Phosphopantetheinyl Transferase CfwA/NpgA Is Required for
            <i>Aspergillus nidulans</i>
            Secondary Metabolism and Asexual Development

Márquez-Fernández, Olivia; Trigos, Ángel; Ramos-Balderas, Jose Luis; Viniegra‐González, Gustavo; Deising, H. B.; Aguirre, Jesús

doi:10.1128/ec.00362-06

Cited by 74 publications

(91 citation statements)

References 67 publications

(86 reference statements)

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“…In this fungus, asexual reproduction (conidiation) is induced by environmental signals such as exposure to air (2,16,69), nutrient starvation (66), and selfgenerated signals (39,43,65,67,70). The mechanisms by which these signals are perceived and transduced are not well understood.…”

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confidence: 99%

Response Regulators SrrA and SskA Are Central Components of a Phosphorelay System Involved in Stress Signal Transduction and Asexual Sporulation in Aspergillus nidulans

et al. 2007

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Among eukaryotes, only slime molds, fungi, and plants contain signal transduction phosphorelay systems. In filamentous fungi, multiple sensor kinases appear to use a single histidine-containing phosphotransfer (HPt) protein to relay signals to two response regulators (RR). In Aspergillus nidulans, the RR SskA mediates activation of the mitogen-activated protein kinase SakA in response to osmotic and oxidative stress, whereas the functions of the RR SrrA were unknown. We used a genetic approach to characterize the srrA gene as a new member of the skn7/prr1 family and to analyze the roles of SrrA in the phosphorelay system composed of the RR SskA, the HPt protein YpdA, and the sensor kinase NikA. While mutants lacking the HPt protein YpdA are unviable, mutants lacking SskA (⌬sskA), SrrA (⌬srrA), or both RR (⌬srrA ⌬sskA) are viable and differentially affected in osmotic and oxidative stress responses. Both RR are involved in osmostress resistance, but ⌬sskA mutants are more sensitive to this stress, and only SrrA is required for H 2 O 2 resistance and H 2 O 2 -mediated induction of catalase CatB. In contrast, both RR are individually required for fungicide sensitivity and calcofluor resistance and for normal sporulation and conidiospore viability. The ⌬srrA and ⌬sskA sporulation defects appear to be related to decreased mRNA levels of the key sporulation gene brlA. In contrast, conidiospore viability defects do not correlate with the activity of the spore-specific catalase CatA. Our results support a model in which NikA acts upstream of SrrA and SskA to transmit fungicide signals and to regulate asexual sporulation and conidiospore viability. In contrast, NikA appears dispensable for osmotic and oxidative stress signaling. These results highlight important differences in stress signal transmission among fungi and define a phosphorelay system involved in oxidative and osmotic stress, cell wall maintenance, fungicide sensitivity, asexual reproduction, and spore viability.

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Response Regulators SrrA and SskA Are Central Components of a Phosphorelay System Involved in Stress Signal Transduction and Asexual Sporulation in Aspergillus nidulans

et al. 2007

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“…Our own genomic analyses suggest that this number may be a slight overestimate (because more than one polyketide synthase [PKS] and/or nonribosomal peptide synthetase may be involved in a single pathway), but clearly A. nidulans has the ability to synthesize many secondary metabolites. Only a limited number of secondary metabolites in A. nidulans have been identified (aspyridones A and B [from a single pathway], aspoquinolones A to D [probably products of a single pathway], penicillin, asperlin, sterigmatocystin, triacetylfusarinine, ferricrocin, shamixanthone, variecoxanthone, terrequinone A, emericellin, dehydroaustinol, and the sterols, ergosterol, peroxiergosterol, and cerevisterol [3,15,20]). It follows that the majority of A. nidulans secondary metabolites remain to be identified.…”

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Identification and Characterization of the Asperthecin Gene Cluster of Aspergillus nidulans

