Dissection of patulin biosynthesis,spatial control and regulation mechanism in Penicillium expansum

The patulin biosynthesis is one of model pathways in an understanding of secondary metabolite biology and network novelties in fungi. However, molecular regulation mechanism of patulin biosynthesis and contribution of each gene related to the different catalytic enzymes in the biochemical steps of the pathway remain largely unknown in fungi. In this study, the genetic components of patulin biosynthetic pathway were systematically dissected in Penicillium expansum, which is an important fungal pathogen and patulin producer in harvested fruits and vegetables. Our results revealed that all the 15 genes in the cluster are involved in patulin biosynthesis. Proteins encoded by those genes are compartmentalized in various subcellular locations, including cytosol, nucleus, vacuole, endoplasmic reticulum, plasma membrane and cell wall. The subcellular localizations of some proteins, such as PatE and PatH, are required for the patulin production. Further, the functions of eight enzymes in the 10-step patulin biosynthetic pathway were verified in P. expansum. Moreover, velvet family proteins, VeA, VelB and VelC, were proved to be involved in the regulation of patulin biosynthesis, but not VosA. These findings provide a thorough understanding of the biosynthesis pathway, spatial control and regulation mechanism of patulin in fungi.     

Mycotoxin production profiles ofPenicillium vulpinum (Cooke & Massee) Seifert & Samson strains

Mycotoxins produced by seven strains ofPenicillium vulpinum (formerlyPenicillium claviforme) isolated from different sources were studied. The strains were characterized by specific profiles of secondary metabolites and produced mycotoxins of different structural types. In addition to toxins already known for this fungal species (patulin, roquefortine, 3,12-dihydroroquefortine, oxalin, viridicatin, cyclopenin, and α-cyclopiazonic acid), the strains studied also produced indolyl-3-acetic acid, griseofulvin, meleagrin, and cyclopeptin.     

Conidiogenesis and secondary metabolism in Penicillium urticae.

Submerged cultures of Penicillium urticae (NRRL 2159A) produced the antibiotics patulin and griseofulvin when grown in a glucose-nitrate medium. A high concentration of calcium (i.e., 68 mM) inhibited the production of both antibiotics while stimulating conidiogenesis. Conidial mutants that were defective in an early stage of conidiogenesis produced markedly less patulin, even under growth conditions that favored secondary metabolism. A mutant which lacked the ability to produce the patulin pathway metabolites m-cresol, toluquinol, m-hydroxybenzyl-alcohol, m-hydroxybenzaldehyde, gentisaldehyde, gentisyl alcohol, gentisic acid and patulin, as well as the pathway enzyme m-hydroxybenzyl-alcohol dehydrogenase, still produced yields of conidia that were equivalent to or greater than those of the parent strain. Other mutants which were blocked at later steps of the patulin pathway also produced conidia. These results indicate that patulin and the other related secondary metabolites noted above are not a prerequisite to conidiogenesis in P. urticae. Environmental and developmental factors such as calcium levels and conidiogenesis do, however, indirectly affect the production of patulin pathway metabolites.     

Post-translational modifications drive secondary metabolite biosynthesis in Aspergillus: a review

Post-translational modifications (PTMs) are important for protein function and regulate multiple cellular processes and secondary metabolites (SMs) in fungi. Aspergillus species belong to a genus renown for an abundance of bioactive secondary metabolites, many important as toxins, pharmaceuticals and in industrial production. The genes required for secondary metabolites are typically co-localized in biosynthetic gene clusters (BGCs), which often localize in heterochromatic regions of genome and are ‘turned off’ under laboratory condition. Efforts have been made to ‘turn on’ these BGCs by genetic manipulation of histone modifications, which could convert the heterochromatic structure to euchromatin. Additionally, non-histone PTMs also play critical roles in the regulation of secondary metabolism. In this review, we collate the known roles of epigenetic and PTMs on Aspergillus SM production. We also summarize the proteomics approaches and bioinformatics tools for PTM identification and prediction and provide future perspectives on the emerging roles of PTM on regulation of SM biosynthesis in Aspergillus and other fungi.     

