Your search keyword '"Aimanianda, Vishukumar"' showing total 11 results

1. Comparative Analysis of the Aspergillus fumigatus Cell Wall Modification and Ensuing Human Dendritic Cell Responses by β-(1,3)-Glucan Synthase Inhibitors—Caspofungin and Enfumafungin.

Author

Guilloux, Karine, Hegde, Pushpa, Wong, Sarah Sze Wah, Aimanianda, Vishukumar, Bayry, Jagadeesh, and Latgé, Jean-Paul

Abstract

Caspofungin, a lipopeptide, is an antifungal drug that belong to the class of echinocandin. It inhibits fungal cell wall β-(1,3)-glucan synthase activity and is the second-line of drug for invasive aspergillosis, a fatal infection caused mainly by Aspergillus fumigatus. On the other hand, Enfumafungin is a natural triterpene glycoside also with a β-(1,3)-glucan synthase inhibitory activity and reported to have antifungal potential. In the present study, we compared the growth as well as modifications in the A. fumigatus cell wall upon treatment with Caspofungin or Enfumafungin, consequentially their immunomodulatory capacity on human dendritic cells. Caspofungin initially inhibited the growth of A. fumigatus, but the effect was lost over time. By contrast, Enfumafungin inhibited this fungal growth for the duration investigated. Both Caspofungin and Enfumafungin caused a decrease in the cell wall β-(1,3)-glucan content with a compensatory increase in the chitin, and to a minor extent they also affected cell wall galactose content. Treatment with these two antifungals did not result in the exposure of β-(1,3)-glucan on A. fumigatus mycelial surface. Enzymatic digestion suggested a modification of β-(1,3)-glucan structure, specifically its branching, upon Enfumafungin treatment. While there was no difference in the immunostimulatory capacity of antifungal treated A. fumigatus conidia, alkali soluble-fractions from Caspofungin treated mycelia weakly stimulated the dendritic cells, possibly due to an increased content of immunosuppressive polysaccharide galactosaminogalactan. Overall, we demonstrate a novel mechanism that Enfumafungin not only inhibits β-(1,3)-glucan synthase activity, but also causes modifications in the structure of β-(1,3)-glucan in the A. fumigatus cell wall. [ABSTRACT FROM AUTHOR]

Published

2024

2. Interplay between host humoral pattern recognition molecules controls undue immune responses against Aspergillus fumigatus.

Author

Dellière, Sarah, Chauvin, Camille, Wong, Sarah Sze Wah, Gressler, Markus, Possetti, Valentina, Parente, Raffaella, Fontaine, Thierry, Krüger, Thomas, Kniemeyer, Olaf, Bayry, Jagadeesh, Carvalho, Agostinho, Brakhage, Axel A., Inforzato, Antonio, Latgé, Jean-Paul, and Aimanianda, Vishukumar

Subjects

PULMONARY aspergillosis, ASPERGILLUS fumigatus, PULMONARY surfactant-associated protein D, IMMUNE response, CONIDIA

