NsdC and NsdD Affect Aspergillus flavus Morphogenesis and Aflatoxin Production

Cary, Jeffrey W.; Harris-Coward, Pamela Y.; Ehrlich, Kenneth C.; Mack, Brian M.; Kale, Shubha P.; Larey, Christy M.; Calvo, Ana M.

doi:10.1128/ec.00069-12

Cited by 108 publications

(113 citation statements)

References 44 publications

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“…However, previous studies also have suggested that NsdD might be a potential repressor of conidiation (Han et al 2001;Cary et al 2012). For instance, overexpression of nsdD resulted in the near total absence of conidiation with formation of elongated aerial hyphae.…”

Section: Discussionmentioning

confidence: 96%

“…However, as enhanced expression of nsdD also resulted in elevated sexual development even under unfavorable conditions for sexual fruiting, it has been hypothesized that NsdD primarily functions in positively regulating sexual development rather than repressing conidiation. Additional studies in A. flavus demonstrated that the removal of nsdD resulted in elevated expression of brlA (Cary et al 2012). They found that both NsdC [another sexual activator and NsdD are required for production of asexual sclerotia, normal aflatoxin biosynthesis, and conidiophore development.…”

Section: Discussionmentioning

confidence: 99%

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NsdD Is a Key Repressor of Asexual Development inAspergillus nidulans

et al. 2014

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Asexual development (conidiation) of the filamentous fungus Aspergillus nidulans occurs via balanced activities of multiple positive and negative regulators. For instance, FluG (+) and SfgA (2) govern upstream regulation of the developmental switch, and BrlA (+) and VosA (2) control the progression and completion of conidiation. To identify negative regulators of conidiation downstream of FluG-SfgA, we carried out multicopy genetic screens using sfgA deletion strains. After visually screening .100,000 colonies, we isolated 61 transformants exhibiting reduced conidiation. Responsible genes were identified as AN3152 (nsdD), AN7507, AN2009, AN1652, AN5833, and AN9141. Importantly, nsdD, a key activator of sexual reproduction, was present in 10 independent transformants. Furthermore, deletion, overexpression, and double-mutant analyses of individual genes have led to the conclusion that, of the six genes, only nsdD functions in the FluG-activated conidiation pathway. The deletion of nsdD bypassed the need for fluG and flbA$flbE, but not brlA or abaA, in conidiation, and partially restored production of the mycotoxin sterigmatocystin (ST) in the DfluG, DflbA, and DflbB mutants, suggesting that NsdD is positioned between FLBs and BrlA in A. nidulans. Nullifying nsdD caused formation of conidiophores in liquid submerged cultures, where wild-type strains do not develop. Moreover, the removal of both nsdD and vosA resulted in even more abundant development of conidiophores in liquid submerged cultures and high-level accumulation of brlA messenger (m)RNA even at 16 hr of vegetative growth. Collectively, NsdD is a key negative regulator of conidiation and likely exerts its repressive role via downregulating brlA.T HE filamentous ascomycete Aspergillus nidulans has served as an excellent model system for studying cell biology, asexual development (conidiation), and secondary metabolism (Timberlake 1990;Martinelli 1994;Yu and Keller 2005). The A. nidulans asexual reproductive cycle can be divided into two distinct phases: growth and development. The growth phase involves germination of an asexually derived spore called a conidium and formation of an undifferentiated network of interconnected hyphal cells that form the mycelium. After a certain vegetative growth period, under appropriate conditions, some of the hyphal cells stop normal growth and begin development by forming complex structures called conidiophores that bear multiple chains of conidia (Adams et al. 1988;Park and Yu 2012a).A key and essential step for conidiophore development in Aspergillus is the activation of brlA, which encodes a C 2 H 2 zinc-finger transcription factor (TF) ( Figure 1A) (Adams et al. 1988;Chang and Timberlake 1993). Further genetic and biochemical studies identified the additional key regulators abaA and wetA that function during the middle and late stages of conidiation, respectively ( Figure 1A) (Sewall et al. 1990;Andrianopoulos and Timberlake 1991;Marshall and Timberlake 1991). These three genes have been proposed to define a c...

