A Myb transcription factor represses conidiation and cephalosporin C production in Acremonium chrysogenum.

Acremonium chrysogenum is the industrial producer of cephalosporin C (CPC). We isolated a mutant (AC554) from a T-DNA inserted mutant library of A. chrysogenum. AC554 exhibited a reduced conidiation and lack of CPC production. In consistent with it, the transcription of cephalosporin biosynthetic genes pcbC and cefEF was significantly decreased in AC554. Thermal asymmetric interlaced polymerase chain reaction (TAIL-PCR) was performed and sequence analysis indicated that a T-DNA was inserted upstream of an open reading frame (ORF) which was designated AcmybA. On the basis of sequence analysis, AcmybA encodes a Myb domain containing transcriptional factor. Observation of red fluorescent protein (RFP) tagged AcMybA showed that AcMybA is naturally located in the nucleus of A. chrysogenum. Transcriptional analysis demonstrated that the AcmybA transcription was increased in AC554. In contrast, the AcmybA deleted mutant (ΔAcmybA) overproduced conidia and CPC. To screen the targets of AcmybA, we sequenced and compared the transcriptome of ΔAcmybA, AC554 and the wild-type strain at different developmental stages. Twelve differentially expressed regulatory genes were identified. Taken together, our results indicate that AcMybA negatively regulates conidiation and CPC production in A. chrysogenum.

Antioxidant Activity of Water Extract from Fermented Mycelia of Cordyceps sobolifera (Ascomycetes) in Caenorhabditis elegans.

This research aimed to evaluate the potential of Cordyceps sobolifera in mycelial biomass production via liquid culture and to assay the safety and determine the antioxidative and antiaging activities of Caenorhabditis elegans. A C. sobolifera isolate was cultured using the one-factor-at-a-time method to illustrate its carbon and nitrogen requirements. To assess safety, we determined the lethality, locomotion behavior, and reproduction of C. elegans cultured on a mycelial water extract (MWE) containing nematode growth medium (NGM). To investigate antiaging activity, C. elegans treated with MWE was incubated on NGM plates. The lethality was recorded throughout the whole life cycle. To identify antioxidant activity, C. elegans treated with MWE was exposed to paraquat, causing superoxide conditions. The results showed that C. sobolifera was favored by glucose and peptone as carbon and nitrogen sources, respectively. MWE was considered to be safe, as no abnormal behaviors were observed in C. elegans. Compared with nematodes pretreated with no MWE but with water instead, MWE at 1.0 mg/mL significantly prolonged the mean lifespan of C. elegans by 24%. We observed an obvious dose-effect relation between concentration and mean lifespan. The effective antioxidant activity was recorded at the high concentration of MWE. These findings demonstrate the potential antiaging and antioxidant properties of C. sobolifera as functional food and dietary supplement.

The thioredoxin reductase-encoding gene ActrxR1 is involved in the cephalosporin C production of Acremonium chrysogenum in methionine-supplemented medium.

The thioredoxin system including thioredoxin and thioredoxin reductase (TrxR) is used for oxidative stress defenses in fungi. Based on the genomic sequence, a thioredoxin reductase-encoding gene (ActrxR1) was isolated from Acremonium chrysogenum CGMCC3.3795. Like other TrxRs, AcTrxR1 contains FAD binding domain, Redox domain, and NADPH binding domain. Disruption of ActrxR1 in A. chrysogenum led to the formation of smaller colonies and hyphal swelling in Tryptic soy agar (TSA). In chemically defined medium, the spore germination of ActrxR1 disruption mutant was strongly inhibited, which was recovered by the addition of DL-methionine. The disruption mutant grew slowly on TSA compared with the wild-type strain, but it did not show to be more sensitive to exogenous hydrogen peroxide or menadione. In defined medium of fermentation supplemented with DL-methionine, the ActrxR1 disruption mutant grew normally, and its cephalosporin C production increased by about onefold compared with the wild type (73 µg/ml for wild-type strain and 136 µg/ml for the mutant at 5 days of fermentation). Real-time polymerase chain reaction (RT-PCR) showed that the transcriptional levels of pcbC, cefEF, and cefG were obviously enhanced in the ActrxR1 mutant at the early stage of fermentation. These results indicate that ActrxR1 is required for the normal growth of A. chrysogenum and related with cephalosporin C production in methionine-supplemented medium.

A septation related gene AcsepH in Acremonium chrysogenum is involved in the cellular differentiation and cephalosporin production.

T-DNA inserted mutants of Acremonium chrysogenum were constructed by Agrobacterium tumefaciens-mediated transformation (ATMT). One mutant 1223 which grew slowly was selected. TAIL-PCR and sequence analysis indicated that a putative septation protein encoding gene AcsepH was partially deleted in this mutant. AcsepH contains nine introns, and its deduced protein AcSEPH has a conserved serine/threonine protein kinase catalytic (S_TKc) domain at its N-terminal region. AcSEPH shows high similarity with septation H proteins from other filamentous fungi based on the phylogenetic analysis of S_TKc domains. In sporulation (LPE) medium, the conidia of AcsepH mutant was only about one-seventh of the wild-type, and more than 20% of conidia produced by the mutant contain multiple nuclei which were rare in the wild-type. During fermentation, the AcsepH disruption mutant grew slowly and its cephalosporin production was only about one quarter of the wild-type, and the transcription analysis showed that pcbC expression was delayed and the expressions of cefEF, cefD1 and cefD2 were significantly decreased. The vegetative hyphae of AcsepH mutant swelled abnormally and hardly formed the typical yeast-like cells. The amount of yeast-like cells was about one-tenth of the wild-type after fermentation for 5days. Comparison of hyphal viabilities revealed that the cells of AcsepH mutant died easily than the wild-type at the late stage of fermentation. Fluorescent stains revealed that the absence of AcsepH in A. chrysogenum led to reduction of septation and formation of multinucleate cells. These data indicates that AcsepH is required for the normal cellular septation and differentiation of A. chrysogenum, and its absence may change the cellular physiological status and causes the decline in cephalosporin production.

Disruption of a glutathione reductase encoding gene in Acremonium chrysogenum leads to reduction of its growth, cephalosporin production and antioxidative ability which is recovered by exogenous methionine.

Glutathione is a ubiquitous thiol in eukaryotic cells, and its high intracellular ratio of reduced form (GSH) to oxidized form (GSSG) is largely maintained by glutathione reductase (GR) using NADPH as electron donor. glrA, a glutathione reductase encoding gene, was found and cloned from Acremonium chrysogenum by searching its genomic sequence based on similarity. Its deduced protein exhibits high similarity to GRs of other eukaryotic organisms. Disruption of glrA resulted in lack of GR activity and accumulation of a high level of GSSG in A. chrysogenum. Overexpression of glrA dramatically enhanced GR activity and the ratio of GSH/GSSG in this fungus. The spore germination and hyphal growth of glrA disruption mutant was strongly reduced in chemical defined medium. Meanwhile, the mutant was more sensitive to hydrogen peroxide than the wild-type strain. We found that the glrA mutant recovered normal germination and growth by adding exogenous methionine (Met). Exogenous Met also enhanced the antioxidative ability of both the mutant and wild-type strain. GSH determination indicated that the total GSH and ratio of GSH/GSSG in the mutant or wild-type strain were significantly increased when addition of Met into the medium. The glrA mutant grew poorly and could not produce detectable cephalosporin in the fermentation medium without Met. However, its growth and cephalosporin production was restored with addition of exogenous Met. These results indicate that glrA is required for the normal growth and protection against oxidative damage in A. chrysogenum, and its absence can be complemented by exogenous Met.