Biological activities of an engineered tautomycetin analogue via disruption of tmcR-encoding hydroxylase in Streptomyces sp. CK4412

Tautomycetin (TMC), originally isolated from Streptomyces griseochromogenes, has been reported to possess biological functions including T cell-specific immunosuppressive and anticancer activities through a mechanism of differential inhibition of protein phosphatases such as PP1, PP2A, and SHP2. Independently isolated Streptomyces sp. CK4412 was also reported to produce a structurally identical TMC compound. Previously, we isolated and characterized the entire TMC biosynthetic gene cluster from Streptomyces sp. CK4412. In silico database comparison revealed a 1,359-bp tmcR as a putative bacterial Cytochrome P450 hydroxylase gene in the TMC biosynthetic gene cluster. Through targeted gene disruption and complementation, the tmcR mutant was confirmed to produce a C5-deoxy-TMC, the same analogue produced by the S. griseochromogenes ttnI mutant, implying that TmcR behaves as a regiospecific C5-oxygenase in the TMC biosynthetic pathway in Streptomyces sp. CK4412. In particular, the C5-deoxy-TMC from the tmcR mutant exhibited 3.2-fold higher inhibition activity toward SHP2 with significantly reduced inhibition activities toward PP1, and human Vero and lung cancer cells. These results suggested that C5 regiospecific modification of the TMC polyketide moiety may result in a drug development target for use in preferentially enhancing immunosuppressive activity while minimizing its undesirable biological activities.     

Biosynthesis,regulation, and engineering of a linear polyketide tautomycetin: a novel immunosuppressant in <Emphasis Type="Italic">Streptomyces</Emphasis> sp. CK4412

Tautomycetin (TMC) is a natural product with a linear structure that includes an ester bond connecting a dialkylmaleic moiety to a type I polyketide chain. Although TMC was originally identified as an antifungal antibiotic in the late 1980s, follow-up studies revealed its novel immunosuppressant activity. Specifically, TMC exhibited a mechanistically unique immunosuppressant activity about 100 times higher than that of cyclosporine A, a widely used immunosuppressant drug. Interestingly, a structurally close relative, tautomycin (TTM), was reported to not possess TMC-like immunosuppressant activity, suggesting that a distinctive polyketide moiety of TMC plays a critical role in immunosuppressant activity. Cloning and engineering of a TMC polyketide biosynthetic gene cluster generated several derivatives showing different biological activities. TMC was also found to be biosynthesized as a linear structure without forming a lactone ring, unlike the most polyketide-based compounds, implying the presence of a unique polyketide thioesterase in the cluster. Although TMC biosynthesis was limited due to its tight regulation by two pathway-specific regulatory genes located in the cluster, its production was significantly stimulated through homologous and heterologous expression of its entire biosynthetic gene cluster using a Streptomyces artificial chromosome vector system. In this mini-review, we summarize recent advances in the biosynthesis, regulation, and pathway engineering of a linear polyketide, TMC, in Streptomyces sp. CK4412.     

A global positive regulator afsR2 stimulates tautomycetin production via pathway-specific regulatory gene over-expression in Streptomyces sp. CK4412

Tautomycetin (TMC) is a T cell-specific immunosuppressant with a unique ester bond linkage between a terminal cyclic anhydride and a linear polyketide chain. Since an afsR2 was proved to be a global antibiotics-stimulating regulatory gene in various Streptomyces species, an afsR2-induced TMC productivity stimulation was investigated in a TMC-producing Streptomyces sp. CK4412 strain. An afsR2 gene was cloned under the influence of a strong constitutive ermE* promoter in an integrative expression vector, followed by its conjugation into the Streptomyces sp. CK4412. Comparing TMC productivity and antifungal activity of the wild type and the afsR2-containing ex-conjugant revealed that afsR2 over-expression stimulated TMC production approximately 2.4-fold in Streptomyces sp. CK4412. Based on both RT-PCR and real-time RT-PCR analyses, an afsR2 over-expression significantly stimulated the expression of a TMC-specific positive regulatory gene, tmcN. This implies that the stimulatory effect of afsR2 functions in Streptomyces sp. CK4412 via up-regulation of a TMC pathway-specific positive regulatory gene over-expression.     

