Your search keyword '"Guo, Cynthia X."' showing total 5 results

1. Alternate synthesis to d-glycero-β-d-manno-heptose 1,7-biphosphate

Author

Sauvageau, Janelle, Bhasin, Milan, Guo, Cynthia X., Adekoya, Itunuoluwa A., Gray-Owen, Scott D., Oscarson, Stefan, Guazzelli, Lorenzo, and Cox, Andrew

Published

2017

2. D-Glycero-β-D-Manno-Heptose 1-Phosphate and D-Glycerob- D-Manno-Heptose 1,7-Biphosphate Are Both Innate Immune Agonists.

Author

Adekoya, Itunuoluwa A., Guo, Cynthia X., Gray-Owen, Scott D., Cox, Andrew D., and Sauvageau, Janelle

Subjects

*IMMUNOLOGY, *EPITHELIAL cells, *CYTOKINES, *INFLAMMATION, *MASS spectrometry

Abstract

D-Glycero-β-D-manno-heptose 1,7-biphosphate (β-HBP) is a novel microbial-associated molecular pattern that triggers inflammation and thus has the potential to act as an immune modulator in many therapeutic contexts. To better understand the structure--activity relationship of this molecule, we chemically synthesized analogs of β-HBP and tested their ability to induce canonical TIFA-dependent inflammation in human embryonic kidney cells (HEK 293T) and colonic epithelial cells (HCT 116). Of the analogs tested, only D-glycero-b-D-manno-heptose 1-phosphate (β-HMP) induced TIFA-dependent NF-κB activation and cytokine production in a manner similar to β-HBP. This finding expands the spectrum of metabolites from the Gram-negative ADP--heptose biosynthesis pathway that can function as innate immune agonists and provides a more readily available agonist of the TIFA-dependent inflammatory pathway that can be easily produced by synthetic methods. [ABSTRACT FROM AUTHOR]

Published

2018

3. Bcl10 synergistically links CEACAM3 and TLR-dependent inflammatory signalling.

Author

Sintsova, Anna, Guo, Cynthia X., Sarantis, Helen, Mak, Tak W., Glogauer, Michael, and Gray‐Owen, Scott D.

Subjects

*NEUTROPHILS, *NEISSERIA gonorrhoeae, *CARCINOEMBRYONIC antigen, *CELL adhesion molecules, *NF-kappa B

Abstract

The neutrophil-specific innate immune receptor CEACAM3 functions as a decoy to capture Gram-negative pathogens, such as Neisseria gonorrhoeae, that exploit CEACAM family members to adhere to the epithelium. Bacterial binding to CEACAM3 results in their efficient engulfment and triggers activation of an nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB)-dependent inflammatory response by human neutrophils. Herein, we report that CEACAM3 cross-linking is not sufficient for induction of cytokine production and show that the inflammatory response induced by Neisseria gonorrhoeae infection is elicited by an integration of signals from CEACAM3 and toll-like receptors. Using neutrophils from a human CEACAM-expressing mouse line (CEABAC), we use a genetic approach to reveal a molecular bifurcation of the CEACAM3-mediated antimicrobial and inflammatory responses. Ex vivo experiments with CEABAC- Rac2−/−, CEABAC- Bcl10−/−, and CEABAC- Malt1−/− neutrophils indicate that these effectors are not necessary for gonococcal engulfment, yet all 3 effectors contribute to CEACAM3-mediated cytokine production. Interestingly, although Bcl10 and Malt1 are often inextricably linked, Bcl10 enabled synergy between toll-like receptor 4 and CEACAM3, whereas Malt1 did not. Together, these findings reveal an integration of the specific innate immune receptor CEACAM3 into the network of more conventional pattern recognition receptors, providing a mechanism by which the innate immune system can unleash its response to a relentless pathogen. [ABSTRACT FROM AUTHOR]

Published

2018

4. Innate Recognition of Intracellular Bacterial Growth Is Driven by the TIFA-Dependent Cytosolic Surveillance Pathway.

Author

Gaudet, Ryan G., Guo, Cynthia X., Molinaro, Raphael, Kottwitz, Haila, Rohde, John R., Dangeard, Anne-Sophie, Arrieumerlou, Cécile, Girardin, Stephen E., and Gray-Owen, Scott D.