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Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

NsdD Is a Key Repressor of Asexual Development inAspergillus nidulans

et al. 2014

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“…Similar to VeA, NsdC modulation could participate to the morphological modifications observed in hyssop-treated cultures (Figure 3). It has also been linked to aflatoxin cluster-gene expression [51] as well as being a global regulator of secondary metabolism [52]. More data is yet to be collected on the individual and possibly collaborative roles of both of these factors in the regulation of secondary metabolism.…”

Section: Discussionmentioning

confidence: 99%

Identification of the Anti-Aflatoxinogenic Activity of Micromeria graeca and Elucidation of Its Molecular Mechanism in Aspergillus flavus

Khoury

Caceres

Puel

et al. 2017

Toxins

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Of all the food-contaminating mycotoxins, aflatoxins, and most notably aflatoxin B1 (AFB1), are found to be the most toxic and economically costly. Green farming is striving to replace fungicides and develop natural preventive strategies to minimize crop contamination by these toxic fungal metabolites. In this study, we demonstrated that an aqueous extract of the medicinal plant Micromeria graeca—known as hyssop—completely inhibits aflatoxin production by Aspergillus flavus without reducing fungal growth. The molecular inhibitory mechanism was explored by analyzing the expression of 61 genes, including 27 aflatoxin biosynthesis cluster genes and 34 secondary metabolism regulatory genes. This analysis revealed a three-fold down-regulation of aflR and aflS encoding the two internal cluster co-activators, resulting in a drastic repression of all aflatoxin biosynthesis genes. Hyssop also targeted fifteen regulatory genes, including veA and mtfA, two major global-regulating transcription factors. The effect of this extract is also linked to a transcriptomic variation of several genes required for the response to oxidative stress such as msnA, srrA, catA, cat2, sod1, mnsod, and stuA. In conclusion, hyssop inhibits AFB1 synthesis at the transcriptomic level. This aqueous extract is a promising natural-based solution to control AFB1 contamination.

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“…Such experiments include a bottom-up approach where specific genes are targeted for disruption or ectopic expression and the resulting effect on transcriptional regulation or biological processes is determined [26][27][28][29] . Other common approaches include the use of chemical treatment, environmental conditioning, host-pathogen interaction or other stimuli relevant to the investigation to identify novel genes, proteins, interactions, expression profiles, and entire processes responding to the stimuli [30][31][32][33] .…”

Section: Functional Genomics and Secondary Metabolismmentioning

confidence: 99%

“…Another global regulatory gene, nsdC, mainly known for its role in development in A. nidulans 91) , was also shown to be required for AF production in A. flavus 27) . In addition to loss of AF biosynthesis, A. flavus ΔnsdC mutants also demonstrated reduced aflatrem content compared to a control strain.…”

Section: -1 Global Regulationmentioning

confidence: 99%

<i>Aspergillus flavus</i> Secondary Metabolites: More than Just Aflatoxins

et al. 2018

Self Cite

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Aspergillus flavus is best known for producing the family of potent carcinogenic secondary metabolites known as aflatoxins. However, this opportunistic plant and animal pathogen also produces numerous other secondary metabolites, many of which have also been shown to be toxic. While about forty of these secondary metabolites have been identified from A. flavus cultures, analysis of the genome has predicted the existence of at least 56 secondary metabolite gene clusters. Many of these gene clusters are not expressed during growth of the fungus on standard laboratory media. This presents researchers with a major challenge of devising novel strategies to manipulate the fungus and its genome so as to activate secondary metabolite gene expression and allow identification of associated cluster metabolites. In this review, we discuss the genetic, biochemical and bioinformatic methods that are being used to identify previously uncharacterized secondary metabolite gene clusters and their associated metabolites. It is important to identify as many of these compounds as possible to determine their bioactivity with respect to fungal development, survival, virulence and especially with respect to any potential synergistic toxic effects with aflatoxin.

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NsdC and NsdD Affect Aspergillus flavus Morphogenesis and Aflatoxin Production

Cited by 108 publications

References 44 publications

NsdD Is a Key Repressor of Asexual Development inAspergillus nidulans

NsdD Is a Key Repressor of Asexual Development inAspergillus nidulans

Identification of the Anti-Aflatoxinogenic Activity of Micromeria graeca and Elucidation of Its Molecular Mechanism in Aspergillus flavus

<i>Aspergillus flavus</i> Secondary Metabolites: More than Just Aflatoxins

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