Identification of a gene cluster encoding meilingmycin biosynthesis among multiple polyketide synthase contigs isolated from<Emphasis Type="Italic"> Streptomyces nanchangensis</Emphasis> NS3226

A cluster encoding genes for the biosynthesis of meilingmycin, a macrolide antibiotic structurally similar to avermectin and milbemycin 11, was identified among seven uncharacterized polyketide synthase gene clusters isolated from Streptomyces nanchangensis NS3226 by hybridization with PCR products using primers derived from the sequences of aveE, aveF and a thioesterase domain of the avermectin biosynthetic gene cluster. Introduction of a 24.1-kb deletion by targeted gene replacement resulted in a loss of meilingmycin production, confirming that the gene cluster encodes biosynthesis of this important anthelminthic antibiotic compound. A sequenced 8.6-kb fragment had aveC and aveE homologues (meiC and meiE) linked together, as in the avermectin gene cluster, but the arrangement of aveF (meiF) and the thioesterase homologues differed. The results should pave the way to producing novel insecticidal compounds by generating hybrids between the two pathways.     

The avermectin receptors of Haemonchus contortus and Caenorhabditis elegans

Most of the recent evidence suggests that the avermectin/milbemycin family of anthelmintics act via specific interactions with glutamate-gated chloride channels. These channels are encoded by a small family of genes in nematodes, though the composition of the gene family and the function of the individual members of the family may vary between species. We review our current knowledge concerning the properties of the glutamate-gated chloride channels from Caenorhabditis elegans and the related parasite, Haemonchus contortus. We conclude that the biological effects of the avermectins/milbemycins can be largely explained by the known pharmacology and distribution of the glutamate-gated chloride channels and that differences between the glutamate-gated chloride channels from different nematodes may underlie species-specific variations in anthelmintic action.     

Mining and engineering exporters for titer improvement of macrolide biopesticides in Streptomyces

Exporter engineering is a promising strategy to construct high-yield Streptomyces for natural product pharmaceuticals in industrial biotechnology. However, available exporters are scarce, due to the limited knowledge of bacterial transporters. Here, we built a workflow for exporter mining and devised a tunable plug-and-play exporter (TuPPE) module to improve the production of macrolide biopesticides in Streptomyces. Combining genome analyses and experimental confirmations, we found three ATP-binding cassette transporters that contribute to milbemycin production in Streptomyces bingchenggensis. We then optimized the expression level of target exporters for milbemycin titer optimization by designing a TuPPE module with replaceable promoters and ribosome binding sites. Finally, broader applications of the TuPPE module were implemented in industrial S. bingchenggensis BC04, Streptomyces avermitilis NEAU12 and Streptomyces cyaneogriseus NMWT1, which led to optimal titer improvement of milbemycin A3/A4, avermectin B_1a and nemadectin α by 24.2%, 53.0% and 41.0%, respectively. Our work provides useful exporters and a convenient TuPPE module for titer improvement of macrolide biopesticides in Streptomyces. More importantly, the feasible exporter mining workflow developed here might shed light on widespread applications of exporter engineering in Streptomyces to boost the production of other secondary metabolites.     

米贝链霉菌DSM41911的米尔贝霉素生物合成的初步研究

对米贝链霉菌DSM41911进行初步研究,通过对16S rRNA及相关功能基因序列进行生物信息学分析,表明米贝链霉菌DSM41911与冰城链霉菌具有较高同源性。设计16种固体和液体培养基对菌株的发酵条件进行筛选,在MB4、MB6培养基中成功检测到milbemycin B5、milbemycin E、milbemycin VM44864和milbemycin B1。参考近似菌株冰城链霉菌的合成基因并结合文献推测出米尔贝霉素在米贝链霉菌DSM41911中的合成途径,为后续高产菌株的筛选提供参考。     

Targeted gene disruption of the avermectin B O-methyltransferase gene in Streptomyces avermitilis

The biological activity of avermectin B components is superior to that of avermectin A components, which are derived from avermectin B by avermectin B 5-O-methyltransferase. Gene disruption, targeting avermectin B 5-O-methyltransferase gene in Streptomyces avermitilis, was carried out to obtain a strain of avermectin B producer. Phenotype analysis of the mutant with the disrupted O-methyltransferase gene showed that only avermectin B components were produced with a significant increase in production     

