Oxidative Stress-Related Transcription Factors in the Regulation of Secondary Metabolism

Hong, Seongjin; Roze, Ludmila V.; Linz, John E.

doi:10.3390/toxins5040683

Cited by 149 publications

(122 citation statements)

References 89 publications

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“…While the redox activity of 1-Me-PHZ can modulate Aspergillus development, PCA and 1-OH-PHZ have been reported to differentially affect Aspergillus siderophore production [16], suggesting that metabolite conversions by neighboring microbes can affect mixed-species biofilms in multiple ways. Pertinent to these findings, fungal secondary metabolism (including siderophore production) and oxidative stress response have been recently implied to be co-regulated in a highly coordinated manner by NapA and another bZIP protein, AtfB [27, 49]. Going forward, it will be of interest to explore whether phenazines (and other redox metabolites) can also direct Aspergillus secondary metabolism via the active oxidative stress response.…”

Section: Discussionmentioning

confidence: 99%

Redox Metabolites Signal Polymicrobial Biofilm Development via the NapA Oxidative Stress Cascade in Aspergillus

et al. 2015

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Summary Background Filamentous fungi and bacteria form mixed-species biofilms in nature and diverse clinical contexts. They secrete a wealth of redox-active small molecule secondary metabolites, which are traditionally viewed as toxins that inhibit growth of competing microbes. Results Here we report that these “toxins” can act as interspecies signals, affecting filamentous fungal development via oxidative stress regulation. Specifically, in co-culture biofilms, Pseudomonas aeruginosa phenazine-derived metabolites differentially modulated Aspergillus fumigatus development, shifting from weak vegetative growth to induced asexual sporulation (conidiation) along a decreasing phenazine gradient. The A. fumigatus morphological shift correlated with the production of phenazine radicals and concomitant reactive oxygen species (ROS) production generated by phenazine redox cycling. Phenazine conidiation signaling was conserved in the genetic model A. nidulans, and mediated by NapA, a homolog of AP-1-like bZIP transcription factor, which is essential for the response to oxidative stress in humans, yeast, and filamentous fungi. Expression profiling showed phenazine treatment induced a NapA-dependent response of the global oxidative stress metabolome including the thioredoxin, glutathione and NADPH-oxidase systems. Conidiation induction in A. nidulans by another microbial redox-active secondary metabolite, gliotoxin, also required NapA. Conclusions This work highlights that microbial redox metabolites are key signals for sporulation in filamentous fungi, which are communicated through an evolutionarily conserved eukaryotic stress response pathway. It provides a foundation for interspecies signaling in environmental and clinical biofilms involving bacteria and filamentous fungi.

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Section: Discussionmentioning

confidence: 99%

Redox Metabolites Signal Polymicrobial Biofilm Development via the NapA Oxidative Stress Cascade in Aspergillus

et al. 2015

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“…Secondary metabolism, such as pigments production, is triggered and intensified by ROS build‐up, with pigments being important for protecting the fungi against stress conditions (Cho et al ., 2012; Hong et al ., 2013). In the absence of MrMsn2 aggravated pigmentation and pigment synthesis‐associated genes were significantly upregulated during conidiation in ▵MrMsn2 mutants.…”

Section: Discussionmentioning

confidence: 99%

“…As the core of signalling pathway, fungal TFs are important for transcriptional regulation of gene expression during cellular growth, secondary metabolism, stress responses and pathogenesis (Klug, 2010; Hong et al ., 2013; Liu et al ., 2013; Marinho et al ., 2014; Zhang et al ., 2014; Huang et al ., 2015; Shelest, 2017; Yin et al ., 2017; Song et al ., 2018). …”

Section: Introductionmentioning

confidence: 99%

A transcription factor, MrMsn2, in the dimorphic fungus Metarhizium rileyi is essential for dimorphism transition, aggravated pigmentation, conidiation and microsclerotia formation

Song

Yang

Xin

et al. 2018

Microbial Biotechnology

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SummaryMicrosclerotia (MS) are pseudoparenchymatous aggregations of hyphae of fungi that can be induced in liquid culture for biocontrol applications. Previously, we determined that the high‐osmolarity glycerol (HOG) signalling pathway was involved in regulating MS development in the dimorphic insect pathogen Metarhizium rileyi. To further investigate the mechanisms by which the signalling pathway is regulated, we characterized the transcriptional factor MrMsn2, a homologue of the yeast C2H2 transcriptional factor Msn2, which is predicted to function downstream of the HOG pathway in M. rileyi. Compared with wild‐type and complemented strains, disruption of MrMsn2 increased the yeast‐to‐hypha transition rate, enhanced conidiation capacity and aggravated pigmentation in M. rileyi. The ▵MrMsn2 mutants were sensitive to stress, produced morphologically abnormal clones and had significantly reduced MS formation and decreased virulence levels. Digital expression profiling revealed that genes involved in antioxidation, pigment biosynthesis and ion transport and storage were regulated by MrMsn2 during conidia and MS development. Taken together, our findings confirm that MrMsn2 controlled the yeast‐to‐hypha transition, conidia and MS formation, and virulence.

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“…Disruption in the AF biosynthetic pathway at an early, middle, or late steps, affected quantities of detected ROS (Roze et al, 2015). AF production apparently could direct the ROS excess accumulated during cell ageing, or as a response to external insults, into extending the fungal lifespan (Hong et al, 2013). AFB 1 biosynthesis is controlled by a wider array of oxidative stress factors, such as lipid hydroperoxide, superoxide, and hydroxyl and thiol radicals (Grintzalis et al, 2014).…”

Section: Environmental Factors Affecting Aflatoxin Biosynthesismentioning

confidence: 99%

Aflatoxins: biosynthesis, prevention and eradication

Šimončicová

Kaliňáková

Kryštofová

2017

Acta Chimica Slovaca

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Filamentous fungi belonging to Aspergilli genera produce many compounds through various biosynthetic pathways. These compounds include a spectrum of products with beneficial medical properties (lovastatin) as well as those that are toxic and/or carcinogenic which are called mycotoxins. Aspergillus flavus, one of the most abundant soil-borne fungi, is a saprobe that is able growing on many organic nutrient sources, such as peanuts, corn and cotton seed. In many countries, food contamination by A. flavus is a huge problem, mainly due to the production of the most toxic and carcinogenic compounds known as aflatoxins. In this paper, we briefly cover current progress in aflatoxin biosynthesis and regulation, pre-and postharvest preventive measures, and decontamination procedures.

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Oxidative Stress-Related Transcription Factors in the Regulation of Secondary Metabolism

Cited by 149 publications

References 89 publications

Redox Metabolites Signal Polymicrobial Biofilm Development via the NapA Oxidative Stress Cascade in Aspergillus

Redox Metabolites Signal Polymicrobial Biofilm Development via the NapA Oxidative Stress Cascade in Aspergillus

A transcription factor, MrMsn2, in the dimorphic fungus Metarhizium rileyi is essential for dimorphism transition, aggravated pigmentation, conidiation and microsclerotia formation

Aflatoxins: biosynthesis, prevention and eradication

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