Cloning, characterization of the acyl-CoA : 6-amino penicillanic acid acyltransferase gene of Aspergillus nidulans and linkage to the isopenicillin N synthase gene

Summary The penDE gene encoding acyl-CoA:6-amino penicillanic acid acyltransferase (AAT), the last enzyme of the penicillin biosynthetic pathway, has been cloned from the DNA of Aspergillus nidulans. The gene contains three introns which are located in the 5 region of the open reading frame. It encodes a protein of 357 amino acids with a molecular weight of 39 240 Da. The penDE gene of A. nidulans shows 73% similarity at the nucleotide level with the penDE gene of Penicillium chrysogenum. The A. nidulans gene was expressed in P. chrysogenum and complemented the AAT deficiency of the non-producer mutants of P. chrysogenum, npe6 and npe8. The penDE gene of A. nidulans is linked to the pcbC gene, which encodes the isopenicillin N synthase, as also occurs in P. chrysogenum. Both genes show the same orientation and are separated by an intergenic region of 822 nucleotides.     

ThePenicillium chrysogenum andAspergillus nidulans wetA developmental regulatory genes are functionally equivalent

Aspergillus nidulans andPenicillium chrysogenum are related fungi that reproduce asexually by forming multicellular conidiophores and uninucleate conidia. InA. nidulans, spore maturation is controlled by thewetA (AwetA) regulatory gene. We cloned a homologous gene (PwetA) fromP. chrysogenum to determine if spore maturation is regulated by a similar mechanism in this species. ThePwetA andAwetA genes are similar in structure and functional organization. The inferred polypeptides share 77% overall amino acid sequence similarity, with several regions having > 85% similarity. The genes also had significant, local sequence similarities in their 5 flanking regions, including conserved binding sites for the product of the regulatory geneabaA.PwetA fully complemented anA. nidulans wetA deletion mutation, demonstrating thatPwetA and its 5 regulatory sequences function normally inA. nidulans. These results indicate that the mechanisms controlling sporulation inA. nidulans andP. chrysogenum are evolutionarily conserved.     

Decreased production ofpara-hydroxypenicillin V in penicillin V fermentations

Summary Penicillin V (phenoxymethyl penicillin) is produced by industrial strains ofPenicillium chrysogenum in the presence of phenoxyacetic acid (POAc), a side-chain precursor for the penicillin V molecule. The wild-type strain ofP. chrysogenum produces an undesirable penicillin byproduct,para-hydroxypenicillin V (p-OH penicillin V), in addition to penicillin V, viapara-hydroxylation of POAc and subsequent incorporation of thep-OH phenoxyacetic acid into the penicillin molecule. Most of thep-OH penicillin V is produced late in cycle when the POAc concentration in the medium is nearly depleted. The level ofp-OH penicillin V produced by the control strain ranges up to 10–15% of the total penicillins produced. 3-Phenoxypropionic acid andp-bromophenylacetic acid partially inhibit the formation ofp-OH penicillin V with a minimal effect on penicillin V productivity. Mutants deficient in their ability to hydroxylate POAc were found to produce lower levels ofp-OH penicillin V. Multi-step mutation and screening, starting with the wild-type strain, have culminated in isolation of mutants which producep-OH penicillin V as 1% of the total penicillins with no adverse effect on penicillin V productivity.     

Resolution of four large chromosomes in penicillin-producing filamentous fungi: the penicillin gene cluster is located on chromosome II (9.6 Mb) in Penicillium notatum and chromosome 1 (10.4 Mb) in Penicillium chrysogenum

Four chromosomes were resolved by pulsed field gel electrophoresis in Penicillium notatum (10.8, 9.6, 6.3 and 5.4 Mb in size) and in five different strains of Penicillium chrysogenum (10.4, 9.6, 7.3 and 6.8 Mb in the wild type). Small differences in size were found between the four chromosomes of the five P. chrysogenum strains. The penicillin gene cluster was localized by hybridization with a pcbAB probe to chromosome II of P. notatum and to chromosome I of all P. chrysogenum strains except the deletion mutant P. chrysogenum npe10, which lacks this DNA region. The pyrG gene was localized to chromosome I in P. notatum and to chromosome II in all P. chrysogenum strains except in the mutant AS-P-78 where the probe hybridized to chromosome 111. A major chromosomal rearrangement seems to have occurred in this high penicillin producing strain. A fast moving DNA band observed in all gels corresponds to mitochondrial DNA. The total genome size has been calculated as 32.1 Mb in P. notatum and 34.1 Mb for the P. chrysogenum strains.     