Selection of different genotype larvae and adult worms for anthelmintic resistance by persistent and short-acting avermectin/milbemycins

To understand the factors that influence selection for anthelmintic resistance, it is necessary to examine the impact of drug treatment, particularly persistent drugs, on all phases of the worm life cycle. The efficacy of various avermectin/milbemycin anthelmintics was determined against resident worms, incoming larvae (L3) and development of eggs in faecal culture. Homozygote-resistant and maternal and paternal F1-heterozygote genotypes of Haemonchus contortus were used to infect sheep before or after treatment with ivermectin (IVM) oral, IVM capsule, moxidectin (MOX) oral or MOX injectable. Total worm count and quantitative larval culture were used to determine efficacy against parasitic and free-living stages, respectively. Selection for resistance by IVM capsules occurred at the adult and L3 stages because of poor efficacy against these stages for all resistant genotypes. However, the selective advantage of these surviving worms was reduced due to the low development of their eggs to L3 in faecal culture. For MOX, selection for resistance predominantly occurred after treatment because of high efficacy against resident adult worms of all resistant genotypes but poor efficacy against resistant L3 ingested after drug administration. The results indicated no evidence of sex-linked inheritance for IVM resistance. Mean IVM efficacies against homozygous and heterozygous resistant adult worms were not different, and IVM capsule efficacy against incoming L3 was approximately 70% for all resistant genotypes, consistent with a dominant trait. MOX was highly effective against adults of all resistant genotypes and approximately 76% effective against incoming L3 regardless of resistance genotype, also consistent with a dominant trait. These results will enable the impact of persistent drugs on worm control and anthelmintic resistance to be estimated. The results indicate that IVM capsules should not be used in populations where avermectin/milbemycin resistance is present.     

Characterization of a regulatory gene, <Emphasis Type="Italic">aveR</Emphasis>, for the biosynthesis of avermectin in <Emphasis Type="Italic">Streptomyces avermitilis</Emphasis>

Avermectin is an important macrocyclic polyketide produced by Streptomyces avermitilis and widely used as an anthelmintic agent in the medical, veterinary, and agricultural fields. The avermectin biosynthetic gene cluster contains aveR, which belongs to the LAL-family of regulatory genes. In this study, aveR was inactivated by gene replacement in the chromosome of S. avermitilis, resulting in the complete loss of avermectin production. The aveR mutant was unable to convert an avermectin intermediate to any avermectin derivatives, and complementation by intact aveR and its proper upstream region restored avermectin production in the mutant, suggesting that AveR is a positive regulator controlling the expression of both polyketide biosynthetic genes and postpolyketide modification genes in avermectin biosynthesis. Despite the general concept that an increased amount of a positive pathway-specific regulator leads to higher production, a higher amount of aveR resulted in complete loss of avermectin, indicating that there is a maximum threshold concentration of aveR for the production of avermectin.     

An ivermectin-sensitive glutamate-gated chloride channel subunit from Dirofilaria immitis

Dirofilaria immitis is a filarial nematode that infects dogs and causes cardiopulmonary disease. The most effective way of controlling the infection is by chemoprophylaxis, using members of the avermectin/milbemycin (A/M) class of anthelmintics, which includes ivermectin; these drugs act at invertebrate glutamate-gated chloride channels (GluCl). We have cloned two cDNAs encoding D. immitis GluCl subunits and demonstrated that at least one may be an important molecular target for the A/Ms in vivo. The subunits are orthologues of the alternatively spliced GluClalpha3A and alpha3B subunits (encoded by the avr-14 gene) previously identified in Caenorhabditis elegans and in Haemonchus contortus. Although the alternative splicing of avr-14 is conserved across the species, the processing of the mature GluClalpha3A mRNA differs in D. immitis compared to C. elegans and H. contortus. Two-electrode voltage clamp recordings were made from Xenopus oocytes injected with subunit-specific cRNAs. The DiGluClalpha3B subunit formed channels that were gated by L-glutamate (1-100 mM) and ivermectin (1 microM). Oocytes injected with DiGluClalpha3A cRNA failed to respond to L-glutamate. The qualitative responses obtained were consistent with the pharmacology observed for the GluClalpha3 subunits from C. elegans and H. contortus.     

