Aquaporin1 regulates development, secondary metabolism and stress responses in Fusarium graminearum

Ding, Mingyu; Li, Jing; Fan, Xinyue; He, Fang; Yu, Xiaoyang; Chen, Lei; Zou, Shenshen; Liang, Yan; Yu, Jinfeng

doi:10.1007/s00294-018-0818-8

Cited by 19 publications

(10 citation statements)

References 61 publications

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“…Transcript levels for each gene were normalized against the tubulin beta chain gene FFUJ_04397 (CCGGTGCTGGAAACAACTG vs CGAGGACCTGGTCGACAAGT, 69 bp) and the glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene FFUJ_13490 (GTGACCTCAAGGGCGTTCTG vs CGAAGATGGAGTTTGTGTT, 84 bp). FFUJ_04397 was used as a reference gene for constitutive expression in former RT-qPCR studies in Fusarium fujikuroi (see, e.g., [19, 21, 23, 28, 35]), and the GAPDH gene was recently used as an internal control in RT-qPCR studies in F. graminearum [55, 56].…”

Section: Methodsmentioning

confidence: 99%

Comparative transcriptomic analysis unveils interactions between the regulatory CarS protein and light response in Fusarium

et al. 2019

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BackgroundThe orange pigmentation of the agar cultures of many Fusarium species is due to the production of carotenoids, terpenoid pigments whose synthesis is stimulated by light. The genes of the carotenoid pathway and their regulation have been investigated in detail in Fusarium fujikuroi. In this and other Fusarium species, such as F. oxysporum, deep-pigmented mutants affected in the gene carS, which encodes a protein of the RING-finger family, overproduce carotenoids irrespective of light. The induction of carotenogenesis by light and its deregulation in carS mutants are achieved on the transcription of the structural genes of the pathway. We have carried out global RNA-seq transcriptomics analyses to investigate the relationship between the regulatory role of CarS and the control by light in these fungi.ResultsThe absence of a functional carS gene or the illumination exert wide effects on the transcriptome of F. fujikuroi, with predominance of genes activated over repressed and a greater functional diversity in the case of genes induced by light. The number of the latter decreases drastically in a carS mutant (1.1% vs. 4.8% in the wild-type), indicating that the deregulation produced by the carS mutation affects the light response of many genes. Moreover, approximately 27% of the genes activated at least 2-fold by light or by the carS mutation are coincident, raising to 40% for an 8-fold activation threshold. As expected, the genes with the highest changes under both regulatory conditions include those involved in carotenoid metabolism. In addition, light and CarS strongly influence the expression of some genes associated with stress responses, including three genes with catalase domains, consistent with roles in the control of oxidative stress. The effects of the CarS mutation or light in the transcriptome of F. oxysporum were partially coincident with those of F. fujikuroi, indicating the conservation of the objectives of their regulatory mechanisms.ConclusionsThe CarS RING finger protein down-regulates many genes whose expression is up-regulated by light in wild strains of the two investigated Fusarium species, indicating a regulatory interplay between the mechanism of action of the CarS protein and the control by light.Electronic supplementary materialThe online version of this article (10.1186/s12864-019-5430-x) contains supplementary material, which is available to authorized users.

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Section: Methodsmentioning

confidence: 99%

Comparative transcriptomic analysis unveils interactions between the regulatory CarS protein and light response in Fusarium

et al. 2019

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“…DON can interfere with normal cellular functions through inhibition of protein translation by binding to the ribosomes. In F. graminearum, the AQP protein FgAQP1 localized at the nuclear membrane was crucial for hyphal growth, sexual and asexual development, stress responses, and secondary metabolism [24]. The deletion of FgAQP1 significantly affected DON production and the expression of related genes, indicating that FgAQP1 may play key roles in F. graminearum-host interaction (Figure 2).…”

Section: Aqps Regulation Of Fungal Pathogen Pathogenicitymentioning

confidence: 99%

“…Some microbes, such as bacteria, show less aquaporin diversity, typically possessing only one or two AQP genes, and the absence of such genes has not revealed any definite phenotype [1]. Moreover, AQP-deletion mutants have also been studied in Botrytis cinerea and Fusarium graminearum, respectively, suggesting that AQPs also have important roles in growth, development, secondary metabolism, and pathogenicity of fungal pathogens [5,24].…”