Abstract

Summary Intestinal epithelial cells (IECs) act as sentinels for incoming pathogens. Cytosol-invasive bacteria, such as Shigella flexneri , trigger a robust pro-inflammatory nuclear factor κB (NF-κB) response from IECs that is believed to depend entirely on the peptidoglycan sensor NOD1. We found that, during Shigella infection, the TRAF-interacting forkhead-associated protein A (TIFA)-dependent cytosolic surveillance pathway, which senses the bacterial metabolite heptose-1,7-bisphosphate (HBP), functions after NOD1 to detect bacteria replicating free in the host cytosol. Whereas NOD1 mediated a transient burst of NF-κB activation during bacterial entry, TIFA sensed HBP released during bacterial replication, assembling into large signaling complexes to drive a dynamic inflammatory response that reflected the rate of intracellular bacterial proliferation. Strikingly, IECs lacking TIFA were unable to discriminate between proliferating and stagnant intracellular bacteria, despite the NOD1/2 pathways being intact. Our results define TIFA as a rheostat for intracellular bacterial replication, escalating the immune response to invasive Gram-negative bacteria that exploit the host cytosol for growth. [ABSTRACT FROM AUTHOR]

Published

2017

5. High-Throughput Screening Identifies Genes Required for Candida albicans Induction of Macrophage Pyroptosis.

Author

O'Meara TR, Duah K, Guo CX, Maxson ME, Gaudet RG, Koselny K, Wellington M, Powers ME, MacAlpine J, O'Meara MJ, Veri AO, Grinstein S, Noble SM, Krysan D, Gray-Owen SD, and Cowen LE

Subjects

Animals, Candida albicans pathogenicity, Female, High-Throughput Screening Assays, Immune Evasion, Macrophages pathology, Mice, Mice, Inbred C57BL, Phagocytosis, Candida albicans genetics, Genes, Fungal, Host-Pathogen Interactions, Macrophages microbiology, Pyroptosis

Abstract

The innate immune system is the first line of defense against invasive fungal infections. As a consequence, many successful fungal pathogens have evolved elegant strategies to interact with host immune cells. For example, Candida albicans undergoes a morphogenetic switch coupled to cell wall remodeling upon phagocytosis by macrophages and then induces macrophage pyroptosis, an inflammatory cell death program. To elucidate the genetic circuitry through which C. albicans orchestrates this host response, we performed the first large-scale analysis of C. albicans interactions with mammalian immune cells. We identified 98 C. albicans genes that enable macrophage pyroptosis without influencing fungal cell morphology in the macrophage, including specific determinants of cell wall biogenesis and the Hog1 signaling cascade. Using these mutated genes, we discovered that defects in the activation of pyroptosis affect immune cell recruitment during infection. Examining host circuitry required for pyroptosis in response to C. albicans infection, we discovered that inflammasome priming and activation can be decoupled. Finally, we observed that a poptosis-associated s peck-like protein containing a C ARD (ASC) oligomerization can occur prior to phagolysosomal rupture by C. albicans hyphae, demonstrating that phagolysosomal rupture is not the inflammasome activating signal. Taking the data together, this work defines genes that enable fungal cell wall remodeling and activation of macrophage pyroptosis independently of effects on morphogenesis and identifies macrophage signaling components that are required for pyroptosis in response to C. albicans infection. IMPORTANCE Candida albicans is a natural member of the human mucosal microbiota that can also cause superficial infections and life-threatening systemic infections, both of which are characterized by inflammation. Host defense relies mainly on the ingestion and destruction of C. albicans by innate immune cells, such as macrophages and neutrophils. Although some C. albicans cells are killed by macrophages, most undergo a morphological change and escape by inducing macrophage pyroptosis. Here, we investigated the C. albicans genes and host factors that promote macrophage pyroptosis in response to intracellular fungi. This work provides a foundation for understanding how host immune cells interact with C. albicans and may lead to effective strategies to modulate inflammation induced by fungal infections., (Copyright © 2018 O’Meara et al.)

Published

2018