Amphibian Mast Cells: Crucial Immune Sentinels Protecting Against Deadly Chytrid Fungus Infections
核心概念
Amphibian skin-resident mast cells play a critical role in conferring protection against the deadly chytrid fungus, Batrachochytrium dendrobatidis (Bd), by modulating skin inflammation, mucus production, and skin microbiome composition.
摘要
This study investigates the roles of amphibian (Xenopus laevis) mast cells in defending against the chytrid fungus, Batrachochytrium dendrobatidis (Bd), which has caused catastrophic global amphibian declines.
The key findings are:
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Xenopus mast cells possess archetypal mast cell cytology and transcriptional profiles similar to their mammalian counterparts.
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Enrichment of mast cells in frog skin confers significant protection against Bd infections, reducing fungal loads and ameliorating Bd-associated skin pathology.
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Mast cell-enriched frog skins exhibit greater mucus production, reduced neutrophil infiltration, and more stable skin microbiome composition compared to control animals during Bd infections.
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The mast cell-derived cytokine, interleukin-4 (IL4), plays a central role in mediating the protective effects against Bd, promoting skin integrity and mucus production.
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In contrast, enrichment of neutrophils in frog skin exacerbates Bd infections, suggesting that excessive inflammation can be detrimental in the context of chytrid fungus infections.
This work highlights the critical importance of skin-resident immune cells, particularly mast cells, in amphibian anti-fungal defenses and provides new insights into the complex host-pathogen interactions underlying the global amphibian biodiversity crisis.
Amphibian mast cells: barriers to chytrid fungus infections
統計資料
Mast cell-enriched frog skins possessed significantly lower Bd loads compared to control animals at both 10 and 21 days post-infection.
Mast cell-enriched, Bd-infected frog skins exhibited significantly greater mucus gland filling compared to control, Bd-infected animals.
Mast cell-enriched, Bd-infected frog skins had significantly reduced epidermal thickening compared to control, Bd-infected animals.
引述
"Enrichment of mast cells in frog skin confers significant protection against Bd infections, reducing fungal loads and ameliorating Bd-associated skin pathology."
"The mast cell-derived cytokine, interleukin-4 (IL4), plays a central role in mediating the protective effects against Bd, promoting skin integrity and mucus production."
"In contrast, enrichment of neutrophils in frog skin exacerbates Bd infections, suggesting that excessive inflammation can be detrimental in the context of chytrid fungus infections."
深入探究
How do the distinct mast cell lineages and subsets in amphibian skin differ from their mammalian counterparts, and how do these differences contribute to their unique roles in anti-fungal defenses
In amphibians, mast cells exhibit unique characteristics compared to their mammalian counterparts. While mammalian mast cells are typically found in connective tissues, amphibian mast cells are present in both epidermal and dermal layers of the skin. This localization likely reflects the more permeable nature of amphibian skin compared to mammalian skin. Additionally, amphibian mast cells in the skin possess substantial heparin content, which is a distinguishing feature from mammalian mast cells. The presence of heparin in amphibian mast cells may play a role in their immune functions and interactions with pathogens.
These differences in mast cell localization and heparin content contribute to the unique roles of amphibian mast cells in anti-fungal defenses. Amphibian skin is a critical barrier to pathogens, including chytrid fungus, and the presence of mast cells in both epidermal and dermal layers allows for rapid immune responses to invading pathogens. The heparin content in amphibian mast cells may also modulate immune responses and contribute to the regulation of inflammation in the skin. Overall, the distinct characteristics of amphibian mast cells enable them to play a crucial role in protecting against fungal infections like chytrid fungus.
What other immune mechanisms, beyond IL4 production, do amphibian mast cells employ to combat chytrid fungus infections, and how do these vary across different amphibian species
Amphibian mast cells employ a variety of immune mechanisms beyond interleukin-4 (IL4) production to combat chytrid fungus infections. These mechanisms include the production of antimicrobial peptides (AMPs) such as PGLa and magainin, which have antifungal properties. Mast cells can upregulate the expression of AMP genes in response to fungal infections, enhancing the skin's ability to fight off pathogens. Additionally, mast cells may influence the skin microbiome composition, promoting the growth of beneficial bacteria that inhibit fungal growth.
The specific immune mechanisms employed by amphibian mast cells may vary across different amphibian species. Some species may have evolved unique strategies to combat chytrid fungus infections, depending on their environmental pressures and evolutionary history. For example, certain species may have developed specialized AMPs or microbial interactions that enhance their resistance to fungal pathogens. Understanding these species-specific immune mechanisms can provide valuable insights into the diversity of anti-fungal defenses in amphibians and guide conservation efforts to protect vulnerable species.
Given the critical importance of skin-resident immune cells in amphibian health, how can this knowledge be leveraged to develop novel strategies for mitigating the global amphibian biodiversity crisis caused by chytrid fungus outbreaks
The knowledge of the critical importance of skin-resident immune cells, such as mast cells, in amphibian health can be leveraged to develop novel strategies for mitigating the global amphibian biodiversity crisis caused by chytrid fungus outbreaks. By understanding the roles of mast cells in anti-fungal defenses, researchers and conservationists can explore targeted interventions to enhance amphibian immunity and resilience to fungal infections.
One potential strategy is to investigate the manipulation of mast cell populations in amphibian skin to boost their anti-fungal defenses. This could involve techniques to enhance mast cell recruitment, activation, or production of key immune mediators like IL4 and AMPs. By modulating mast cell functions, researchers may be able to strengthen the skin barrier against chytrid fungus and reduce infection rates in vulnerable amphibian populations.
Furthermore, studying the interactions between mast cells, skin microbiota, and fungal pathogens can provide insights into how microbial communities influence amphibian health. Manipulating the skin microbiome to promote the growth of beneficial bacteria that inhibit fungal growth could be a promising avenue for developing probiotic treatments for amphibians. Overall, leveraging the knowledge of skin-resident immune cells in amphibians can lead to innovative approaches for conserving amphibian biodiversity and combating chytrid fungus outbreaks.