fungal infections – Page 15

Changing Climate, Changing Candida: Environmental and Social Pressures on Invasive Candidiasis and Antifungal Resistance in Latin America

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Invasive fungal infections caused by Candida species are becoming increasingly common and dangerous in Latin American hospitals, with newer strains showing resistance to multiple antifungal drugs. Rising temperatures from climate change and widespread use of fungicides in agriculture appear to be selecting for these resistant fungi. Most hospitals in the region lack advanced diagnostic tools to quickly identify which fungal strain is causing infection, leading to delayed and sometimes inappropriate treatment. Implementing better diagnostic access, stricter antifungal use policies, and coordinated surveillance programs across the region could help control this growing public health problem.

Editorial: Dermatopathology and Associated Laboratory Investigations in the Study of Skin Disease

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This special journal issue brings together several studies on how doctors diagnose skin diseases using laboratory tests. The papers cover different methods including examining fungal infections under a microscope, using new staining techniques, and applying molecular tests to identify skin cancers and autoimmune conditions. Together, these studies show how combining pathology examination with laboratory techniques is essential for accurately diagnosing and treating various skin disorders.

Species-specific circular RNA circDS-1 enhances adaptive evolution in Talaromyces marneffei through regulation of dimorphic transition

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Researchers discovered a special type of RNA called circDS-1 that helps a deadly fungus switch between two different forms depending on temperature. This fungus normally grows as a mold in soil but transforms into a yeast when it infects humans at body temperature. The circDS-1 RNA acts like a molecular switch that controls this transformation and helps the fungus cause infection. This discovery reveals that fungi may use hidden genetic elements beyond traditional genes to adapt to their environment.

The transcription factor RttA contributes to sterol regulation and azole resistance in Aspergillus fumigatus

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Researchers corrected the mislabeled rttA gene in the dangerous fungus Aspergillus fumigatus and discovered it acts as a master control switch for sterol production and antifungal drug resistance. When this gene is active, it helps fungi survive azole medications by boosting production of ergosterol, a critical component of fungal cell membranes. This discovery reveals how fungi develop resistance to our frontline antifungal treatments and suggests new ways to combat these life-threatening infections.

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.

Improving treatment of chromoblastomycosis: the potential of COP1T-HA and antimicrobial photodynamic therapy against Fonsecaea monophora in vitro

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Chromoblastomycosis is a stubborn skin fungal infection that is difficult to treat with current medications and often comes back after treatment. Researchers tested a new treatment using a special light-activated compound called COP1T-HA combined with blue light, which successfully killed the fungus in laboratory tests. The treatment worked quickly and at low doses, showing promise as a potential new therapy for this challenging infection.

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.

Cytophysiological manifestations of wheat’s defense reactions against stem rust induced by the biofungicide Novochizol

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Scientists studied how a new plant-based product called Novochizol helps wheat plants defend themselves against stem rust, a destructive fungal disease. When wheat seedlings were treated with Novochizol before being exposed to the rust fungus, the plants showed strong defensive reactions including increased production of protective hydrogen peroxide and phenolic compounds. The treatment significantly reduced the number and size of rust pustules (infection spots) on susceptible wheat plants, effectively converting them to a more resistant state without harming the plants.

The fungal STRIPAK complex: Cellular conductor orchestrating growth and pathogenicity

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The STRIPAK complex is a cellular control hub found in fungi that acts like a conductor orchestrating multiple cellular processes essential for fungal growth and the ability to cause disease. Scientists have discovered that this complex is highly conserved across different fungal species and regulates critical virulence factors like melanin production and capsule formation in pathogenic fungi. Because the fungal version differs from the human version, it presents a promising target for developing selective antifungal medications. Understanding how STRIPAK works provides insights into how fungi cause infections and could lead to new treatment strategies.

The protein kinases family in fungi: adaptability, virulence and conservation between species

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Protein kinases are cellular ‘switches’ that help fungi survive harsh conditions by regulating how cells make proteins and adapt to stress. A particularly important kinase called GCN2 acts as a sensor that detects when fungi lack amino acids, triggering a survival response that helps the fungus adapt and maintain pathogenicity. This review shows how understanding GCN2 could help scientists develop new antifungal drugs to treat fungal infections.

Disease: fungal infections