Rapid engineering of the geldanamycin biosynthesis pathway by Red/ET recombination and gene complementation

Genetic manipulation of antibiotic producers, such as Streptomyces species, is a rational approach to improve the properties of biologically active molecules. However, this can be a slow and sometimes problematic process. Red/ET recombination in an Escherichia coli host has permitted rapid and more versatile engineering of geldanamycin biosynthetic genes in a complementation plasmid, which can then be readily transferred into the Streptomyces host from which the corresponding wild type gene(s) has been removed. With this rapid Red/ET recombination and gene complementation approach, efficient gene disruptions and gene replacements in the geldanamycin biosynthetic gene cluster have been successfully achieved. As an example, we describe here the creation of a ketoreductase 6 null mutation in an E. coli high-copy-number plasmid carrying gdmA2A3 from Streptomyces hygroscopicus NRRL3602 and the subsequent complementation of a gdmA2A3 deletion host with this plasmid to generate a novel geldanamycin analog.     

Reconstitution of the Myxothiazol Biosynthetic Gene Cluster by Red/ET Recombination and Heterologous Expression in Myxococcus xanthus

Although many secondary metabolites exhibiting important pharmaceutical and agrochemical activities have been isolated from myxobacteria, most of these microorganisms remain difficult to handle genetically. To utilize their metabolic potential, heterologous expression methodologies are currently being developed. Here, the Red/ET recombination technology was used to perform all required gene cluster engineering steps in Escherichia coli prior to the transfer into the chromosome of the heterologous host. We describe the integration of the complete 57-kbp myxothiazol biosynthetic gene cluster reconstituted from two cosmids from a cosmid library of the myxobacterium Stigmatella aurantiaca DW4-3/1 into the chromosome of the thus far best-characterized myxobacterium, Myxococcus xanthus, in one step. The successful integration and expression of the myxothiazol biosynthetic genes in M. xanthus results in the production of myxothiazol in yields comparable to the natural producer strain.     

Characterization of a methyltransferase involved in herboxidiene biosynthesis

The herboxidiene biosynthetic gene cluster contains a regulatory gene and six biosynthetic genes that encode three polyketide synthases (HerB, HerC and HerD) and three tailoring enzymes (HerE, HerF and HerG). Through single crossover recombination, an integrative plasmid was inserted into the genome of Streptomyces chromofuscus ATCC 49982 between herE and herF, resulting in low-level expression of herF and the downstream herG. The mutant strain produced two new compounds, 18-deoxy-25-demethyl-herboxidiene and 25-demethyl-herboxidiene. HerF was expressed in Escherichia coli and biochemically characterized as the dedicated methyltransferase in herboxidiene biosynthesis. It prefers 25-demethyl-herboxidiene to 18-deoxy-25-demethyl-herboxidiene, suggesting that C-25 methylation is the last tailoring step.     

A new method for rapid identification of ansamycin compounds by inactivating KLM gene clusters in potential ansamycin-producing actinomyces

Aims: In this study, we explored the possibility of construction of a ‘universal targeting vector’ by Red/ET recombination to inactivate L gene encoding 3‐amino‐5‐hydroxybenzoic acid (AHBA)‐oxidoreductase in AHBA biosynthetic gene cluster to facilitate the detection of ansamycins production in actinomycetes. Methods and Results: Based on the conserved regions of linked AHBA synthase (K), oxidoreductase (L) and phosphatase (M) gene clusters, degenerate primers were designed and PCR was performed to detect KLM gene clusters within 33 AHBA synthase gene‐positive actinomycetes strains. Among them, 22 KLM gene cluster‐positive strains were identified. A ‘universal targeting vector’ was further constructed using the 50‐nt homologous sequences chosen from four strains internal L gene in KLM gene clusters through Red/ET recombination. The L gene from nine of the KLM gene cluster‐positive actinomycetes strains was inactivated by insertion of a kanamycin (Km) resistance marker into its internal region from the ‘universal targeting vector’. By comparison of the metabolites produced in parent strains with those in L gene‐inactivated mutants, we demonstrated the possible ansamycins production produced by these strains. One strain (4089) was proved to be a geldanamycin producer. Three strains (3‐20, 7‐32 and 8‐32) were identified as potential triene‐ansamycins producers. Another strain (3‐27) was possible to be a streptovaricin C producer. Strains 24‐100 and 4‐124 might be served as ansamitocin‐like producers. Conclusions: The results confirmed the feasibility that a ‘universal targeting vector’ could be constructed through Red/ET recombination using the conserved regions of KLM gene clusters to detect ansamycins production in actinomycetes. Significance and Impact of the Study: The ‘universal targeting vector’ provides a rapid approach in certain degree to detect the potential ansamycin producers from the 22 KLM gene cluster‐positive actinomycetes strains.     

