The Cch1-Mid1 High-Affinity Calcium Channel Contributes to the Virulence of Cryptococcus neoformans by Mitigating Oxidative Stress.

Eukaryotic Cell Pub Date : 2015-11-01 Epub Date: 2015-09-18 DOI:10.1128/EC.00100-15
Kiem Vu, Jennifer M Bautos, Angie Gelli
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引用次数: 12

Abstract

Pathogenic fungi have developed mechanisms to cope with stresses imposed by hosts. For Cryptococcus spp., this implies active defense mechanisms that attenuate and ultimately overcome the onslaught of oxidative stresses in macrophages. Among cellular pathways within Cryptococcus neoformans' arsenal is the plasma membrane high-affinity Cch1-Mid1 calcium (Ca(2+)) channel (CMC). Here we show that CMC has an unexpectedly complex and disparate role in mitigating oxidative stress. Upon inhibiting the Ccp1-mediated oxidative response pathway with antimycin, strains of C. neoformans expressing only Mid1 displayed enhanced growth, but this was significantly attenuated upon H2O2 exposure in the absence of Mid1, suggesting a regulatory role for Mid1 acting through the Ccp1-mediated oxidative stress response. This notion is further supported by the interaction detected between Mid1 and Ccp1 (cytochrome c peroxidase). In contrast, Cch1 appears to have a more general role in promoting cryptococci survival during oxidative stress. A strain lacking Cch1 displayed a growth defect in the presence of H2O2 without BAPTA [(1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid, cesium salt] or additional stressors such as antimycin. Consistent with a greater contribution of Cch1 to oxidative stress tolerance, an intracellular growth defect was observed for the cch1Δ strain in the macrophage cell line J774A.1. Interestingly, while the absence of either Mid1 or Cch1 significantly compromises the ability of C. neoformans to tolerate oxidative stress, the absence of both Mid1 and Cch1 has a negligible effect on C. neoformans growth during H2O2 stress, suggesting the existence of a compensatory mechanism that becomes active in the absence of CMC.

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Cch1-Mid1高亲和力钙通道通过减轻氧化应激参与新生隐球菌的毒力
病原真菌已经发展出应对宿主施加的胁迫的机制。对于隐球菌来说,这意味着主动防御机制可以减弱并最终克服巨噬细胞中氧化应激的冲击。在新型隐球菌的细胞途径中,有一条高亲和力的质膜Cch1-Mid1钙(Ca(2+))通道(CMC)。在这里,我们表明CMC在减轻氧化应激方面具有出乎意料的复杂和不同的作用。在用抗霉素抑制ccp1介导的氧化反应途径后,只表达Mid1的新生C. formmans菌株的生长增强,但在没有Mid1的H2O2环境下,这种增强明显减弱,这表明Mid1通过ccp1介导的氧化应激反应发挥调节作用。Mid1和Ccp1(细胞色素c过氧化物酶)之间的相互作用进一步支持了这一观点。相比之下,Cch1似乎在促进氧化应激下隐球菌存活方面具有更普遍的作用。缺乏Cch1的菌株在没有BAPTA[(1,2-双(2-氨基苯氧基)乙烷-N,N,N',N'-四乙酸,铯盐]或抗霉素等附加胁迫源的H2O2存在下表现出生长缺陷。与Cch1对氧化应激耐受的更大贡献相一致,在巨噬细胞系J774A.1中观察到cch1Δ菌株的细胞内生长缺陷。有趣的是,虽然Mid1或Cch1的缺失会显著降低新生生物耐受氧化应激的能力,但Mid1和Cch1的缺失对新生生物在H2O2胁迫下的生长影响可以忽略不计,这表明存在一种补偿机制,在缺乏CMC的情况下变得活跃。
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Eukaryotic Cell
Eukaryotic Cell 生物-微生物学
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1 months
期刊介绍: Eukaryotic Cell (EC) focuses on eukaryotic microbiology and presents reports of basic research on simple eukaryotic microorganisms, such as yeasts, fungi, algae, protozoa, and social amoebae. The journal also covers viruses of these organisms and their organelles and their interactions with other living systems, where the focus is on the eukaryotic cell. Topics include: - Basic biology - Molecular and cellular biology - Mechanisms, and control, of developmental pathways - Structure and form inherent in basic biological processes - Cellular architecture - Metabolic physiology - Comparative genomics, biochemistry, and evolution - Population dynamics - Ecology
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