黄独微型块茎低温离体保存的GC/MS代谢组学分析

GC/MS检测方法采用初步探明黄独低温离体保存微型块茎的差异代谢物。与黄独微型块茎25℃离体保存相比较,黄独微型块茎4℃离体保存的差异性代谢物有丙氨酸（Alanine）、儿茶素（Catechin）、N,N-双（2-羟乙基）甲胺（N,N-Di-（2-Hydroxyethyl）-methanamine）、水杨酸（Salicylic acid）、柠檬酸（Citric acid）和山梨糖（Sorbose）等。在黄独微型块茎4℃离体保存中,丙氨酸（Alanine）参与氰基氨基酸代谢;儿茶素（Catechin）参与次生代谢产物生物合成、黄酮类化合物的生物合成和苯丙素的生物合成;水杨酸（Salicylic acid）参与多环芳烃降解、微生物在不同环境中的代谢、植物激素信号转导、次生代谢产物生物合成、二恶英降解、苯丙氨酸代谢、芳烃降解、植物激素生物合成、铁载体组非核糖体肽合成和苯丙素的生物合成等。柠檬酸（Citric acid）参与来自鸟氨酸、赖氨酸和烟酸的生物碱生物合成、组氨酸和嘌呤的生物碱生物合成、微生物在不同环境中的代谢、植物次生代谢产物的生物合成、2-氧代羧酸代谢、萜类和类固醇的生物合成、原核生物固碳途径、次生代谢产物生物合成、来自莽草酸途径的生物碱生物合成、来自萜类化合物和聚酮的生物碱生物合成、柠檬酸循环（TCA循环）、植物激素生物合成、乙醛酸和二羧酸代谢、双组分系统、苯丙素的生物合成以及来自鸟氨酸,赖氨酸和烟酸的生物碱生物合成等。黄独低温离体保存微型块茎差异代谢物的初步发现为进一步了解其低温离体保存的分子机制奠定了基础,也为低温离体保存黄独微型块茎的破除休眠以及其后续萌发提供了理论依据。     

Cell and tissue cultures ofCatharanthus roseus (L.) G. Don: a literature survey

The literature concerning the formation of secondary metabolites in cell and tissue cultures ofCatharanthus roseus has been reviewed. Several aspects involved in the formation of secondary metabolites are discussed; e.g. regulation of secondary metabolism, environmental factors influencing secondary metabolism, biosynthesis and enzymology of the products, analysis of product formation, immobilization of cultured cells and stability of cell lines. Some economical aspects of production processes are discussed.     

Comparative metabolomic analysis of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> during the degradation of patulin using gas chromatography–mass spectrometry

A comparative metabolomic analysis was conducted on Saccharomyces cerevisiae cells with and without patulin treatment using gas chromatography–mass spectrometry-based approach. A total of 72 metabolites were detected and compared, including 16 amino acids, 29 organic acids and alcohols, 19 sugars and sugar alcohols, 2 nucleotides, and 6 miscellaneous compounds. Principle component analysis showed a clear separation of metabolome between the cells with and without patulin treatment, and most of the identified metabolites contributed to the separation. A close examination of the identified metabolites showed an increased level of most of the free amino acids, an increased level of the intermediates in the tricarboxylic acid cycle, a higher amount of glycerol, a changed fatty acid composition, and a decreased level of cysteine and glutathione in the cells with patulin treatment. This finding indicated a slower protein synthesis rate and induced oxidative stress in the cells with patulin treatment, and provided new insights into the effect of toxic chemicals on the metabolism of organisms.     