Abstract

Pentraxin 3 (PTX3), a long pentraxin and a humoral pattern recognition molecule (PRM), has been demonstrated to be protective against Aspergillus fumigatus, an airborne human fungal pathogen. We explored its mode of interaction with A. fumigatus, and the resulting implications in the host immune response. Here, we demonstrate that PTX3 interacts with A. fumigatus in a morphotype-dependent manner: (a) it recognizes germinating conidia through galactosaminogalactan, a surface exposed cell wall polysaccharide of A. fumigatus, (b) in dormant conidia, surface proteins serve as weak PTX3 ligands, and (c) surfactant protein D (SP-D) and the complement proteins C1q and C3b, the other humoral PRMs, enhance the interaction of PTX3 with dormant conidia. SP-D, C3b or C1q opsonized conidia stimulated human primary immune cells to release pro-inflammatory cytokines and chemokines. However, subsequent binding of PTX3 to SP-D, C1q or C3b opsonized conidia significantly decreased the production of pro-inflammatory cytokines/chemokines. PTX3 opsonized germinating conidia also significantly lowered the production of pro-inflammatory cytokines/chemokines while increasing IL-10 (an anti-inflammatory cytokine) released by immune cells when compared to the unopsonized counterpart. Overall, our study demonstrates that PTX3 recognizes A. fumigatus either directly or by interplaying with other humoral PRMs, thereby restraining detrimental inflammation. Moreover, PTX3 levels were significantly higher in the serum of patients with invasive pulmonary aspergillosis (IPA) and COVID-19-associated pulmonary aspergillosis (CAPA), supporting previous observations in IPA patients, and suggesting that it could be a potential panel-biomarker for these pathological conditions caused by A. fumigatus. Healthy humans mount a protective immune response against Aspergillus fumigatus, an airborne opportunistic fungal pathogen, via interplay between their humoral pattern recognition molecules. Here, Dellière et al., probe the interaction between A. fumigatus and pentraxin 3 and show it restricts pro-inflammatory responses. [ABSTRACT FROM AUTHOR]

Published

2024

3. Humoral Immunity Against Aspergillus fumigatus.

Author

Dellière, Sarah and Aimanianda, Vishukumar

Abstract

Aspergillus fumigatus is one the most ubiquitous airborne opportunistic human fungal pathogens. Understanding its interaction with host immune system, composed of cellular and humoral arm, is essential to explain the pathobiology of aspergillosis disease spectrum. While cellular immunity has been well studied, humoral immunity has been poorly acknowledge, although it plays a crucial role in bridging the fungus and immune cells. In this review, we have summarized available data on major players of humoral immunity against A. fumigatus and discussed how they may help to identify at-risk individuals, be used as diagnostic tools or promote alternative therapeutic strategies. Remaining challenges are highlighted and leads are given to guide future research to better grasp the complexity of humoral immune interaction with A. fumigatus. [ABSTRACT FROM AUTHOR]

Published

2023

4. Comparative proteome analysis identifies species-specific signature proteins in Aspergillus pathogens.

Author

Venugopalan, Lakshmi Prabha, Aimanianda, Vishukumar, Namperumalsamy, Venkatesh Prajna, Prajna, Lalitha, Kuppamuthu, Dharmalingam, and Jayapal, Jeya Maheshwari

Subjects

*ASPERGILLUS, *ASPERGILLUS fumigatus, *ASPERGILLUS flavus, *PROTEOMICS, *PROTEINS, *EXTRACELLULAR space, *COMPARATIVE studies

Abstract

Aspergillus flavus and Aspergillus fumigatus are important human pathogens that can infect the lung and cornea. During infection, Aspergillus dormant conidia are the primary morphotype that comes in contact with the host. As the conidial surface-associated proteins (CSPs) and the extracellular proteins during the early stages of growth play a crucial role in establishing infection, we profiled and compared these proteins between a clinical strain of A. flavus and a clinical strain of A. fumigatus. We identified nearly 100 CSPs in both Aspergillus, and these non-covalently associated surface proteins were able to stimulate the neutrophils to secrete interleukin IL-8. Mass spectrometry analysis identified more than 200 proteins in the extracellular space during the early stages of conidial growth and germination (early exoproteome). The conidial surface proteins and the early exoproteome of A. fumigatus were enriched with immunoreactive proteins and those with pathogenicity-related functions while that of the A. flavus were primarily enzymes involved in cell wall reorganization and binding. Comparative proteome analysis of the CSPs and the early exoproteome between A. flavus and A. fumigatus enabled the identification of a common core proteome and potential species-specific signature proteins. Transcript analysis of selected proteins indicate that the transcript-protein level correlation does not exist for all proteins and might depend on factors such as membrane-anchor signals and protein half-life. The probable signature proteins of A. flavus and A. fumigatus identified in this study can serve as potential candidates for developing species-specific diagnostic tests. Key points: • CSPs and exoproteins could differentiate A. flavus and A. fumigatus. • A. fumigatus conidial surface harbored more antigenic proteins than A. flavus. • Identified species-specific signature proteins of A. flavus and A. fumigatus. [ABSTRACT FROM AUTHOR]

Published

2023

5. Genetics and immunity of Anopheles response to the entomopathogenic fungus Metarhizium anisopliae overlap with immunity to Plasmodium.

