丝状真菌新型全局性调控因子LaeA

全局调控在丝状真菌次级代谢调控及其生长发育过程中有着重要的作用。LaeA是2004年首次在构巢曲霉中被发现的第一个丝状真菌全局性调控因子,继而在烟曲霉、黄曲霉、产黄青霉、橘青霉中相继被报道。LaeA能够全局性调控抗生素和真菌毒素等次级代谢产物的合成,影响真菌形态分化,另外还通过影响沉默基因的表达从而调控未知代谢产物的产生,因而能为真菌中天然产物的开发提供新的重要途径。本文就其在丝状真菌中的发现、功能、作用机制及其应用等方面进行综述。     

Fungal Secondary Metabolites and Their Fundamental Roles in Human Mycoses

Understanding which fungal factors allow colonization and infection of a human host is critical to lowering the incidence of human mycoses and related mortalities. In the pathogen Aspergillus fumigatus, secondary metabolites, small bioactive molecules produced by many opportunistic fungal pathogens, have important roles in suppressing and providing protection from host defenses. Deletion of LaeA, a global regulator of secondary metabolism in fungi, significantly decreases A. fumigatus virulence, in part owing to loss of gliotoxin and hydrophobin production. In addition to gliotoxin, dihydroxynaphthalene (DHN) melanin and siderophores are other A. fumigatus virulence factors; all three metabolites are derived from hallmark secondary metabolite gene clusters. Many of the gene clusters producing toxin metabolites have yet to be deciphered, and the study of secondary metabolites and their role in the virulence of human pathogens is a nascent field.     

过表达LaeA激活海洋土曲霉中isoflavipucine类化合物的合成及其抗弧菌活性研究

丝状真菌土曲霉因产生结构独特且药理活性强烈的次级代谢产物而受到真菌学家和药学家的广泛关注。然而,在丝状真菌中,大部分次级代谢基因在常规实验室培养条件下表达量较低甚至沉默。本研究通过过表达全局性调控因子LaeA试图激活一株海洋来源土曲霉中的沉默基因簇以发现新次级代谢产物。结果表明,laeA基因过表达突变中未知产物基因簇被激活,指纹图谱分析发现了2个在野生菌株不存在的化合物吸收峰。质谱和核磁共振波谱分析确证了这2个化合物为dihydroisoflavipucine类小分子,特别是化合物1的产量在突变体中高达183 mg/L。此外,抗菌活性测试发现,这2个化合物对4种病原弧菌显示了强烈的活性,特别是化合物1抗弧菌活性更强,MIC低至16μg/mL。本研究提供了一条大量合成dihydroisoflavipucine类抗生素的新路线,并证明了次级代谢调控因子LaeA在丝状真菌中的功能是高度保守的,过表达LaeA是激活丝状真菌中沉默基因簇的有效手段。     

Motif-Independent Prediction of a Secondary Metabolism Gene Cluster Using Comparative Genomics: Application to Sequenced Genomes of Aspergillus and Ten Other Filamentous Fungal Species

Despite their biological importance, a significant number of genes for secondary metabolite biosynthesis (SMB) remain undetected due largely to the fact that they are highly diverse and are not expressed under a variety of cultivation conditions. Several software tools including SMURF and antiSMASH have been developed to predict fungal SMB gene clusters by finding core genes encoding polyketide synthase, nonribosomal peptide synthetase and dimethylallyltryptophan synthase as well as several others typically present in the cluster. In this work, we have devised a novel comparative genomics method to identify SMB gene clusters that is independent of motif information of the known SMB genes. The method detects SMB gene clusters by searching for a similar order of genes and their presence in nonsyntenic blocks. With this method, we were able to identify many known SMB gene clusters with the core genes in the genomic sequences of 10 filamentous fungi. Furthermore, we have also detected SMB gene clusters without core genes, including the kojic acid biosynthesis gene cluster of Aspergillus oryzae. By varying the detection parameters of the method, a significant difference in the sequence characteristics was detected between the genes residing inside the clusters and those outside the clusters.     

Heterochromatin influences the secondary metabolite profile in the plant pathogen Fusarium graminearum

Chromatin modifications and heterochromatic marks have been shown to be involved in the regulation of secondary metabolism gene clusters in the fungal model system Aspergillus nidulans. We examine here the role of HEP1, the heterochromatin protein homolog of Fusarium graminearum, for the production of secondary metabolites. Deletion of Hep1 in a PH-1 background strongly influences expression of genes required for the production of aurofusarin and the main tricothecene metabolite DON. In the Hep1 deletion strains AUR genes are highly up-regulated and aurofusarin production is greatly enhanced suggesting a repressive role for heterochromatin on gene expression of this cluster. Unexpectedly, gene expression and metabolites are lower for the trichothecene cluster suggesting a positive function of Hep1 for DON biosynthesis. However, analysis of histone modifications in chromatin of AUR and DON gene promoters reveals that in both gene clusters the H3K9me3 heterochromatic mark is strongly reduced in the Hep1 deletion strain. This, and the finding that a DON-cluster flanking gene is up-regulated, suggests that the DON biosynthetic cluster is repressed by HEP1 directly and indirectly. Results from this study point to a conserved mode of secondary metabolite (SM) biosynthesis regulation in fungi by chromatin modifications and the formation of facultative heterochromatin.     

