The bacterial virulence factor CagA induces microbial dysbiosis that contributes to excessive epithelial cell proliferation in the Drosophila gut

Gut microbiota facilitate many aspects of human health and development, but dysbiotic microbiota can promote hyperplasia and inflammation and contribute to human diseases such as cancer. Human patients infected with the gastric cancer-causing bacterium Helicobacter pylori have altered microbiota; however, whether dysbiosis contributes to disease in this case is unknown. Many H. pylori human disease phenotypes are associated with a potent virulence protein, CagA, which is translocated into host epithelial cells where it alters cell polarity and manipulates host-signaling pathways to promote disease. We hypothesized that CagA alone could contribute to H. pylori pathogenesis by inducing microbial dysbiosis that promotes disease. Here we use a transgenic Drosophila model of CagA expression to genetically disentangle the effects of the virulence protein CagA from that of H. pylori infection. We found that expression of CagA within Drosophila intestinal stem cells promotes excess cell proliferation and is sufficient to alter host microbiota. Rearing CagA transgenic flies germ-free revealed that the dysbiotic microbiota contributes to cell proliferation phenotypes and also elicits expression of innate immune components, Diptericin and Duox. Further investigations revealed interspecies interactions are required for this dysbiotic CagA-dependent microbiota to promote proliferation in CagA transgenic and healthy control Drosophila. Our model establishes that CagA can alter gut microbiota and exacerbate cell proliferation and immune phenotypes previously attributed to H. pylori infection. This work provides valuable new insights into the mechanisms by which interactions between a specific virulence factor and the resident microbiota can contribute to the development and progression of disease.

• Publication year

  2017

• Venue

  PLoS Pathogens

• Publication date

  2017-10-01

• Fields of study

  Biology, Medicine, Environmental Science

• Identifiers
  DOI 10.1371/journal.ppat.1006631PMID 29049360PMCID 5648253
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• Interspecies interactions are required for the dysbiotic, CagA-dependent microbiota to promote proliferation in both transgenic and control Drosophila.

  Confidence 0.90

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• Germ-free rearing showed that the dysbiotic microbiota contributes to proliferation phenotypes and induces Diptericin and Duox expression.

  Confidence 0.93

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• CagA expression in Drosophila intestinal stem cells is sufficient to alter host microbiota and promote excessive epithelial cell proliferation.

  Confidence 0.97

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review

• caga

  protein

  A Helicobacter pylori virulence protein that is expressed transgenically in the Drosophila gut model.

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• diptericin

  gene

  An antimicrobial peptide gene measured as an innate immune readout in the fly gut.

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• drosophila intestinal stem cells

  cell population

  The fly gut stem-cell population used as the tissue context for CagA expression.

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• duox

  gene

  A dual oxidase gene measured as an innate immune readout in the fly gut.

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• excessive epithelial cell proliferation

  phenotype

  An abnormally increased level of epithelial cell proliferation in the fly gut.

  Aliases: excess cell proliferation

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• germ-free rearing

  experimental condition

  A housing condition in which flies are raised without associated microbes.

  Aliases: germ-free

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• interspecies interactions

  ecological interaction

  Interactions among different microbial species in the gut community considered in the dysbiosis-dependent phenotype.

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review
• microbial dysbiosis

  microbiome state

  An altered gut microbiota state examined in flies carrying CagA.

  Aliases: dysbiotic microbiota

  박진우 (dztg5apj7m) extraction뀨 (7c402c1b98) reviewq (76h6bfydm6) reviewAK (4715169a40) review

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