<i>Burkholderia cenocepacia</i>Creates an Intramacrophage Replication Niche in Zebrafish Embryos, Followed by Bacterial Dissemination and Establishment of Systemic Infection

Vergunst, Annette C.; Meijer, Annemarie H.; Renshaw, Stephen A.; O’Callaghan, David

doi:10.1128/iai.00743-09

Cited by 106 publications

(130 citation statements)

References 84 publications

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“…Detailed examination of inflammation and host-pathogen interactions at the cellular level has been enabled by several transgenic strains marking embryonic and adult neutrophils, such as Tg(mpx:EGFP) 3,4 and lyz-driven transgenes. 5,6 Such lines have been used to study neutrophil responses and fluxes during infection 7,8 and during acute and chronic inflammation. 3,4,9 Combinations of these approaches have provided some important new insights (eg, regarding the role of leukocytes in mycobacterial infection).…”

Section: Introductionmentioning

confidence: 99%

mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish

Ellett

Pase

Hayman

et al. 2011

Blood

935

1,004

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Macrophages and neutrophils play important roles during the innate immune response, phagocytosing invading microbes and delivering antimicrobial compounds to the site of injury. Functional analyses of the cellular innate immune response in zebrafish infection/ inflammation models have been aided by transgenic lines with fluorophore-marked neutrophils. However, it has not been possible to study macrophage behaviors and neutrophil/macrophage interactions in vivo directly because there has been no macrophage-only reporter line. To remove this roadblock, a macrophagespecific marker was identified (mpeg1) and its promoter used in mpeg1-driven transgenes. mpeg1-driven transgenes are expressed in macrophage-lineage cells that do not express neutrophil-marking transgenes. Using these lines, the different dynamic behaviors of neutrophils and macrophages after wounding were compared side-by-side in compound transgenics. Macrophage/neutrophil interactions, such as phagocytosis of senescent neutrophils, were readily observed in real time. These zebrafish transgenes provide a new resource that will contribute to the fields of inflammation, infection, and leukocyte biology. (Blood. 2011;117(4): e49-e56)

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Section: Introductionmentioning

confidence: 99%

mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish

Ellett

Pase

Hayman

et al. 2011

Blood

935

1,004

View full text Add to dashboard Cite

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“…Also, B. cenocepacia can be transmitted from patient to patient (Drevinek & Mahenthiralingam, 2010). B. cenocepacia is pathogenic in several plant and non-mammalian animal infection models (Khodai-Kalaki et al, 2015;Thomson & Dennis, 2013;Uehlinger et al, 2009;Vergunst et al, 2010) and can survive intracellularly within epithelial cells (Burns et al, 1996;Sajjan et al, 2006), macrophages (Lamothe et al, 2007;Martin & Mohr, 2000;Saini et al, 1999) and amoebae (Lamothe et al, 2004;Marolda et al, 1999).…”

Section: Introductionmentioning

confidence: 99%

Quantification of type VI secretion system activity in macrophages infected with Burkholderia cenocepacia

Aubert

Valvano

2015

Microbiology

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The Gram-negative bacterial type VI secretion system (T6SS) delivers toxins to kill or inhibit the growth of susceptible bacteria, while other secretion systems target eukaryotic cells. Deletion of atsR, a negative regulator of virulence factors in B. cenocepacia K56-2, increases T6SS activity. Macrophages infected with a K56-2 DatsR mutant display dramatic alterations in their actin cytoskeleton architecture that rely on the T6SS, which is responsible for the inactivation of multiple Rho-family GTPases by an unknown mechanism. We employed a strategy to standardize the bacterial infection of macrophages and densitometrically quantify the T6SS-associated cellular phenotype, which allowed us to characterize the phenotype of systematic deletions of each gene within the T6SS cluster and ten vgrG genes in K56-2 DatsR. None of the genes from the T6SS core cluster nor the individual vgrG genes were directly responsible for the cytoskeletal changes in infected cells. However, a mutant strain with all vgrG genes deleted was unable to cause macrophage alterations. Despite not being able to identify a specific effector protein responsible for the cytoskeletal defects in macrophages, our strategy resulted in the identification of the critical core components and accessory proteins of the T6SS assembly machinery and provides a screening method to detect T6SS effectors targeting the actin cytoskeleton in macrophages by random mutagenesis.

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“…The increasing success of this alternative vertebrate model relies on major and unique opportunities that motivated and validated its use for a better understanding of numerous viral and bacterial infections 19,22,23,24,25,26,27,28,29 . As opposed to most other animal models, zebrafish embryos are optically transparent, allowing non-invasive fluorescence imaging 30 .…”

Section: Introductionmentioning

confidence: 99%

Deciphering and Imaging Pathogenesis and Cording of <em>Mycobacterium abscessus</em> in Zebrafish Embryos

Bernut

Dupont

Sahuquet

et al. 2015

JoVE

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Zebrafish (Danio rerio) embryos are increasingly used as an infection model to study the function of the vertebrate innate immune system in host-pathogen interactions. The ease of obtaining large numbers of embryos, their accessibility due to external development, their optical transparency as well as the availability of a wide panoply of genetic/immunological tools and transgenic reporter line collections, contribute to the versatility of this model. In this respect, the present manuscript describes the use of zebrafish as an in vivo model system to investigate the chronology of Mycobacterium abscessus infection. This human pathogen can exist either as smooth (S) or rough (R) variants, depending on cell wall composition, and their respective virulence can be imaged and compared in zebrafish embryos and larvae. Micro-injection of either S or R fluorescent variants directly in the blood circulation via the caudal vein, leads to chronic or acute/lethal infections, respectively. This biological system allows high resolution visualization and analysis of the role of mycobacterial cording in promoting abscess formation. In addition, the use of fluorescent bacteria along with transgenic zebrafish lines harbouring fluorescent macrophages produces a unique opportunity for multi-color imaging of the host-pathogen interactions. This article describes detailed protocols for the preparation of homogenous M. abscessus inoculum and for intravenous injection of zebrafish embryos for subsequent fluorescence imaging of the interaction with macrophages. These techniques open the avenue to future investigations involving mutants defective in cord formation and are dedicated to understand how this impacts on M. abscessus pathogenicity in a whole vertebrate. Video LinkThe video component of this article can be found at

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Burkholderia cenocepaciaCreates an Intramacrophage Replication Niche in Zebrafish Embryos, Followed by Bacterial Dissemination and Establishment of Systemic Infection

Cited by 106 publications

References 84 publications

mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish

mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish

Quantification of type VI secretion system activity in macrophages infected with Burkholderia cenocepacia

Deciphering and Imaging Pathogenesis and Cording of <em>Mycobacterium abscessus</em> in Zebrafish Embryos

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