Section: Introductionmentioning

confidence: 99%

Roles of Aquaporins in Plant-Pathogen Interaction

Chen

Zhang

et al. 2020

Plants

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Aquaporins (AQPs) are a class of small, membrane channel proteins present in a wide range of organisms. In addition to water, AQPs can facilitate the efficient and selective flux of various small solutes involved in numerous essential processes across membranes. A growing body of evidence now shows that AQPs are important regulators of plant-pathogen interaction, which ultimately lead to either plant immunity or pathogen pathogenicity. In plants, AQPs can mediate H2O2 transport across plasma membranes (PMs) and contribute to the activation of plant defenses by inducing pathogen-associated molecular pattern (PAMP)-triggered immunity and systemic acquired resistance (SAR), followed by downstream defense reactions. This involves the activation of conserved mitogen-activated protein kinase (MAPK) signaling cascades, the production of callose, the activation of NPR1 and PR genes, as well as the opening and closing of stomata. On the other hand, pathogens utilize aquaporins to mediate reactive oxygen species (ROS) signaling and regulate their normal growth, development, secondary or specialized metabolite production and pathogenicity. This review focuses on the roles of AQPs in plant immunity, pathogenicity, and communications during plant-pathogen interaction.

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“…These channels facilitate the transport of water and a variety of small molecules across biological membranes, the plasmalemic and the endomembrane system, of unicellular and multicellular organisms [19]. In filamentous fungi, preliminary evidence shows that MIPs are involved in the regulation of hyphal growth, sclerotia formation, conidiation, spore germination, virulence, secondary metabolisms, and the transport of various molecules [20][21][22][23][24][25]. In this respect, the impact of transcriptional and protein regulation of MIPs on the fungus' life cycle remains a fascinating area that deserves further exploration.…”

Section: Introductionmentioning

confidence: 99%

“…In silico analysis showed that fungal XIP transports water and possibly other small polar molecules like H 2 O 2 , but intriguingly, not glycerol concerning the plant counterparts. However, unlike some AQPs or AQGPs from fungi that have been functionally characterized [21,23,25,36], knowledge of XIP 3D structure, expression and physiological roles is still hypothetical. Thus, a fungal XIP prototype needs to be considered carefully.…”

Section: Introductionmentioning

confidence: 99%

Fungal X-Intrinsic Protein Aquaporin from Trichoderma atroviride: Structural and Functional Considerations

et al. 2021

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The major intrinsic protein (MIP) superfamily is a key part of the fungal transmembrane transport network. It facilitates the transport of water and low molecular weight solutes across biomembranes. The fungal uncharacterized X-Intrinsic Protein (XIP) subfamily includes the full protein diversity of MIP. Their biological functions still remain fully hypothetical. The aim of this study is still to deepen the diversity and the structure of the XIP subfamily in light of the MIP counterparts—the aquaporins (AQPs) and aquaglyceroporins (AQGPs)—and to describe for the first time their function in the development, biomass accumulation, and mycoparasitic aptitudes of the fungal bioagent Trichoderma atroviride. The fungus-XIP clade, with one member (TriatXIP), is one of the three clades of MIPs that make up the diversity of T. atroviride MIPs, along with the AQPs (three members) and the AQGPs (three members). TriatXIP resembles those of strict aquaporins, predicting water diffusion and possibly other small polar solutes due to particularly wider ar/R constriction with a Lysine substitution at the LE2 position. The XIP loss of function in ∆TriatXIP mutants slightly delays biomass accumulation but does not impact mycoparasitic activities. ∆TriatMIP forms colonies similar to wild type; however, the hyphae are slightly thinner and colonies produce rare chlamydospores in PDA and specific media, most of which are relatively small and exhibit abnormal morphologies. To better understand the molecular causes of these deviant phenotypes, a wide-metabolic survey of the ∆TriatXIPs demonstrates that the delayed growth kinetic, correlated to a decrease in respiration rate, is caused by perturbations in the pentose phosphate pathway. Furthermore, the null expression of the XIP gene strongly impacts the expression of four expressed MIP-encoding genes of T. atroviride, a plausible compensating effect which safeguards the physiological integrity and life cycle of the fungus. This paper offers an overview of the fungal XIP family in the biocontrol agent T. atroviride which will be useful for further functional analysis of this particular MIP subfamily in vegetative growth and the environmental stress response in fungi. Ultimately, these findings have implications for the ecophysiology of Trichoderma spp. in natural, agronomic, and industrial systems.

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Aquaporin1 regulates development, secondary metabolism and stress responses in Fusarium graminearum

Cited by 19 publications

References 61 publications

Comparative transcriptomic analysis unveils interactions between the regulatory CarS protein and light response in Fusarium

Comparative transcriptomic analysis unveils interactions between the regulatory CarS protein and light response in Fusarium

Roles of Aquaporins in Plant-Pathogen Interaction

Fungal X-Intrinsic Protein Aquaporin from Trichoderma atroviride: Structural and Functional Considerations

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