Submerged Conidiation and Product Formation by Aspergillus niger at Low Specific Growth Rates Are Affected in Aerial Developmental Mutants

Jørgensen, Tina; Nielsen, Kristian Fog; Arentshorst, Mark; Park, Joohae; Hondel, Cees A. M. J. J. van den; Frisvad, Jens Christian; Ram, Arthur F. J.

doi:10.1128/aem.00118-11

Cited by 32 publications

(34 citation statements)

References 48 publications

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“…By integration of data from transcriptome analysis and metabolic modeling, L. plantarum was predicted to produce plant growthstimulating metabolites, including indole compounds and phenylacetate, at (near-)zero growth rates (6). Short-term retentostat cultivation elicited significant metabolic changes in A. niger, including the production of the secondary metabolites flavasperone, aurasperone B, tensidol B, and fumonisins B 2 , B 4 , and B 6 (54). These results show that in some but not all (two of the four analyzed here) species, (near-)zero growth elicits the production of secondary metabolites.…”

Section: Energy Metabolism At (Near-)zero Growth Rates: Impact Of Maimentioning

confidence: 57%

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

Ercan

Bisschops

Overkamp

et al. 2015

Appl Environ Microbiol

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The current knowledge of the physiology and gene expression of industrially relevant microorganisms is largely based on laboratory studies under conditions of rapid growth and high metabolic activity. However, in natural ecosystems and industrial processes, microbes frequently encounter severe calorie restriction. As a consequence, microbial growth rates in such settings can be extremely slow and even approach zero. Furthermore, uncoupling microbial growth from product formation, while cellular integrity and activity are maintained, offers perspectives that are economically highly interesting. Retentostat cultures have been employed to investigate microbial physiology at (near-)zero growth rates. This minireview compares information from recent physiological and gene expression studies on retentostat cultures of the industrially relevant microorganisms Lactobacillus plantarum, Lactococcus lactis, Bacillus subtilis, Saccharomyces cerevisiae, and Aspergillus niger. Shared responses of these organisms to (near-)zero growth rates include increased stress tolerance and a downregulation of genes involved in protein synthesis. Other adaptations, such as changes in morphology and (secondary) metabolite production, were species specific. This comparison underlines the industrial and scientific significance of further research on microbial (near-)zero growth physiology. Most research in microbial physiology focuses on growing cells, although under natural and industrial conditions, microbes frequently encounter a state in which neither growth nor deterioration of cells occurs. However, the experimental design to study microbes in this clearly relevant physiological state is far from trivial.In this minireview, we define zero growth as a nongrowing state in which the viability and metabolic activity of a microbial culture are maintained for prolonged periods. As such, zero growth differs from starvation, which is coupled to cellular deterioration, loss of activity, and ultimately, cell death (1, 2). Zero growth also differs from differentiated survival states, such as bacterial or fungal spores, in which metabolism comes to a standstill (3). Conversely, under zero-growth conditions, microbes exclusively use available substrates for processes that contribute to maintenance of cellular integrity and homeostasis (4-7). Such processes include homeostasis of transmembrane gradients of protons and solutes, defense and repair systems, osmoregulation, and protein turnover (8, 9).In classical food fermentation processes, (near-)zero growth occurs during prolonged periods of extremely restricted availability of energy substrates. Examples include cheese ripening by lactic acid bacteria (LAB) (10-12), wine fermentation by Saccharomyces cerevisiae (13,14), and natto fermentation by Bacillus subtilis (15). Despite the severely energy-limiting conditions, microbes manage to survive in these processes for many weeks, while continuing to produce aroma and flavor compounds in the product matrix (10,13,15,16). Another incentive for studying...