Thioesterase domain swapping of a linear polyketide tautomycetin with a macrocyclic polyketide pikromycin in <Emphasis Type="Italic">Streptomyces</Emphasis> sp. CK4412

Tautomycetin (TMC) is a linear polyketide metabolite produced by Streptomyces sp. CK4412 that has been reported to possess multiple biological functions including T cell-specific immunosuppressive and anticancer activities that occur through a mechanism of differential inhibition of protein phosphatases such as PP1, PP2A, and SHP2. We previously reported the characterization of the entire TMC biosynthetic gene cluster constituted by multifunctional type I polyketide synthase (PKS) assembly and suggested that the linear form of TMC could be generated via free acid chain termination by a narrow TMC thioesterase (TE) pocket. The modular nature of the assembly presents a unique opportunity to alter or interchange the native biosynthetic domains to produce targeted variants of TMC. Herein, we report swapping of the TMC TE domain sequence with the exact counterpart of the macrocyclic polyketide pikromycin (PIK) TE. PIK TE-swapped Streptomyces sp. CK4412 mutant produced not only TMC, but also a cyclized form of TMC, implying that the bioengineering based in vivo custom construct can be exploited to produce engineered macrolactones with new structural functionality.     

Biosynthesis of an engineered tautomycetin analogue via disruption of tmcK-encoding terminal decarboxylase in Streptomyces CK4412

Tautomycetin (TMC), produced by Streptomyces sp. CK4412, is an antifungal secondary metabolite with an unusual ester bond linkage between a terminal cyclic anhydride moiety and a linear polyketide chain bearing an unusual terminal alkene. Recently, TMC was identified to possess additional biological functions including T cell-specific immunosuppressive and anti-cancer activities through differential inhibition of protein phosphatases, such as PP1, PP2A, and SHP2. These findings led us to isolate and characterize its entire biosynthetic and regulatory pathway gene cluster. In silico database comparisons revealed that the deduced products of two translationally coupled genes, a 666-bp tmcJ and a 1458-bp tmcK located on the 3′-terminus of the polyketide synthase gene, were found to have amino acid sequence homologies with putative bacterial decarboxylase genes. Targeted gene disruption of tmcK, but not tmcJ, from the Streptomyces sp. CK4412 chromosome resulted in production of a 5-deoxy-3″-carboxylic TMC. The tmcK mutant strain was functionally complemented using an integrative plasmid carrying tmcK and/or tmcJ–tmcK in order to restore TMC biosynthesis, a result suggesting that only TmcK is a functional TMC terminal decarboxylase. Unlike an authentic TMC, this engineered 5-deoxy-3″-carboxylic TMC analogue failed to show PP1 selectivity over PP2A, and it showed significantly reduced cytotoxicity against a human lung cancer cell line. These results imply that regio-specific modifications of TMC polyketide moiety, such as C3″-terminal carboxylation and/or C5-deketonization, could differentiate multiple biological activities in TMC produced from Streptomyces sp. CK4412.     

The pur6 gene of the puromycin biosynthetic gene cluster from Streptomyces alboniger encodes a tyrosinyl-aminonucleoside synthetase

The pur6 gene of the puromycin biosynthetic gene (pur) cluster from Streptomyces alboniger is shown to be essential for puromycin biosynthesis. Cell lysates from this mycelial bacterium were active in linking L-tyrosine to both 3'-amino-3'-deoxyadenosine and N6,N6-dimethyl-3'-amino-3'-deoxyadenosine with a peptide-like bond. Identical reactions were performed by cell lysates from Streptomyces lividans or Escherichia coli transformants that expressed pur6 from a variety of plasmid constructs. Physicochemical and biochemical analyses suggested that their products were tridemethyl puromycin and O-demethylpuromycin, respectively. Therefore, it appears that Pur6 is the tyrosinyl-aminonucleoside synthetase of the puromycin biosynthetic pathway.     