The light-dependent regulator velvet A of <Emphasis Type="Italic">Aspergillus nidulans</Emphasis> acts as a repressor of the penicillin biosynthesis

The biosynthesis of the β-lactam antibiotic penicillin in Aspergillus nidulans is catalysed by three enzymes that are encoded by the genes acvA, ipnA and aatA. Several studies have indicated that these genes are controlled by a complex regulatory network, including a variety of cis-acting DNA elements and regulatory factors. Until now, however, relatively little information is available on external signals and their transmission influencing the expression of the structural genes. Here, we show that the light-dependent regulator velvet A (VeA) acts as a repressor on the penicillin biosynthesis, mainly via repression of the acvA gene. Expression of a regulatable alcAp-veA gene fusion in an A. nidulans strain carrying, in addition, acvAp-uidA and ipnAp-lacZ gene fusions indicated that under alcAp-inducing conditions, penicillin titres and expression of acvAp-uidA were drastically reduced compared with untransformed wild-type strains. The same level of repression was found irrespective of whether the alcAp-veA gene fusion was expressed in a veA1 or ΔveA background, with or without light. The expression of the ipnAp-lacZ gene fusion was only moderately affected indicating a less prominent effect. These findings were confirmed by the analysis of a regulatable niiAp-veA gene fusion. Under niiAp-inducing conditions, penicillin titres and acvAp-uidA expression were much lower than in untransformed wild-type strains.     

Semicontinuous penicillin production by two Penicillium chrysogenum strains immobilized in calcium alginate beads

Summary The growth rates of immobilized Penicillium chrysogenum strains are important in their application to semicontinuous penicillin production. Immobilized P. chrysogenum strains produced about 10–15% less biomass but about 1–2 times more penicillin than free suspended mycelia.In a chemically defined medium an industrial P. chrysogenum strain, S₁, produced about 10–12 times more penicillin than strain ATCC 12690. In a complex medium the immobilized P. chrysogenum S₁ produced about 12% penicillin more than in shaken cultures. In bubble column fermentations, penicillin production was 163% higher in the complex medium than in the chemically defined medium.     

Analysis of the regulation of penicillin biosynthesis in Aspergillus nidulans by targeted disruption of the acvA gene

To analyse the regulation of the biosynthesis of the secondary metabolite penicillin in Aspergillus nidulans, a strain with an inactivated acvA gene produced by targeted disruption was used. acvA encodes -(l--aminoadipyl)-l-cysteinyl-d-valine synthetase (ACVS), which catalyses the first step in the penicillin biosynthetic pathway. To study the effect of the inactivated acvA gene on the expression of acvA and the second gene, ipnA, which encodes isopenicillin N synthase (IPNS), A. nidulans strain XEPD, with the acvA disruption, was crossed with strain AXB4A carrying acvA-uidA and ipnA-lacZ fusion genes. Ascospores with the predicted non-penicillin producing phenotype and a hybridization pattern indicating the presence of the disrupted acvA gene, and the fusion genes integrated in single copy at the chromosomal argB locus were identified. Both fusion genes were expressed at the same level as in the non-disrupted strain. Western blot analysis (immunoblotting) revealed that similar amounts of IPNS enzyme were present in both strains from 24 to 68 h of a fermentation run. In the acvA disrupted strain, IPNS and acyl-CoA: 6-aminopenicillanic acid acyltransferase (ACT) specific activities were detected, excluding a sequential induction mechanism of regulation of the penicillin biosynthesis gene ipnA and the third gene aat.     

Transformation of a nitrate reductase deficient mutant of Penicillium chrysogenum with the corresponding Aspergillus niger and A. nidulans niaD genes

Summary A heterologous gene mediated transformation system based on niaD, the structural gene encoding nitrate reductase, has been developed for Penicillium chrysogenum. Transformation frequencies of up to 20 transformants per microgram DNA were obtained using the Aspergillus nidulans gene and 9 transformants per microgram using the A. niger gene. Vector constructs carrying the A. nidulans ans-1 sequence and the A. niger niaD gene did not show increased transformation frequencies. Southern blot hybridisation analysis demonstrated that vector sequences had integrated into the recipient genome. The control of heterologous niaD gene expression generally agreed with that found in the wild-type strain, that is, induction by nitrate and repression in the presence of ammonium.     

CefR modulates transporters of beta-lactam intermediates preventing the loss of penicillins to the broth and increases cephalosporin production in Acremonium chrysogenum

The Acremonium chrysogenum cephalosporin biosynthetic genes are divided in two different clusters. The central step of the biosynthetic pathway (epimerization of isopenicillin N to penicillin N) occurs in peroxisomes. We found in the “early” cephalosporin cluster a new ORF encoding a regulatory protein (CefR), containing a nuclear targeting signal and a “Fungal_trans” domain. Targeted inactivation of cefR delays expression of the cefEF gene, increases penicillin N secretion and decreases cephalosporin production. Overexpression of the cefR gene decreased (up to 60%) penicillin N secretion, saving precursors and resulting in increased cephalosporin C production. Northern blot analysis revealed that the CefR protein acts as a repressor of the exporter cefT and exerts a small stimulatory effect over the expression level of cefEF that explains the increased cephalosporin yields observed in transformants overexpressing cefR. In summary, we describe for the first time a modulator of beta-lactam intermediate transporters in A. chrysogenum.     

