<i>Cryptococcus gattii</i> urease as a virulence factor and the relevance of enzymatic activity in cryptococcosis pathogenesis

Feder, Vanessa; Kmetzsch, Lívia; Staats, Charley Christian; Vidal-Figueiredo, Natalia; Ligabue-Braun, Rodrigo; Carlini, Célia R.; Vainstein, Marilene Henning

doi:10.1111/febs.13229

Cited by 52 publications

(34 citation statements)

References 57 publications

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“…For CFU assays, the treated cells were washed with fresh drug-free medium 3 times, and then infected with C. neoformans as described above. To test the effects of the examined chemicals on the activity or expression of fungal virulence determinants, we measured urease activity and capsule as described (Feder et al, 2015; Kwon-Chung et al, 1987). …”

Section: Star Methodsmentioning

confidence: 99%

Global Reprogramming of Host Kinase Signaling in Response to Fungal Infection

Pandey

Ding

Qin

et al. 2017

Cell Host & Microbe

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Summary Cryptococcus neoformans (Cn) is a deadly fungal pathogen whose intracellular lifestyle is important for virulence. Host mechanisms controlling fungal phagocytosis and replication remain obscure. Here, we perform a global phosphoproteomic analysis of the host response to Cryptococcus infection. Our analysis reveals numerous and diverse host proteins that are differentially phosphorylated following fungal ingestion by macrophages, thereby indicating global reprogramming of host kinase signaling. Notably, phagocytosis of the pathogen activates the host autophagy initiation complex (AIC) and the upstream regulatory components LKB1 and AMPKα1, which regulate autophagy induction through their kinase activities. AMPKα1 deletion in monocytes results in resistance to fungal colonization of mice. Finally, the recruitment of AIC components to nascent Cryptococcus-containing vacuoles (CnCVs) regulates the intracellular trafficking and replication of the pathogen. These findings demonstrate that host AIC regulatory networks confer susceptibility to infection and establish a proteomic resource for elucidating host mechanisms that regulate fungal intracellular parasitism.

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Section: Star Methodsmentioning

confidence: 99%

Global Reprogramming of Host Kinase Signaling in Response to Fungal Infection

Pandey

Ding

Qin

et al. 2017

Cell Host & Microbe

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“…For example, the two cryptococcal complex species complexes share such virulence-associated phenotypes as polysaccharide capsules (18), thermotolerance of mammalian temperatures (18), melanin production (18), urease (19, 20) and phospholipase (21, 22) activities, intracellular replication (23, 24), nonlytic exocytosis (25, 26), and inositol production (27). Although it is possible that these phenotypes evolved independently, the fact that they are not shared, or rarely shared, by other closely related species supports the view that they evolved in the common ancestor of both the C. neoformans and C. gattii species complexes.…”

Section: Introductionmentioning

confidence: 99%

Continental Drift and Speciation of the Cryptococcus neoformans and Cryptococcus gattii Species Complexes

Casadevall

Freij

Hann‐Soden

et al. 2017

mSphere

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Genomic analysis has placed the origins of two human-pathogenic fungi, the Cryptococcus gattii species complex and the Cryptococcus neoformans species complex, in South America and Africa, respectively. Molecular clock calculations suggest that the two species separated ~80 to 100 million years ago. This time closely approximates the breakup of the supercontinent Pangea, which gave rise to South America and Africa. On the basis of the geographic distribution of these two species complexes and the coincidence of the evolutionary divergence and Pangea breakup times, we propose that a spatial separation caused by continental drift resulted in the emergence of the C. gattii and C. neoformans species complexes from a Pangean ancestor. We note that, despite the spatial and temporal separation that occurred approximately 100 million years ago, these two species complexes are morphologically similar, share virulence factors, and cause very similar diseases. Continuation of these phenotypic characteristics despite ancient separation suggests the maintenance of similar selection pressures throughout geologic ages.

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“…Deletion of either gene results in decreased ability for NIC1 Δ and URE1 Δ yeast cells to penetrate the central nervous system [82]. URE1 also contributes to the pathogenesis of Cryptococcus gattii , which primarily causes pulmonary infection without an increased predilection for CNS invasion in animal models [83, 84]. C. gattii URE1 Δ have attenuated virulence during pulmonary infection, reduced capacity to disseminate to the bloodstream, and impaired intracellular replication within macrophages [83].…”

Section: In Vivo Transcriptional Profilingmentioning

confidence: 99%

Fungal Dimorphism and Virulence: Molecular Mechanisms for Temperature Adaptation, Immune Evasion, and In Vivo Survival

Gauthier

2017

Mediators of Inflammation

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The thermally dimorphic fungi are a unique group of fungi within the Ascomycota phylum that respond to shifts in temperature by converting between hyphae (22–25°C) and yeast (37°C). This morphologic switch, known as the phase transition, defines the biology and lifestyle of these fungi. The conversion to yeast within healthy and immunocompromised mammalian hosts is essential for virulence. In the yeast phase, the thermally dimorphic fungi upregulate genes involved with subverting host immune defenses. This review highlights the molecular mechanisms governing the phase transition and recent advances in how the phase transition promotes infection.

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Cryptococcus gattii urease as a virulence factor and the relevance of enzymatic activity in cryptococcosis pathogenesis

Cited by 52 publications

References 57 publications

Global Reprogramming of Host Kinase Signaling in Response to Fungal Infection

Global Reprogramming of Host Kinase Signaling in Response to Fungal Infection

Continental Drift and Speciation of the Cryptococcus neoformans and Cryptococcus gattii Species Complexes

Fungal Dimorphism and Virulence: Molecular Mechanisms for Temperature Adaptation, Immune Evasion, and In Vivo Survival

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