链霉菌形态分化与次级代谢产物合成的研究进展

链霉菌是一类具有复杂的形态分化周期和强大的次级代谢能力的高GC含量的放线菌,能够利用其初级代谢产生的前体化合物和能量,合成多种结构复杂、功能多样的具有生物活性的次级代谢产物,在农业、食品、畜牧业、工业以及医药研究等领域都具有重要的价值。在链霉菌的形态分化后期常常伴随着次级代谢产物的生物合成,并且两者都受到复杂的网络调控;同时链霉菌的形态对次级代谢产物的产量和种类造成很大影响。对链霉菌生长周期的全面理解将加深对链霉菌形态分化与次级代谢产物合成关系的认识。本文将对链霉菌的形态分化过程、形态分化和抗生素合成两者共同的调控因子以及链霉菌形态与抗生素产量之间的关系进行综述,这将有助于理解抗生素的合成过程,也将会在缩短发酵周期、构建高产工程菌株、新型杀菌剂的研发以及新型抗生素的合成等方面给予我们启发。     

Novel synthetic 2,6-dichloroisonicotinate derivatives as effective elicitors for inducing the biosynthesis of plant secondary metabolites

Two novel 2,6-dichloroisonicotinic acid (INA) derivatives [trifluoroethyl 2,6-dichloroisonicotinate (TFINA) and 2-(2,6-dichloro-pyridine-4-carbonyloxy)-ethyl jasmonate (DPCEJ)] were chemically synthesized and evaluated by bioassay as potential elicitors for inducing the biosynthesis of plant secondary metabolites. A suspension culture of Taxus chinensis, which stably produces a high level of bioactive taxuyunnanine C (Tc), was taken as a model plant cell system. A significant increase in Tc accumulation was observed in the presence of TFINA or DPCEJ. For example, addition of 100 μM TFINA or DPCEJ on day 7 led to a high Tc content of 21.6±2.0 or 27.7±1.0 mg g⁻¹ (on day 21), while the Tc content was 13.7±1.0 and 17.1±0.9 mg g⁻¹ for the control and that with addition of 100 μM INA, respectively. To the best of our knowledge, this is the first report on the use of synthetic INA derivatives for inducing the biosynthesis of plant secondary metabolites. The results indicate that the newly synthesized INA analogues can act as promising elicitors for secondary metabolism induction in plant cell cultures.     

Ammonium repression of antibiotic and intracellular proteinase production inPenicillium urticae

In this study the addition of ammonium ions (5–30 mM) toPenicillium urticae shake-flask cultures before, during and after the onset of polyketide biosynthesis was examined in a time-dependent manner for its repressive effect on metabolites and a marker enzyme of the patulin pathway and on the intracellular proteinases that also appear during the non-growth or idiophase. A study of the effect of ammonium ion addition, showed that both secondary enzyme and proteinase appearance were maximally delayed if the addition was made before the normal 7 h period of derepression/induction. If added during this period the effect of ammonium ions was progressively less. A reduction in the extracellular ammonium ion concentration from 30 to 4mM appeared to be required to initiate the derepression/induction process. Adding ammonium ions during the appearance of secondary enzymes caused a rapid decrease in specific activity, about 67% for the patulin pathway enzyme and 12% for proteinase. Nitrogen repression exerts a much stronger effect on the expression of polyketide genes as opposed to proteinase genes. Both patulin pathway enzymes and proteinases are subjected to proteolysis, but the proteinases retain much of their activity, whereas the polyketide biosynthetic enzymes do not.     