Intergeneric Conjugation in Streptomyces peucetius and Streptomyces sp. Strain C5: Chromosomal Integration and Expression of Recombinant Plasmids Carrying the chiC Gene

Intergeneric conjugal transfer of plasmid DNA from Escherichia coli to Streptomyces circumvents problems such as host-controlled restriction and instability of foreign DNA during the transformation of Streptomyces protoplasts. The anthracycline antibiotic-producing strains Streptomyces peucetius and Streptomyces sp. strain C5 were transformed using E. coli ET12567(pUZ8002) as a conjugal donor. When this donor species, carrying pSET152, was mated with Streptomyces strains, the resident plasmid was mobilized to the recipient and the transferred DNA was also integrated into the recipient chromosome. Analysis of the exconjugants showed stable integration of the plasmid at a single chromosomal site (attB) of the Streptomyces genome. The DNA sequence of the chromosomal integration site was determined and shown to be conserved. However, the core sequence, where the crossover presumably occurred in C5 and S. peucetius, is TTC. These results also showed that the C31 integrative recombination is active and the phage attP site is functional in S. peucetius as well as in C5. The efficiency and specificity of C31-mediated site-specific integration of the plasmid in the presence of a 3.7-kb homologous DNA sequence indicates that integrative recombination is preferred under these conditions. The integration of plasmid DNA did not affect antibiotic biosynthesis or biosynthesis of essential amino acids. Integration of a single copy of a mutant chiC into the wild-type S. peucetius chromosome led to the production of 30-fold more chitinase.     

Restoration of Gene Function by Homologous Recombination: from PCR to Gene Expression in One Step

We have developed a simple method for single-step cloning of any PCR product into a plasmid. A novel selection principle has been applied, in which activation of a drug selection marker is achieved following homologous recombination. In this method a DNA fragment is amplified by PCR with standard oligonucleotides that contain flanking tails derived from the host plasmid and the complete λP_R or rrnA1 promoter regions. The resulting PCR product is then electroporated into an Escherichia coli strain harboring both the phage λ Red functions and the host plasmid. Upon homologous recombination of the PCR fragment into the plasmid, expression of a drug selection marker is fully induced due to restoration of its truncated promoter, thus allowing appropriate selection. Recombinant plasmid vectors encoding β-galactosidase and neomycin phosphotransferase were constructed by using this method in two well-known Red systems. This cloning strategy significantly reduces both the time and costs associated with cloning procedures.     

Modification of human β-globin locus PAC clones by homologous recombination in Escherichia coli

We report here modifications of human β-globin PAC clones by homologous recombination in Escherichia coli DH10B, utilising a plasmid temperature sensitive for replication, the recA gene and a wild-type copy of the rpsL gene which allows for an efficient selection for plasmid loss in this host. High frequencies of recombination are observed even with very small lengths of homology and the method has general utility for introducing insertions, deletions and point mutations. No rearrangements were detected with the exception of one highly repetitive genomic sequence when either the E.coli RecA- or the lambdoid phage encoded RecT and RecE-dependent recombination systems were used.     

Characterization of a Large, Stable, High-Copy-Number Streptomyces Plasmid That Requires Stability and Transfer Functions for Heterologous Polyketide Overproduction

A major limitation to improving small-molecule pharmaceutical production in streptomycetes is the inability of high-copy-number plasmids to tolerate large biosynthetic gene cluster inserts. A recent finding has overcome this barrier. In 2003, Hu et al. discovered a stable, high-copy-number, 81-kb plasmid that significantly elevated production of the polyketide precursor to the antibiotic erythromycin in a heterologous Streptomyces host (J. Ind. Microbiol. Biotechnol. 30:516-522, 2003). Here, we have identified mechanisms by which this SCP2*-derived plasmid achieves increased levels of metabolite production and examined how the 45-bp deletion mutation in the plasmid replication origin increased plasmid copy number. A plasmid intramycelial transfer gene, spd, and a partition gene, parAB, enhance metabolite production by increasing the stable inheritance of large plasmids containing biosynthetic genes. Additionally, high product titers required both activator (actII-ORF4) and biosynthetic genes (eryA) at high copy numbers. DNA gel shift experiments revealed that the 45-bp deletion abolished replication protein (RepI) binding to a plasmid site which, in part, supports an iteron model for plasmid replication and copy number control. Using the new information, we constructed a large high-copy-number plasmid capable of overproducing the polyketide 6-deoxyerythronolide B. However, this plasmid was unstable over multiple culture generations, suggesting that other SCP2* genes may be required for long-term, stable plasmid inheritance.     