The global regulator LaeA controls penicillin biosynthesis, pigmentation and sporulation, but not roquefortine C synthesis in Penicillium chrysogenum

The biosynthesis of the beta-lactam antibiotic penicillin is an excellent model for the study of secondary metabolites produced by filamentous fungi due to the good background knowledge on the biochemistry and molecular genetics of the beta-lactam producing microorganisms. The three genes (pcbAB, pcbC, penDE) encoding enzymes of the penicillin pathway in Penicillium chrysogenum are clustered, but no penicillin pathway-specific regulators have been found in the genome region that contains the penicillin gene cluster. The biosynthesis of this beta-lactam is controlled by global regulators of secondary metabolism rather than by a pathway-specific regulator. In this work we have identified the gene encoding the secondary metabolism global regulator LaeA in P. chrysogenum (PcLaeA), a nuclear protein with a methyltransferase domain. The PclaeA gene is present as a single copy in the genome of low and high-penicillin producing strains and is not located in the 56.8-kb amplified region occurring in high-penicillin producing strains. Overexpression of the PclaeA gene gave rise to a 25% increase in penicillin production. PclaeA knock-down mutants exhibited drastically reduced levels of penicillin gene expression and antibiotic production and showed pigmentation and sporulation defects, but the levels of roquefortine C produced and the expression of the dmaW involved in roquefortine biosynthesis remained similar to those observed in the wild-type parental strain. The lack of effect on the synthesis of roquefortine is probably related to the chromatin arrangement in the low expression roquefortine promoters as compared to the bidirectional pbcAB-pcbC promoter region involved in penicillin biosynthesis. These results evidence that PcLaeA not only controls some secondary metabolism gene clusters, but also asexual differentiation in P. chrysogenum.     

Biosynthesis of a natural polyketide-isoprenoid hybrid compound, furaquinocin A: identification and heterologous expression of the gene cluster

Furaquinocin (FQ) A, produced by Streptomyces sp. strain KO-3988, is a natural polyketide-isoprenoid hybrid compound that exhibits a potent antitumor activity. As a first step toward understanding the biosynthetic machinery of this unique and pharmaceutically useful compound, we have cloned an FQ A biosynthetic gene cluster by taking advantage of the fact that an isoprenoid biosynthetic gene cluster generally exists in flanking regions of the mevalonate (MV) pathway gene cluster in actinomycetes. Interestingly, Streptomyces sp. strain KO-3988 was the first example of a microorganism equipped with two distinct mevalonate pathway gene clusters. We were able to localize a 25-kb DNA region that harbored FQ A biosynthetic genes (fur genes) in both the upstream and downstream regions of one of the MV pathway gene clusters (MV2) by using heterologous expression in Streptomyces lividans TK23. This was the first example of a gene cluster responsible for the biosynthesis of a polyketide-isoprenoid hybrid compound. We have also confirmed that four genes responsible for viguiepinol [3-hydroxypimara-9(11),15-diene] biosynthesis exist in the upstream region of the other MV pathway gene cluster (MV1), which had previously been cloned from strain KO-3988. This was the first example of prokaryotic enzymes with these biosynthetic functions. By phylogenetic analysis, these two MV pathway clusters were identified as probably being independently distributed in strain KO-3988 (orthologs), rather than one cluster being generated by the duplication of the other cluster (paralogs).     

A gene cluster for biosynthesis of kanamycin from Streptomyces kanamyceticus: comparison with gentamicin biosynthetic gene cluster

Gene clusters for the biosynthesis of kanamycin (Km) and gentamicin (Gm) were isolated from the genomic libraries of Streptomyces kanamyceticus and Micromonospora echinospora, respectively. The sequencing of the 47 kb-region of S. kanamyceticus genomic DNA revealed 40 putative open reading frames (ORFs) encoding Km biosynthetic proteins, regulatory proteins, and resistance and transport proteins. Similarly, the sequencing of 32.6 kb genomic DNA of M. echinospora revealed a Gm biosynthetic gene cluster flanked by resistant genes. Biosynthetic pathways for the formation of Km were proposed by the comparative study of biosynthetic genes. Out of 12 putative Km biosynthetic genes, kanA was expressed in Escherichia coli and determined its function as a 2-deoxy-scyllo-inosose synthase. Furthermore, the acetylations of aminoglycoside-aminocyclitols (AmAcs) by Km acetyltransferase (KanM) were also demonstrated. The acetylated derivatives completely lost their antibacterial activities against Bacillus subtilis. The comparative genetic studies of Gm, Km, tobramycin (Tm), and butirosin (Bn) reveal their similar biosynthetic routes and provide a framework for the further biosynthetic studies.     