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Section: Energy Metabolism At (Near-)zero Growth Rates: Impact Of Maimentioning

confidence: 57%

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

Ercan

Bisschops

Overkamp

et al. 2015

Appl Environ Microbiol

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“…We noticed that these two genes are very highly expressed during sclerotia formation in the A. niger sclA-1 mutant strain [73], based on RNA analysis extracted from sclerotia (Jørgenson and Ram, unpublished results). In several filamentous fungi, Tup1 functions as a global repressor which regulates genes associated with morphological differentiation, sexual and asexual reproduction, and pathogenicity [31]–[33].…”

Section: Discussionmentioning

confidence: 99%

The Transcriptional Repressor TupA in Aspergillus niger Is Involved in Controlling Gene Expression Related to Cell Wall Biosynthesis, Development, and Nitrogen Source Availability

Schachtschabel

Arentshorst²,

Nitsche³

et al. 2013

PLoS ONE

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The Tup1-Cyc8 (Ssn6) complex is a well characterized and conserved general transcriptional repressor complex in eukaryotic cells. Here, we report the identification of the Tup1 (TupA) homolog in the filamentous fungus Aspergillus niger in a genetic screen for mutants with a constitutive expression of the agsA gene. The agsA gene encodes a putative alpha-glucan synthase, which is induced in response to cell wall stress in A. niger. Apart from the constitutive expression of agsA, the selected mutant was also found to produce an unknown pigment at high temperatures. Complementation analysis with a genomic library showed that the tupA gene could complement the phenotypes of the mutant. Screening of a collection of 240 mutants with constitutive expression of agsA identified sixteen additional pigment-secreting mutants, which were all mutated in the tupA gene. The phenotypes of the tupA mutants were very similar to the phenotypes of a tupA deletion strain. Further analysis of the tupA-17 mutant and the ΔtupA mutant revealed that TupA is also required for normal growth and morphogenesis. The production of the pigment at 37°C is nitrogen source-dependent and repressed by ammonium. Genome-wide expression analysis of the tupA mutant during exponential growth revealed derepression of a large group of diverse genes, including genes related to development and cell wall biosynthesis, and also protease-encoding genes that are normally repressed by ammonium. Comparison of the transcriptome of up-regulated genes in the tupA mutant showed limited overlap with the transcriptome of caspofungin-induced cell wall stress-related genes, suggesting that TupA is not a general suppressor of cell wall stress-induced genes. We propose that TupA is an important repressor of genes related to development and nitrogen metabolism.

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“…All three isolates produced naphtho-γ-pyrones and pyranonigrin A, but the relative amounts of a polar naphtho-γ-pyrone-related compound (BMS 192548) was higher in the laeA knockout than in the WT and laeA-overexpressed strains. The naphtho-γ-pyrones are related to the black pigment in Aspergillus section Nigri conidia [19,30], but BMS 192548 may also be secreted into the medium as a yellow pigment if overproduced as in the laeA knockout.…”

Section: Morphology and Secondary Metabolite Productionmentioning

confidence: 99%

The global regulator LaeA controls production of citric acid and endoglucanases inAspergillus carbonarius

Linde

Zoglowek

Lübeck

et al. 2016

Journal of Industrial Microbiology and Biotechnology

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The global regulatory protein LaeA is known for regulating the production of many kinds of secondary metabolites in Aspergillus species, as well as sexual and asexual reproduction, and morphology. In Aspergillus carbonarius, it has been shown that LaeA regulates production of ochratoxin. We have investigated the regulatory effect of LaeA on production of citric acid and cellulolytic enzymes in A. carbonarius. Two types of A. carbonarius strains, having laeA knocked out or overexpressed, were constructed and tested in fermentation. The knockout of laeA significantly decreased the production of citric acid and endoglucanases, but did not reduce the production of beta-glucosidases or xylanases. The citric acid accumulation was reduced with 74-96 % compared to the wild type. The endoglucanase activity was reduced with 51-78 %. Overexpression of LaeA seemed not to have an effect on citric acid production or on cellulose or xylanase activity.

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Submerged Conidiation and Product Formation by Aspergillus niger at Low Specific Growth Rates Are Affected in Aerial Developmental Mutants

Cited by 32 publications

References 48 publications

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

The Transcriptional Repressor TupA in Aspergillus niger Is Involved in Controlling Gene Expression Related to Cell Wall Biosynthesis, Development, and Nitrogen Source Availability

The global regulator LaeA controls production of citric acid and endoglucanases inAspergillus carbonarius

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