. Haas, A. Lai, D. Oehler, S. Mester, K.S. Frese, F. Sedaghat-Hamedani, E. Kayvanpour, A. Keller, and B. Meder. 2016. The role of quality control in targeted next-generation sequencing library preparation. Genom Ptoteom Bioinf 14: 200–206.

24.

Escobar, A., P.I. Rodas, and C. Acuña-Castillo. 2018. Macrophage-Neisseria gonorrhoeae interactions: A better understanding of pathogen mechanisms of immunomodulation. Frontiers in Immunology 9: 3044.PubMedPubMedCentral

25.

BoseDasgupta, S., and J. Pieters. 2018. Macrophage-microbe interaction: Lessons learned from the pathogen mycobacterium tuberculosis. Seminars in Immunopathology 40: 577–591.PubMed

26.

Xu, S.J., H.T. Hu, H.L. Li, and S. Chang. 2019. The role of miRNAs in immune cell development, immune cell activation, and tumor immunity: With a focus on macrophages and natural killer cells. Cells. https://doi.org/10.3390/cells8101140.

27.

Hartenstein, V., and P. Martinez. 2019. Phagocytosis in cellular defense and nutrition: A food-centered approach to the evolution of macrophages. Cell and Tissue Research 377: 527–547.PubMedPubMedCentral

28.

Wang, Y., H. Liu, and J. Zhao. 2019, 2019. Macrophage polarization induced by probiotic bacteria: A concise review. Probiotics Antimicrob Proteins. https://doi.org/10.1007/s12602-019-09612-y.

29.

Ma, Y., Y. Liang, N. Wang, L. Cui, Z. Chen, H. Wu, C. Zhu, Z. Wang, S. Liu, and H. Li. Avian flavivirus infection of monocytes/macrophages by extensive subversion of host antiviral innate immune responses. 2019. Journal of Virology. https://doi.org/10.1128/JVI.00978-19.

30.

Sidhu-Muñoz, R.S., P. Sancho, and N. Vizcaíno. 2018. Evaluation of human trophoblasts and ovine testis cell lines for the study of the intracellular pathogen Brucella ovis. FEMS Microbiology Letters 365: 24.

31.

Silva, T.M., J.P. Mol, M.G. Winter, V. Atluri, M.N. Xavier, S.F. Pires, T.A. Paixão, H.M. Andrade, R.L. Santos, and R.M. Tsolis. 2014. The predicted ABC transporter AbcEDCBA is required for type IV secretion system expression and lysosomal evasion by Brucella ovis. PLoS One 9: e114532.PubMedPubMedCentral

32.

Silva, T.M., Paixão, T.A., Costa, E.A., Xavier, M.N., Sá, J.C., Moustacas, V.S., den Hartigh, A.B., Carvalho Neta, A.V, Oliveira, S.C., Tsolis, R., and Santos, R.L. Putative ATP-binding cassette transporter is essential for Brucella ovis pathogenesis in mice. 2011. Infection and Immunity 79: 1706–1717.PubMedPubMedCentral

33.

Covert, J., A.J. Mathison, L. Eskra, M. Banai, and G. Splitter. 2009. Brucella melitensis, B. neotomae and B. ovis elicit common and distinctive macrophage defense transcriptional responses. Experimental Biology and Medicine (Maywood, N.J.) 234: 1450–1467.

34.

Galindo, R.C., P.M. Muñoz, M.J. de Miguel, C.M. Marin, J.M. Blasco, C. Gortazar, K.M. Kocan, and J. de la Fuente. 2009. Differential expression of inflammatory and immune response genes in rams experimentally infected with a rough virulent strain of Brucella ovis. Veterinary Immunology and Immunopathology 127: 295–303.PubMed

35.

David, V., A. Martin, T. Isakova, C. Spaulding, L. Qi, V. Ramirez, K.B. Zumbrennen-Bullough, C.C. Sun, H.Y. Lin, J.L. Babitt, and M. Wolf. 2016. Inflammation and functional iron deficiency regulate fibroblast growth factor 23 production. Kidney International 89: 135–146.PubMedPubMedCentral

36.

Reyes, A.W., L.T. Arayan, H.L. Simborio, H.T. Hop, W. Min, H.J. Lee, D.H. Kim, H.H. Chang, and S. Kim. 2016. Dextran sulfate sodium upregulates MAPK signaling for the uptake and subsequent intracellular survival of Brucella abortus in murine macrophages. Microbial Pathogenesis 91: 68–73.PubMed

37.

Dimitrakopoulos, O., K. Liopeta, G. Dimitracopoulos, and F. Paliogianni. 2013. Replication of Brucella melitensis inside primary human monocytes depends on mitogen activated protein kinase signaling. Microbes and Infection 15: 450–460.PubMed

38.

Mika, L.A., W. Braun, E. Ciaccio, and R.J. Goodlow. 1954. The nature of the effect of alpha-alanine on population changes of Brucella. Journal of Bacteriology 68: 562–569.PubMedPubMedCentral

39.