Molecular basis for cytokinin biosynthesis

Cytokinins (CKs) are a group of phytohormones that play a crucial role in the regulation of plant growth and development. Identification of the enzymes and the corresponding genes that are involved in CK metabolism allowed us to understand how plants synthesize CKs and adjust CK activity to optimal levels. A major accomplishment toward these goals was the identification of genes for the first enzyme in the CK biosynthetic pathway, adenosine phosphate-isopentenyltransferase (IPT). In Arabidopsis thaliana and Agrobacterium tumefaciens, detailed analyses of IPTs were conducted through not only enzymatic characterization but also molecular structural approaches. These studies revealed the molecular basis for the Agrobacterium-origin of IPT used for the efficient biosynthesis of trans-zeatin that promotes tumorigenesis in host plants. Another landmark in CK research was the identification of CYP735A as an enzyme that converts iP-nucleotide to tZ-nucleotide. Furthermore, the identification of a CK-activating enzyme, LOG, which catalyzes a novel activation pathway, is a remarkable recent achievement in CK research. Collectively, these advances have revealed the complexity of the entire metabolic scheme for CK biosynthesis.     

Evolution of beta-lactam biosynthesis genes and recruitment of trans-acting factors

Penicillins and cephalosporins belong chemically to the group of beta-lactam antibiotics. The formation of hydrophobic penicillins has been reported in fungi only, notably Penicillium chrysogenum and Emericella nidulans, whereas the hydrophilic cephalosporins are produced by both fungi, e.g., Acremonium chrysogenum (cephalosporin C), and bacteria. The producing bacteria include Gram-negatives and Gram-positives, e.g. Lysobacter lactamdurans (cephabacins) and Streptomyces clavuligerus (cephamycin C), respectively. For a long time the evolutionary origin of beta-lactam biosynthesis genes in fungi has been discussed. As often, there are arguments for both hypotheses, i.e., horizontal gene transfer from bacteria to fungi versus vertical descent. There were strong arguments in favour of horizontal gene transfer, e.g., fungal genes were clustered or some genes lack introns. The recent identification and characterisation of cis-/trans-elements involved in the regulation of the beta-lactam biosynthesis genes has provided new arguments in favour of horizontal gene transfer. In contrast to the bacterium S. clavuligerus, all regulators of fungal beta-lactam biosynthesis genes represent wide-domain regulators which were recruited to also regulate the beta-lactam biosynthesis genes. Moreover, the fungal regulatory genes are not part of the gene cluster. If bacterial regulators were co-transferred with the gene cluster from bacteria to fungi, most likely they would have been non-functional in eukaryotes and lost during evolution. Alternatively, it is conceivable that only a part of the beta-lactam biosynthesis gene cluster was transferred to some fungi, e.g., the acvA and ipnA gene without a regulatory gene.     

卡伍尔氏链霉菌NA4的Ⅱ型聚酮基因簇的靶向激活及其产物鉴定

【目的】以基因组信息为导向,定向激活海洋来源卡伍尔氏链霉菌（Streptomyces cavourensis） NA4中沉默的Ⅱ型聚酮类次级代谢产物生物合成基因簇,鉴定新产生的次级代谢产物的结构和抑菌活性。【方法】通过添加启动子和敲除负调控基因的方法激活实验室培养条件下沉默或低表达的生物合成基因簇,并完成目标化合物的分离与纯化,通过电喷雾质谱（electrospray ionization-mass spectrometry,ESI-MS）和核磁共振（nuclear magnetic resonance,NMR）数据分析鉴定目标化合物结构,对目标化合物进行抑菌活性鉴定,基于生物信息学信息推导化合物的生物合成途径。【结果】根据基因组生物信息学分析,从海洋来源链霉菌Streptomyces cavourensis NA4中选取一个编码PKSⅡ型次级代谢产物的生物合成基因簇开展研究,成功激活目标基因簇,从中分离到1个PKSⅡ型化合物,推导了其生物合成途径并进行了抑菌活性鉴定。【结论】基因组导向下的天然产物挖掘,可以目标明确地分离产物,充分挖掘链霉菌编码次级代谢产物的潜力。