Author

Bukhari, Tullu, Aimanianda, Vishukumar, Bischoff, Emmanuel, Brito-Fravallo, Emma, Eiglmeier, Karin, Riehle, Michelle M., Vernick, Kenneth D., and Mitri, Christian

Subjects

*METARHIZIUM anisopliae, *ANOPHELES, *INSECTICIDE resistance, *MALARIA, *PLASMODIUM, *GENETICS, *GENETIC variation, *PLASMODIUM falciparum

Abstract

Entomopathogenic fungi have been explored as a potential biopesticide to counteract the insecticide resistance issue in mosquitoes. However, little is known about the possibility that genetic resistance to fungal biopesticides could evolve in mosquito populations. Here, we detected an important genetic component underlying Anopheles coluzzii survival after exposure to the entomopathogenic fungus Metarhizium anisopliae. A familiality study detected variation for survival among wild mosquito isofemale pedigrees, and genetic mapping identified two loci that significantly influence mosquito survival after fungus exposure. One locus overlaps with a previously reported locus for Anopheles susceptibility to the human malaria parasite Plasmodium falciparum. Candidate gene studies revealed that two LRR proteins encoded by APL1C and LRIM1 genes in this newly mapped locus are required for protection of female A. coluzzii from M. anisopliae, as is the complement-like factor Tep1. These results indicate that natural Anopheles populations already segregate frequent genetic variation for differential mosquito survival after fungal challenge and suggest a similarity in Anopheles protective responses against fungus and Plasmodium. However, this immune similarity raises the possibility that fungus-resistant mosquitoes could also display enhanced resistance to Plasmodium, suggesting an advantage of selecting for fungus resistance in vector populations to promote naturally diminished malaria vector competence. [ABSTRACT FROM AUTHOR]

Published

2022

6. Phagosomal removal of fungal melanin reprograms macrophage metabolism to promote antifungal immunity.

Author

Gonçalves, Samuel M., Duarte-Oliveira, Cláudio, Campos, Cláudia F., Aimanianda, Vishukumar, ter Horst, Rob, Leite, Luis, Mercier, Toine, Pereira, Paulo, Fernández-García, Miguel, Antunes, Daniela, Rodrigues, Cláudia S., Barbosa-Matos, Catarina, Gaifem, Joana, Mesquita, Inês, Marques, António, Osório, Nuno S., Torrado, Egídio, Rodrigues, Fernando, Costa, Sandra, and Joosten, Leo AB.

Subjects

MELANINS, HYPOXIA-inducible factor 1, GLYCOLYSIS, METABOLISM, ASPERGILLOSIS, ASPERGILLUS fumigatus, INTRACELLULAR calcium

Abstract

In response to infection, macrophages adapt their metabolism rapidly to enhance glycolysis and fuel specialized antimicrobial effector functions. Here we show that fungal melanin is an essential molecule required for the metabolic rewiring of macrophages during infection with the fungal pathogen Aspergillus fumigatus. Using pharmacological and genetic tools, we reveal a molecular link between calcium sequestration by melanin inside the phagosome and induction of glycolysis required for efficient innate immune responses. By remodeling the intracellular calcium machinery and impairing signaling via calmodulin, melanin drives an immunometabolic signaling axis towards glycolysis with activation of hypoxia-inducible factor 1 subunit alpha (HIF-1α) and phagosomal recruitment of mammalian target of rapamycin (mTOR). These data demonstrate a pivotal mechanism in the immunometabolic regulation of macrophages during fungal infection and highlight the metabolic repurposing of immune cells as a potential therapeutic strategy. Macrophages undergo a Warburg-like switch from oxidative phosphorylation to glycolysis in response to inflammatory stimulus. Here the authors show that fungal melanin can trigger this switch in human macrophages by sequestering calcium in the phagosome and enabling protection against Aspergillus fumigatus infection. [ABSTRACT FROM AUTHOR]