Genetic modification of the Streptomyces cholesterol oxidase gene for expression in Escherichia coli and development of promoter-probe vectors for use in enteric bacteria

Streptomyces cholesterol oxidase was produced in Escherichia coli by a modification of the cholesterol oxidase gene (choA′) in which the native codons for the precursor NH₂-terminal region and the ribosome binding site were substituted for those favored by E. coli. The choA′ gene was expressed under the control of the lac or tac promoter in a multiple copy plasmid vector, although no expression of the native choA gene from Streptomyces was observed in E. coli. E. coli cells carrying the plasmid, pCo117, produced 2-fold more cholesterol oxidase intracellularly during 18-h culture than did the producing strain of Streptomyces sp. SA-COO cultured for 4 d. The NH₂-terminal amino acid sequence of cholesterol oxidase produced by E. coli appeared to be processed between Ala²⁰ and Ala²¹ of the precursor enzyme, while the Streptomyces enzyme was processed between Ala⁴² and Asp⁴³. Based on the facts that the cholesterol oxidase was stable, could be assayed rapidly, and no endogenous cholesterol oxidase activity was found in any enteric bacteria, we developed two widely applicable, new promoter-probe vectors posessing the choA′ gene, multiple cloning sites, and either a low or high copy number plasmid. Since these plasmids can replicate in enteric bacteria, the new plasmid vectors have a great potential for use in enteric bacteria without the isolation of Cho⁻ mutants.     

Insights into an Unusual Nonribosomal Peptide Synthetase Biosynthesis: IDENTIFICATION AND CHARACTERIZATION OF THE GE81112 BIOSYNTHETIC GENE CLUSTER*

The GE81112 tetrapeptides (1–3) represent a structurally unique class of antibiotics, acting as specific inhibitors of prokaryotic protein synthesis. Here we report the cloning and sequencing of the GE81112 biosynthetic gene cluster from Streptomyces sp. L-49973 and the development of a genetic manipulation system for Streptomyces sp. L-49973. The biosynthetic gene cluster for the tetrapeptide antibiotic GE81112 (getA-N) was identified within a 61.7-kb region comprising 29 open reading frames (open reading frames), 14 of which were assigned to the biosynthetic gene cluster. Sequence analysis revealed the GE81112 cluster to consist of six nonribosomal peptide synthetase (NRPS) genes encoding incomplete di-domain NRPS modules and a single free standing NRPS domain as well as genes encoding other biosynthetic and modifying proteins. The involvement of the cloned gene cluster in GE81112 biosynthesis was confirmed by inactivating the NRPS gene getE resulting in a GE81112 production abolished mutant. In addition, we characterized the NRPS A-domains from the pathway by expression in Escherichia coli and in vitro enzymatic assays. The previously unknown stereochemistry of most chiral centers in GE81112 was established from a combined chemical and biosynthetic approach. Taken together, these findings have allowed us to propose a rational model for GE81112 biosynthesis. The results further open the door to developing new derivatives of these promising antibiotic compounds by genetic engineering.     

High-Efficiency Scarless Genetic Modification in Escherichia coli by Using Lambda Red Recombination and I-SceI Cleavage

Genetic modifications of bacterial chromosomes are important for both fundamental and applied research. In this study, we developed an efficient, easy-to-use system for genetic modification of the Escherichia coli chromosome, a two-plasmid method involving lambda Red (λ-Red) recombination and I-SceI cleavage. An intermediate strain is generated by integration of a resistance marker gene(s) and I-SceI recognition sites in or near the target gene locus, using λ-Red PCR targeting. The intermediate strain is transformed with a donor plasmid carrying the target gene fragment with the desired modification flanked by I-SceI recognition sites, together with a bifunctional helper plasmid for λ-Red recombination and I-SceI endonuclease. I-SceI cleavage of the chromosome and the donor plasmid allows λ-Red recombination between chromosomal breaks and linear double-stranded DNA from the donor plasmid. Genetic modifications are introduced into the chromosome, and the placement of the I-SceI sites determines the nature of the recombination and the modification. This method was successfully used for cadA knockout, gdhA knock-in, seamless deletion of pepD, site-directed mutagenesis of the essential metK gene, and replacement of metK with the Rickettsia S-adenosylmethionine transporter gene. This effective method can be used with both essential and nonessential gene modifications and will benefit basic and applied genetic research.     

