cell wall remodeling

Is Cryptococcus neoformans a pleomorphic fungus?

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Researchers have discovered that Cryptococcus neoformans, a dangerous fungus that causes serious infections, is actually much more shape-shifting than previously thought. Instead of existing as just one simple budding yeast form, the fungus can transform into several different cell types including large ‘titan cells’ and small ‘seed cells,’ each with different characteristics that help it survive and spread in the body. These different forms have distinct genetic programs and can evade the immune system in different ways, making the infection harder to treat. This discovery fundamentally changes how scientists understand this pathogen and could lead to new treatment strategies.

Acidic pH Modulates Cell Wall and Melanization in Paracoccidioides brasiliensis, Affecting Macrophage Interaction

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A dangerous fungal infection called paracoccidioidomycosis affects people in Latin America. Researchers found that when this fungus encounters acidic conditions similar to those inside immune cells in the body, it protects itself by producing a dark pigment called melanin and changing its cell surface. These changes help the fungus hide from the immune system and reduce the ability of immune cells called macrophages to attack and destroy it.

Is Cryptococcus neoformans a pleomorphic fungus?

mycolabadmin

Cryptococcus neoformans is a dangerous fungal pathogen that causes serious infections in humans. For many years, scientists thought this fungus existed primarily as regular yeast cells. However, new research shows the fungus can change into several different cell forms during infection, including larger ‘titan cells’ and smaller ‘seed cells.’ These shape-shifting abilities help the fungus survive in the human body and evade immune responses, making infections harder to treat.

Deubiquitinase Ubp5 is essential for pulmonary immune evasion and hematogenous dissemination of Cryptococcus neoformans

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This study shows that removing a fungal enzyme called Ubp5 from Cryptococcus neoformans significantly weakens the fungus and allows the body’s immune system to fight the infection more effectively. The fungus without Ubp5 loses its ability to hide from the immune system, triggering stronger protective immune responses including more T cells and beneficial inflammatory signals. This research suggests that targeting Ubp5 could be a promising strategy to help treat cryptococcal infections by enhancing the body’s natural defense mechanisms.

Hyphal swelling induced in the phagosome of macrophages

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When Candida albicans yeast cells are engulfed by immune cells called macrophages, they transform into thread-like hyphae. Researchers discovered that these hyphae sometimes develop swollen, bulbous compartments rather than maintaining their normal shape. Surprisingly, these swollen fungal cells survive much better inside the hostile macrophage environment than normal-shaped hyphae. This swelling appears to be a clever survival strategy that helps the fungus resist being killed by the immune system.

Revealing structure and shaping priorities in plant and fungal cell wall architecture via solid-state NMR

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This review explains how scientists use a special type of microscopy called solid-state NMR to study the protective outer layers of fungi and plants. The research shows that fungal pathogens can cleverly rearrange their cell walls to resist antifungal medicines, and that plants carefully organize their cell walls during growth by forming specific connections between different molecules. Understanding these structures at the molecular level could help develop better antifungal treatments and improve how we use plant biomass for biofuels and materials.

Cell walls of filamentous fungi – challenges and opportunities for biotechnology

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Filamentous fungi like Aspergillus and Trichoderma are workhorses of the biotechnology industry, producing enzymes and pharmaceuticals worth billions annually. The cell wall surrounding these fungal cells acts as both a barrier and a filter, affecting how well proteins can be secreted into the fermentation medium. By genetically modifying cell wall components, scientists can improve enzyme production efficiency. Additionally, the billions of tons of fungal biomass left over from fermentation contain valuable chitin and chitosan that could be extracted and reused, creating a more sustainable manufacturing process.

The Gcn5 lysine acetyltransferase mediates cell wall remodeling, antifungal drug resistance, and virulence of Candida auris

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Candida auris is a dangerous fungal infection that resists many standard antifungal drugs. Researchers discovered that a protein called Gcn5 helps this fungus survive both drugs and the body’s immune system. By targeting Gcn5 with a new compound called CPTH2, scientists showed they could make the fungus more vulnerable to standard treatments like caspofungin, suggesting a promising new approach to fighting these infections.

Breaking down the wall: Solid-state NMR illuminates how fungi build and remodel diverse cell walls

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Scientists have developed a new technique called solid-state NMR that can examine fungal cell walls without damaging them, revealing how these structures are built and reorganized. This research shows that different fungi have different wall architectures made of sugar-like molecules including chitin and various glucans, and that fungi can quickly adapt their walls when exposed to antifungal drugs. These findings could help develop better antifungal treatments by targeting the specific structural features that different fungi rely on for survival.

Differential hypo-osmotic stress responses and regulatory mechanisms of Aspergillus sydowii in amphipod guts and hadal sediments

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Scientists isolated a fungus from the gut of deep-sea amphipods in the Mariana Trench and discovered how it uniquely adapts to low-salt conditions. Unlike other fungal strains from different habitats, this gut fungus showed special abilities to survive and even thrive when salt levels dropped dramatically. The researchers found that the fungus rapidly rewired its genes and cellular structures to maintain water balance and protect itself, revealing how life in extreme deep-sea environments drives evolution of novel survival strategies.

Research Keyword: cell wall remodeling