Altenbern, R.A., H.S. Ginoza, and D.R. Willoams. 1957. Metabolism and population changes in Brucella abortus. I. Roles of alanine and pantothenate in population changes. Journal of Bacteriology 73: 691–696.PubMedPubMedCentral

40.

Tomita, H., Y. Yokooji, T. Ishibashi, T. Imanaka, and H. Atomi. 2014. An archaeal glutamate decarboxylase homolog functions as an aspartate decarboxylase and is involved in β-alanine and coenzyme a biosynthesis. Journal of Bacteriology 196: 1222–1230.PubMedPubMedCentral

41.

Yokota, M., S. Yahagi, and H. Masaki. 2018. Ethyl 2,4-dicarboethoxy pantothenate, a derivative of pantothenic acid, prevents cellular damage initiated by environmental pollutants through Nrf2 activation. Journal of Dermatological Science 92: 162–171.PubMed

42.

Taminiau, B., M. Daykin, S. Swift, M.L. Boschiroli, A. Tibor, P. Lestrate, X. De Bolle, D. O'Callaghan, P. Williams, and J.J. Letesson. 2002. Identification of a quorum-sensing signal molecule in the facultative intracellular pathogen Brucella melitensis. Infection and Immunity 70: 3004–3011.PubMedPubMedCentral

43.

Delrue, R.M., C. Deschamps, S. Léonard, C. Nijskens, I. Danese, J.M. Schaus, S. Bonnot, J. Ferooz, A. Tibor, X. De Bolle, and J.J. Letesson. 2005. A quorum-sensing regulator controls expression of both the type IV secretion system and the flagellar apparatus of Brucella melitensis. Cellular Microbiology 7: 1151–1161.PubMed

44.

Wu, S., J. Liu, C. Liu, A. Yang, and J. Qiao. 2020. Quorum sensing for population-level control of bacteria and potential therapeutic applications. 2019. Cellular and Molecular Life Sciences. https://doi.org/10.1007/s00018-019-03326-8.

45.

Mahdizade-Ari, M., M. Pourhajibagher, and A. Bahador. 2019. Changes of microbial cell survival, metabolic activity, efflux capacity, and quorum sensing ability of Aggregatibacter actinomycetemcomitans due to antimicrobial photodynamic therapy-induced bystander effects. Photodiagnosis and Photodynamic Therapy 26: 287–294.PubMed

46.

Gül, B.Y., D.Y. Imer, P.K. Park, and I. Koyuncu. 2018. Selection of quorum quenching (QQ) bacteria for membrane biofouling control: Effect of different Gram-staining QQ bacteria, Bacillus sp. T5 and Delftia sp. T6, on microbial population in membrane bioreactors. Water Science and Technology 78: 358–366.PubMed

47.

Camele, I., H.S. Elshafie, L. Caputo, and V. De Feo. 2019. Anti-quorum sensing and antimicrobial effect of mediterranean plant essential oils against phytopathogenic bacteria. Frontiers in Microbiology 10: 2619.PubMedPubMedCentral

48.

Theodora, N.A., V. Dominika, and D.E. Waturangi. 2019. Screening and quantification of anti-quorum sensing and antibiofilm activities of phyllosphere bacteria against biofilm forming bacteria. BMC Research Notes 12: 732.PubMedPubMedCentral

49.

Al-Shabib, N.A., F.M. Husain, R.A. Khan, M.S. Khan, M.Z. Alam, F.A. Ansari, S. Laeeq, M. Zubair, S.A. Shahzad, J.M. Khan, A. Alsalme, and I. Ahmad. 2019. Interference of phosphane copper (I) complexes of β-carboline with quorum sensing regulated virulence functions and biofilm in foodborne pathogenic bacteria: A first report. Saudi Journal of Biological Sciences 26: 308–316.PubMed

50.

Uzureau, S., J. Lemaire, E. Delaive, M. Dieu, A. Gaigneaux, M. Raes, X. De Bolle, and J.J. Letesson. 2010. Global analysis of quorum sensing targets in the intracellular pathogen Brucella melitensis 16 M. Journal of Proteome Research 9: 3200–3217.PubMedPubMedCentral

Titel: Transcriptome Landscape of Intracellular Brucella ovis Surviving in RAW264.7 Macrophage Immune System
verfasst von: Hanwei Jiao
Bowen Li
Zonglin Zheng
Zhixiong Zhou
Wenjie Li
Guojing Gu
Juan Liu
Yichen Luo
Xuehong Shuai
Yu Zhao
Yuxuan Liu
Yidan Wang
Xinglong Wang
Xiaoyan Hu
Li Wu
Jixuan Chen
Qingzhou Huang
Publikationsdatum: 19.05.2020
Verlag: Springer US
Erschienen in: Inflammation / Ausgabe 5/2020
Print ISSN: 0360-3997
Elektronische ISSN: 1573-2576
DOI: https://doi.org/10.1007/s10753-020-01239-4

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Transcriptome Landscape of Intracellular Brucella ovis Surviving in RAW264.7 Macrophage Immune System

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