Construction and Application of a Food-Grade Expression System for Lactococcus lactis

A food-grade host/vector expression system for Lactococcus lactis was constructed using alanine racemase gene (alr) as the complementation marker. We obtained an alanine racemase auxotrophic mutant L. lactis NZ9000Δalr by double-crossover recombination using temperature-sensitive integration plasmid pG⁺host9 and a food-grade vector pALR with entirely lactococcal DNA elements, including lactococcal replicon, nisin-inducible promoter PnisA and the alr gene from Lactobacillus casei BL23 as a complementation marker. By using the new food-grade host/vector system, the green fluorescent protein and capsid protein of porcine circovirus type II were successfully overexpressed under the nisin induction. These results indicate that this food-grade host/vector expression system has application potential as an excellent antigen delivery vehicle, and is also suitable for the use in the manufacture of ingredients for the food industry.     

An ‘instant gene bank’ method for gene cloning by mutant complementation

We describe a new method of gene cloning by complementation of mutant alleles which obviates the need for construction of a gene library in a plasmid vector in vitro and its amplification in Escherichia coli. The method involves simultaneous transformation of mutant strains of the fungus Aspergillus nidulans with (i) fragmented chromosomal DNA from a donor species and (ii) DNA of a plasmid without a selectable marker gene, but with a fungal origin of DNA replication (‘helper plasmid’). Transformant colonies appear as the result of the Joining of chromosomal DNA fragments carrying the wild-type copies of the mutant allele with the helper plasmid. Joining may occur either by ligation (if the helper plasmid is in linear form) or recombination (if it is cccDNA). This event occurs with high efficiency in vivo, and generates an autonomously replicating plasmid cointegrate. Transformants containing Penicillium chrysogenum genomic DNA complementing A. nidulans niaD, nirA and argB mutations have been obtained. While some of these cointegrates were evidently rearranged or consisted only of unaltered replicating plasmid, in other cases plasmids could be recovered into E. coli and were subsequently shown to contain the selected gene. The utility of this “instant gene bank” technique is demonstrated here by the molecular cloning of the P. canescens trpC gene.     

Point mutation of bacterial artificial chromosomes by ET recombination

Bacterial artificial chromosomes (BACs) offer many advantages for functional studies of large eukaryotic genes. To utilize the potential applications of BACs optimally, new approaches that allow rapid and precise engineering of these large molecules are required. Here, we describe a simple and flexible two-step approach based on ET recombination, which permits point mutations to be introduced into BACs without leaving any other residual change in the recombinant product. Introduction of other modifications, such as small insertions or deletions, is equally feasible. The use of ET recombination to achieve site-directed mutagenesis opens access to a powerful use of BACs and is extensible to DNA molecules of any size in Escherichia coli, including the E. coli chromosome.     

Streptomycetes: Surrogate hosts for the genetic manipulation of biosynthetic gene clusters and production of natural products

Due to the worldwide prevalence of multidrug-resistant pathogens and high incidence of diseases such as cancer, there is an urgent need for the discovery and development of new drugs. Nearly half of the FDA-approved drugs are derived from natural products that are produced by living organisms, mainly bacteria, fungi, and plants. Commercial development is often limited by the low yield of the desired compounds expressed by the native producers. In addition, recent advances in whole genome sequencing and bioinformatics have revealed an abundance of cryptic biosynthetic gene clusters within microbial genomes. Genetic manipulation of clusters in the native host is commonly used to awaken poorly expressed or silent gene clusters, however, the lack of feasible genetic manipulation systems in many strains often hinders our ability to engineer the native producers. The transfer of gene clusters into heterologous hosts for expression of partial or entire biosynthetic pathways is an approach that can be used to overcome this limitation. Heterologous expression also facilitates the chimeric fusion of different biosynthetic pathways, leading to the generation of “unnatural” natural products. The genus Streptomyces is especially known to be a prolific source of drugs/antibiotics, its members are often used as heterologous expression hosts. In this review, we summarize recent applications of Streptomyces species, S. coelicolor, S. lividans, S. albus, S. venezuelae and S. avermitilis, as heterologous expression systems.     