Published

2020

7. Recognition of DHN-melanin by a C-type lectin receptor is required for immunity to Aspergillus.

Author

Stappers, Mark H. T., Clark, Alexandra E., Aimanianda, Vishukumar, Bidula, Stefan, Reid, Delyth M., Asamaphan, Patawee, Hardison, Sarah E., Dambuza, Ivy M., Valsecchi, Isabel, Kerscher, Bernhard, Plato, Anthony, Wallace, Carol A., Yuecel, Raif, Hebecker, Betty, da Glória Teixeira Sousa, Maria, Cunha, Cristina, Liu, Yan, Feizi, Ten, Brakhage, Axel A., and Kwon-Chung, Kyung J.

Abstract

Resistance to infection is critically dependent on the ability of pattern recognition receptors to recognize microbial invasion and induce protective immune responses. One such family of receptors are the C-type lectins, which are central to antifungal immunity. These receptors activate key effector mechanisms upon recognition of conserved fungal cell-wall carbohydrates. However, several other immunologically active fungal ligands have been described; these include melanin, for which the mechanism of recognition is hitherto undefined. Here we identify a C-type lectin receptor, melanin-sensing C-type lectin receptor (MelLec), that has an essential role in antifungal immunity through recognition of the naphthalene-diol unit of 1,8-dihydroxynaphthalene (DHN)-melanin. MelLec recognizes melanin in conidial spores of Aspergillus fumigatus as well as in other DHN-melanized fungi. MelLec is ubiquitously expressed by CD31+ endothelial cells in mice, and is also expressed by a sub-population of these cells that co-express epithelial cell adhesion molecule and are detected only in the lung and the liver. In mouse models, MelLec was required for protection against disseminated infection with A. fumigatus. In humans, MelLec is also expressed by myeloid cells, and we identified a single nucleotide polymorphism of this receptor that negatively affected myeloid inflammatory responses and significantly increased the susceptibility of stem-cell transplant recipients to disseminated Aspergillus infections. MelLec therefore recognizes an immunologically active component commonly found on fungi and has an essential role in protective antifungal immunity in both mice and humans. [ABSTRACT FROM AUTHOR]

Published

2018

8. H, C and N resonance assignments of the RodA hydrophobin from the opportunistic pathogen Aspergillus fumigatus.

Author

Pille, Ariane, Kwan, Ann, Cheung, Ivan, Hampsey, Matthew, Aimanianda, Vishukumar, Delepierre, Muriel, Latgé, Jean-Paul, Sunde, Margaret, and Guijarro, J.

Abstract

Hydrophobins are fungal proteins characterised by their amphipathic properties and an idiosyncratic pattern of eight cysteine residues involved in four disulphide bridges. The soluble form of these proteins spontaneously self-assembles at hydrophobic/hydrophilic interfaces to form an amphipathic monolayer. The RodA hydrophobin of the opportunistic pathogen Aspergillus fumigatus forms an amyloid layer with a rodlet morphology that covers the surface of fungal spores. This rodlet layer bestows hydrophobicity to the spores facilitating their dispersal in the air and rendering the conidia inert relative to the human immune system. As a first step in the analysis of the solution structure and self-association of RodA, we report the H, C and N resonance assignments of the soluble monomeric form of RodA. [ABSTRACT FROM AUTHOR]

