Jean-Paul Latgé’s research while affiliated with University of Crete and other places

Background The use of fluconazole for long-term oral candidiasis treatment in HIV/AIDS patients can potentially affect the clearance rate and antifungal efficacy of voriconazole against Talaromyces marneffei infection. We isolated two T. marneffei strains that were both resistant to fluconazole and voriconazole. To investigate the mechanism underlying the induction of the cross-resistance in T. marneffei. Methods Fluconazole-resistant strains were induced in vitro. The target enzyme 14-α sterol demethylase Cyp51B was sequenced, and drug efflux pump expression was determined by RT–qPCR in all strains. Results The sensitivity of fluconazole-induced resistant strains to fluconazole was greater than 128 mg/L, and this resistance was stably inherited after fluconazole pressure was removed. MICs of voriconazole for resistant strains were 4∼16 times greater than FRR (0.25–1 versus 0.06 mg/L). Two mutation hotspots in Cyp51B were detected: G441D and G441V. The AtrF, Mdr1 and Pmfcz genes were significantly overexpressed in the vast majority of the fluconazole-resistant strains (P < 0.05). Conclusions The growth of T. marneffei in the presence of fluconazole could induce voriconazole resistance in vitro. The main cause of this cross-resistance in T. marneffei appears to be related to a mutation in Cyp51B at G441 and overexpression of the efflux pumps AtrF, Mdr1 and Pmfcz.

Zygomycetous fungal infections pose an emerging medical threat among individuals with compromised immunity and metabolic abnormalities. Our pathophysiological understanding of these infections, particularly the role of fungal cell walls in growth and immune response, remains limited. Here we conducted multidimensional solid-state NMR analysis to examine cell walls in five Mucorales species, including key mucormycosis causative agents like Rhizopus and Mucor species. We show that the rigid core of the cell wall primarily comprises highly polymorphic chitin and chitosan, with minimal quantities of β-glucans linked to a specific chitin subtype. Chitosan emerges as a pivotal molecule preserving hydration and dynamics. Some proteins are entrapped within this semi-crystalline chitin/chitosan layer, stabilized by the sidechains of hydrophobic amino acid residues, and situated distantly from β-glucans. The mobile domain contains galactan- and mannan-based polysaccharides, along with polymeric α-fucoses. Treatment with the chitin synthase inhibitor nikkomycin removes the β-glucan-chitin/chitosan complex, leaving the other chitin and chitosan allomorphs untouched while simultaneously thickening and rigidifying the cell wall. These findings shed light on the organization of Mucorales cell walls and emphasize the necessity for a deeper understanding of the diverse families of chitin synthases and deacetylases as potential targets for novel antifungal therapies.

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.

Invasive aspergillosis poses a significant threat to immunocompromised patients, leading to high mortality rates associated with these infections. Targeting the biosynthesis of cell wall carbohydrates is a promising strategy for antifungal drug development and will be advanced by a molecular-level understanding of the native structures of polysaccharides within their cellular context. Solid-state NMR spectroscopy has recently provided detailed insights into the cell wall organization of Aspergillus fumigatus, but genetic and biochemical evidence highlights species-specific differences among Aspergillus species. In this study, we employed a combination of 13C, 15N, and 1H-detection solid-state NMR, supplemented by Dynamic Nuclear Polarization (DNP), to compare the structural organization of cell wall polymers and their assembly in the cell walls of A. fumigatus and A. nidulans, both of which are key model organisms and human pathogens. The two species exhibited a similar rigid core architecture, consisting of chitin, α-glucan, and β-glucan, which contributed to comparable cell wall properties, including polymer dynamics, water retention, and supramolecular organization. However, differences were observed in the chitin, galactosaminogalactan, protein, and lipid content, as well as in the dynamics of galactomannan and the structure of the glucan matrix. Keywords: cell wall, fungi, polysaccharide, Aspergillus, solid-state NMR, DNP

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.

Antifungal echinocandins inhibit the biosynthesis of β−1,3-glucan, a major and essential polysaccharide component of the fungal cell wall. However, the efficacy of echinocandins against the pathogen Aspergillus fumigatus is limited. Here, we use solid-state nuclear magnetic resonance (ssNMR) and other techniques to show that echinocandins induce dynamic changes in the assembly of mobile and rigid polymers within the A. fumigatus cell wall. The reduction of β−1,3-glucan induced by echinocandins is accompanied by a concurrent increase in levels of chitin, chitosan, and highly polymorphic α−1,3-glucans, whose physical association with chitin maintains cell wall integrity and modulates water permeability. The rearrangement of the macromolecular network is dynamic and controls the permeability and circulation of the drug throughout the cell wall. Thus, our results indicate that echinocandin treatment triggers compensatory rearrangements in the cell wall that may help A. fumigatus to tolerate the drugs’ antifungal effects.

Halophilic fungi thrive in hypersaline habitats and face a range of extreme conditions. These fungal species have gained considerable attention due to their potential applications in harsh industrial processes, such as bioremediation and fermentation under unfavorable conditions of hypersalinity, low water activity, and extreme pH. However, the role of the cell wall in surviving these environmental conditions remains unclear. Here we employ solid-state NMR spectroscopy to compare the cell wall architecture of Aspergillus sydowii across salinity gradients. Analyses of intact cells reveal that A. sydowii cell walls contain a rigid core comprising chitin, β-glucan, and chitosan, shielded by a surface shell composed of galactomannan and galactosaminogalactan. When exposed to hypersaline conditions, A. sydowii enhances chitin biosynthesis and incorporates α-glucan to create thick, stiff, and hydrophobic cell walls. Such structural rearrangements enable the fungus to adapt to both hypersaline and salt-deprived conditions, providing a robust mechanism for withstanding external stress. These molecular principles can aid in the optimization of halophilic strains for biotechnology applications.

The insufficient efficacy of existing antifungal drugs and the rise in resistance necessitate the development of new therapeutic agents with novel functional mechanisms. Echinocandins are an important class of antifungals that inhibit β-1,3-glucan biosynthesis to interfere with cell wall structure and function. However, their efficacy is limited by the fungistatic activity against Aspergillus species and the trailing effect during clinical application. Here, we describe how echinocandins remodel the supramolecular assembly of carbohydrate polymers in the fungal cell wall in an unexpected manner, possibly resulting in a subsequent inhibition of the activity of these drugs. Solid-state nuclear magnetic resonance (ssNMR) analysis of intact cells from the human pathogenic fungus Aspergillus fumigatus showed that the loss of β-1,3-glucan and the increase of chitin content led to a decrease in cell wall mobility and water-permeability, thus enhancing resistance to environmental stresses. Chitosan and α-1,3-glucan were found to be important buffering molecules whose physical association with chitin maintained the wall integrity. These new findings revealed the difficult-to-understand structural principles governing fungal pathogens′ response to echinocandins and opened new avenues for designing novel antifungal agents with improved efficacy.

The fungal cell is surrounded by a thick cell wall which obviously play an essential role in the protection of the fungus against external aggressive environments. In spite of 50 years of studies, the cell wall remains poorly known and especially its constant modifications during growth as well as environmental changes is not well appreciated. This review focus on the cell wall changes seen between different fungal stages and cell populations with a specific view to explain the resistance to stresses.