Overexpression of ribosome recycling factor causes increased production of avermectin in <Emphasis Type="Italic">Streptomyces avermitilis</Emphasis> strains

Ribosome recycling factor (RRF), encoded by frr gene, is involved in the release of ribosomes from the translational post-termination complex for a new round of initiation. In this study, the frr gene with either its own promoter or with ermE*p was cloned into a multi-copy vector, pKC1139, and a single-site integrative vector, pSET152, respectively. The resulting plasmids were transformed into Streptomyces avermitilis wild-type strain ATCC31267, avermectin high-producing mutant strain 76-02-e, and the engineered strain GB-165 that produces only avermectin B. The results showed that overexpression of frr increased avermectin yield (by 3- to 3.7-fold in the wild-type strain) and revealed an frr gene “copy number effect”; i.e., multiple copies of frr had a greater promoting effect on avermectin production than a single copy in each of the three transformed S. avermitilis strains. Comparison of the growth and expression of the ave genes in an frr-overexpressing strain and wild-type ATCC31267 indicated that frr overexpression promoted cell growth as well as the expression of ave genes (including pathway-specific positive regulatory gene aveR for avermectin biosynthesis and ave structural genes), leading in turn to avermectin overproduction. These findings provide an effective approach for the improvement of antibiotic production in Streptomyces.     

除虫链霉菌10个聚酮类抗生素生物合成基因簇的敲除对阿维菌素产量的影响

【目的】考察除虫链霉菌基因组中其它聚酮合成酶类(Polyketide synthase,PKS)抗生素生物合成基因簇的敲除突变对于阿维菌素产量的影响。【方法】构建了11个PKS基因簇的打靶Cosmid和质粒载体,导入除虫链霉菌中筛选突变株。【结果】在工业菌株MMR630中成功敲除了10个PKS基因簇。发酵结果显示7个PKS基因簇敲除突变株中阿维菌素的产量均有不同程度的提高,而2个突变株不能产生阿维菌素。然而,在3个连续敲除2个PKS基因簇的突变株中阿维菌素产量没有能够超过单个PKS敲除突变株的提升幅度。【结论】除虫链霉菌基因组的一些PKS基因簇的敲除可以提高阿维菌素的产量,同时暗示同一类次生代谢产物的代谢流之间存在复杂的相互作用关系。     

Cloning and Analysis of a DNA Fragment Stimulating Avermectin Production in Various Streptomyces avermitilis Strains

To isolate a gene for stimulating avermectin production, a genomic library of Streptomyces avermitilis ATCC 31267 was constructed in Streptomyces lividans TK21 as the host strain. An 8.0-kb DNA fragment that significantly stimulated actinorhodin and undecylprodigiosin production was isolated. When wild-type S. avermitilis was transformed with the cloned fragment, avermectin production increased approximately 3.5-fold. The introduction of this fragment into high-producer (ATCC 31780) and semi-industrial (L-9) strains also resulted in an increase of avermectin production by more than 2.0- and 1.4-fold, respectively. Subclones were studied to locate the minimal region involved in stimulation of pigmented-antibiotic and avermectin production. An analysis of the nucleotide sequence of the entire DNA fragment identified eight complete and one incomplete open reading frame. All but one of the deduced proteins exhibited strong homology (68 to 84% identity) to the hypothetical proteins of Streptomyces coelicolor A3(2). The orfX gene product showed no significant similarity to any other protein in the databases, and an analysis of its sequence suggested that it was a putative membrane protein. Although the nature of the stimulatory effect is still unclear, the disruption of orfX revealed that this gene was intrinsically involved in the stimulation of avermectin production in S. avermitilis.     