Lysine is catabolized to 2-aminoadipic acid in <Emphasis Type="Italic">Penicillium chrysogenum</Emphasis> by an omega-aminotransferase and to saccharopine by a lysine 2-ketoglutarate reductase. Characterization of the omega-aminotransferase

The biosynthesis and catabolism of lysine in Penicillium chrysogenum is of great interest because these pathways provide 2-aminoadipic acid, a precursor of the tripeptide δ-L-2-aminoadipyl-L-cysteinyl-D-valine that is an intermediate in penicillin biosynthesis. In vivo conversion of labelled L-lysine into two different intermediates was demonstrated by HPLC analysis of the intracellular amino acid pool. L-lysine is catabolized to 2-aminoadipic acid by an ω-aminotransferase and to saccharopine by a lysine-2-ketoglutarate reductase. In lysine-containing medium both activities were expressed at high levels, but the ω-aminotransferase activity, in particular, decreased sharply when ammonium was used as the nitrogen source. The ω-aminotransferase was partially purified, and found to accept L-lysine, L-ornithine and, to a lesser extent, N-acetyl-L-lysine as amino-group donors. 2-Ketoglutarate, 2-ketoadipate and, to a lesser extent, pyruvate served as amino group acceptors. This pattern suggests that this enzyme, previously designated as a lysine-6-aminotransferase, is actually an ω-aminotransferase. When 2-ketoadipate is used as substrate, the reaction product is 2-aminoadipic acid, which contributes to the pool of this intermediate available for penicillin biosynthesis. The N-terminal end of the purified 45-kDa ω-aminotransferase was sequenced and was found to be similar to the corresponding segment of the OAT1 protein of Emericella (Aspergillus) nidulans. This information was used to clone the gene encoding this enzyme.     

Nitrogen regulation in fungi

Nitrogen regulation has been extensively studied in fungi revealing a complex array of interacting regulatory genes. The general characterisation of the systems inAspergillus nidulans andNeurospora crassa shall be briefly described, but much of this paper will concentrate specifically on the recent molecular characterisation ofareA, the principle regulatory gene fromA. nidulans which mediates nitrogen metabolite repression. Three areas shall be explored in detail, firstly the DNA binding domain, which has been characterised extensively by both molecular and genetic analysis. Secondly we shall report recent analysis which has revealed the presence of related DNA binding activities inA. nidulans. Finally we shall discuss the mechanism by which the nitrogen state of the cell is monitored by theareA product, in particular localisation of the domain within theareA product which mediates the regulatory response within the protein.     

Use of primer selection and restriction enzymes to assess bacterial community diversity in an agricultural soil used for potato production via terminal restriction fragment length polymorphism

The disparity of secondary metabolites in Penicillium chrysogenum between two scales of penicillin G fermentation (50 L as pilot process and 150,000 L as industrial one) was investigated by ion-pair reversed-phase liquid chromatography tandemed with hybrid quadrupole time-of-flight mass spectrometry. In industrial process, the pools of intracellular L-α-aminoadipyl-L-cysteinyl-D-valine (LLD-ACV) and isopenicillin N (IPN) were remarkably less than that in the pilot one, which indicated that the productivity of penicillin G might be higher in the large scale of fermentation. This conclusion was supported by the higher intracellular penicillin G concentration as well as its higher yield per unit biomass in industrial cultivation. The different changing tendencies of IPN, 6-aminopenicillanic acid and 6-oxopiperide-2-carboxylic acid between two processes also suggested the same conclusion. The higher content of intracellular LLD-ACV in pilot process lead to a similarly higher concentration of bis-δ-(L-α-aminoadipyl)-L-cysteinyl-D-valine, which had an inhibitory effect on ACV synthetase and also subdued the activity of IPN synthetase. The interconversion of secondary metabolites and the influence they put on enzymes would intensify the discrepancy between two fermentations more largely. These findings provided new insight into the changes and regulation of secondary metabolites in P. chrysogenum under different fermentation sizes.     

头孢菌素C生物合成调控研究进展北大核心CSCD

头孢菌素C由丝状真菌顶头孢霉产生,属于β-内酰胺类抗生素。其经改造后的7-氨基头孢烷酸是头孢类抗生素的重要中间体。头孢类抗生素在国内外抗生素市场中占有巨大的份额,是临床上的主要抗感染药物。随着分子生物学的发展,头孢菌素C的生物合成途径已基本阐明。为提高头孢菌素C的产量和降低生产成本,越来越多的研究者开始关注其较为精细、复杂的调控机制。本文重点对头孢菌素C生物合成及其调控机制的最新进展进行了简述,希望为今后头孢菌素C生产菌株的菌种改造和传统产业的升级换代提供一定的借鉴。