LaeA regulation of secondary metabolism modulates virulence in Penicillium expansum and is mediated by sucrose

Penicillium expansum, the causal agent of blue mould rot, is a critical health concern because of the production of the mycotoxin patulin in colonized apple fruit tissue. Although patulin is produced by many Penicillium species, the factor(s) activating its biosynthesis are not clear. Sucrose, a key sugar component of apple fruit, was found to modulate patulin accumulation in a dose‐responsive pattern. An increase in sucrose culture amendment from 15 to 175 mm decreased both patulin accumulation and expression of the global regulator laeA by 175‐ and five‐fold, respectively, whilst increasing expression of the carbon catabolite repressor creA. LaeA was found to regulate several secondary metabolite genes, including the patulin gene cluster and concomitant patulin synthesis in vitro. Virulence studies of ΔlaeA mutants of two geographically distant P. expansum isolates (Pe‐21 from Israel and Pe‐T01 from China) showed differential reduction in disease severity in freshly harvested fruit, ranging from no reduction for Ch‐Pe‐T01 strains to 15%–25% reduction for both strains in mature fruit, with the ΔlaeA strains of Is‐Pe‐21 always showing a greater loss in virulence. The results suggest the importance of abiotic factors in LaeA regulation of patulin and other secondary metabolites that contribute to pathogenicity.     

拟核结合蛋白调控链霉菌形态分化和次级代谢的作用和机制

链霉菌具有独特而复杂的形态分化周期,涉及到染色体复制、浓缩和分离等多个步骤,并伴随着菌丝的分隔和片段化。拟核结合蛋白作为染色体高级结构的重要组成成分,在调控链霉菌的形态分化中发挥了重要作用,调控许多与DNA相关的过程,包括基因表达、DNA保护、重组/修复和拟核的形成与维持等。此外,拟核结合蛋白作为细菌重要的全局性调控因子,也广泛参与了链霉菌次级代谢的调控。本文总结了链霉菌拟核结合蛋白的结构和功能,特别是调控形态分化和次级代谢的最新研究成果。     

The shikimic acid pathway and polyketide biosynthesis

The shikimic acid pathway, ubiquitous in microorganisms and plants, provides precursors for the biosynthesis of primary metabolites such as the aromatic amino acids and folic acid. Several branchpoints from the primary metabolic pathway also provide aromatic and, in some unusual cases, nonaromatic precursors for the biosynthesis of secondary metabolites. We report herein recent progress in the analysis of two unusual branches of the shikimic acid pathway in streptomycetes; the formation of the cyclohexanecarboxylic acid (CHC)-derived moiety of the antifungal agent ansatrienin and the dihydroxycyclohexanecarboxylic acid (DHCHC) starter unit for the biosynthesis of the immunosuppressant ascomycin. A gene for 1-cyclohexenylcarbonyl-CoA reductase, chcA, which plays a role in catalyzing three of the reductive steps leading from shikimic acid to CHC has been characterized from Streptomyces collinus. A cluster of six open reading frames (ORFs) has been identified by sequencing in both directions from chcA and the putative role of these in CHC biosynthesis is discussed. The individual steps involved in the biosynthesis of DHCHC from shikimic acid in Streptomyces hygroscopicus var ascomyceticus has been delineated and shown to be stereochemically and enzymatically distinct from the CHC pathway. A dehydroquinate dehydratase gene (dhq) likely involved in providing shikimic acid for both DHCHC biosynthesis and primary metabolism has been cloned, sequenced and characterized. Received 17 February 1998/ Accepted in revised form 26 April 1998     

Clavulanic acid biosynthesis and genetic manipulation for its overproduction

Clavulanic acid, a β-lactamase inhibitor, is used together with β-lactam antibiotics to create drug mixtures possessing potent antimicrobial activity. In view of the clinical and industrial importance of clavulanic acid, identification of the clavulanic acid biosynthetic pathway and the associated gene cluster(s) in the main producer species, Streptomyces clavuligerus, has been an intriguing research question. Clavulanic acid biosynthesis was revealed to involve an interesting mechanism common to all of the clavam metabolites produced by the organism, but different from that of other β-lactam compounds. Gene clusters involved in clavulanic acid biosynthesis in S. clavuligerus occupy large regions of nucleotide sequence in three loci of its genome. In this review, clavulanic acid biosynthesis and the associated gene clusters are discussed, and clavulanic acid improvement through genetic manipulation is explained.