Identification of <Emphasis Type="Italic">mokB</Emphasis> involved in monacolin K biosynthesis in <Emphasis Type="Italic">Monascus pilosus</Emphasis>

Monacolin K (MK), which is widely used as an antihypercholesterolemia medicine, is produced as a fungal secondary metabolite through the polyketide pathway. The MK biosynthetic gene cluster proposed for Monascus pilosus BCRC38072 was also identified in M. pilosus NBRC4480. The mokB gene, located at the end of the putative gene cluster and possibly encoding polyketide synthase, was disrupted. The mokB disruptant did not produce MK, but accumulated an intermediate that was confirmed to be monacolin J, indicating that mokB encodes the polyketide synthase responsible for the biosynthesis of side-chain diketide moiety.     

Heterochromatic marks are associated with the repression of secondary metabolism clusters in Aspergillus nidulans

Fungal secondary metabolites are important bioactive compounds but the conditions leading to expression of most of the putative secondary metabolism (SM) genes predicted by fungal genomics are unknown. Here we describe a novel mechanism involved in SM‐gene regulation based on the finding that, in Aspergillus nidulans, mutants lacking components involved in heterochromatin formation show de‐repression of genes involved in biosynthesis of sterigmatocystin (ST), penicillin and terrequinone A. During the active growth phase, the silent ST gene cluster is marked by histone H3 lysine 9 trimethylation and contains high levels of the heterochromatin protein‐1 (HepA). Upon growth arrest and activation of SM, HepA and trimethylated H3K9 levels decrease concomitantly with increasing levels of acetylated histone H3. SM‐specific chromatin modifications are restricted to genes located inside the ST cluster, and constitutive heterochromatic marks persist at loci immediately outside the cluster. LaeA, a global activator of SM clusters in fungi, counteracts the establishment of heterochromatic marks. Thus, one level of regulation of the A. nidulans ST cluster employs epigenetic control by H3K9 methylation and HepA binding to establish a repressive chromatin structure and LaeA is involved in reversal of this heterochromatic signature inside the cluster, but not in that of flanking genes.     

Origin and distribution of epipolythiodioxopiperazine (ETP) gene clusters in filamentous ascomycetes

Background  

Genes responsible for biosynthesis of fungal secondary metabolites are usually tightly clustered in the genome and co-regulated with metabolite production. Epipolythiodioxopiperazines (ETPs) are a class of secondary metabolite toxins produced by disparate ascomycete fungi and implicated in several animal and plant diseases. Gene clusters responsible for their production have previously been defined in only two fungi. Fungal genome sequence data have been surveyed for the presence of putative ETP clusters and cluster data have been generated from several fungal taxa where genome sequences are not available. Phylogenetic analysis of cluster genes has been used to investigate the assembly and heredity of these gene clusters.     

Key role of LaeA and velvet complex proteins on expression of β-lactam and PR-toxin genes in <Emphasis Type="Italic">Penicillium chrysogenum</Emphasis>: cross-talk regulation of secondary metabolite pathways

Penicillium chrysogenum is an excellent model fungus to study the molecular mechanisms of control of expression of secondary metabolite genes. A key global regulator of the biosynthesis of secondary metabolites is the LaeA protein that interacts with other components of the velvet complex (VelA, VelB, VelC, VosA). These components interact with LaeA and regulate expression of penicillin and PR-toxin biosynthetic genes in P. chrysogenum. Both LaeA and VelA are positive regulators of the penicillin and PR-toxin biosynthesis, whereas VelB acts as antagonist of the effect of LaeA and VelA. Silencing or deletion of the laeA gene has a strong negative effect on penicillin biosynthesis and overexpression of laeA increases penicillin production. Expression of the laeA gene is enhanced by the P. chrysogenum autoinducers 1,3 diaminopropane and spermidine. The PR-toxin gene cluster is very poorly expressed in P. chrysogenum under penicillin-production conditions (i.e. it is a near-silent gene cluster). Interestingly, the downregulation of expression of the PR-toxin gene cluster in the high producing strain P. chrysogenum DS17690 was associated with mutations in both the laeA and velA genes. Analysis of the laeA and velA encoding genes in this high penicillin producing strain revealed that both laeA and velA acquired important mutations during the strain improvement programs thus altering the ratio of different secondary metabolites (e.g. pigments, PR-toxin) synthesized in the high penicillin producing mutants when compared to the parental wild type strain. Cross-talk of different secondary metabolite pathways has also been found in various Penicillium spp.: P. chrysogenum mutants lacking the penicillin gene cluster produce increasing amounts of PR-toxin, and mutants of P. roqueforti silenced in the PR-toxin genes produce large amounts of mycophenolic acid. The LaeA-velvet complex mediated regulation and the pathway cross-talk phenomenon has great relevance for improving the production of novel secondary metabolites, particularly of those secondary metabolites which are produced in trace amounts encoded by silent or near-silent gene clusters.