Published

2015

9. Aspergillus Cell Wall and Biofilm.

Author

Beauvais, Anne, Fontaine, Thierry, Aimanianda, Vishukumar, and Latgé, Jean-Paul

Abstract

The fungal cell is surrounded by a cell wall that acts as a sieve and a reservoir for effector molecules that play an active role during infection. This cell wall is essential for fungal growth as well as for resisting host defense mechanisms. The Aspergillus fumigatus cell wall is almost exclusively composed of polysaccharides. The fibrillar core is composed of a branched β-(1,3)-glucan to which chitin, β-(1,3)-/β-(1,4)-glucan, and galactomannan are covalently bound. The alkali-soluble amorphous fraction is mainly composed of α-(1,3)-glucan that has adhesive property and stabilizes the cell wall. Although the same polysaccharides are found in the cell wall of different A. fumigatus morphotypes (conidia and hyphae), their concentration and localization are different. Conidial (the morphotype that mainly enters host respiratory system) cell wall is covered by an outer layer of rodlets and melanin, which confers hydrophobic properties and imparts immunological inertness. In contrast, outer layer of the hypha contains galactosaminogalactan, recently identified as an A. fumigatus virulence factor. The hypha grows either as a network of agglutinated and hydrophobic mass (called mycelium) embedded in an extracellular matrix (ECM) rich in polysaccharides, hydrophobin, and melanin or segregated without ECM. [ABSTRACT FROM AUTHOR]

Published

2014

10. Surface hydrophobin prevents immune recognition of airborne fungal spores.

Author

Aimanianda, Vishukumar, Bayry, Jagadeesh, Bozza, Silvia, Kniemeyer, Olaf, Perruccio, Katia, Elluru, Sri Ramulu, Clavaud, Cécile, Paris, Sophie, Brakhage, Axel A., Kaveri, Srini V., Romani, Luigina, and Latgé, Jean-Paul

Subjects

*HYDROPHOBINS, *FUNGAL proteins, *FUNGAL spores, *ASPERGILLUS fumigatus, *CELL membranes, *PLANT physiology

Abstract

The air we breathe is filled with thousands of fungal spores (conidia) per cubic metre, which in certain composting environments can easily exceed 109 per cubic metre. They originate from more than a hundred fungal species belonging mainly to the genera Cladosporium, Penicillium, Alternaria and Aspergillus. Although these conidia contain many antigens and allergens, it is not known why airborne fungal microflora do not activate the host innate immune cells continuously and do not induce detrimental inflammatory responses following their inhalation. Here we show that the surface layer on the dormant conidia masks their recognition by the immune system and hence prevents immune response. To explore this, we used several fungal members of the airborne microflora, including the human opportunistic fungal pathogen Aspergillus fumigatus, in in vitro assays with dendritic cells and alveolar macrophages and in in vivo murine experiments. In A. fumigatus, this surface ‘rodlet layer’ is composed of hydrophobic RodA protein covalently bound to the conidial cell wall through glycosylphosphatidylinositol-remnants. RodA extracted from conidia of A. fumigatus was immunologically inert and did not induce dendritic cell or alveolar macrophage maturation and activation, and failed to activate helper T-cell immune responses in vivo. The removal of this surface ‘rodlet/hydrophobin layer’ either chemically (using hydrofluoric acid), genetically (ΔrodA mutant) or biologically (germination) resulted in conidial morphotypes inducing immune activation. All these observations show that the hydrophobic rodlet layer on the conidial cell surface immunologically silences airborne moulds. [ABSTRACT FROM AUTHOR]

Published

2009

11. Surface hydrophobin prevents immune recognition of airborne fungal spores.

Author

Aimanianda, Vishukumar, Bayry, Jagadeesh, Bozza, Silvia, Kniemeyer, Olaf, Perruccio, Katia, Elluru, Sri Ramulu, Clavaud, Cécile, Paris, Sophie, Brakhage, Axel A., Kaveri, Srini V., Romani, Luigina, and Latgé, Jean-Paul

Subjects

*IMMUNE recognition

Abstract

A correction to the article "Surface hydrophobin prevents immune recognition of airborne fungal spores," that was published in the 2009 issue is presented.

Published

2010