A Simple and Effective Method for Construction of Escherichia coli Strains Proficient for Genome Engineering

Multiplex genome engineering is a standalone recombineering tool for large-scale programming and accelerated evolution of cells. However, this advanced genome engineering technique has been limited to use in selected bacterial strains. We developed a simple and effective strain-independent method for effective genome engineering in Escherichia coli. The method involves introducing a suicide plasmid carrying the λ Red recombination system into the mutS gene. The suicide plasmid can be excised from the chromosome via selection in the absence of antibiotics, thus allowing transient inactivation of the mismatch repair system during genome engineering. In addition, we developed another suicide plasmid that enables integration of large DNA fragments into the lacZ genomic locus. These features enable this system to be applied in the exploitation of the benefits of genome engineering in synthetic biology, as well as the metabolic engineering of different strains of E. coli.     

Heterologous erythromycin production across strain and plasmid construction

The establishment of erythromycin production within the heterologous host E. coli marked an accomplishment in genetic transfer capacity. Namely, over 20 genes and 50 kb of DNA was introduced to E. coli for successful heterologous biosynthetic reconstitution. However, the prospect for production levels that approach those of the native host requires the application of engineering tools associated with E. coli. In this report, metabolic and genomic engineering were implemented to improve the E. coli cellular background and the plasmid platform supporting heterologous erythromycin formation. Results include improved plasmid stability and metabolic support for biosynthetic product formation. Specifically, the new plasmid design for erythromycin formation allowed for ≥89% stability relative to current standards (20% stability). In addition, the new strain (termed LF01) designed to improve carbon flow to the erythromycin biosynthetic pathway provided a 400% improvement in titer level. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 34:271–276, 2018     

Lambda Red Mediated Gap Repair Utilizes a Novel Replicative Intermediate in Escherichia coli

The lambda phage Red recombination system can mediate efficient homologous recombination in Escherichia coli, which is the basis of the DNA engineering technique termed recombineering. Red mediated insertion of DNA requires DNA replication, involves a single-stranded DNA intermediate and is more efficient on the lagging strand of the replication fork. Lagging strand recombination has also been postulated to explain the Red mediated repair of gapped plasmids by an Okazaki fragment gap filling model. Here, we demonstrate that gap repair involves a different strand independent mechanism. Gap repair assays examining the strand asymmetry of recombination did not show a lagging strand bias. Directly testing an ssDNA plasmid showed lagging strand recombination is possible but dsDNA plasmids did not employ this mechanism. Insertional recombination combined with gap repair also did not demonstrate preferential lagging strand bias, supporting a different gap repair mechanism. The predominant recombination route involved concerted insertion and subcloning though other routes also operated at lower frequencies. Simultaneous insertion of DNA resulted in modification of both strands and was unaffected by mutations to DNA polymerase I, responsible for Okazaki fragment maturation. The lower efficiency of an alternate Red mediated ends-in recombination pathway and the apparent lack of a Holliday junction intermediate suggested that gap repair does not involve a different Red recombination pathway. Our results may be explained by a novel replicative intermediate in gap repair that does not involve a replication fork. We exploited these observations by developing a new recombineering application based on concerted insertion and gap repair, termed SPI (subcloning plus insertion). SPI selected against empty vector background and selected for correct gap repair recombinants. We used SPI to simultaneously insert up to four different gene cassettes in a single recombineering reaction. Consequently, our findings have important implications for the understanding of E. coli replication and Red recombination.     

Sterptomyces rochei4089的L基因阻断变株的构建及功能研究

运用同源重组技术破坏了一株格尔德霉素产生菌Sterptomyces rochei 4089的L基因,该基因编码氧化还原酶.以Sterptomyces rochei 4089基因组总DNA为模板,PCR扩增AHBA-KLM基因簇,采取Red/ET重组技术,构建L基因阻断质粒pKC1139-KLM-KmR.采用大肠杆菌与链霉菌的结合转移将阻断质粒含AHBA-KLM基因簇和Kan表达单元的3.0 kb线性片段转化Sterptomyces rochei 4089菌株,在卡纳霉素的平板上筛选卡纳霉素抗性转化子,经PCR检测分离到L基因阻断突变菌株.对原、变株的发酵液进行TLC和HPLC分析显示,Sterptomyces rochei 4089基因组中的L基因失活后,导致该菌株不能合成安莎类抗生素格尔德霉素.通过阻断L基因,为筛查这类放线菌产生安莎类抗生素提供了明确的组分指示作用.