Szewczyk

Chiang

Oakley

et al. 2008

Appl Environ Microbiol

155

165

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The sequencing of Aspergillus genomes has revealed that the products of a large number of secondary metabolism pathways have not yet been identified. This is probably because many secondary metabolite gene clusters are not expressed under normal laboratory culture conditions. It is, therefore, important to discover conditions or regulatory factors that can induce the expression of these genes. We report that the deletion of sumO, the gene that encodes the small ubiquitin-like protein SUMO in A. nidulans, caused a dramatic increase in the production of the secondary metabolite asperthecin and a decrease in the synthesis of austinol/ dehydroaustinol and sterigmatocystin. The overproduction of asperthecin in the sumO deletion mutant has allowed us, through a series of targeted deletions, to identify the genes required for asperthecin synthesis. The asperthecin biosynthesis genes are clustered and include genes encoding an iterative type I polyketide synthase, a hydrolase, and a monooxygenase. The identification of these genes allows us to propose a biosynthetic pathway for asperthecin.Secondary metabolites are a remarkably rich source of medically useful compounds. A survey of the literature on 1,500 secondary metabolites isolated and characterized between 1993 and 2001 revealed that over half of these compounds have antibacterial, antifungal, or antitumor activity (19). Fungal secondary metabolites, in particular, include a number of important compounds, such as penicillin, cephalosporin, the antihypercholesterolemic agent lovastatin and other statins, and immunosuppressants such as cyclosporine, as well as antifungals (reviewed in references 3, 13, 16, and 19). Other fungal secondary metabolites are important not for their benefits but rather for the problems they cause. For example, the carcinogenic toxins aflatoxin and sterigmatocystin are produced by members of the genus Aspergillus (see references 7, 28, and 29 and earlier references therein; reviewed additionally in references 1 and 26).The sequencing of fungal genomes has revealed several important things about fungal secondary metabolism. First, as was suspected from the results of previous work (13), the genes of pathways that produce particular secondary metabolites are often clustered together (10, 14, 18). Second, fungi have many more secondary metabolism pathways than was previously thought. Analyses of the A. nidulans genome, for example, indicate that A. nidulans has 50 clusters that are predicted to synthesize secondary metabolites (27 polyketides, 14 nonribosomal peptides, 6 fatty acids, 1 terpene, and 2 indole alkaloids) (3, 18). Our own genomic analyses suggest that this number may be a slight overestimate (because more than one polyketide synthase [PKS] and/or nonribosomal peptide synthetase may be involved in a single pathway), but clearly A. nidulans has the ability to synthesize many secondary metabolites. Only a limited number of secondary metabolites in A. nidulans have been identified (aspyridones A and B [from a single pathway], aspoqui...

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“…FlbA is a regulator of a heterotrimeric G protein signaling pathway that stimulates vegetative growth and inhibits conidiation (83). In contrast, FluG is responsible for the production of an extracellular signaling factor required for activation of the flbD-E genes in vegetative cells and to induce conidiation, along with other unidentified compounds (38,39,44,56,64). FlbB is a TF of the bZIP type that unexpectedly also localizes at the hyphal tips of vegetative hyphae, forming a complex with FlbE (17,18,21).…”

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confidence: 99%

“…nidulans asexual reproduction is induced by environmental signals such as exposure to air (2,70) or nutrient starvation (63). It involves the production of chemical signals (9,25,38,40,44,64,72) and depends on activation of the brlA gene (10), which encodes a transcription factor (TF) of the Zn finger family (1,29,48,54). Normally, conidiation involves the production of a mycelial cell compartment, from which a conidiophore stalk develops.…”

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FlbD, a Myb Transcription Factor of Aspergillus nidulans, Is Uniquely Involved in both Asexual and Sexual Differentiation

et al. 2012

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ABSTRACTIn the fungusAspergillus nidulans, inactivation of theflbAto-E,fluG,fluF, andtmpAgenes results in similar phenotypes, characterized by a delay in conidiophore and asexual spore production.flbBto-Dencode transcription factors needed for proper expression of thebrlAgene, which is essential for asexual development. However, recent evidence indicates that FlbB and FlbE also have nontranscriptional functions. Here we show thatfluF1is an allele offlbDwhich results in an R47P substitution. Amino acids C46 and R47 are highly conserved in FlbD and many other Myb proteins, and C46 has been proposed to mediate redox regulation. Comparison of ΔflbDandflbDR47Pmutants uncovered a new and specific role forflbDduring sexual development. WhileflbDR47Pmutants retain partial function during conidiation, bothΔflbDandflbDR47Pmutants are unable to develop the peridium, a specialized external tissue that differentiates during fruiting body formation and ends up surrounding the sexual spores. This function, unique among otherfluffygenes, does not affect the viability of the naked ascospores produced by mutant strains. Notably, ascospore development in these mutants is still dependent on the NADPH oxidase NoxA. We generated R47K, C46D, C46S, and C46A mutant alleles and evaluated their effects on asexual and sexual development. Conidiation defects were most severe inΔflbDmutants and stronger in R47P, C46D, and C46S strains than in R47K strains. In contrast, mutants carrying theflbDC46Aallele exhibited conidiation defects in liquid culture only under nitrogen starvation conditions. The R47K, R47P, C46D, and C46S mutants failed to develop any peridial tissue, while theflbDC46Astrain showed normal peridium development and increased cleistothecium formation. Our results show that FlbD regulates both asexual and sexual differentiation, suggesting that both processes require FlbD DNA binding activity and that FlbD is involved in the response to nitrogen starvation.

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Phosphopantetheinyl Transferase CfwA/NpgA Is Required for Aspergillus nidulans Secondary Metabolism and Asexual Development

Cited by 74 publications

References 67 publications

Response Regulators SrrA and SskA Are Central Components of a Phosphorelay System Involved in Stress Signal Transduction and Asexual Sporulation in Aspergillus nidulans

Response Regulators SrrA and SskA Are Central Components of a Phosphorelay System Involved in Stress Signal Transduction and Asexual Sporulation in Aspergillus nidulans

Identification and Characterization of the Asperthecin Gene Cluster of Aspergillus nidulans

FlbD, a Myb Transcription Factor of Aspergillus nidulans, Is Uniquely Involved in both Asexual and Sexual Differentiation

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