Engineering the aveC gene to enhance the ratio of doramectin to its CHC-B2 analogue produced in Streptomyces avermitilis

Avermectin and its analogues are produced by the actinomycete Streptomyces avermitilis and are major commercial products for parasite control in the fields of animal health, agriculture, and human infections. Historically, the avermectin analogue doramectin (CHC-B1), which is sold commercially as Dectomax is co-produced during fermentation with the undesired analogue CHC-B2 at a CHC-B2:CHC-B1 ratio of 1.6:1. Although the identification of the avermectin gene cluster has allowed for characterization of most of the biosynthetic pathway, the mechanism for determining the avermectin B2:B1 ratio remains unclear. The aveC gene, which has an essential role in avermectin biosynthesis, was inactivated by insertional inactivation and mutated by site-specific mutagenesis and error-prone PCR. Several unrelated mutations were identified that resulted in improved ratios of the desirable avermectin analogue CHC-B1, produced relative to the undesired CHC-B2 fermentation component. High-throughput (HTP) screening of cultures grown on solid-phase fermentation plates and analysis using electrospray mass spectrometry was implemented to significantly increase screening capability. An aveC gene with mutations that result in a 4-fold improvement in the ratio of doramectin to CHC-B2 was identified. Subsequent integration of the enhanced aveC gene into the chromosome of the S. avermitilis production strain demonstrates the successful engineering of a specific biosynthetic pathway gene to significantly improve fermentation productivity of a commercially important product.     

阿维链霉菌bkdAB的基因中断对阿维菌素合成的影响

以阿维菌B组分菌株StreptomycesavermitilisBjbm0 0 0 6为出发菌株 ,用PCR的方法构建bkdAB基因簇(Branched_chainα_ketoaciddehydrogenasegeneAB)的基因置换质粒pHJ582 1(pHZ13 58∷bkdAB&erm) ,并对其进行基因中断 ,得到重组菌株Bjbm582 1。Bjbm582 1的发酵产物经HPLC检测发现 ,除了产生B1a和B2a外 ,还产生一种原菌株没有的新组分 ,3个组分的总含量只有出发菌株Bjbm0 0 0 6的 2 5%。结果表明bkdAB的中断不仅部分阻断了阿维菌素的合成 ,还阻断了阿维菌素b组分的合成 ,可以推测bkdAB的产物在阿维菌素合成途径中主要承担了α酮基异戊酸脱氢酶 (α_ketoisovalericaciddehydrogenase)角色     

Avermectin: biochemical and molecular basis of its biosynthesis and regulation

Avermectin and its analogues, produced by Streptomyces avermitilis, are major commercial antiparasitic agents in the field of animal health, agriculture, and human infections. They are 16-membered pentacyclic lactone compounds derived from polyketide and linked to a disaccharide of the methylated deoxysugar l-oleandrose. Labeling studies, analyses of the biosynthetically blocked mutants, and the identification of the avermectin gene cluster allows characterization of most of the biosynthetic pathway. Recent completion of S. avermitilis genome sequencing is also expected to help in revealing the precise biosynthetic sequence and the complicated regulatory mechanism for avermectin biosynthesis, which has been long-awaited to be elucidated. The well characterized avermectin biosynthetic pathway and availability of S. avermitilis genome information in combination with the recent development of combinatorial biosynthesis should allow us to redesign more potent avermectin analogues and to engineer S. avermitilis as a more efficient host for the production of important commercial analogues.     

Cloning and analysis of a DNA fragment stimulating avermectin production in various Streptomyces avermitilis strains

To isolate a gene for stimulating avermectin production, a genomic library of Streptomyces avermitilis ATCC 31267 was constructed in Streptomyces lividans TK21 as the host strain. An 8.0-kb DNA fragment that significantly stimulated actinorhodin and undecylprodigiosin production was isolated. When wild-type S. avermitilis was transformed with the cloned fragment, avermectin production increased approximately 3.5-fold. The introduction of this fragment into high-producer (ATCC 31780) and semi-industrial (L-9) strains also resulted in an increase of avermectin production by more than 2.0- and 1.4-fold, respectively. Subclones were studied to locate the minimal region involved in stimulation of pigmented-antibiotic and avermectin production. An analysis of the nucleotide sequence of the entire DNA fragment identified eight complete and one incomplete open reading frame. All but one of the deduced proteins exhibited strong homology (68 to 84% identity) to the hypothetical proteins of Streptomyces coelicolor A3(2). The orfX gene product showed no significant similarity to any other protein in the databases, and an analysis of its sequence suggested that it was a putative membrane protein. Although the nature of the stimulatory effect is still unclear, the disruption of orfX revealed that this gene was intrinsically involved in the stimulation of avermectin production in S. avermitilis.